Information and Communication Technology for Disaster Risk Management in Japan How Digital Solutions are Leveraged to Increase Resilience through Improving Early Warnings and Disaster Information Sharing i ©2019 The World Bank International Bank for Reconstruction and Development The World Bank Group 1818 H Street NW, Washington, DC 20433 USA October 2019 RIGHTS AND PERMISSIONS The material in this work is subject to copyright. Because The World Bank encourages dissemination of its knowledge, this work may be reproduced, in whole or in part, for noncommercial purposes as long as full attribution to this work is given. Any queries on rights and licenses, including subsidiary rights, should be addressed to World Bank Publications, The World Bank Group, 1818 H Street NW, Washington, DC 20433, USA; e-mail: pubrights@ worldbank.org. CITATION Please cite the report as follows: World Bank. 2019. “Information and Communication Technology for Disaster Risk Management in Japan: How Digital Solutions are Leveraged to Increase Resilience through Improving Early Warnings and Disaster Information Sharing” World Bank, Washington, D.C. COVER IMAGE Disaster information collection drill using drones conducted by Kashihara City Government, Nara Prefecture (May 2015). Source: Kyodo News Images. Information and Communication Technology for Disaster Risk Management in Japan How Digital Solutions are Leveraged to Increase Resilience through Improving Early Warnings and Disaster Information Sharing Table of Contents Acknowledgement 1 Abbreviations 2 Executive Summary 4 1. Introduction 7 1.1 Why Japan? 9 1.2 ICT for DRM 10 1.3 Scope of This Report 12 2. Disasters and ICT Development in Japan: Historical Review 15 2.1 Natural Disasters in Japan 16 2.1.1 Disaster Types and Impacts 16 2.1.2 Major Policies and Institutional Framework for DRM in Japan 20 2.2 ICT Development in Japan 22 2.2.1 Definitions of ICT 22 2.2.2 High Level Technology Development in Japan 23 2.2.3 Major Policies and Institutional Framework for ICT Development in Japan 23 2.3 Historical Evolution and Utilization of ICT to Strengthen Disaster Resilience in Japan 26 3. Early Warning Systems 31 3.1 Early Warning Systems in Japan: Key Lessons 33 Systems Discussed 33 3.1.1 Key Lessons from the EWSs 34 3.1.2 3.2 Earthquake Early Warning Systems in Japan 36 3.2.1 Earthquake Early Warning System: Overview 36 3.2.2 Earthquake Early Warning System: Lessons and Recommendations 37 3.2.3 Earthquake Early Warning System: ICT Systems and Context 38 3.2.4 Earthquake Early Warning System: Enabling Environment 40 3.3 J-ALERT: Nationwide Instantaneous Warning and Alert System 42 J-ALERT: System Overview 42 3.3.1 J-ALERT: Lessons and Recommendations 43 3.3.2 J-ALERT: ICT Systems and Context 44 3.3.3 Enabling Environment 46 3.3.4 3.4 Emergency Alert Mail: Cell Broadcast Early Warning System 48 3.4.1 Emergency Alert Mail: System Overview 48 3.4.2 Emergency Alert Mail: Lessons and Recommendations 49 3.4.3 Emergency Alert Mail: ICT Systems and Infrastructures 50 3.4.4 Emergency Alert Mail: Enabling Environment 53 4. Multi-Hazard Disaster Information management Systems (DIMS) in Japan 55 4.1 DIMS Overview 58 4.1.1 Systems Discussed 58 4.1.2 Key Lessons 59 4.2 L-ALERT: Common Public Information System for Safety and Security 60 4.2.1 L-ALERT: System Overview 60 4.2.2 L-ALERT: Lessons and Recommendations 61 4.2.3 L-ALERT: ICT Systems and Context 62 4.2.4 Enabling Environment 65 4.3 GIS-Based DIMS 66 4.3.1 GIS-Based DIMS: System Overview 66 4.3.2 GIS-Based DIMS: Lessons and Recommendations 68 4.3.3 GIS-Based DIMS: ICT Systems and Context 69 4.3.4 Enabling Environment 72 4.4 Tokushima DIMS: Disaster Information Management System 74 4.4.1 Tokushima DIMS: System Overview 74 4.4.2 Tokushima DIMS: Lessons and Recommendations 76 4.4.3 Tokushima DIMS: ICT Systems and Context 78 4.4.4 Tokushima DIMS: Enabling Environment 81 4.5 K-DIS: DIMS for Utilities 82 K-DIS: System Overview 82 4.5.1 K-DIS: Lessons and Recommendations 83 4.5.2 K-DIS: ICT Systems and Context 84 4.5.3 K-DIS: Enabling Environment 85 4.5.4 4.6 Hyogo Asset Management System: DIMS for Infrastructure 86 4.6.1 Hyogo Asset Management System: System Overview 86 4.6.2 Hyogo Asset Management System: Lessons and Recommendations 87 4.6.3 Hyogo Asset Management System: ICT Systems and Context 88 4.6.4 Hyogo Asset Management System: Enabling Environment 91 5. Key Takeaways and Next Steps on ICT for DRM 93 Appendix of Additional Technical Details 99 Appendix A: High Level Technology Development in Japan: Historical Review 100 A.1 History of Earthquakes and ICT Development in Japan: 100 A.2. Comparison of JMA Intensity Scale 102 Appendix B: Earthquake Early Warning System 108 B.1 Examples of Application During Disaster Events 108 B.2 Earthquake Early Warning System: ICT Systems and Context 108 Systems and Infrastructures  108 Institutional Framework 113 B.3. Earthquake Early Warning System: Enabling Environment 114 Limitations of Earthquake Early Warning System 114 Appendix C: J-ALERT: Nationwide Instantaneous Warning/Alert System 116 C.1 Examples of Application During Disaster Events 116 C.2 J-ALERT: ICT Systems and Context 118 Systems and Infrastructures  118 Warning Types 120 C.3 J-ALERT: Enabling Environment 121 System Costs 121 Appendix D: Emergency Alert Mail (Cell Broadcast Early Warning System) 122 D.1 Examples of Application During Disaster Events 122 D.2 Emergency Alert Mail: ICT Systems and Context 123 Systems and Infrastructures  123 Warning Types 125 Appendix E: L-ALERT 126 E.1 Examples of Application During Disaster Events 126 E.2 L-ALERT: ICT Systems and Context 126 Systems and Infrastructures  126 Dissemination 128 Institutional Framework 129 Appendix F: GIS-based Disaster Management Information System 130 F.1 Examples of Application During Disaster Events 130 F.2 GIS-Based DIMS: ICT Systems and Context 131 Systems and Infrastructures 131 Institutional Framework 135 Appendix G: Tokushima Prefecture: Disaster Information Management System 136 G.1 Examples of Application During Disaster Events 136 G.2 GIS-Based DIMS: ICT Systems and Context 137 Systems and Infrastructures 137 Deployment 141 Institutional Framework 142 Appendix H: K-DIS: DIMS for Utilities 144 H.1 Examples of Application During Disaster Events 144 H.2 K-DIS: ICT Systems and Context 144 Systems and Infrastructures 144 Institutional Framework 147 Appendix I: Hyogo Asset Management System for Resilience: DIMS for Infrastructure 150 I.1 Hyogo Asset Management System: ICT Systems and Context 150 Systems and Infrastructures 150 Institutional Framework 154 References 156 Disclaimer This work is a product of the staff of The World Bank with external contributions. The findings, interpretations, and conclusions expressed in this work do not necessarily reflect the views of The World Bank, its Board of Executive Directors, or the governments they represent. The World Bank does not guarantee the accuracy of the data included in this work. The boundaries, colors, denominations, and other information shown on any map in this work do not imply any judgment on the part of The World Bank concerning the legal status of any territory or the endorsement or acceptance of such boundaries. The report reflects information available up to March 31, 2019. Acknowledgement This report was prepared by a World Bank team comprised of Shoko Takemoto, Naho Shibuya, Siou Chew Kuek, Alexander Ryota Keeley, and Lizzie Yarina. Primary and secondary data gathering was conducted by the Mitsubishi Research Institute (MRI). The report benefited from additional research and contributions by Robin Lewis and Yasuko Kusakari. Special gratitude is extended to the Japanese professionals and experts on early warning and disaster information management systems at national and local governments, utility companies, and universities that kindly provided primary data, information, analysis, and their invaluable perspectives and time. These include: Ministry of Internal Affairs and Communications (MIC); Fire and Disaster Management Agency (FDMA) of MIC; Ministry of Land, Infrastructure, Transport and Tourism (MLIT); Japan Meteorological Agency (JMA); Hyogo Prefectural Government, Department of Land and Infrastructure; Tokushima Prefectural Government, Crisis Management Department; Foundation for Multi-Media Communications (FMMC); The Japan Bosai Platform (JBP); Micro Media Disaster Information Network (MMDIN); Fujitsu Limited; Hitachi, Ltd.; The Kansai Electric Power Company, Incorporated; Mitsubishi Electric Corporation; NEC Corporation; Nippon Telegraph and Telephone Corporation (NTT); NTT DATA Corporation; Crisis Mappers Japan; and Aoyama Gakuin University. The report benefited from the guidance and contributions from the following Japanese experts: Professor Haruo Hayashi, National Research Institute for Earth Science and Disaster Resilience (NIED); Professor Isao Nakamura, Faculty of Sociology, University of Toyo; Ms. Kaori Kowada, Reconstruction Agency and GensaiInfo (NPO); Professor Norio Maki, Disaster Prevention Research Institute (DPRI), Kyoto University; Professor Taichi Furuhashi, Spatial Information, School of Global Studies and Collaboration, Aoyama Gakuin University. The team also acknowledges the valuable contributions from the World Bank peer reviewers, including: Ko Takeuchi, Koji Nishida, Keiko Saito, Makoto Suwa, Masatake Yamamichi, Naohisa Koide, and Satoshi Ogita. The team is also grateful for the support from Mika Iwasaki, Luis Tineo, Guillermo Siercke, Satoshi Imura, Thimali Thanuja Pathirana Batuwita Pathiranage, Reiko Udagawa, and Haruko Nakamatsu. Editorial services were provided by Pasquale Franzese. Lizzie Yarina designed the report. This report was prepared with support from the Japan-World Bank Program for Mainstreaming Disaster Risk Management in Developing Countries. 1 Abbreviations 3GPP 3rd Generation Partnership Project EWS Early Warning System AI Artificial Intelligence FAX Facsimile AMS Asset Management System FDMA Fire and Disaster Management Agency API Application Programming Interface FMMC Foundation for MultiMedia ASP Application Service Provider Communications BCP Business Continuity Plan GFDRR Global Facility for Disaster Reduction BC-SMS Broadcast SMS and Recovery bps Bits per second GIS Geographical Information System CAO Cabinet Office GPL GNU General Public License CAS Cabinet Secretariat GPS Global Positioning System CBS Cell Broadcast Service GSI Geospatial Information Authority of Japan CD-R Compact Disc-Recordable HDD Hard Disk Drive CMAS Commercial Mobile Alert System HTML Hyper Text Markup Language CMID Crisis Management Information Databank ICT Information and Communication Technology CSOs Civil Society Organizations ID Identification CTC Hyogo Construction Technology Center for Regional Development IDC Internet Data Center DA Digital Access IP Internet Protocol DID Densely Inhabited District IP-VPN Internet Protocol Virtual Private Network DMAT Disaster Medical Assistance Team J-ALERT Nationwide Instantaneous Warning/ DIMS Disaster Information Management Alert System System JBP Japan Bosai* (bosai: holistic DRM Disaster Risk Management approach to reduce disaster impact) EDXL Emergency Data Exchange Language Platform EEWS Earthquake Early Warning System J-LIS Japan Agency for Local Authority Information Systems EMIS Emergency Medical Information System JAMSTEC Japan Agency for Marine-Earth EOC Emergency Operations Center Science and Technology EPOS Earthquake Phenomena Observation JMA Japan Meteorological Agency System JMBSC Japan Meteorological Business ETWS Earthquake and Tsunami Warning Support Center System 2 DIGITAL SOLUTIONS FOR RESILIENCE JPY Japanese Yen PLUM Propagation of Local Undamped Motion JR Japan Railway Company JSDF Japan Self-defense Force PR Public Relations JWA Japan Weather Association PWS Public Warning System Kansai Kansai Electric Power Company R&D Research and Development L-ALERT Local Alert: Common public RFU Radio Frequency Unit information for safety and security RSS Rich Site Summary LAN Local Area Network SAR Synthetic Aperture Radar LASCOM Local Authorities Satellite SIP4D Sharing Information Platform for Communications Organization Disaster management LGWAN Local Government Wide Area Network SMS Short Message Service MHLW Ministry of Health, Labour and SNS Social Networking Service Welfare SOAP Simple Object Access Protocol MIC Ministry of Internal Affairs and Communications SOP Standard Operating Procedure MJ Ministry of Justice TS Technical Specification MLIT Ministry of Land, Infrastructure, TTL Task Team Leader Transport and Tourism TV Television MMDIN Micro Media Disaster Information UI User Interface Network UN United Nations MOE Ministry of the Environment UNISDR United Nations International Strategy MOFA Ministry of Foreign Affairs for Disaster Reduction MVNO Mobile Virtual Network Operator UPS Uninterruptible Power Supply NHK Nippon Hoso Kyokai (Japan URL Uniform Resource Locator Broadcasting Corporation) USB Universal Serial Bus NIED National Research Institute for Earth Science and Disaster Resilience USD US Dollar NTT Nippon Telegraph and Telephone USGS United States Geological Survey Corporation VPN Virtual Private Network O&M Operation and Maintenance WAN Wide Area Network OSM OpenStreetMap WS- Web Services Security PC Personal Computer Security PCXML Public Commons XML XML Extensible Markup Language 3 Executive Summary Scope Breakthroughs in information and communication technology (ICT) increasingly offer new tools to support disaster risk management (DRM). Due to the rapid advancement of computing and communication devices, ICT’s capacity to improve the DRM framework became a critical factor to strengthen resilience. As a nation with high levels of disaster risk and technological development, Japan has developed several forward-looking ICT for DRM. This report highlights the application of ICT for DRM in two specific areas: Early Warning System (EWS) and Disaster Information Management System (DIMS). The analysis of eight Japanese case studies of ICT solutions for DRM across various sectors, hazards, and levels of governance gives insight into their development, selection process and enabling environments, and provides case-specific lessons and recommendations. Purpose This report is intended as a reference tool for global DRM practitioners seeking to develop an enabling environment for applying ICT solutions toward resilience. The lessons learned from the Japanese case studies are intended to support practitioners and decision-makers in other countries to envision and explore ways to better leverage ICT to strengthen resilience. While valuable information can be extracted from the analysis, each case is contextualized within its particular social, political and environmental framework: our recommendations should be adapted to local needs and capacities. Early Warning Systems (EWSs) EWSs are integrated systems of hazard monitoring, forecasting and prediction, disaster risk assessment, communication and preparedness activities systems and processes that enable individuals, communities, governments, businesses and others to take timely action to reduce disaster risks in advance of hazardous events (United Nations, 2016). In Japan, EWSs were developed primarily for hydrometeorological or geological events. The following EWSs from Japan are discussed in Chapter 3: • Earthquake Early Warning System (EEWS) • J-ALERT: Nationwide instantaneous warning system • Emergency Alert Mail (EAM): a cell broadcast early warning system These 3 ICTs are part of a larger warning system ecosystem in Japan, in which each plays a well-defined and unique role. EEWS is an alert system based on seismic wave data recorded by seismometer stations. The data are immediately processed to calculate earthquake hypocenter, magnitude and intensity distribution, and warnings are issued seconds before an earthquake strikes, allowing individuals and organizations (e.g., Japan’s high-speed rail system) to take immediate actions. Earthquake early warnings are transmitted via J-ALERT and EAM. J-ALERT disseminates urgent warnings (for tsunamis, earthquakes, and ballistic missile attacks) via municipal disaster prevention radio receivers, broadcast media, and mobile phones. The mobile phone notifications are delivered via EAM, which sends disaster and evacuation information to mobile phones in warning areas. EEWS and J-ALERT are operated by Japan’s national government; EAM is provided as a free service by mobile phone carriers and was developed with their assistance. 4 DIGITAL SOLUTIONS FOR RESILIENCE Several lessons and recommendations have been developed from these cases: • Warning systems should be selected in accordance with the local ICT context; • Warning dissemination should be redundant and diverse; • Interoperability among relevant systems allows EWSs to build upon and work with existing systems; • Periodic education and training to officials and residents is important to respond quickly and effectively to early warnings. • Multi-functional for disaster and non-disaster times: EWSs that can be utilized in normal times will be more effective during a disaster. Disaster Information Management Systems (DIMSs) DIMSs are mechanisms for effectively processing, organizing, storing and disseminating information required for disaster response and recovery, particularly in the immediate aftermath of a natural disaster. In Japan there are various types of DIMSs which are differentiated by target hazards, key functions, actors involved, technologies utilized, and key information communicated. The following DIMS cases from Japan are discussed in Chapter 4: • L-ALERT Common Public Information for Safety and Security • GIS-based DIMS • Tokushima Prefecture DIMS • K-DIS: DIMS for Utilities • Hyogo Asset Management System for Resilience: DIMS for Infrastructure These DIMS cases reveal several lessons, the most important of which can be summarized as: • To ensure effective operations when a disaster strikes the legislation should clearly define the roles and procedures of relevant organizations, for example by implementing a Standard Operating Procedure (SOP) at multiple levels of government to clarify key roles and responsibilities. • Pre-disaster outreach and engagement with the system in order to familiarize with it increase the use and effectiveness of DIMS during a disaster. • DIMSs are more effective and affordable when they are based upon existing communication infrastructure and user contexts. 5 Image: Students hiding under their desks after receiving Earthquake Early Warning (disaster drill), conducted at Hanawaho Kichi Gakuen, Kawagoe City, Saitama Prefecture (Oct. 2012). Source: Kyodo News Images. [1] Introduction 1.0 Introduction Information and Communication Technology (ICT) provides new tools for challenges that many countries face in achieving sustainable and equitable development. ICT systems play a critical role in enhancing disaster and climate resilience: augmenting the capacities of people, communities, organizations, and nations to gather risk and damage information; enabling quick and meaningful analysis and communication; and offering innovative and effective technological tools, platforms, and systems to make disaster risk management and response more efficient. Across the globe, ICTs are now essential within all phases of Disaster Risk Management (DRM1)– i) Prevention and mitigation; ii) Preparedness; iii) Response; and iv) Rehabilitation, recovery and reconstruction. However, in a world of fast-paced digital innovations, the nexus of ICT and DRM is dynamic. While continuous development increases the possibilities to apply ICT to resilience, ICT users often face the paradox of choice; understanding the implications of one set of ICT solutions from an array of software and hardware options is often a complex task for DRM practitioners and decision-makers at national and local levels. Furthermore, limited information, technical capacity, and awareness can make it difficult to navigate the complex and fast-changing technologies necessary to create an enabling environment for effective and sustained use of ICT systems within DRM operations. These factors can represent significant barriers to fully access and utilize ICT systems, and benefiting from their potential to reduce and manage disaster-related risks more effectively. Recognizing the significant opportunities and challenges of utilizing ICT to strengthen resilience to natural disasters, this report draws upon practical examples of ICT solutions to DRM in Japan to help answering the following three questions: 1. Which ICT systems have a track record in reducing disaster risks, damages, and losses? 2. What are the key enabling environments that allow ICT to be used effectively and sustainably before, during, and after disasters? 3. How can the best available ICT be identified and applied to address disaster risks in the context of developing countries? This report is intended as a reference tool for global DRM practitioners and decision-makers seeking to develop or improve ICT strategies to strengthen resilience and to design, roll out, operate and maintain ICT systems for DRM. It presents a historical review of ICT development in Japan, and case studies of ICT solutions to DRM in Japan across various sectors, hazards, and levels of governance. Concluding remarks and several recommendations are also provided. Note that the cases from Japan are to be understood within their particular social, political and environmental contexts: any ICT for DRM strategy should be developed accounting for local needs and capacities. 1 “Disaster risk management most regularly refers to both disaster risk reduction (prevention, preparedness and mitigation) and humanitarian and development action (emergency response, relief and reconstruction).” (Schipper & Pelling, 2006). The term DRM is sometimes used interchangeably with Disaster Risk Reduction (DRR). However, DRR is the policy objective of disaster risk management, and its goals and objectives are defined in DRR strategies and plans. On the other hand, DRM is the application of DRR policies and strategies to prevent new disaster risk, reduce existing disaster risk and manage residual risk, contributing to the strengthening of resilience and reduction of disaster losses (UNISDR, 2017). 8 DIGITAL SOLUTIONS FOR RESILIENCE 1.1 Why Japan? Japan is one of the most technologically advanced countries in the world 2, and one of the most exposed to natural disasters, including earthquakes, tsunamis, volcanic eruptions, typhoons, rainstorms, flooding, landslides3, and snowstorms (Government of Japan, 2006). Faced with diverse and significant disaster risks, Japan has accumulated significant experience in recovering from diverse disaster impacts. Large-scale earthquakes, though less frequent than floods, have strongly impacted Japanese society. For example, in 1995 the Great Hanshin-Awaji Earthquake (magnitude4 7.3) caused six thousand deaths, and property damages of USD 100 billion (World Bank, 2011). In 2011, the magnitude 9.05 Great East Japan Earthquake (GEJE), one of the largest earthquakes ever recorded in the world, and the giant tsunami it triggered, devastated the northeastern coastal regions on the main island of Japan. The destruction included more than 17,500 fatalities and estimated economic damage of USD 210 billion (World Bank, 2012). The history of disasters in Japan is further discussed in Chapter 2. After each disaster Japan has channeled significant efforts to recover from extensive damages, prepare for and mitigate future risks by “building back better”, learning from response and risk reduction challenges to improve the design of ICT systems – often doing so through modernizing outdated and underperforming systems or adopting new technologies. Notably, such “post-disaster technology innovation” (Toya, 2014) has increased economic productivity in the long-run; a phenomenon which has been studied by various researchers (e.g., Akao and Sakamoto, 2013; Skidmore and Toya, 2002) indicating the opportunity for policymakers and stakeholders to rebuild infrastructures in more efficient and resilient ways. 2 Japan is ranked 10th out of 176 nations for ICT Development Index (ITU-D, 2017), and Networked Readiness Index (Dutta et. al., 2015). 3 Japan is ranked 37th out of 191 countries for Hazard and Exposure Risk Index (INFORM, 2017) 4 Measured in local magnitude (Mj). The two magnitude scales used by the Japan Meteorological Agency (JMA) to express the intensity of earthquakes are JMA magnitude (Mj) and moment magnitude (Mw). Mj is calculated from the maximum amplitude of seismic waves as observed by strong-motion seismometers recording strong motion with a period of up to around five seconds. As Mj information can be provided within around three minutes of an earthquake, it is suitable for the prompt issuance of warnings. See https://www.data.jma.go.jp/svd/eqev/data/en/tsunami/LessonsLearned_Improvements_brochure.pdf for more information. 5 Measured in moment magnitude (Mw) 9 1.2 ICT for DRM ICT plays a critical, yet complex role throughout the different phases of the DRM cycle, typically fulfilling operation and communication purposes (Ng, 2011). The role of ICT in DRM is further complicated by the myriad of ways that ‘ICT’ and ‘DRM’ are interpreted by various stakeholders. Current DRM strategies center around the four phases of the disaster management cycle (Adapted from ADRC, 2005): 1. Prevention and mitigation – Prevention indicates all activities and measures to avoid existing and new disaster risks; mitigation PREP AR N ED refers to the lessening or minimizing of the IO AT NE IG adverse impacts of a hazardous event (UNISDR, SS IT /M 2017). N TIO 2. Preparedness refers to all activities aimed at PREVEN DISASTER developing or improving the knowledge and capacities necessary to effectively anticipate, respond to and recover from the impacts of likely, imminent or current disasters. RE 3. Response, which “begins as a disaster occurs SP RY O N or is imminent” (Sylves, 2008), consists E SE COV of actions taken directly before, during or RE immediately after a disaster to save lives, reduce health impacts, ensure public safety and meet the basic subsistence needs of the people Figure 1-1 Disaster Risk Management Cycle. affected. (Adapted from ADRC, 2005) 4. Recovery, include all actions aimed at preventing additional losses by restoring governments and communities affected by a disaster. Figure 1-1 shows a schematic of the four phases of the DRM cycle. Although various definitions of ICT have been proposed6, there is an increasing consensus on considering ICT as a holistic system that includes aspects of technology (hardware and software) as well as activities and interactions performed in specific social and cultural contexts (“humanware7”). Sophisticated products have drastically enhanced the range and speed of communication and information exchange but also changed the types of information that are gathered and the ways in which they can be visualized and shared. As a result, ICT acquired a critical role to improve the DRM framework, and the ways in which ICTs are utilized for DRM are increasing and expanding. Table 1-1 presents examples of ICT utilization within the four phases of the DRM Cycle. 6 Definitions of ICT in Japan are elaborated in Section 2.2 7 For comprehensive explanations on the different views of ICT, refer to: Orlikowski and Iacono, 2001 10 DIGITAL SOLUTIONS FOR RESILIENCE Table 1-1: Examples of ICT Utilization within the Four Phases of the DRM Cycle. Highlighted areas are discussed in detail as individual cases within this report. Phase DRM Activities Example of ICT Applications in Japan Hazard Construction of DRM Application of computational methods and models to integrate disaster risk (seismic, Prevention Mitigation infrastructure flood, storm, etc) calculations into infrastructure design [IT] All Asset management of DRM Use of technology (UAVs, models, AI, etc) for critical infrastructure (i.e. roads, bridge, infrastructure utilities, etc) asset monitoring and management [IT] All Modernization of hydromet services through installation and management of automated weather stations (AWS), radars, satellite, cameras (permanent, helicopter, mobile), AI, etc. [IT] River monitoring through improved/real-time sensors, image processing , etc. [IT] Improving observation Tools and systems for climate and hydrology data, models, computation, analysis Storm, and collection of hazard (including AI) [IT]nstallation and management of automated weather stations (AWS), landslide, information radars, satellite, cameras (permanent, helicopter, mobile), AI, etc. [IT] flood, etc. Tools and systems for seismic monitoring (data gathering and analysis), communication (including underground sensors, cables, etc) and prediction (modeling, including machine learning) technology [IT] Earthquake Preparation and dissemination of hazard Tools to gather and analyze geospatial risk data (GIS, mapping tools, spatial data, maps mobile software/hardware, crowdsourcing technologies, open source, etc) [IT & CT] All Preparation of safety and evacuation information Data gathering and analysis software and tools for shelter and evacuee management Preparedness collection systems systems [IT] All Data gathering and analysis software and tools for risk information [IT] Typhoon, Risk communication tools (i.e. real-time river level, landslide risk levels, etc) [CT] landslide, Development of early Last mile communication tools (Radio, SMS, alert mail, internet, mobile phones, etc.) [CT] flood, etc warning systems Data gathering and analysis tools for risk information [IT] Last mile communication (fixed communication (telecom), alert mail, mobile phones, smartphones, internet, TV and radio (J-Alert), seismic warning receivers) [CT] Earthquake Emergency drills (SOPs EOC facility, communication/networks, local/national interoperability [IT & CT] and EOCs) & awareness Decision-support information systems (baseline and real-time data monitoring i.e. raising evacuation routes, critical infrastructure, damage assessment, etc) [IT & CT] SOP for ICT BCP [IT & CT] All Preparation of emergency kits Radio/backup communication tools [CT] All Food and material stockpiling Emergency supply database [IT] All Disaster risk insurance Data gathering, analysis, models to design insurance products based on risk [IT] All ICT BCP; relocation of crucial communication hardware, redundancy of key ICT Business continuity planning systems, digitalization/cloud storage/backup of key DRM info, etc.  [IT & CT] All Search and rescue Robots, sensors, satellite data, etc. [IT] ; Disaster message phone line [CT] All Incident report (real time data management system – i.e. EMIS/DMAT in Japan); First aid treatment medical supply monitoring/request software [IT & CT] All Evacuation GIS info/mobile application for evacuation center locations [IT] All Establishment of Disaster management information system for real-time data gathering and Emergency Operation visualization for decision-making; communication channels incident report database Centers [IT & CT] All Establishment and Response operation of evacuation Disaster management information system to update and communicate evacuees, center supply, services, etc [IT & CT] All Identification and distribution of relief Communication, disaster management information system to connect evolving supplies demand (needs at evacuation center) and supply (needs) [IT & CT] All Assessment, analysis, and communication of damage/ Disaster management information system integrating updated (real-time) information situation reports and response from image monitoring tools (drones, helisat, satellite image assessments). [IT plans, monitoring and warning Communication software (social media, media, and hardware (mobile phones, radio, of secondary disasters etc) [CT] All Utility and infrastructure recovery Disaster management information system [IT] All Disaster resilient Reconstruction Rehabilitation reconstruction and land use Risk communication and awareness raising through risk visualization/artificial reality Recovery planning [CT] All Assessment, analysis, and communication of status reports and reconstruction Data management and communication software (social media, media, and hardware plans/progress (mobile phones, radio, etc) [IT & CT] All Notes: [IT = Information Technology, CT = Communication Technology] [Sections highlighted with white text are covered by cases in this report] 11 Source: Developed by WB for this report including DRM measures information from ADRC, 2005; MIC, 2017a 1.3 Scope of This Report This report focuses specifically on the development and applications of ICT to early warning systems and disaster information management systems, drawing evidence-based information and lessons learned from experience in Japan. Additional examples of ICT for DRM are discussed in the following reports: “Information and communication technologies for disaster risk management in the Caribbean” (ECLAC, 2014); and “Building e-resilience: Enhancing the role of ICTs for Disaster Risk Management” (ESCAP, 2016). The Early Warning System (EWS) and Disaster Information Management System (DIMS) cases considered in this report are summarized in Table 1-2. Table 1-2 Case Studies of ICT Solutions in Japan included in this Report DRM Phase ICT System Example of ICT Applications in Japan Hazard All (incl. man- Preparedness J-ALERT: Nationwide Instantaneous Warning System [CT] made) EWS: Early Emergency Alert Mail (EAM): Cell Broadcast Early Warning All (incl. man- Warning System System [CT] made) Earthquake Early Warning System (EEWS) [IT & CT] Earthquake L-ALERT Common Public Information for Safety and Security All (incl. man- [IT & CT] made) GIS-based DIMS [IT] All (natural) Response DIMS: Disaster Information Management Tokushima Prefecture DIMS [IT] All (natural) System K-DIS: DIMS for Utilities [IT] All (natural) Hyogo Asset Management System for Resilience [IT] All (natural) Notes: [IT = Information Technology, CT = Communication Technology] The report describes the technical specifications and disaster usage of each case, and unveils the enabling environments which allowed the introduction, adoption, and sustainable use of the ICT systems before and/ or after disasters. 12 DIGITAL SOLUTIONS FOR RESILIENCE The report is organized into five chapters. Chapter 1 introduces the motivation and objectives of this study; the unique context of Japan and its relevance to exploring possible advancements of ICT for DRM globally; the framework of the nexus of ICT and DRM; and the specific areas investigated in this report. Chapter 2 illustrates the historical context of EWSs and DIMSs in Japan, highlighting the incremental development of ICT systems. Significant advancements have often been triggered by large-scale disasters, attempting to respond to challenges and incorporate lessons into future preparedness and response programs. Chapters 3 and 4 include specific examples of ICT applications within EWSs and DIMSs in Japan, respectively. For each case study the key enabling factors are identified, and recommendations are extracted to support practitioners and decision-makers in other countries designing or implementing a fit- for-purpose ICT for EWSs or DIMSs. Chapter 5 summarizes the key findings and takeaways, identifies areas that require further analysis and proposes next steps. INTRODUCTION 13 Image: Officials from MLIT and JMA checking how to utilize disaster information map obtained through DiMAPS (Sep. 2015). Source: Kyodo News Images. 14 [2] Disasters and ICT Development in Japan: Historical Review 2.0 Disasters and ICT Development in Japan: Historical Review Japan is an archipelago of more than 6,000 islands highly exposed to seismic, meteorological, and hydrological hazards. Its history is closely interwoven with its experiences of confronting natural disasters and the incremental efforts made to build back better from each catastrophic event. Simultaneously, Japan’s rapid and sustained socioeconomic development after the Second World War has been driven by significant advances in science and technology. At present, technology serves as a critical backbone of Japanese economic competitiveness. In light of this context, Japan’s history of DRM and technological innovation is fundamentally interrelated. 2.1 Natural Disasters in Japan 2.1.1 Disaster Types and Impacts Earthquakes are low-frequency but high-impact disasters that create Earthquakes (and tsunamis that are often widespread losses and damages associated with them) and floods8 are the two over a large geographic area. A major natural hazards that threaten Japan. They review of economic losses, poverty, had the highest rates of human losses reported and disasters (including climatic from disasters in Japan between 1993 and 2017, and geophysical) between 1998 followed by flood, as illustrated in Figure 2-1 and – 2017 by UNISDR highlights that Figure 2-2 (Government of Japan, 2018). while earthquake events accounted Figure 2-3 shows the probability of each point for only 7.8% of the total number of to be hit by an earthquake of seismic intensity disasters and 3% of the total number of 6-lower or more within 30 years. Typhoons, people affected between 1998 – 2017, heavy rains, and melting of snow (mostly in the earthquakes were the major cause of Northern part of Japan) are some of the main disaster-related fatalities, accounting causes of floods in Japan. Figure 2-4 presents for more than 56% (747,234) of the flood hazard map for a super typhoon hitting deaths caused by disasters globally Japan’s capital. Based on the worst-case scenario, between 1998 – 2017. Furthermore, like approximately a third of Tokyo’s 23 wards could other natural disasters, earthquake be at risk of being flooded by a storm surge. risks are not evenly distributed across geographic locations; most earthquakes are generated at boundaries where plates converge, diverge or move laterally past one another. The Pacific Ring of Fire – which refers to a 40,000 km path in the Pacific Ocean along which a continuous series of oceanic trenches, volcanic arcs, and volcanic belts and plate movements are concentrated – is known as one of the most active seismic zones on the planet; about 90% of the world’s earthquakes and 8 Japanese government adopts GLobal unique disaster IDEntifier number (GLIDE) for disaster information statistics reporting, and based on the associated tsunamis have historically GLIDE classification, floods in this report include: coastal flood; riverine occurred there. flood flash flood and; ice jam flood. 16 DIGITAL SOLUTIONS FOR RESILIENCE Great Hanshin-Awaji Earthquake Death toll: 6,437 Economic damage (direct): Approx. 10 trillion yen Great East Japan Earthquake Death toll: 22,199 Economic damage (direct): Approx. 17 trillion yen Niigata Prefecture Chuetsu Typhoon Talas, Roke, and Kumamoto Earthquake Earthquake Nigata/Fukushima Flood Death toll: 267 Death toll: 68 Death toll: 124 Economic damage (direct): Economic damage (direct): Economic damage (direct): 2.4 to 4.6 trillion yen Approx. 3 trillion yen Approx. 0.7 trillion Yen Typhoon Tokage and Nigata/ Fukushima Flood Death toll: 114 Economic damage (direct): Approx. 2.2 trillion Yen 1993 1994 1995 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015 2016 2017 Flood Earthquake and Tsunami Volcanic Eruption Heavy Snow Others Figure 2-1 Impacts of Natural Disasters in Japan: Death Tolls and Economic Damage9 by Year from 1993 - 2017 Source: Created based on Government of Japan, 2018 and e-Stat10 0.21% 0.35% 3.91% 4.97% Flood Earthquake and Tsunami Volcanic Eruption Earthquake and Tsunami, 90.57% Heavy Snow Others Figure 2-2 Impacts of Natural Disasters in Japan: Cumulative Death Tolls by Natural Hazards from 1993 – 2017 Source: Created based on Government of Japan, 2018 9 Economic damage (direct) refers to direct capital stock losses including loss and damages to critical infrastructure, public and private buildings including housing, etc. It does not represent total cost of reconstruction, nor indirect damages caused to the economy due to production losses resulting from infrastructure and supply chain disruptions. 10 Economic damage of flood events was obtained from e-Stat: https://www.e-stat.go.jp/stat-search/files?page=1&toukei=00600590 17 Figure 2-3 Probabilistic Seismic Hazard Map. (Adapted from JMA11) Note: Exceedance probability within 30 years considering all earthquakes (JMA seismic intensity: 6 Lower or more; average case; period starting Jan. 2010) Figure 2-4 Flood Hazard Map of Tokyo. (Adapted from Bureau of Port and Harbor, Tokyo Metropolitan Government12 ) Note: The flood hazard map is the worst-case flooding scenario created based on the scale of the 1934 Muroto Typhoon that made landfall in Muroto, Awaji Island and Kobe. 11 For more information, see: http://www.j-shis.bosai.go.jp/en/shm 12 For more information, see: https://www.kouwan.metro.tokyo.lg.jp/yakuwari/takashio/index.html 18 DIGITAL SOLUTIONS FOR RESILIENCE Earthquakes and floods have different frequency, magnitude of impacts, predictability, and lead time (i.e. the time between the warning and the occurrence of the event, that is available for people and systems to take actions for protection13). Earthquakes are less frequent than floods, but can have higher human and economic losses per event (See Figure 2-1). Since these two types of hazards are distinct in character, the measures for preparedness and response vary significantly. The first public earthquake early warning in Japan was issued as recently as 2007; while significant progress has been made since then in terms of timeliness and accuracy, earthquake warning capability and lead time are still very limited, with the lead time being usually a matter of seconds rather than minutes14. Flood prediction and warning on the other hand have a much longer history of implementation and improvement – today flood risks are normally detected and information is shared with high accuracy up to 5 days before the event, and warnings with higher accuracy are issued 3 to 6 hours before the event15. Tsunami Earthquake Primary Seismic Landslides Event South-coast Heavy Snow Cyclone & Northwest Seasonal Winds Heavy Rains River Floods Tropical Depression Strong Winds Urban Floods Typhoon Coastal Storm Surge Floods Primary Hydromet Event Secondary Hazard Hazard Event Impacts Figure 2-5 Major Natural Disasters in Japan: Typologies & Relationships of Natural Hazards and Impacts 13 Earthquake and tsunami hazards are also different in terms of their frequency, magnitude of impacts, predictability, and lead time. 14 At the time of the official launch of the system, the lead time was usually no more than few seconds. However, significant progress has been made throughout the system, including detection and analysis methods, and information distribution system. The improved system could provide lead times of more than 10 seconds, depending on the location of the epicenter. 15 See https://www.jma.go.jp/jma/kishou/know/bosai/warning.html for more information, provided by JMA [in Japanese] DISASTERS AND ICT DEVELOPMENT IN JAPAN: HISTORICAL REVIEW 19 Current and future directions for DRM in Japan are driven by the following disaster-related trends: • Heavy rain events (more than 80 mm rainfall per hour) are increasing and intensifying and the trend is expected to continue due to climate change16, suggesting that the magnitude and frequency of flood events are expected to increase. • Earthquakes risks are imminent and urgent: there is a high probability that high density economic and political centers in the Kanto and Kansai Regions will be affected by a large-scale earthquake in the near future17: in particular, the Government of Japan estimates the probability of an earthquake of magnitude 7 or more hitting the Tokyo metropolitan area at 70% in the next three decades18. Furthermore, Japan is also preparing for a 70% chance of a magnitude 8 to 9 quake, followed by tsunami, striking along the Nankai Trough (which extends southwest from the Pacific coast of central Japan) within the next 30 years19. A disaster of this magnitude has the potential to cause significant human and economic damage in the Kansai Region, with an estimated 1.4 quadrillion JPY in reconstruction costs over 20 years. 2.1.2 Major Policies and Institutional Framework for DRM in Japan Japan has incrementally developed various DRM policies and institutional frameworks over time, with adjustments made after each major disaster. The primary legal and institutional framework for DRM in Japan is the Disaster Countermeasures Basic Act (DCBA). The DCBA was adopted in 1961 following the Ise- wan Typhoon, which caused devastating damage and the loss of more than 5,000 people in 1959. The DCBA defines20: • Responsibilities of the citizens and the national, prefectural, municipal, and designated public authorities. • Institutional set up and organizational structure of national and subnational government required for disaster risk management before and after disasters (such as establishment of the Central Disaster Management Council and Disaster Management Headquarters, etc.). • Types of DRM plans at the national level, designated public authority and prefectural/municipal levels. • Efforts to promote preparedness and mitigation measures. • Financing mechanism of disaster countermeasures, directing the responsible national and local government entities to bear the cost of implementing designated countermeasures (responsible implementation body burden principle) except for extreme events designated by the Prime Minister of Japan, whereby additional national financing will be allocated by law. • Emergency response mechanisms, which establish that in times of an extraordinary disaster with serious and far-reaching repercussions for the national economy and public welfare, the Prime Minister may declare a state of emergency involving the whole or part of the affected area by issuing a Cabinet Notice of Disaster Emergency Situation. 16 For more information about the recent trends of flood events, see the Cabinet Office website at: http://www.bousai.go.jp/kyoiku/ hokenkyousai/suigai.html [in Japanese] 17 According to the Earthquake and Disaster-Reduction Research Division of Ministry of Education, Culture, Sports, Science and Technology (MEXT) 18 For more information on the long-term evaluations of probability of occurrence of earthquakes, see http://cais.gsi.go.jp/UJNR/6th/ orally/O01_UJNR_Dobashi.pdf 19 According to the Earthquake and Disaster-Reduction Research Division of Ministry of Education, Culture, Sports, Science and Technology (MEXT) 20 See http://www.bousai.go.jp/taisaku/kihonhou/pdf/kihonhou_gaiyou.pdf [in Japanese] 20 DIGITAL SOLUTIONS FOR RESILIENCE The DCBA clearly states that administrators of public organizations and of any relevant facility must endeavor to gather and transmit information related to disasters, as provided for by laws and regulations or under a disaster management plan. It also recommends the creation of a platform for disaster information sharing and enhancement of ICT to make use of multiple means of transmission. Furthermore, the DCBA outlines Japan’s Basic Principles for DRM, which are21: 1. In view of the natural characteristics of the country, always assume the imminent occurrence of a disaster, and in the event of a disaster take measures to minimize the damage and to recover promptly considering the constant changes in the population, the industry, and other socio- economic conditions. 2. Ensure appropriate role sharing and mutual cooperation between the national and local governments and other public institutions, and promote voluntary and diverse disaster prevention activities by residents, organizations and community groups, etc. 3. Prepare for disasters through a combination of appropriate measures and ensure continuous improvement based on scientific knowledge and lessons learned from past disaster experiences. 4. Appropriately distribute human resources, supplies and other necessary resources to prioritize protection of lives and physical wellbeing of people, by grasping the situation of the disaster as accurately as possible, even in difficult situations. 5. Take measures to protect disaster victims in consideration of their age, gender, disability, and other relevant factors, without impeding proactive measures implemented by disaster victims. 6. In the event of a disaster, promptly restore facilities and provide support to the victims for disaster recovery. The above policies and principles guide the development of the DRM approaches in Japan. However, DRM policies and institutional frameworks are compelled to continuously strengthen and advance by the frequency and severity of past natural disasters, as well as significant future risks. 21 See http://www.bousai.go.jp/kaigirep/kentokai/bousai_specialist/03/pdf/sankou4.pdf [in Japanese] DISASTERS AND ICT DEVELOPMENT IN JAPAN: HISTORICAL REVIEW 21 2.2 ICT Development in Japan 2.2.1 Definitions of ICT The definitions of ICT are diverse, complex, and evolving. In 2002, the World Bank Group defined key concepts related to ICT within its publication “Information and Communications Technologies: A World Bank Group Strategy” (World Bank, 2002) as summarized in Table 2-1. Table 2-1: Description of Key ICT Concepts ICT Terms Description Information Covers the underlying systems and stakeholders directly involved in or affected by and the production, delivery, and regulation of ICT products and services. It includes the Communication telecommunications and broadcasting sectors, as well as information technology (IT). Technologies Sector Information Consists of hardware, software, networks, and media for collection, storage, and processing, transmission, and presentation of information (voice, data, text, images). Communication Technologies Information Refers to the telecommunication and information networks through which information infrastructure is transmitted, stored and delivered, as well as the embedded technologies and knowhow. Types of networks include cellular, data, broadband, backbone, satellite, broadcasting, multimedia, the Internet, and other networks; they may be wireline, wireless, or a combination of both. Network components may include terrestrial wires, undersea cables, radio waves, satellites, towers, base stations, equipment (transmitters, repeaters, switches, routers), and related hardware and software. Networks may be independent, or interconnected and interoperable. Information Refers to the creation, storage and processing of data, including hardware technology (computer networks, servers, storage devices, and desktop computers), system software (operating systems, middleware, programming languages), and software applications. Applications Created using software tools; they can be standardized, customized, or custom- designed. IT applications serve multiple purposes, such as knowledge sharing (public administration, social services, and business solutions. Content The actual information and knowledge created by individuals and groups that may be processed, transformed and presented by information technology and carried through the information infrastructure (material on web sites or online library systems, news, video, etc.). Source: World Bank, 2002. Japan’s Ministry of Internal Affairs and Communication (MIC) highlights the two distinct types of ICT infrastructure: “ICT as Infrastructure” and “ICT for Infrastructure” (MIC, 2017b). Within DRM, the role of ICT is defined as “ICT for Infrastructure” whereby ICT systems and tools are utilized to strengthen relevant infrastructure for disaster mitigation, preparedness, and response. 22 DIGITAL SOLUTIONS FOR RESILIENCE Table 2-2: Types of ICT Infrastructure Type Description ICT as ICT that provides value as infrastructure, including hard ICT infrastructure, such Infrastructure: as physical ICT network functions (optical submarine cables, terrestrial digital broadcasting facilities, satellites, data centers etc.); and Soft ICT infrastructure, such as ICT services and platforms (IoT/AI platforms, cybersecurity related systems, big data related systems etc.) ICT for ICT used to enhance the value of existing infrastructure, and to support development Infrastructure: of new infrastructure. These include: i) Functional improvement, such as durability improvements and demand forecasting, of public infrastructure (e.g., roads, rails, aviation, etc.); and ii) Improvements in the activity content and environment for social infrastructure (e.g., Public administration, Agriculture, Education, Disaster prevention, Health and Medical care, etc.). 2.2.2 High Level Technology Development in Japan Japan is one of the leading countries in the development of high-level technology. One notable example is the early developments in optoelectronics, which produced important commercial products such as the optical fiber communications systems that revolutionized the communications sector. A survey conducted by Fortune Magazine in 1986 ranked22 Japan as the most advanced country in the field of optoelectronic research and development, followed by the US and West Europe; and the second most advanced country after the US in the following sectors: i) Computers, chips, and factory automation; ii) Life sciences; and iii) Advanced materials (Gene, 1986). Furthermore, early adoption of the key ICT elements for DRM, including TV, radio, fixed and mobile communication technologies, contributed to create the basis that enabled advanced use of ICT for DRM (for more information on the early adoption of ICT elements, see Appendix A). 2.2.3 Major Policies and Institutional Framework for ICT Development in Japan The development of ICT policies and institutions in Japan has been guided by: strategies and legal frameworks; radio, telecommunication and internet regulations; broadcasting rights and policies, information privacy legislation, and DRM development. The ICT legislations and strategies described in the following tables form the basis for existing ICT infrastructures in Japan. Table 2-3 discusses key legislations shaping the policy foundation for ICT in Japan, including ICT for DRM. Figure 2-6 describes more recent strategies for information technology (IT) in Japan, emphasizing a national agenda aiming at the development and adoption of cutting-edge IT. Figure 2-7 illustrates Japan’s institutional structure for IT implementation in general, including implementation of ICT for DRM: a strongly centralized hierarchy which enhances coordination between industries and institutions, facilitating ICT implementation. 22 Ranked by scholars, business executives, government officials, and foundation leaders DISASTERS AND ICT DEVELOPMENT IN JAPAN: HISTORICAL REVIEW 23 Table 2-3: Key ICT Legislations in Japan Legislation Description of the key legislations relevant to ICT for DRM Radio Act, 1950 Article 74 (1) When an emergency situation, including earthquakes, typhoons, floods, tidal waves, snow damage, conflagration, and riots, has occurred or is anticipated to occur, the Minister of Internal Affairs and Communications may order any radio station to conduct radio communications necessary for saving lives, for disaster relief, to ensure telecommunications for transportation, or to maintain public order. Article 74-2 (1) In case of emergency, the Minister of Internal Affairs and Communications must develop telecommunications plans, conduct telecommunications training, and take other necessary measures to maintain and improve the systems, and to ensure good communications as prescribed in paragraph (1) of the preceding Article (Article 74). Broadcast Act, 1950 Article 108 (Updated in 2010) If a windstorm, heavy rain, flood, earthquake, large-scale fire or other disaster occurs or is likely to occur while conducting domestic basic broadcasts, the basic broadcaster must transmit broadcasts which will serve to prevent such occurrence or mitigate such damage thereto. Telecommunications Article 8 (1) Business Act, 1984 When a natural disaster, accident or any other emergency occurs or is likely to occur, any telecommunications carrier shall give priority to communications on matters that are necessary for disaster prevention or relief efforts, for securing of transportation, communications or electric power supply, or for the maintenance of public order. The same shall apply to other communications that are specified by an Ordinance of the Ministry of Internal Affairs and Communications to be performed urgently for the public interest23. Basic Act on the Formation Article 25 of an Advanced Information and Telecommunications The Strategic Headquarters for the Promotion of an Advanced Network Society (IT Basic Information and Telecommunications Network Society (hereinafter Act), 2000 referred to as “the Headquarters”) shall be established under the Cabinet for the purpose of swiftly and thoroughly pursuing strategies to form an advanced information and telecommunications network society. Provider Liability Limitation Directed ISPs to establish a self-regulatory framework to govern take- Act, 2001 down requests involving illegal or objectionable content, defamation, privacy violations and copyright infringement. Source: Created based on MIC (2008) and; National Institute of Informatics (2012) 23 Based on the Telecommunications Business Act, privatization of NTT (Japan Telegraph and Telephone Corporation) occurred in 1985, and led to the expansion of the role of telecommunication sector in post disaster to private sector companies. 24 DIGITAL SOLUTIONS FOR RESILIENCE E- Japan Strategy | 2001 Development of broadband 2001 infrastructure 2003 By 2005, become an IT E- Japan Strategy II | 2003 country on the global Emphasis on IT utilization cutting edge 2006 New IT Reform Strategy | 2006 Advancing IT structural revolution By 2010, achieve a society where everyone can experience the benefits of IT at any time i - Japan Strategy 2015 | 2009 2009 Making digital technology benefits accessible to all The benefits of digital technologies for all A New Strategy in IT | 2010 2010 Establishment of a new society where the Achieve transition to a citizens hold IT sovereignty citizen-driven society and a true knowledge - information society Declaration to Become the 2013 World’s Most Advanced IT Nation | 2013 By 2020, become a Breaking dead lock and revitalize Japan’s country on the global economy by IT cutting edge of IT 2020 Figure 2-6: Japan’s Major IT Strategies: Historical Milestones. Adapted from METI (2015) PRIME MINISTER CABINET SECRETARIAT IT Strategic Headquarters Prime Minister IT Policy Minister Other Headquarters Government CIO Ministers MINISTRIES Reconstruction Ministry of Internal Ministry of Economy, Cabinet Office Agency Communications Trade, and Industry Figure 2-7: Institutional Structure for IT Policy Implementation in Japan. Adapted from METI (2015) DISASTERS AND ICT DEVELOPMENT IN JAPAN: HISTORICAL REVIEW 25 2.3 Historical Evolution and Utilization of ICT to Strengthen Disaster Resilience in Japan In line with the context of DRM and ICT in Japan described above, and drawing upon existing international discourse, within this report ICT for DRM is defined as: “The utilization of digital technologies for information and communication – consisting of hardware, software, networks, and media for collection, storage, processing, transmission, and presentation of information (voice, data, text, images, maps, etc.) – to enhance the resilience of existing infrastructure and systems in face of disaster risks and impacts.” In the context of Japan, ICT’s role within DRM has evolved and expanded significantly over time, particularly in the areas of pre-disaster early warning and post-disaster information management systems. The integration and utilization of ICT to enhance DRM capacity in Japan is the result of a dedicated and sustained effort. The development of ICT for disaster resilience has been a continuous process evolving over several decades, reflecting lessons learned from the various successes and challenges experienced in DRM and response. Placed at the heart of DRM policies and actions at all levels of governance, the evolution of ICT solutions for DRM in Japan has been shaped by various national and global drivers. Table 2-4 illustrates how diverse drivers have influenced the development of EWSs and DIMSs. In Japan, the advancement of ICT for DRM has been driven by three key factors: 1. Large scale disasters have led to in-depth analyses of the impacts and the identification of measures to avoid, reduce, and manage future risks. These activities have catalyzed various investments to develop and utilize new technologies and solutions, including ICT for EWS and DIMS. 2. Policy and legal frameworks are usually updated and enhanced after major disasters, reflecting the lessons learned and the identification of areas of improvement. They outline the national direction for research, development, and utilization of new information and communication technologies needed to improve disaster preparedness, prevention, mitigation, and response. By establishing legislation, subsidies, or incentives, these policies often catalyze private and public initiatives to implement ICT solutions with financial and technical support often induced by the government. 3. Existing and planned national and global ICT infrastructure investments and knowledge, as well as international standards for ICT and DRM, have significantly extended the range of ICT options available for DRM. The underlying ICT infrastructure and policy context, as well as global and local consumer trends, has also influenced how public and private sectors invest in EWS and DIMS solutions. Chapters 3 and 4 will detail how and why an earthquake EWS and a multi-hazard DIMS have been developed in Japan and will identify key success factors. Additional resources for hydromet and volcanic EWSs, which are outside of the scope of this report, are referenced in Table 2-4. 26 DIGITAL SOLUTIONS FOR RESILIENCE Table 2-4: Overview of Key Driving Factors of EWS and DIMS in Japan Key Driving EWS for EWS for EWS for Volcanic Multi-hazard Factors Hydrometeorological Earthquakes and Eruptions24 DIMS Events Tsunamis Disaster 1959 Typhoon Vera 1995 Great 2000 Mount Usu 1995 Great triggering (Isewan Typhoon) Hanshin Awaji and Sakurajima Hanshin Awaji major Earthquake Eruptions Earthquake development Disaster Any major disaster Any major disaster Any major disaster Any major triggering events events (i.e. 2011 events disaster events system Great East Japan (i.e. 2011 Great review and Earthquake East Japan improvement and Tsunami; Earthquake 2016 Kumamoto and Tsunami; Earthquake) 2016 Kumamoto Earthquake) Policy River Law (1964, Meteorological Meteorological Disaster and Legal 1997 update) and Service Act Update Service Act Update Countermeasures Frameworks Meteorological (2007) (2007). Act on Basic Act (1961). Service Act (1952, Special Measures Expert Panel 2007 update) for Active on Disaster Volcanoes (1973, Information 2015 update) Sharing (2002) within the Central Disaster Management Council. Basic Act on the Advancement of Utilizing Geospatial Information (2007) 24 Volcanic eruption observation was initiated in 1974 at Mount Usu. Development of the modern system was driven largely by the large-scale eruption that occurred in 2000. For more information, see: http://data.nistep.go.jp/dspace/bitstream/11035/2010/1/NISTEP- STT094-20.pdf DISASTERS AND ICT DEVELOPMENT IN JAPAN: HISTORICAL REVIEW 27 ICT Observation: Observation: Observation: Geospatial: US Infrastruc- Japanese Seismic waves (S Seismic, tilt, satellite-based ture Con- Geostationary and P waves) Electronic Distance Global Positioning texts Meteorological Analysis: Measurement, System27; Quisi- Satellites Himawari-1 Integrated Particle meteorological, Zenith Satellite Filter (IPF) method summit crater, to Himawari-9, Mobile: High using point-source video recording weather radar and of volcanic plume, smartphones AMeDAS, etc. (World models and Propagation of etc.25 and mobile Bank, 2017) penetration rates. Local Undamped Analysis: Analysis: Continuous Motion (PLUM) observation Disruptive: IoT, development of NWP method (JMA, data processing AI, Big Data, models since 1959. 2015; Kodera et al., software (i.e. wearable (World Bank, 2017) 2018) MaGCAP-V devices, social Communication: software, SAR, Communication: etc)26 media and Mobile, TV, radio Mobile, TV, radio applications, etc. (temporary disaster (temporary Communication: (MIC, 2017c) disaster Mobile, TV, radio broadcasting broadcasting (temporary stations / Community stations / disaster radio / municipal Community radio / broadcasting disaster prevention municipal disaster stations / radio communication prevention radio Community radio / network), internet, communication municipal disaster etc. network), internet, prevention radio etc. communication network), internet, etc. Additional World Bank report JMA Resources JMA Resources for 2018 White Paper Resources on “Modernization for Current Current Volcanic of Disaster of Japan’s Hydromet Earthquake [ EWS [ http://www. Management Services” (World http://www.jma. data.jma.go.jp/svd/ in Japan Bank, 2017) go.jp/en/quake/ ] vois/data/tokyo/ (Government of and tsunami EWS STOCK/kaisetsu/ Japan, 2018) [ http://www.jma. English/level.html ] go.jp/en/tsunami/ ] Source: Created based on Government of Japan (2002); JMA (2015); Kodera et al. (2018); MIC (2017c); World Bank (2017) 25 For more information, see: http://www.wovo.org/0803_11.html 26 For more information, see: http://www.mri-jma.go.jp/Research/evaluation/Assignment/assign_2006_09.htmlhttp://www.mri-jma. go.jp/Research/evaluation/Assignment/assign_fy2013_30.html 27 For more information, see: http://www.mlit.go.jp/common/001036025.pdf 28 DIGITAL SOLUTIONS FOR RESILIENCE 29 Image: People in Osaka checking Emergency Alert Mail for Nankai Trough earthquake (training alert) (Sep. 2012). Source: Kyodo News Images. [3] Early Warning Systems 31 3. Early Warning Systems Early Warning System: An integrated system of hazard monitoring, forecasting and prediction, disaster risk assessment, communication and preparedness activities systems and processes that enables individuals, communities, governments, businesses and others to take timely action to reduce disaster risks in advance of hazardous events. (United Nations, 2016) Early warning systems (EWSs) are designed to communicate risk information quickly and effectively to mitigate losses by taking timely actions. In Japan, there are two major types of EWSs: i) hydrometeorological events (heavy rain, strong winds, storm surges, high waves, snow storms, and heavy snow); and ii) geological events (earthquakes, tsunamis and volcanic eruptions28). The EWSs vary in terms of functions, actors involved, technologies utilized, and information communicated. Table 3-1 presents a brief description of these characteristics, along with parameters of success and factors of success of EWSs. Figure 3-1 shows a conceptual diagram illustrating the EWS process and the objectives to be pursued to enhance the system: the risk information is acquired, processed and communicated to municipalities and private sector actors, which disseminate it to utilities, critical infrastructures, people and institutions. Efforts to enhance the system focus on: i) shortening the lead time (the time between the acquisition of risk information at the source and delivery to the final recipient); and ii) expanding the reach (the number of recipients) by diversifying the dissemination channels. Table 3-1: ICT for Early Warning Systems: Key Features Functions: Hazard monitoring, forecasting and prediction, disaster risk assessment, communication and preparedness activities Actors: Warning issuer, warning communicator, and warning recipient (national govern- ment, local government, utilities and firms, citizens) Hardware, such as measuring instruments, computers, servers and communica- Technology: tions equipment, and software for data collection, forecasting and prediction, assessment, and communication. Information: Lead time, risk level, predicted impact, evacuation (shelter) information, and other precautionary info. Parameters of Speed / lead time, accuracy and validity of information, reach (number and types success: of channels and recipients), ease of decision-making / action, pre-programmed / automatic, etc. Factors of Multi-channel, redundancy, private sector engagement, coordination through law success: and SOP 28 For more information, see: https://www.jma.go.jp/jma/kishou/know/tokubetsu-keiho/kizyun.html [in Japanese] 32 DIGITAL SOLUTIONS FOR RESILIENCE Figure 3-1: Conceptual EWS Diagram: ICT for EWS Shorten time between source risk info to recipient Diversify information dissemination channels Expand reach / recipients of risk information Utilities & Critical Infrastructures Municipalities Risk Information Earthquake, typhoons, floods, volcano, etc. Private Sector Mobile Companies, TV, Radio, Internet, etc Recipient of Risk Information: People & Institutions DIMS 3.1 Early Warning Systems in Japan: Key Lessons Private Sector Mobile Companies, 3.1.1 Systems Discussed TV, Radio, Internet, etc This section discusses the following EWS case studies from Japan: disaster impact and response information Expand sources, types and quality of Expand reach and ease of access by recipients of disaster information • The Earthquake Early Warning System (EEWS) creates earthquake warnings seconds before Hub for an earthquake strikes, allowing individuals Disasterand organizations to take immediate actions. The Utilities & Critical Information earthquake warnings are transmitted via J-ALERT [Municipal and Emergency Alert Mail. Infrastructures Government] • J-ALERT is a nationwide instantaneous warning system which disseminates urgent warnings nationwide (including tsunami early warnings, earthquake early warnings, and ballistic missile attack alerts) to people in impacted communities via municipal disaster prevention radio stations, broadcast media, and mobile phones. Sources of Disaster Impact & Response Information • Emergency Alert Mail (EAM) is a cell broadcast early warning system which delivers J-ALERT Institutions and other warnings via mobile phone notifications. This free service offered by mobile carriers disseminates disaster and evacuation information to mobile phones in warning areas. Recipient of Risk Information: People & Institutions These three ICTs work together as part of a larger warning ecosystem in Japan, where each plays a unique role. The EEWS generates warnings, J-ALERT disseminates alerts via multiple communication systems, and EAM transmits J-ALERT warnings directly to mobile phones. The EEWS and J-ALERT are operated by Japan’s national government; EAM is provided by private mobile phone carriers and was developed with their assistance. 33 3.1.2 Key Lessons from the EWSs Suitability - Hardware and software for EWSs should be selected taking into account the existing and planned ICT specific to the country and its institutions. Japan’s initial EWS was radio-based because at the time of its development in 1985 (Ito, 2007), radio was the most reliable, far reaching, and low- cost technology available for broadcasting warnings. Today, Japan is adapting its EWSs to integrate new ICT (e.g., mobile phones). If an EWS were to be designed from scratch today, it would look very different given the advances in national and global ICT. Redundancy - Redundant and diverse warning dissemination ensures reach, reliability and resilience: Japanese EWSs use multiple means of transmission. Earthquake early warnings can be transmitted via mobile operators, broadcasters, and J-ALERT. In turn, J-ALERT warnings are primarily disseminated through Disaster Administrative Radios Systems in municipalities, but the system is also linked to EAM via mobile operators, as well as television and radio networks via broadcasting companies. Likewise, use of redundant ICT infrastructures, such as multiple communication lines between public organizations and the Japan Meteorological Agency (JMA) with EAM, and communication from FDMA to municipalities duplicated by satellite and terrestrial lines with J-ALERT, ensures backup in case the primary systems fail during a disaster. Standardization - Standardizing alert warning sounds can reduce confusion and improve the reaction times of the recipients. In the case of J-ALERT, alert warning sounds from various media including TV, Disaster Prevention Radios, community FM, and mobile phones, are standardized for each type of disaster. The most effective auditory warnings can be defined by the local cultural context; otherwise, it is advisable to adopt existing standards to promote global standardization. Interoperability - Interoperability among systems allows EWSs to build upon and work with existing systems, expand and adapt to new requirements, and securely disseminate warnings via multiple systems. Interoperability is ensured by well-defined protocols which should be made public. For example, the standard specifications for J-ALERT receivers in municipalities and trigger controllers of Disaster Administrative Radios Systems were developed by a national agency (Fire and Disaster Management Agency), which benefited from the collaboration of major developers. Preparedness - Periodic education and training help officials and residents to respond quickly and effectively to early warnings. The preparedness goals are: i) clearly understand the warning messages and know in advance the actions to be taken (in the case of an earthquake, the recipient has only a few seconds to act). In Japan, very high levels of awareness and understanding of the system were achieved as a result of extensive public awareness campaigns. For example, a Disaster Prevention Day was established in 1960 to commemorate the 1923 Great Kanto earthquake and since then most of the prefectural and municipal governments, schools, and private companies have been conducting disaster drills every year on that day. The Japanese government has made large efforts to promote development of Business Continuity Plans29 (BCPs) in the ICT sector of local governments to enhance preparedness and enable actions in response to alerts. A BCP specifies the methodologies and procedures required for managing risks, emergencies, and recovery of an organization during a crisis and ensuring the return to normal business operations (Doughty, 2000). Examples of BCP for ICT at prefectural and municipal governments include establishment of emergency response teams upon reception of an EWS alert. As of 2018, 93.6 % of the prefectural governments and 27.5% of the municipal governments have ICT-BCP (MIC, 2019). 29 BCP have been mainly developed since 2008, when development guidelines in the ICT sector of local governments were developed by MIC. 34 DIGITAL SOLUTIONS FOR RESILIENCE 35 3.2 Earthquake Early Warning Systems in Japan 3.2.1 Earthquake Early Warning System: Overview An advanced earthquake warning of even just a few seconds can be enough to allow the residents to take shelter, and critical facilities to take often life-saving preemptive measures. The Earthquake Early Warning System (EEWS) is an alert system operated by JMA which sends out earthquake information immediately after an earthquake occurs. Based on seismic wave (P-wave) data obtained by seismometer stations, the EEWS calculates the hypocenter, magnitude and distribution of earthquake intensity30 over the territory, and sends out an alert to residents and visitors (commuters, students, temporary residents, and others) in designated areas a few seconds before they are hit by the earthquake. Since an electric signal, which travels at about 300,000 kilometers per second, is much faster than a seismic wave, which travels at several kilometers per second, it can convey a warning before the ground starts shaking. Resiliency of the EEWS is enhanced by backup satellite communication lines to ensure successful data transfer from seismometers to receiver units. The organizations involved in the process are equipped with backup power supplies in case of a blackout. Multiple communication channels are used to extend the reach, including voice via the Disaster Prevention Radio Communication Network, text and sound via EAM on mobile phones and smartphones, and in-house announcements in department stores and companies. Although the EEWSs provide warnings only a few seconds before the event, they have Organizations Japan Meteorological Agency been prototyped in at least 7 other countries adopting this (JMA) solution (including China, Italy, Mexico, Romania, Taiwan, Beneficiaries People in designated areas who Turkey, and US), all of which have in common (Recipients of have access to alert receiving urban centers exposed to high earthquake risks, early warnings) devices (i.e. TV, mobile phones, and experiences of devastating earthquakes (see household receivers), municipal Appendix Table B.2.1). governments and private companies with Dedicated Receivers System NEC Corporation Ltd. Developers Year of Launch October 2007 Costs Development cost: About JPY 1.1 Billion Operation and maintenance cost: About JPY 280 Million/ year. Source: Developed by the authors based on Takano (2018) and inputs from JMA 30 In JMA, employees previously estimated seismic intensity from experience and surrounding circumstances, but since 1996 it has been estimated automatically based on data observed by seismic intensity meters. For more information, see: http://www.jma.go.jp/ 36 jma/kishou/know/shindo DIGITAL SOLUTIONS FOR RESILIENCE 3.2.2 Earthquake Early Warning System: Lessons and Recommendations The system resilience is enhanced by: • Reliability - Internet Protocol Virtual Private Network (IP-VPN) and stable power supply to seismometers and communication units are indispensable to achieve continuous real-time data transfer for the EEWS. • Redundancy - Satellite communication lines are employed as backups to ensure data transfer from seismometers to the receiver unit at JMA in the case of a blackout, and the organizations involved are equipped with backup power supplies. • Complementarity - All warning systems have limitations: complementary systems should be implemented to fill potential gaps. • Risk management - The EEWS is effective mainly in areas far from the hypocenter; seismic risk management strategies should be implemented, such as: • Appropriate building standards and land-use management; • Awareness raising, evacuation procedures and safe suspension of hazardous work and operations; • Mitigation strategies for infrastructure and plants unable to shut down rapidly. • Clarity – Clear warning messages are critical in crowded areas to ensure safe evacuation procedures, in areas close to the hypocenter to minimize the reaction time, and in areas where multiple earthquakes occur concurrently31, where the system may become inaccurate. To mitigate these issues, JMA launched intense outreach activities to raise awareness of the EEWS and its capability. • Accuracy – To ensure continuous technological and operational improvements JMA has operated the “Committee for improving the technology and operation of EEWS” since 2009. The committee promotes technological developments to upgrade existing methods and develop fundamentally different ones32. • Interagency communication – Effective operation of the EEWS requires cooperation between organizations that carry out seismic observations (JMA and the National Research Institute for Earth Science and Disaster Resilience (NIED) in the case of Japan) and those that transmit information (telecommunications companies etc.). 31 For example, on January 5, 2018, seismic intensity was overestimated because two consecutive earthquakes were detected as one earthquake and therefore, an erroneous earthquake early warning was released. 32 For example, in the past, seismic intensity at each location was estimated after estimating the position and magnitude of the hypocenter based on data from a few observation points. In 2011, strong shakes off the Pacific coast of Great East Japan Earthquake could not be accurately predicted far from the hypocenter by the conventional method. However, with the new method (PLUM: Propagation of Local Undamped Motion), seismic intensities at given points can be estimated without estimating the hypocenter. JMA improved the accuracy of predictions by hybridizing these two methods and then updated the Earthquake Early Warning System. Operation by this hybrid method began in March 2018, and the first warning using this method was announced at the time of Shimane prefecture earthquake on April 9, 2018. 37 3.2.3 Earthquake Early Warning System: ICT Systems and Context Systems and Infrastructures The alert process starts when a NIED or JMA seismometer close to the epicenter senses the first vibration, corresponding to the faster P-waves, followed by the slower, larger amplitude S-waves. The hypocenter, magnitude, seismic intensity and arrival time of the S-waves are calculated just after the first detection of the P-waves by a computing system owned by JMA. Initially, only data from a single seismometer station are processed within a few seconds. Then, accuracy is enhanced by adding data from a few more stations. When the calculated maximum intensity is at level 5-Lower or greater on the Japanese seven-stage seismic scale (See table A.2. for comparison of various seismic intensity scale), an emergency earthquake early warning is sent out in the areas of anticipated intensity level 4 or more via J-ALERT33, EAM, the Disaster Prevention Radio Communication Network, and other tools34. Seismometer JMA JMA The seismometer estimates the position and the scale of the epicenter instantaneously, and Earthquake early warning is predicts the seismic intensity and the arrival announced before the S-wave S-Wave P-Wave time of the S-wave S-Wave P-Wave (strong tremors) arrive. Figure 3 ‑2 Overview of the EEWS Source: Based on “Overview of Earthquake Early Warning System,” [in Japanese], JMA: http://www.data.jma.go.jp/svd/eew/data/nc/ shikumi/shikumi.html Note: Seismic intensities35 announced by JMA are values observed using a seismic intensity meter installed. It may vary even within the same city. It is a scale of 1 to 7, with 5 and 6 each divided into “lower” and “upper.” Then, the calculated information is sent to relevant organizations such as mobile carriers, broadcasters, and municipalities that disseminate earthquake early warnings. The EEWS is described in the figure below; for a detailed description of components, see Appendix B.2. Institutional Framework The EEWS requires an extensive network of seismometers: in Japan, more than 1,000 seismometers are installed nationwide, at distances of approximately 20 km from each other36. The seismometers are owned and maintained by JMA and NIED37. 33 J-ALERT is a system to instantaneously transmit information on situations where there is no time to deal with such as ballistic missile information, tsunami information, and earthquake early warnings from the national government (Cabinet Secretariat/JMA via FDMA) to residents. The Earthquake Early Warning System instantaneously transmits warnings to residents using J-ALERT and EAM. 34 For an overview of the Warning System’s calculation process, see Appendix Figure B.2.1. 35 Based on JMA’s definition of “Seismic Intensity Scale”. For more information, see: http://www.jma.go.jp/jma/en/Activities/inttable.html 36 For a map of seismometer locations in Japan, see Appendix Figure B.2.2. 37 For a detailed description of Organizations and their roles related to the Earthquake Early Warning System, see Appendix Table B.3. 38 DIGITAL SOLUTIONS FOR RESILIENCE SENSOR NETWORK OBSERVATION & ANALYSIS DISSEMINATION USERS IN WARNING SYSTEM SYSTEM AREAS [12] Mobile Phone Networks [8] Digital Access Network [13] Broadcasting Networks [1] Seismometers (JMA) [14] Disaster Management [9] Mobile Phone Radio Communication Networks Networks [3] Receiver [4] Analyzing Unit Unit [5] General Communication [2] Seismometers [7] EPOS Software Devices (NIED) JMA [10] Satellite Communication Lines BUSINESS OPERATORS Authorized Organizations JMBSC EEW: Earthquake Early Warning of Forecast Operation An EEW is transmitted when an earthquake is detected at more than two observation points and its intensity is projected to be [15] Internet [6] Dedicated higher than “5- Lower.” Receivers Figure 3‑3 System Diagram Source: Based on World Bank (2017); material of JMA: http://www.data.jma.go.jp/svd/eew/data/nc/shikumi/shikumi.html; and material provided by NEC Corporation Ltd. [1] JMA [3] Mobile carriers [8] People in Warning Areas • Installs and maintains • Provide the communication seismometers lines free of charge to transfer the earthquake early • Sends seismic data warning to communication • Installs and maintains the devices such as mobile automatic calculation system phones. • Improves the calculation EARTHQUAKE algorithms for accuracy enhancement [4] Broadcasters • Transmits an earthquake • Broadcast the earthquake early warning when an early waning on TV or radio earthquake is detected at more than two observation points and its intensity is • Upon receiving the projected to be higher than [5] Municipalities information, they take seek “5 Lower.” safety and protection before • Transmit the earthquake strong tremors start early waning over their own • Companies, utilities and Disaster Management Radio infrastructure operators receive Communication Network emergency earthquake early (J-ALERT) [2] NIED warnings by using dedicated receivers, which are then to be used for in-house announce- • Installs and maintains [6] JSMBC [7] Provider ments or for controlling seismometers elevators or factory machines. • Sends seismic data • Distributes • Disseminates emergency emergency earthquake early earthquake early warnings (alerts warnings to the and notices) to users weather service providers Figure 3‑4 Institutional overview of the Earthquake Early Warning System Source: Based on material of JMA: http://www.data.jma.go.jp/svd/eew/data/nc/shikumi/shikumi.html EARLY WARNING SYSTEMS: Earthquake Early Warning System 39 3.2.4 Earthquake Early Warning System: Enabling Environment Policy and Legislation According to the Meteorological Service Act, JMA is mandated to issue forecasts and warnings of earthquake ground motions38. JMA transmits the warning to relevant organizations which distribute it in the designated disaster areas (although areas close to the epicenter may not receive advanced warnings39). The Meteorological Service Act forbids anyone except JMA from issuing earthquake warnings, in part to prevent issuance of improper warnings. Before starting to operate the EEWS, JMA took steps to ensure warnings did not create confusion or chaos: in 2003 it arranged an organizational structure for setting up a project team in charge of developing the EEWS; in 2004 it started feasibility studies on information transfer; and in 2007 it finally started providing earthquake early warnings for regular use. While JMA has been promoting use and enhancing transfer of early warnings through pilot operations, feasibility studies, and preliminary live operations, it also started familiarization and outreach activities, which continued after launching system operations for regular use40. The awareness campaign was successful in promoting the earthquake early warning system and emphasizing the difference between EEW and earthquake information41. Since earthquakes tend to occur less frequently than other natural hazards such as floods, cyclones, heatwaves or droughts, it is difficult to allocate resources to invest in the development of an EEWS, unless a catastrophic event has just occurred. Furthermore, although earthquake early warnings are considered an effective component of earthquake hazard preparedness, research points to various limitations in terms of reliability and challenges improving accuracy by reducing false/missed alarms. Given these barriers, in order to manage risks of earthquake disasters, priorities are often placed on implementing preventative measures such as strengthening building codes to ensure seismic resilience, as well as awareness, education, and drills to improve the capacity for protection and preparedness. Several countries have developed and operationalized prototypes of validated EEWS including China, Italy, Japan, Mexico, Romania, Taiwan, Turkey, and the United States of America (U.S.A.) - all countries that have urban centers exposed to high earthquake risks, and with experiences of severe earthquakes (see Appendix B.2 for details). Each system is unique depending on the local seismic faults and the specific ground motion data available. 38 See Table B.2.4 in Appendix B on the relationship between an earthquake early warning and JMA forecasts/warnings 39 See Appendix B.3 for more on the limitations of the Warning System 40 In order to examine the “know-how” in using the EEWS and the measures for disseminating and improving awareness of the system, JMA set up a “Committee for the launch of operation of the Earthquake Early Warning System” in 2005, and a final report was compiled in 2007. JMA has also held the “Committee for improving the technology and operation of the Earthquake Early Warning System” since 2009, and further development of conventional as well as new methods are underway. 41 For details see Appendix Figure B.3.1. Awareness of Earthquake Early Warning Systems. 40 DIGITAL SOLUTIONS FOR RESILIENCE System Costs The capital costs of the EEWS was about JPY 11 billion. Operation and maintenance costs are about JPY 2.8 billion a year42 (excluding personnel costs). Besides communication devices such as mobile phones, TV and radios, a variety of specially designed EEWS receivers are available at a cost ranging from 10,000 yen to hundreds of thousands of yen. Lower cost receivers generally use the warning information transmitted by broadcasters, and higher cost receivers use internet and/or dedicated ISDN lines. 42 The O&M costs are borne by JMA and NIED. EARLY WARNING SYSTEMS: Earthquake Early Warning System 41 3.3 J-ALERT: Nationwide Instantaneous Warning and Alert System 3.3.1 J-ALERT: System Overview The lack of a system that could rapidly issue widespread warnings of large-scale disaster that require immediate response led to the development of J-ALERT. This emergency warning system disseminates urgent information received directly from the government in vulnerable areas through automatic activation of local radio communications and other communication lines. Warnings are transmitted from the Cabinet secretariat and JMA through the Fire and Disaster Management Agency (FDMA). Information delivered include warnings for natural hazards such as earthquake, tsunami, volcano, meteorological events and flood forecasts as well as man-made hazards such as ballistic missiles and terrorism. J-ALERT employs a satellite for communication from the government to municipalities and to citizens, with terrestrial backup lines that are also used for monitoring and software updating of J-ALERT receivers. All of Japan’s municipalities have installed via an FDMA subsidy ‘trigger controllers’, devices which allow information to be automatically delivered to their disaster prevention radios or other delivery channels. Emergency information is distributed to the public not only through local public loudspeakers Key adopters Fire and Disaster Management but also by EAM, mobile phones and broadcast of J-ALERT Agency (FDMA) of the Ministry of media (i.e. TV and FM radio). This multi-format Internal Affairs and Communications communication ensures widespread penetration (MIC), Cabinet Secretariat, of essential disaster-related information. The Japan Meteorological Agency (JMA) system has further developed to allow J-ALERT Beneficiaries People who have access to warnings to be received by major utility (Recipients alert receiving devices (i.e. TV, companies, hospitals, public schools, and mass of early disaster prevention radios, radios, communication media, expanding the reach of warnings) and mobile phones), municipal governments with J-ALERT receivers, urgent emergency messages. While adoption and private companies that have was not complete at the time of the 2011 Great subscribed to the alert email service East Japan Earthquake and Tsunami, affected System Backbone system: NTT DATA municipalities that had already introduced the Developers Corporation Ltd receiver and trigger controller reported that J-ALERT receiver: (Century Systems J-ALERT was effective for protecting lives (see Co. Ltd., NTT Communications Appendix C.1) Corporation Co., Ltd, Panasonic Corporation Ltd, Rikei Corporation In 2004, the Civil Protection Act defined the role Ltd.) of the national government in issuing warnings to protect the public, and of municipalities to Trigger controller for the disaster prevention radio: (Fujitsu General transfer information to residents by means Ltd., Hitachi Kokusai Electric of disaster prevention radio communication Inc., Japan Radio Co. Ltd., Meisei systems. To bring this framework into operation, Electric Co. Ltd., Mitsubishi Electric J-ALERT was developed by FDMA of the Ministry Corporation., NEC Corporation., Oki of Internal Affairs and Communications (MIC) Electric Industry Co. Ltd., Plum Five beginning in 2004, and operations were launched Co. Ltd., Toshiba Corporation Ltd., Panasonic Corporation Ltd.) in February 200743 as a new information Year of Launch February 2007 system to generate and disseminate early warnings. By enshrining disaster communication Costs Development cost: About JPY 472 responsibilities in law, widespread adoption million is mandated and disaster messages are able to Operation and maintenance cost: reach a wide segment of the public. About JPY 300-400 million/year 43 For more information, see FDMA, 2009 Source: Developed by the authors with inputs from MIC 42 DIGITAL SOLUTIONS FOR RESILIENCE 3.3.2 J-ALERT: Lessons and Recommendations • Rapidity and penetration - Effective emergency alert systems must be rapid and widespread. J-ALERT’s potency lies in its ability to reach rapidly most of Japan’s population. This is achieved using direct satellite communication to municipalities with terrestrial backups, and by dissemination to individuals via multiple methods. Outside of Japan, existing technology and penetration should be considered in order to select systems for emergency alerts which are already widely available and cost-effective. The wide reach of J-ALERT is also facilitated by legislation which defines the responsibilities of national and local governments in relationship to disaster communications. To enhance rapidity and penetration a combination of ICT systems and government policies is advisable. • Informative warnings - The actions to be taken should be communicated along with the alert, and awareness-raising activities such as training in normal times should be introduced. Because J-ALERT is simply an alert, it does not include information on how to respond to hazards. In some cases, people alerted via J-ALERT in recent years did not know exactly what actions to take (e.g., evacuate to safe area based on hazard map), in spite of Japan’s broad use of drills and preparedness programs in schools, workplaces, and civil society; populations in other contexts are likely to be less prepared. • Maintenance - Alert systems require periodic inspections to maintain reliability. In a nationwide simultaneous simulation drill conducted by FDMA in 2018, 15 local governments found that J-ALERT did not operate due to incorrect setting of J-ALERT receivers or trigger controllers, failures of wireless devices and/or incorrect setting of mail transmission devices. An instantaneous alert system deployed in another context would similarly require a maintenance budget to conduct drills and checks to ensure the system is fully operational when a disaster does strike. • Tailoring the system - Both capital and O&M costs for alert systems could be reduced by reducing extents and complexity. The relatively high up-front capital costs associated with J-ALERT include the cost of designing and developing the original technical standards from scratch, and overhead costs from frequent modifications; in other countries, systems similar to J-ALERT can be developed at less cost by using existing technologies. Moreover, while in Japan the government is mandated to deliver early warnings to all citizens, in developing countries new alert systems may begin with the development of programs targeted at mobile phone users or other priority groups. While full penetration is ideal, a smaller initial scope may be useful as the system is being developed and tested. The cooperation of telecom companies or broadcasting companies which allow dissemination via their networks provides another option for reducing the cost for national governments and municipalities while retaining reasonable effectiveness. 43 3.3.3 J-ALERT: ICT Systems and Context Systems and Infrastructures When urgent disaster-related information becomes available, JMA and the Cabinet secretariat44 enter the necessary information (emergency information code, area codes of recipients, etc.) into terminal computers. The data is transferred over the Central Disaster Prevention Radio Network to the J-ALERT management system at FDMA. In municipalities, terminal computers receive warning data and trigger controllers allow information to be automatically delivered to disaster prevention radios or other delivery channels. To transmit extremely urgent information from FDMA to municipalities with high reliability, J-ALERT adopted a satellite communication system, because of its robustness in various disasters. The terrestrial communication of Local Government Wide Area Network (LGWAN) is used as a backup, and is dedicated to administrative use by local governments. In normal times, LGWAN is used to monitor J-ALERT receivers or to update their software. For a detailed system diagram of J-ALERT, see Appendix Figure C.2.1 and Table C.2.1. Dissemination In Japan, municipalities are mandated to deliver emergency warnings to all residences by law, and most municipal governments have adopted disaster prevention radio communication systems to disseminate disaster information to their residents45. Many municipalities also arrange cooperation with cable TV or community FM broadcasting companies as additional warning dissemination channels. By connecting these systems to the trigger controller, Figure 3-5 J-ALERT receiver information is distributed directly to households over Source: Century Systems Co., Ltd. Website: communication networks. Some municipalities have https://www.centurysys.co.jp/products/jalert/jars2000.html adopted subscription emailing systems which can be connected to the automatic triggering system as well, to distribute information to registered mobile phones. The ability to connect to various distribution systems is one of the key advantages of J-ALERT as a critical last-mile option for delivering disaster information to people. The entities that can receive J-ALERT have been expanded to designated groups including administrative organizations (ministries and agency of central government, local branch of ministries), and public corporations (important technical institutions and infrastructure operator companies). J-ALERT provides its technical specifications to these organizations. Hence, not only related ministry and local government bodies but also major utility companies, hospitals, public schools, and mass communication media are able to receive information today. Emergency alerts will be redirected to those organizations’ communication methods such as public announcement systems or service networks. The expansion of receiving organizations increases the residents’ opportunities to catch critical alerts. 44 The Cabinet Secretariat (Naikaku-kanbō) is an agency in the Japanese government, headed by the Chief Cabinet Secretary, which organizes the Cabinet’s public relations, coordinates ministries and agencies, collects intelligence for the government, and organizes miscellaneous other tasks for the Cabinet. The CAO - Cabinet Office (Naikaku-fu) is also responsible for handling the day-to-day affairs of the Cabinet but is formally headed by the Prime Minister. 45 Act for Partial Revision of the Act on Meteorological Service and Act for Establishment of the Ministry of Land, Infrastructure, Transport and Tourism (Act No. 23 of 2013). According to the law, municipalities are mandated to “reliably” deliver to all residents (so methods that clearly are not 100% effective, such as TV, Mobile phone, and Web do not comply with this law). Because MIC strongly encourages disaster prevention radio communication systems, they are generally considered compliant systems, and most municipalities adopted them as a result. 44 DIGITAL SOLUTIONS FOR RESILIENCE In addition, it is also possible to send J-ALERT information using EAM46 as described in section 3.4 of this report, and L-ALERT as described in section 4.2. Warning Types Warnings transmitted by J-ALERT have three levels of urgency, which determine how the dissemination system (such as disaster prevention radio communication systems) is triggered: Level A – Mandatory automatic trigger; Level B – Optional automatic trigger as a municipality’s decision; and Level C - Manual trigger. Warnings include natural hazards such as earthquake, tsunami, volcano, meteorological events and flood forecasts as well as man-made hazards such as ballistic missiles and terrorism. See Appendix Table C.2.2 for details on warning Figure 3‑6 An image of Disaster Prevention Radio types and levels, and Appendix Table C.1.1 for past Source: Seiryo Electric Corporation’s website: http://www. Level A warnings issued by J-ALERT. seiryodenki.com/biz/solution/wireless/mca.html Deployment By the end of 2013, all municipalities had installed J-ALERT receivers and trigger controllers. As of August 2017, 85.6% of municipalities had more than two means to automatically distribute information using the trigger controller [see Appendix Figure C.1.2]. The major dissemination channels managed by the municipal government are the municipal disaster prevention radio communication system (mandatory), TV, and FM radios. However, TV is still the largest distributor of information47 followed closely by mobile phones48, so broadcast television and mobile phones are also important distribution channels for J-ALERT. Each communication channel has strengths and weaknesses in terms of reach and functionality so encouraging diversification of dissemination channels is key. Institutional Framework The relationships between the organizations that work together to make J-ALERT function are detailed in Figure 3-7. FDMA is the primary developer and manager for the J-ALERT system. It also establishes technical specifications for J-ALERT receivers and trigger control devices. Disaster warnings are issued by the Cabinet Secretariat for civil protection alerts such as terrorist attacks or the JMA for natural disasters. 46 Emergency Alert Mail is an alert mail sent from mobile carriers using their exclusive communication technologies to avoid congestion. In contrast, the subscription mail is an alert and information sent by municipalities using ordinary email. 47 Household penetration rate of television in Japan is 95.2% as of Mar. 2017, based on Cabinet Office “The consumer behavior survey”. 48 Individual penetration rate is 83.6% as of 2016, according to MIC (2016a). EARLY WARNING SYSTEMS: J-ALERT 45 [2] Cabinet [1] FDMA [4] Municipalites [6] Private [7] Residents Secretariat Companies • Develops, manages • Install, manage, Issues civil protection and maintains the and maintain the J-ALERT backbone disaster prevention •Through the trigger Information on warnings such as Satellite system (for sending radio controller owned by armed attacks armed attacks and receiving data) municipalities, etc. •Install the trigger warnings are • Compiles the controller for the transferred to general specifications disaster prevention private companies, of the J-ALERT radio such as cable TV, [3] JMA receiver •Distribute disaster community TV, or • Monitors the status information by using subscription email •Take prompt Issues natural disaster of J-ALERT receivers communication service providers actions to ensure warnings and updates its media other than the safety upon software disaster receiving warnings management radio from J-ALERT on the LGWAN communication disaster prevention Internet system radio, TV, radio, or mobile messages Civil [5] Mobile Phone Carriers protection warning • Distribute the early warning emails, when receiving civil Emergency Alert Mail Tsunami warning, protection warnings from FDMA or Earthquake Early Warning, etc. natural disaster warnings from JMA, such as Tsunami or Earthquake early warnings Natural Disaster Event Figure 3‑7 Institutional overview of J-ALERT Source: Based on MIC (2016b) Note: LGWAN = General government WAN that connects all local governments. 3.3.4 Enabling Environment Policy and Legislation J-ALERT’s operational processes are stipulated in the operational rules “The Provisions for Operation Process of the National Early Warning System (J-ALERT49).” Of particular significance within the operational rules is Article 4, which identifies the types of information J-ALERT should transmit, with high-urgency information (Level A) automatically triggering municipal disaster prevention radio communication systems50. Under the Meteorological Service Act (1952), JMA is defined as the sole organization responsible for issuing warnings and advisories regarding natural disasters. At the same time, under the Disaster Countermeasures Basic Act, municipalities are required (with the cooperation of related organizations) to protect lives and properties by providing disaster information and countermeasures to residents. As part of this requirement, municipalities are responsible for developing and improving the communication method to distribute disaster information. As a rapid, automated warning system, J-ALERT supports these responsibilities. 49 Created in 2010, updated in 2016. For more information, see: https://www.fdma.go.jp/mission/protection/item/ protection001_05_J-ALERT_gyomu_kitei_280322.pdf [In Japanese] 50 For more information, see: https://www.fdma.go.jp/mission/protection/item/protection001_05_J-ALERT_gyomu_kitei_280322.pdf [In Japanese] 46 DIGITAL SOLUTIONS FOR RESILIENCE The following are the major acts related to J-ALERT: • Act for Establishment of the Ministry of Land, Infrastructure, Transport and Tourism (MLIT): defines the position and role of MLIT, JMA and other agencies under MLIT. • Meteorological Service Act: defines rules of meteorological services especially including the roles and responsibilities of JMA and its partners, as well as the collaboration mechanism. • Disaster Countermeasures Basic Act: defines the institutional framework for disaster prevention and management, including the organization, functioning, powers, and responsibilities of central and local disaster prevention councils. • Civil Protection Act: defines the responsibilities of national and local governments and measures, such as evacuation, relief, and response to armed attacks in order to protect lives and property. Japan has a strong central government. This helps the policy making process, and the above legislation ensures ongoing funding and support for the system, and widespread dissemination. System Costs The total cost to develop and enhance J-ALERT was approximately 1.37 billion JPY51 from 2005-2009. Additional smaller costs were associated with municipal subsidies for implementation. Over the long- term, however, the main investment is associated with the operation and maintenance of the FDMA-owned system, about JPY 300-400 million annually. See the Appendix C.3 for additional information. Substantial financial and human resources have been allocated to develop and operate J-ALERT because disaster early warning is a critical mission and responsibility as outlined in the legislations listed above. Countries and institutions seeking to design and implement a nationwide instantaneous warning and alert system modeled on J-ALERT should expect a lower cost given the significant technological advances made in recent years. Furthermore, the J-ALERT development cost include designing and developing the original technical standard from scratch, and overhead costs from frequent modifications and changes, which are not to be incurred by a new developer. 51 Based on the inputs from MIC: Initial development cost (472 million JPY), and system enhancement cost (900 million JPY) to enable remote operations for monitoring the receivers’ statuses and updating the software. EARLY WARNING SYSTEMS: J-ALERT 47 3.4 Emergency Alert Mail: Cell Broadcast Early Warning System 3.4.1 Emergency Alert Mail: System Overview “Emergency Alert Mail” is a Cell Broadcast Early Warning System through which national, prefectural, and municipal governments can simultaneously disseminate disaster and evacuation information to mobile phones in warning areas via a free service offered by mobile carriers. The system capitalizes on the widespread diffusion of mobile phones across Japanese society. The system utilizes existing mobile networks, but avoids congestion via a special traffic channel which prioritizes the delivery of alerts. Mobile phone users are notified via text and ringtone alerts; a special ‘wailing’ ringtone also helps alert others in the vicinity that an emergency alert is in effect. Because the system is based on the presence of mobile phones within the designated area, not on the area codes, even transient populations (commuters, students, temporary residents, and others) will receive the alert. The effectiveness of the EAM system has been proved in past disaster events: according to a recent survey, 85.1% of the survivors of the 2016 Kumamoto Earthquake reported that EAM was the first warning message they received [see Appendix D.1]. Earlier systems existed for sending mass emails to mobile phones in disaster areas, but these required local governments to create and manage a database of email addresses of their citizens. They also had the disadvantage of generating network congestion, resulting in delays. After major Key adopters Japan Meteorological Agency (JMA), earthquakes hit Japan at Niigata Chuetsu in of the solution Ministry of Land, Infrastructure, October 2004 and on the Noto Peninsula in Transport and Tourism (MLIT), March 2007, requests were made from local Fire and Disaster Management governments to provide disaster and rescue Agency (FDMA) of the Ministry of information to people in warning areas. EAM Inter Affairs and Communications was developed in 2007 with the assistance (MIC), of mobile carriers as a continuation of Almost all local governments the development of the EEWS, in order to (prefectural level and municipal disseminate warnings more effectively. level) Mobile phones were the technology of choice Beneficiaries People with mobile phones in as the communication channel because (Recipients designated areas of their increasingly widespread usage. of early warnings) Currently, three mobile carriers provide the EAM service, which as a centralized system System Mobile Carrier Network: Developers KDDI Corporation Ltd., NTT reduces the burden on local governments. DOCOMO Inc., SoftBank Group Corporation. Distribution System: NEC Corporation Ltd. (management and maintenance by mobile carriers) Year of October 2007 Launch Costs Development cost: Not disclosed (contributed by mobile carriers) Service charge: Free (contributed by mobile carriers) Source: Developed by the authors with inputs from NTT DOCOMO Inc. 48 DIGITAL SOLUTIONS FOR RESILIENCE 3.4.2 Emergency Alert Mail: Lessons and Recommendations • Redundancy - Redundant systems ensure that alert messages are not disrupted. EAM uses redundant systems to communicate from public organizations such as JMA to mobile carriers (Dedicated line, IP-VPN, and Wide-area Ethernet), and from mobile carriers to individuals via station substitution in affected areas, to ensure that alerts are distributed even if some lines of infrastructure and communication are disrupted. • Diversification - Although mobile phone rate penetration is high, diversification is key to a wide reach for emergency alerts. Because disaster information is distributed by push notifications to mobile phones the EAM has high penetration. However, mobile phone ownership among elderly residents is low in Japan and in many other countries. To address this issue, in Japan emergency alerts are distributed through multiple communication channels, including TV, radio, or municipal disaster prevention radio communication networks. Other countries exploring new emergency alert systems should consider the penetration of different messaging systems amongst different subsets of the population, and diversify accordingly. • Language - Alert messages should be multilingual. This is important for many multilingual states among developing countries. It is also a critical need for Japan, which hosts a growing number of foreign residents and tourists. In Japan, EAM started to provide alert messages in five languages with Android models in 2015. Since the operating system enables multilingual services, the issues associated with multilingual correspondence should be handled primarily at the upstream level (for example, Google) rather than among mobile phone carriers. For instance, the iPhone automatically translates the texts to the device’s pre-set language. • Partnership - Public-Private Partnerships with communication providers can keep down costs, but incentives and secondary alert mechanisms may be required. The operating costs of EAM are borne by cell phone carriers and are relatively low. Carriers have some incentive to participate in terms of public image and the fact that customers may factor the availability of the service when choosing their mobile carrier. However, while in Japan the perceived responsibility of private companies to participate in disaster preparedness-related programs is high, elsewhere additional incentives or legislation may be required. Currently, only the three major mobile carriers participate in EAM, whereas low-cost carriers (a growing segment) do not. In these cases many users install applications that can receive J-ALERT such as Yahoo! Disaster Prevention Bulletin. In other countries, if alerts are not guaranteed by all mobile carriers, outreach mechanisms may be required to gain high levels of participations in opt-in alert applications. • Customization - The scale of alert delivery areas matters: currently EAM is delivered to an entire municipality. The system could be made more effective by tailoring the alert distribution areas depending on the characteristics of a disaster, based on requests by municipal governments. The areas covered by an alert are becoming larger due to continuing municipal mergers. In cooperation with municipalities, FDMA started a feasibility study in 2016 to distribute alert messages to areas smaller than a municipality. Elsewhere, a combination of local capacity, system capacity, and hazard types can help inform the decision of what scale to use for alert delivery. 49 3.4.3 Emergency Alert Mail: ICT Systems and Infrastructures Systems, Infrastructures and Dissemination Senders of emergency information (i.e. JMA, MLIT, FDMA, and municipalities) enter messages as text through an input terminal, select distribution areas (in units of municipality), and then transmit it to mobile carriers. The emergency distribution server of each mobile carrier (see (6) in Figure 3-8) designates mobile base stations in warning areas, then delivers the information. A portable mobile base station could be deployed in post-disaster sites in order to restore mobile phone service. An emergency distribution server manages the data table linking mobile base stations of each mobile carrier to municipalities. Redundancy makes the system resilient. Communication from public organizations such as JMA to mobile carriers is carried on by different types of lines (Dedicated line, IP-VPN, and Wide-area Ethernet). Mobile carriers ensure their services by substitution so that affected stations can be covered by nearby stations. JMA [12] Mobile Carrier Network JMA, Ports and Harbors Bureau, MLIT, NIED, NTT DOCOMO Warning Area JAMSTEC, Municipalities, [9] EPOS Universities Digital Access [8] ETWS (DA) Network [5] Input [1] Seismometers terminal [2] Seismic Intensity [6] Emergency [7] Wireless network meters Distribution Server management devices Mobile Base Regional Development Stations [3] Strain meters Mobile Comm. Bureau, MLIT Network (Tokai area) au (KDDI) Warning Area [4] Tsunami Observation [5] Input terminal [8] ETWS Facilities Satellite Comm. FDMA Network [6] Emergency [7] Wireless network Distribution Server management devices Mobile Base Stations [5] Input terminal SoftBank Warning Area [8] ETWS Municipalities [5] Input [10] Dedicated terminal [6] Emergency [7] Wireless network line Distribution Server management devices Mobile Base [11] IP VPN Stations 1. Alert Issued 2. Message Processed and 3. Alert Received Delivered to Target Cell Area by Mobiles Figure 3-8 System Diagram Source: Based on materials provided by NEC Corp. One year after the official launch of EAM in 2007, in order to further increase reliability and speed, Third Generation Partnership Project (3GPP) standardized the Earthquake and Tsunami Warning System (ETWS) based on the EAM system originally developed by NTT Docomo (Area Mail). The standardization process established parameters and steps to separate “Primary Notification” and “Secondary Notification”. As depicted in Figure 3-9, the Primary Notification contains the minimum, most urgently required information such as “An earthquake occurred”; the Secondary Notification includes supplementary information such as seismic intensity, epicenter location, and so on. Following the standardization, the ETWS technical specifications were adopted by the mobile carriers in Japan for their EAM services [see Appendix section D.2]. 50 DIGITAL SOLUTIONS FOR RESILIENCE A AREA MAIL alert sound EARTHQUAKE -9 seconds Evacuation EARTHQUAKE ARRIVES MAJOR TREMOR Meteorological Mobile Phones: Agency, etc Data received A ETWS alert sound -4 seconds: 10-20 seconds: EARTHQUAKE Primary Notification Evacuation EARTHQUAKE ARRIVES MAJOR TREMOR Meteorological Mobile Phones: Agency, etc Disaster information Detailed data received: received Extinguish Fires Open Doors Hide Under Desk Figure 3-9 Differences in information distribution method in the original Area Mail and ETWS Source: Tanaka et al., (2009) Warning Types Warning types include evacuation information, tsunami warnings and advisories, eruption notifications, flood forecasts, landslide warnings, EEW, Tokai earthquake52 warnings, and civil protection warnings (i.e. air attack or mass terrorism). See Appendix Table D.2.3 for details on warning types. Institutional Framework The entities that are permitted to provide disaster information and disaster prevention information through the EAM53 include CAO, 12 ministries and agencies, commission extra-ministerial bureaus Figure 3‑10 An example (stipulated by the Basic Act on National Government Reform54) and of the screen of EAM all 47 prefectures, municipalities, and special wards (stipulated by Source: NTT DOCOMO the Local Autonomy Act55). Inc. website: https://www. nttdocomo.co.jp/info/news_ release/2016/09/01_01.html 52 The Tokai Earthquake is a possible large earthquake affecting the area around the Tokai region; a prediction system has been developed for it under a special act established in 1978. Tokai earthquakes could reach magnitude 8. 53 For more information, see: NTT DOCOMO Inc., Article 2, “Terms of Use for Early Warning “Area Mail” https://www.docomo.biz/ pdf/html/service/areamail/rules.pdf and; SoftBank, Article 2, “Terms of Use for Emergency Breaking News Mail Service” https://cdn. softbank.jp/biz/set/data/mobile/sbm/solution/smartphone/kinkyuu/pdf/tos_urgent_news.pdf 54 The objective of the Basic Act on National Government Reform is to downsize and streamline Japanese administrative organs by defining the organizational structures of 12 ministries, including MIC, Ministry of Justice (MJ), and Ministry of Foreign Affairs (MOFA), and related organizations. 55 The Local Autonomy Act stipulates the organizational structures and operations of local governments. It determines basic relations between them and the national government with the objective of achieving democratic and efficient operations of local administrations. EARLY WARNING SYSTEMS: Emergency Alert Mail 51 [1] JMA [3] Mobile carriers [8] People in Warning Areas Automatically issues alerts or Provide the communication advisories on natural lines free of charge to disasters, earthquakes and transfer the Emergency Alert tsunamis. Delivers special Email to communication warnings related to weather devices such as mobile and volcanic eruptions. phones. [2] MLIT Issues flood forecasts of designated rivers and landslide disaster warning information Company A • Upon receiving information, they take actions to ensure safety and protection. • Emails can be delivered to Company B municipal or prefectural areas. [3] Municipalities Deliver necessary information for evacuation. Company C [4] FDMA Sends information for civil protection. Figure 3‑11 Institutional overview of EAM Source: Based on mobile carriers’ website: https://www.nttdocomo.co.jp/biz/service/areamail/?dh=svam and material provided by NEC Corporation Ltd. 52 DIGITAL SOLUTIONS FOR RESILIENCE 3.4.4 Emergency Alert Mail: Enabling Environment System Costs The capital costs of EAM were not disclosed. The operating costs are sustained by mobile carriers, and so there is no cost to the government. Costs to mobile carriers are also low. In addition to EAM, mobile carriers also provide free services related to disasters such as disaster message dial56 (call number 171) as social contribution activities. The partnership between private companies and the Japanese government to improve disaster preparedness and response may have been made possible in part because private companies in Japan feel responsible to contribute to disaster preparedness, given the country frequent experiences with large-scale disasters. However, private companies may also have a financial incentive if people choose their mobile carrier based upon whether or not they will provide EAM, as indicated by people highly rating the effectiveness of EAM at the time of Kumamoto Earthquake (FMMC, 2016). In other countries, it may be necessary to provide subsidies or legal mechanisms that might encourage companies to participate in the program. Technical Standardization Technical specifications have been key to standardizing the Cell Alert System across the private mobile carriers which operate the system. NTT Docomo’s creation of specifications through 3GPP (discussed in the above section on Systems, Infrastructures and Dissemination) unifies alert sounds and message distribution: no matter which mobile carrier a user employs, they receive alerts in the same way. The standardization also contributed to making alert delivery faster and more reliable across all three mobile carriers. 56 Disaster Emergency Message Dial 171 is a service that enables to post and check safety status and other information by voice, using the phone number of a person in the disaster zone as a key. Since during disasters phone lines get clogged up, people can leave messages to a specific mobile number by calling 171. The owner of the mobile number can access the messages left from them by calling 171. EARLY WARNING SYSTEMS: Emergency Alert Mail 53 54 DIGITAL SOLUTIONS FOR RESILIENCE [4] Multi-Hazard Disaster Information management Systems (DIMS) in Japan Image: Disaster information for quick recovery after major power outage - drill (Jul. 2016). Source: Sankei Visual. 55 4. Multi-Hazard Disaster Information Management Systems (DIMS) in Japan Disaster Information Management System (DIMS): a mechanism for effectively processing, organizing, storing and disseminating information required for disaster response and recovery, particularly in the immediate aftermath of a natural disaster event Information Management is defined as the collection, processing, organization, storage and dissemination of information for a specific purpose (UNISDR, 2013). Effective information management for disasters is vital for disaster preparedness, response and relief. While information management through an EWS is utilized to save lives and assets, effective management of disaster information for quick relief, recovery, and/or continuity is also crucial, particularly in the immediate aftermath of a disaster event. Disaster Information Management Systems (DIMSs) allow information related to a specific disaster to be readily accessed by relevant stakeholders: after a disaster, delivering the right information to the right recipients allows response and recovery teams to begin their work quickly and effectively. DIMSs are typically developed and setup before a disaster strikes. Related or synonymous concepts include Emergency Management Information System (EMIS57), Disaster Management Information System (DMIS58), Integrated Disaster Information System (DiMAPS59), and National Emergency Management Information System (NEMIS60). Various types of DIMSs exist in Japan, differentiated by target hazards, key functions, actors involved, technologies utilized, and key information communicated. Table 4-1 summarizes these features of DIMSs, including parameters of success and factors of success. Figure 4-1 shows a schematic of the DIMS process, where the information flows from the sources of disaster impact and the response information institutions to a hub for disaster information, and from there disseminated to utilities and critical infrastructures, private sector stakeholders, people and institutions. Enhancement of DIMSs should aim at: i) increasing the sources monitored; ii) the types and quality of disaster impacts and response information; and iii) expand the reach and ease of access of the recipients of disaster information. 57 EMIS is an information sharing system developed by the Ministry of Health, Labour and Welfare based on the lessons from 1995 Great Hanshin-Awaji Earthquake. It provides disaster medical care information, such as medical service availabilities, to be shared not only within the damaged areas but among all prefectures, in order to support medical care and rescue activities in damaged areas. 58 See http://www.mlit.go.jp/river/bousai/olympic/en/helpful01/index.html 59 See http://www.mlit.go.jp/river/bousai/olympic/en/helpful01/index.html 60 See https://www.fema.gov/nemis-system EWS 4-1: ICT TableShorten for DIMS: Key Features time between source risk info to recipient Multi-hazard system including natural (i.e. hydrometeorological events, earth- Hazards: quakes, and volcanic eruptions, etc.) and human-induced disasters (i.e. accidents, epidemics, nuclear missile attacks, etc.) Diversify information dissemination channels Expand reach / recipients of risk information Functions: Monitoring, reporting and management of hazards and incidents Utilities & Critical Infrastructures Information users, managers, and providers, including national & municipal Actors: government emergency operation centers, utility companies/managers of critical Municipalities infrastructures, media, academia and citizens. Risk Hardware, such as computers, servers and communications equipment, and Technology: Information software for monitoring, reporting and management of disaster information. Earthquake, typhoons, floods, volcano, etc. Number, location, and status of a ected population, emergency response status Information: and needs (i.e. evacuation centers, hospitals, distribution of supplies/relief items, etc.), damage/condition of utility and critical infrastructure, etc. Private Sector Speed/lead time, accuracy and validity of information, accessibility (number and Mobile Companies, Parameters of types of recipient), ease of decision-making/action, TV, Radio, Internet, multi-use/multi-purpose, success: etc interoperability, flexibility, ease of management, etc. Recipient of Risk Information: Factors of pressure Consolidation, multi/private sector engagement, easingPeople of responder, & Institutions success: coordination through law and SOP DIMS Private Sector Mobile Companies, TV, Radio, Internet, etc disaster impact and response information Expand sources, types and quality of Expand reach and ease of access by recipients of disaster information Hub for Utilities & Disaster Critical Information [Municipal Infrastructures Government] Sources of Disaster Impact & Response Information Institutions Recipient of Risk Information: People & Institutions Figure 4-1: Conceptual Diagram: ICT for DIMS 57 4.1 DIMS Overview 4.1.1 Systems Discussed This section discusses the following Disaster Information Management System (DIMS) case studies from Japan: • L-ALERT Common Public Information for Safety and Security is a centralized repository for gathering and distributing disaster-related information developed by the MIC; the information it handles includes warnings from J-ALERT. • GIS-based DIMSs. Three technologies for obtaining imagery of disaster areas are discussed: • Helicopter Satellite Communication System, which transfers disaster images from helicopters to disaster management centers via satellite; • Disaster Damage Map, an interface for displaying before-and-after images of disaster-impacted areas; • Crisis Mapping, which publishes post-disaster drone imagery online. • Tokushima Prefecture: Disaster Information Management System is a platform for disaster information sharing covering the entire prefecture, used by 499 organizations. • K-DIS: DIMS for Utilities. Kansai prefecture’s K-DIS focuses on sharing the post-disaster status of utilities, including the status of damage of facilities such as substations and transmission lines, as well as power outages and recovery status of the Kansai Electric Power Co. Inc. • Hyogo Asset Management System for Resilience of the Hyogo Prefecture explores the role of DIMS for infrastructure by assessing damages and response status in a ledger system. It also serves as an asset management system for infrastructure facilities during non-disaster periods. L-Alert and the GIS-based DIMS are national-scale systems, whereas the last three case studies are developed and operated by prefectures; while each has a unique emphasis, they all work to streamline sharing disaster-related information. 58 DIGITAL SOLUTIONS FOR RESILIENCE 4.1.2 Key Lessons • Legislative framework - Laws which clearly define the roles of relevant organizations ensure that operations of DIMS are effective when a disaster strikes. To develop DIMSs, it is necessary to clarify who does what and when in the event of a disaster, with respect to collecting, disseminating, and utilizing information through DIMS. In the case of Japan, the disaster management plan has been developed by all administrative bodies, including national agencies, prefectures, and municipalities, based on the Disaster Countermeasures Basic Act. The chain of command at the time of a disaster, the flow for processing information on damage and disaster response, and the responsibilities of each organization are clearly defined. In most developing countries, a disaster management plan has already been prepared at the national level, however, not all have prepared one at a local level. Therefore, it is necessary to develop the Standard Operating Procedure (SOP) not only at the national level but also at the level of local governments, as well as utilities (lifeline operators and transportation infrastructure operators), and to clarify the roles taken by each organization. This will allow response, recovery, and associated communications to operate effectively based on DIMS during a crisis. • Outreach - Pre-disaster outreach and system engagement can promote use of DIMSs during a disaster. To fully utilize any DIMS, users should be motivated to regularly use and update the system in normal times. For example, in Tokushima Prefecture’s system, government employees benefit by linking other disaster management systems within the prefectural government. The latest information on damage is registered in the system, saving time spent for administrative work by disaster management officials responding to mass media. DIMSs cannot be used effectively in an emergency unless participants are accustomed to using it in normal times. For example, Hyogo Prefecture’s Asset Management System (AMS) is used for maintaining facilities in the prefecture and preparing updated plans in normal times. At the time of a disaster it is possible to share images of disaster areas with the same system. When designing new DIMSs, potentials for non-disaster use and promoting its use should be integrated into the system. • Contextualization - Information access for DIMSs should be based upon existing communication infrastructures and user contexts. In Tokushima Prefecture’s DMIS, Hyogo Prefecture’s Asset Management System and GIS-based DIMS, users are able to register and view disaster information anytime and anywhere via internet networks and mobile communication networks. In addition, information security is taken into consideration by setting access restrictions with login management. On the other hand, K-DIS uses a dedicated line inside the company and is connected to all departments of Kansai Electric Power Company and information is shared with all employees. In developing countries, access methods and information management should be based on the existing communication infrastructure development status and the circumstances of DIMS users. Systems should be implemented in accordance with the actual situation of developing countries. 59 4.2 L-ALERT: Common Public Information System for Safety and Security 4.2.1 L-ALERT: System Overview L-ALERT is a common public information system for safety and security, which serves as a one- stop platform for dissemination of disaster early warnings, evacuation information, and post- disaster information from different sources, such as municipalities and utility companies. L-ALERT disseminates the information sent from senders across Japan to distributors of information regardless of their locations, so that the same information is accessible to residents through various media, including TV, radio, mobile phones, and web portal sites61. Since the system itself does not store information, it does not require storage and backup solutions, keeping maintenance and management costs low. Although L-ALERT includes some EWS functions, it is classified as a DIMS considering its paramount function as a shared platform of disaster information. Here we focus on the way L-ALERT creates a system of consolidation, aggregation, and dissemination of information from multiple Key adopters Ministry of Internal Affairs and sources and makes this information accessible of the Communications of Japan (MIC) to affected residents and local businesses/ solution organizations. Beneficiaries National and prefectural (Users of the governments, municipal L-ALERT gathers and distributes disaster database) governments, utility companies, information in a centralized fashion, relieving and distributors of information local governments from individually providing (i.e. broadcast companies, disaster information to each media outlet, mobile phone carriers, web consuming time and resources, and enabling to portal site operators, and browse disaster information issued in nearby newspaper publishers) local governments. Through L-ALERT media System Development: NEC Corp. outlets can receive information from each region Developers Operation: Foundation for in a unified format, streamlining information MultiMedia Communications transmission. Residents in disaster areas can (FMMC) receive the same information through a variety Year of 2011 of mediums, allowing them to receive important Launch messages whether they are at home, work, or on Costs Development cost: About JPY the move. 63.6 million Source: Developed by the authors with inputs from MIC L-ALERT was developed by the MIC in order to quickly and accurately convey post-disaster information, and it has been adopted by all municipalities in Japan62. The system is operated by the Foundation for MultiMedia Communications (“FMMC” hereafter), a public organization which participated in the working group and feasibility studies. 61 For more information and an overview of L-ALERT, see: http://www.soumu.go.jp/soutsu/kanto/saigai/osirase/lalert.html (in Japanese) 62 For a description of the history of L-ALERT’s development, see Appendix E.2. 60 DIGITAL SOLUTIONS FOR RESILIENCE 4.2.2 L-ALERT: Lessons and Recommendations • Centralization - A centralized platform to gather and communicate disaster information reduces the burden on local governments. • Outreach - Advance planning and everyday usage can ensure that DIMS are effective post- disaster. Lessons from the 2016 Kumamoto earthquake emphasized the need for adequate preparedness when planning to share disaster-related information (FMMC, 2016). For example, not all the public relations (PR) divisions of municipalities, which are usually responsible for updating information on their websites, transmitted the information obtained from L-ALERT to residents. Transmitting L-ALERT announcements in normal times would help PR divisions become familiar with the system. Similarly, pre-disaster outreach activities help major media to increase their usage of L-ALERT. Inputting data into L-ALERT can be difficult for municipalities during a crisis. Establishing an organizational support framework for municipalities in advance, such as in cooperation with the MIC, can help them to cope with the human resource shortages they are likely to face post disaster as they deal with various disaster-related missions such as search and rescue, and recovering infrastructure. • Capacity building - Drills and other forms of capacity building are required in order to ensure that a DIMS can be operated effectively during a crisis. L-ALERT requires data providers (including municipal government and operators of critical infrastructure) to decide and take responsibility for the information to be disseminated. Furthermore, data input requirements are also many and complex. Therefore, capacity building and simulation drills, such as those conducted in Japan, would also be critical in developing countries for this system to be applicable. • Multilingual services - Alert messages should be received in the appropriate language for residents of and visitors to the country. Japan is currently working to improve multilingual services for increasing numbers of foreign visitors. Elsewhere, the language needs of both resident populations and visitors (tourists, businesspeople, foreign workers) should be considered. • Visual impact - Combining text and visual information improves comprehension. In Japan, there is currently an effort to incorporate visualization of landslide disaster information on the map for related areas: as the number of related areas increase, it becomes more difficult to understand text information. Some information can be more quickly and clearly understood visually, and visual information, if well-designed, can also help overcome some language and comprehension barriers. • Redundancy - The L-ALERT system operates with a redundant architecture consisting of national data center and backup data center ensuring uninterrupted operations. Information sent to each center is synchronized automatically. 61 4.2.3 L-ALERT: ICT Systems and Context Systems and Infrastructures L-ALERT mainly consists of three components: 1. “Commons Node System,” to receive, convert, and transfer information. It is the core of L-ALERT, comes in two versions: one is the national node operated as Local Government Wide Area Network (LGWAN) Application Service Provider (ASP) for Japan as a whole, and the other is the local node operated as an independent ASP. Each node is equipped with a commons node system with the same functionality. Because nodes are connected to each other to form the commons network, the Commons Node System was developed to provide a high level of redundancy and availability as a large-scale distributed system, ensuring completion of information delivery even if there are problems with communication paths by resending data at system recovery regardless of the timing or location of a failure. 2. “Editor” and “Viewer”, which are two tools available for users to connect easily to L-ALERT without developing a cooperative system. 3. “Master data management system”, which is a web system for controlling configurations for receiving and sending data63. Senders of information have two options to connect to the node system. They either develop a cooperative application system to be interfaced with L-ALERT, or install the commons editor on their PCs. L-ALERT system operates with a redundant architecture consisting of national data center and backup data center. Information sent to each center is synchronized automatically64. In addition to Figure 4-2, a more detailed table of L-ALERT components can be found in Appendix E, Table E.2.1. Dissemination L-ALERT is often used as a post-disaster tool for local governments to quickly and widely disseminate relevant information such as rainfall, water levels, tide heights, shelters, or evacuation65. However, L-ALERT also works as an EWS that disseminates alerts and evacuation information (for example, L-ALERT handles warnings from J-ALERT too66). The contents of L-ALERT are being continuously improved and enhanced, especially after each disaster experiences. For example, in addition to basic features for transmitting evacuation advisories, directives, shelter, and disaster information, L-ALERT has an “announcement feature” to provide daily life information such as on administrative procedures, assistance and support regarding welfare, education, and childcare for victims of disasters. This announcement feature was used in the aftermath of the 2016 Kumamoto earthquake to deliver evacuation advisories, directives, and other information. Municipal officers could input this information directly into L-ALERT instead of multiple organizations separately (see Appendix E.1 for details). In order to disseminate disaster information based on L-ALERT more effectively, new services are also being generated through the cooperative efforts of the public sector and private companies. Some examples 63 For more information, see: http://www.fmmc.or.jp/commons/merit/index.html 64 Since 2014, the backup data center has been used according to the following backup policies: 65 See Appendix Table E.2.2 for more details 66 Recent examples (disclosed from FMMC on “Measures for utilization of L-ALERT”) of when and how L-ALERT was activated include: in the summer of 2016, L-ALERTS was used to issue 147 evacuation warnings for typhoon No. 8, 785 for typhoon No. 9 and 491 for typhoon No. 10. 62 DIGITAL SOLUTIONS FOR RESILIENCE include: (1) a smartphone application called “Disaster prevention bulletin” developed by Yahoo!Japan to provide disaster information based on data acquired via L-ALERT; similar smartphone services on the opening page of Yahoo!Japan, and PC and smartphone services on the “Yahoo!Weather & Disaster” page; (2) smartphone applications that use L-ALERT data to get information to access the nearest shelters upon the issuance of evacuation advisories. SENDERS OF INFORMATION SENDERS OF INFORMATION [1] National Node Ministries and Broadcast national agencies [11] [6] Cooperative Companies Commons [6] Cooperative VPN system system [11] Commons [7][9] Prefectures VPN Commons tool [3] Input terminal [7][8] Commons tool Mobile Phone Disaster information [6] Cooperative Companies system, etc. system [3] Input [2] Users’ terminal node [6] Cooperative Postal [10] Commons Network system Services LGWAN Municipalities [7][9] Commons tool [3] Input terminal [3] Input terminal [7][8] Commons tool Newspaper companies, etc Utilities / [7][9] Transportation Commons tool [11] [12] Commons Internet [3] Input terminal VPN [4] PC [6] Cooperative [7][8] Commons tool system [1] National Node Figure 4‑2 L-ALERT system diagram. Adapted from FMMC, 2017 Deployment The number of registered L-ALERT users, including both senders and distributors of information, totals 1,181 organizations as of May 2017. Senders of information include all municipalities and transportation (such as operator of mass-transportation or road/highway) and utility companies, while distributors include broadcasters, newspaper publishers, web portal site operators, and digital signage companies. Among distributors, almost all TV and radio stations participate. Institutional Framework Figure 4-3 shows an institutional overview of L-ALERT, and a detailed table can be found in Appendix E, Table E.2.3. In the L-ALERT system, senders of information use a standardized protocol so that distributors of information can communicate efficiently and effectively. The protocol called “Commons XML” has been adopted for L-ALERT, with the exception of disaster information from JMA. Because JMA has its own XML- based protocol to transmit its disaster information nationwide to broadcasters and carriers, data are used without conversion. L-ALERT is operated and maintained by FMMC. To use L-ALERT, organizations have to submit an application to FMMC, and they can start using L-ALERT upon receiving approval from the FMMC’s advisory board. It is also FMMC’s role to define the XML and EDXL67 formats for L-ALERT. 67 Emergency Data Exchange Language: XML base message format for L-ALERT, which is open to public from the FMMC web site. DISASTER INFORMATION MANAGEMENT SYSTEMS: L-ALERT 63 Senders of information include municipalities, central government ministries, and utility and transportation companies. Municipalities normally use L-ALERT installed at prefectural governments to transfer information. Some municipalities, such as major cities designated by government ordinance, install L-ALERT by themselves. Distributors of information include press and media companies such as broadcasters, telecommunication carriers, web portal site operators, and digital signage companies. In recent years, data linkage with car navigation systems has also been enabled. SENDERS OF DISTRIBUTORS OF RESIDENTS & INFORMATION INFORMATION COMPANIES [2] Municipalities [6] TV Broadcasters • Disseminate evacuation • Data broadcasting on digital TV (text advisories and directives, display). announcements, etc. [3] Prefectures [1] FMMC [7] Radio Broadcasters • Disseminate disaster prevention • Operate and manage • Emergency radio broadcasting (text information, announcement, etc. the L-ALERT. reading). • Distribute evacuation related Define and update information when municipalities communication can not distribute. protocols. [8] Internet Service Providers • Distribution on the internet (text display) [4] Ministries and national agencies • FDMA disseminates J-ALERT [9] Mobile Carriers information. JMA disseminates meteorological • Dissemination of emergency warning information. emails to mobile and smart phones. Cabinet O ce disseminates Data distribution on disaster prevention general disaster prevention applications. information. [5] Utilities / [10] Other Service Providers Transportation • Distribution via various services such as • To disseminate service status on digital signages, car navigation systems. telecommunication, electricity, gas, transportation, and commodities. Figure 4 ‑3 Institutional Overview of L-ALERT Source: Based on MIC, 2015a 64 DIGITAL SOLUTIONS FOR RESILIENCE 4.2.4 Enabling Environment Policy and Legislation L-ALERT was initially developed under the name “Public Information Commons” as a result of an MIC working group and feasibility studies beginning in 2008, and its use was expanded by a series of legislation. Under the trial project funded by MIC, L-ALERT was developed as a light and simple system consisting of a single gateway server connected to the network. The Basic Act on Sediment Disaster Control Measures was amended following the 2014 Hiroshima landslides to require prefectural governments to specify warning zones in regard to landslides and to publish the results of geotechnical investigation. The act also requires governors to supply landslide disaster warnings to mayors of municipalities, who in turn keep residents informed. Based on this amendment, the guidelines on landslide disaster control measures were modified in January 2015, providing methods to announce or distribute disaster-related information. This modification stipulates the expansion of L-ALERT as a tool for disseminating landslide disaster information to various mass media (MIC, 2015b). L-ALERT is not subject to telecommunication laws because it only relays information already submitted by each sender organizations (which are regulated by telecommunication laws). This condition simplified its development and enabled increased utilization. For example, L-ALERT receives, among the others, J-ALERT information through the J-ALERT receiver, but the legislation and operational rules regulating the dissemination of information obtained using J-ALERT68 are not relevant to L-ALERT. System Costs Capital cost for L-ALERT is about JPY 63.6 million69. Operation and maintenance costs have not been disclosed. All capital costs were borne by MIC, while the O&M costs are borne by FMMC. Therefore users, including municipalities, do not pay a user fee. 68 For example, “The Provisions for Operation Process of the National Early Warning System (J-ALERT)” 69 Based on inputs from MIC. DISASTER INFORMATION MANAGEMENT SYSTEMS: L-ALERT 65 4.3 GIS-Based DIMS 4.3.1 GIS-Based DIMS: System Overview Maps and images are the best ways to assess the post-disaster status of an area in order to send in rescue and response teams. Japan has developed a variety of technologies to obtain images or videos of disaster-affected areas, such as city cameras, helicopters, aircraft, and satellite terrestrial observations. This chapter examines three Geographical Information System-based DIMSs used in Japan: the Helicopter Satellite Communication System, the Disaster Damage Map, and Crisis Mapping. The Helicopter Satellite Communication System, in use since 2013, transfers photos taken from (a) Helicopter Satellite Communication System helicopters in real-time via satellite to disaster management centers and other organizations. Key adopters Ministry of Land, Infrastructure, of the Transport and Tourism (MLIT) (The Satellite transmission overcomes shortcomings in solution system has been implemented for an earlier “Helicopter-TV transfer system” which Development Bureaus of Kyushu suffered from small transmission range and and Kinki regions, and is currently communication obstruction from mountains and being rolled out for bureaus of high buildings70. other regions.) Fire and Disaster Management After collecting images of affected areas, it is Agency (FDMA) (The system necessary to compare them with those taken has been implemented for fire before the disaster in order to assess the department helicopters in Tokyo, damages. The Disaster Damage Map includes Kyoto, Saitama, Miyagi, and Kochi.) comparable aerial photographs of impacted areas Beneficiaries Prefectural and municipal before and immediately after a disaster. This (Users of the governments, hospitals, the Japan system assists with rapid damage assessments, database) Self-Defense Forces (JSDF), Fire helping to determine priorities of search departments, Police and rescue activities. It can also be used to System Mitsubishi Electric Corporation Developers investigate building damages after an accident. The map is available on the Internet and can be Year of April 2013 Launch used by anyone free of charge. Costs Development cost: Approx. JPY Once the rescue teams locate the areas where 200 million (only equipment the damages are more severe, they need to loaded on a helicopter) access the damaged sites, so information on Source: Developed by the authors based on inputs from Hyogo prefecture. viability and road infrastructure damages is essential. Updating and sharing road information of affected areas also helps people to find routes to destinations. The Crisis Mapping system takes photographic images using drones in affected areas, and publishes them on the Internet by linking them to a GIS map (OpenStreetMap: OSM). The system is updated by mapping volunteers around the world. These enriched OSM maps have been employed in car navigation systems to assist with post- disaster routing. Each of these tools performs a specific function, depicting one part of the full post-disaster picture: together they provide a comprehensive view of the impacted areas. They can be easily accessed, especially Disaster Damage Map and Crisis Mapping, enabling people to see the status of damage using common devices such as smartphones and PCs71. 70 For example, in the case of the 2004 Niigata-Chuetsu Earthquake it was difficult to collect disaster information at the Yamakoshi- village (which has been consolidated in Nagaoka-city) just after the earthquake due to disruption of the only road accessing the village. At the time of the Great East Japan Earthquake, the ground facility was damaged in Sendai-city due to the earthquake, and it was not possible to take photographic images of tsunami damage in some areas. 71 For details on how these systems have been used in past disasters, see Appendix F.1. 66 DIGITAL SOLUTIONS FOR RESILIENCE (b) Disaster Damage Map (c) Crisis Mapping Key adopters Micro Media Disaster Information Key adopters Yamato City in Kanagawa of the Network (MMDIN) of the Prefecture, solution solution Chofu City and Komae City in the Beneficiaries Anyone with access to the Internet, Tokyo Metropolitan Government (Users of the search and rescue operators Beneficiaries People who need disaster database) (Users of the information (e.g., the central System MMDIN and Environmental database) government, prefectural and Developers Systems Research Institute, Inc. municipal governments, disaster Data providers: PASCO management centers, residents in Corporation Ltd., NTT GEOSPACE affected areas) Corporation., Geospatial System Specified non-profit corporation Information Authority of Japan, etc. Developers Crisis Mappers Japan Secretariat: Global Survey Year of March 2011 (in Japan) Corporation Ltd. Launch Costs Development cost: JPY 100 – 300 Year of 2013 million (drone purchase cost) Launch Map updating: Free (as maps Costs Not disclosed* are updated using open source services) Note: * Expenses related to the system such as development and Source: Developed by the authors based on the Crisis Mappers maintenance costs are not known. This is because total costs Japan website, and inputs from Prof. Furuhashi (Aoyama Gakuin contributed by related companies have not been calculated. University) Administration is financed by membership fees from corporate groups supporting this activity. Source: Developed by the authors based on the MMDIN website, and inputs from Dr. Hayashi (president of NIED) 67 4.3.2 GIS-Based DIMS: Lessons and Recommendations • Outreach - Crowdsourced or volunteer-operated platforms require promotion campaigns to be effective at broad geographic scales. The Disaster Damage Map has not been widely used nationwide in Japan and to reach its full potential requires promotion activities highlighting the system’s role in assessing damage, searching for missing persons, and building damage investigations. In addition to emphasizing the functions of systems, outreach campaigns should also identify potential users and target the campaigns towards these users. • Preparedness - Some data collection or agreements may be necessary pre-disaster for GIS-based DIMS to be effective post-disaster. When creating a Disaster Damage Map, housing footprints on the map before a disaster occurs should be available. Pre-disaster housing footprints is required because if a house is carried away (e.g., by a landslide, or a flood), officials of the JSDF, fire departments, and police dispatched to the site for search and rescue have information on the existence and original location of the house by comparing housing footprints before and after the disaster. For this system, drone routes are also pre-approved prior to disasters. OpenStreetMap is an open source system, and anyone can use it free of charge. However, map information is not adequate everywhere, and it is not usually feasible to create a base map after a disaster. Therefore, it is important to start creating maps in normal times. Disaster Damage Map and Crisis Mapping can be accessed from anywhere in the world as long as an internet connection is available. However, in order to ensure smooth cooperation among stakeholders in the event of a disaster, it is essential to prepare in advance a cooperation agreement and/or an SOP. Other mapping systems might require preemptively drawing or identifying other types of resources, creating effective labeling systems, or identifying systems of communication or other sorts of permissions. • Appropriate technology - Different mapping and visual image collection systems have different strength and weaknesses-it is important to understand and identify these parameters to select the right technology for each purpose. With the Heli-Sat system, images could be blurred by shadows cast by the helicopter (the blocking effect). Since the Heli-Sat system transmits imagery information through geostationary satellites, the blocking effect is less likely to occur at low latitudes or equatorial areas, whereas it may occur at mid latitude locations such as Japan. The use of drones may create legal or permissions challenges. Satellite and aerial photographs avoid these challenges, but their collection process is slower. These technologies have different shortcomings and benefits in various aspects, including start-up time, areas that could be covered, impact of weather, night time operation etc. The ways the images will be used will help determine which technologies will be most effective, and how different technologies can complement one another. Disaster management is also evolving along with technology: in the future, crowd-sourced mapping may work in concert with AI systems for collecting disaster information, that are currently under development around the world. Also, disaster mapping is evolving to use three-dimensional information rather than two-dimensional data, such as AW3D72, which is the world’s first and most precise 3D map covering all Earth with 5-meter resolution, developed jointly by NTT DATA and Remote Sensing Technology Center of Japan. • Standard base maps - Creating cross-platform systems increases effectiveness. Heli-Sat, Disaster Damage Map and Crisis Mapping each provide an effective approach, but the systems lack interoperability because they use different base maps. Integrating the base maps would allow for data to be more easily shared and compared between the platforms. In Japan, integration of maps via Sharing Information Platform for Disaster Management (SIP4D73) is being studied. In countries where similar systems are being newly designed and/or implemented, there is an opportunity to create a standard base map to ease information sharing across platforms. 72 For more information on AW3D, see: https://www.aw3d.jp/en/about/ 73 System for sharing disaster information with collaboration among central agencies 68 DIGITAL SOLUTIONS FOR RESILIENCE 4.3.3 GIS-Based DIMS: ICT Systems and Context ICT Systems: Helicopter Satellite Communication System Figure 4-4 shows the system structure of the Heli-Sat System. At the time of a disaster, MLIT-owned helicopters are dispatched to capture real-time images and videos in affected areas74. The recorded data are transferred to various organizations, including local development bureaus of MLIT, using Heli-Sat communication lines over the regional satellite communication network75. The most notable characteristic of the Heli-Sat system is the adoption of an intermittent transfer technology synchronized with the rotation of the helicopter blades. Using intermittent transfer technology, radio signals are transmitted to a satellite from an open space between the rotating blades. Direct satellite transmission enhances the stability of data transfer. Besides, H.264/MPEG-4 Advanced Video Coding is employed in the system as the video compression technique, which reduces the amount of data in a video file and enables real-time data transfer to capture aerial photograph images anywhere in Japan. In terms of system resilience, the Heli-Sat system installed in helicopters is available as long as the helicopter is usable. On the other hand, the base station system can be installed into safer places because of its wide communication range. Images taken by the Heli-Sat system are distributed in real-time using a fiber-optic network owned by the development bureau of Kyushu region to related organizations such as universities and municipalities. The Heli-Sat system is also implemented in the development bureau of Kinki region and municipalities (Disaster Prevention Air Corps). Video Voice Auto-tracking Antenna Indoor Outdoor Equipment Equipment HSA System Equipment Ground A icted Station Area Figure 4 ‑ 4 System Diagram of Heli-Sat System Source: Mitsubishi Electric Corporation Ltd.:www.mitsubishielectric.com/bu/space/satellite_communications/systems/ ICT Systems: Disaster Damage Map Micro Media Disaster Information Network (MMDIN) decides whether to create a disaster damage map, sets the target area, and notifies related agencies. Then, a surveying company or Geospatial Information Authority of Japan (GSI) conducts aerial photography and ortho data conversion, and NTT GEOSPACE prepares detailed map data (including house shape data). Esri Japan then receives information from each organization and inputs it into their GIS. Finally, the MMDIN Secretariat creates a website and makes it public, and announces the public release of information. Information is exchanged using general internet lines and storage media. Because there is no need to prepare a dedicated line, implementing the Disaster Damage Map is relatively easy. Disaster Damage Map is free of charge, and can be accessed by anyone with an internet connection, in particular municipalities, NGOs, and relief organizations. This technology allows to quickly assess damages in affected areas in most cases. Figure 4-5 shows a schematic visual interface of the Disaster Damage Map. 74 For a Comparison of still and moving image technologies for collecting information in affected areas, see Appendix Table F.2.2. 75 FDMA also has five sets of the Heli-Sat System and uses them with fire department helicopters of Tokyo, Kyoto, Saitama, Miyagi, and Kochi. 69 [14] [14] [14] Internet Internet Internet [4] Aerial Surveying [3] Terminal PC Aircraft [8] ArcGIS Online [3] Terminal PC MMDIN Surveying ESRI Japan MMDIN Companies/GSI Secretariat [5] Storage Media [9] Detailed Map Data Disaster Event GEOSPACE Figure 4 ‑5 System Diagram of Disaster Damage Map Source: Based on material of MMDIN: http://www.mmdin.org/agonline.html Pre-disaster Post-disaster Figure 4‑6 Example of Disaster Status Map Source: Based on material of MMDIN: http://www.mmdin.org/agonline.html Note: The left side of the vertical line is an aerial photograph taken before the disaster and the right side is an aerial photograph taken after the disaster. The Disaster Damage Map helps to compare images before and after a disaster by moving the vertical line to the left and right. Red frames on the map show the shapes of buildings. 70 DIGITAL SOLUTIONS FOR RESILIENCE ICT Systems: Crisis Mapping Immediately after a disaster event, Crisis Mappers Japan, a non-profit organization, sends drones from the nearest station to the affected area to take photographs of the damages. Based on the aerial images, it applies for a project with the OpenStreetMap (OSM) task manager. Upon approval, mapping volunteers go to the affected area to update the status of damage after obtaining images captured by the drones. The images generated by this system can help people assess road damage very quickly. Crisis Mappers Japan mainly uses the following two drone models: SenseFly eBee, and Parrot Disco76. Crisis Mapping data or images of affected areas are shared through the Internet, with mapping volunteers updating map data remotely, so the system is highly resilient. From the user’s point of view, downloaded map data are available offline as well, so a user can continue to work even if there are communication failures in affected areas. Users (municipalities, NGOs, relief organizations, etc.) can access the Crisis Mapping system to edit updated map data from internet-enabled devices, and access is open to anyone. Taking aerial Orthorectifying Register as Task Posting necessary Reflecting the map data imagery of the imagery with Performing instructions Manager of OSM cooperation requirements in the OSM a ected areas OpenDroneMap (16) Satellite Communication [12] OpenStreetMap Network Crowdfunding Supporters Original Map Processing: Volunteer Mappers [14] Internet [14] Internet [12] OpenAerialMap Collaborators Map updated after Input: Crisis Mappers Japan [13] GitHub a disaster [14] [14] Internet Internet [14] [15] Mobile Internet Communication Network SD [3] Terminal PC [11] OpenDroneMap Card [12] OpenStreetMap Disaster a ected [6] Drones areas Voluntary Supporting Municipalities anti-disaster organizations organizations Figure 4-7 System Diagram of Crisis Mapping Source: Based on interview survey with Prof. Furuhashi (Aoyama Gakuin University) 76 For more information, see Appendix Table F.2.3 and Figure F.2.1. DISASTER INFORMATION MANAGEMENT SYSTEMS: GIS-Based Disaster MIS 71 1. Take and transmit images of disaster area 2. Integrate images and map data on GIS 3. Make and share the updated road maps HELICOPTER SATELLITE DISASTER STATUS MAP CRISIS MAPPING COMMUNICATION SYSTEM [2] Regional Development [3] MMDIN [8] Crisis Mappers Japan Bureau of MLIT • Judges whether to execute the opening of the disaster situation map • Dispatches a helicopter with a Heli-sat system to the a ected area • (If yes) Sets area and notifies data provider and take images of the area when a • Takes aerial images by using drones, disaster occurs converts them into ortho data, uploads the data, posts instructions to describe the support • Those image data are transmitted [4] GSI etc. [5] GEOSPACE activities necessary to update the map to the Regional Development Bureau and MLIT through the communication satellite. • Monitors the images and carries [9] Volunteer mappers • Take aerial images • Prepares detailed out the disaster response map data such as • Convert into ortho building structure data and send to polygon data Esri Japan [6] Esri Japan • Based on the instruction, mapping [1] MLIT • Mashups images and map data volunteers all over the world will carry out the tasks by region divided by the mesh. on ArcGIS Online • Monitors the images taken from • Other volunteers will check the updated the Heli-sat and dispatches support • Creates a disaster status map map and release it. from other Regional Development Bureaus as necessary • The updated maps are automatically taken into the web services or smartphone [3] MMDIN Secretariat applications using OSM as their base map. • Announces publicly that disaster status map is open [10] Disaster response agencies and support organizations • Grasp the damage distribution of the a ected areas Disaster Event Figure 4 ‑ 8 Institutional Overview of this Solution Source: Based on websites of JBP and MMDIN, and interview surveys with Dr. Hayashi (president of NIED), Prof. Furuhashi (Aoyama Gakuin University), and Mitsubishi Electric Corporation Ltd. 4.3.4 Enabling Environment Policy and Legislation (a) Heli-Sat System In Japan, Heli-Sat operations are not stipulated in the Radio Act. Therefore, the MIC has assigned the frequency band needed for Heli-Sat operations, and has defined the technical standards for communication devices to be loaded in helicopters in the enforcement regulations of the Radio Act and the radio facility regulations77. (b) Disaster Damage Map Permission is not necessary, except for implementation of aerial photography. There are no particular regulations or restrictions to create the disaster maps. 77 For instance, the device should have a function to control radio signals in relation to the rotation of blades, to immediately stop radio wave dissemination in the case of a communication failure with the satellite, and to detect device failures at the operator’s stations. In addition, part of the license issuance procedure has been modified so that satellite communications can be provided at the time of a failure of a contracted satellite using an alternative one (a partial amendment to the Regulations for radio stations licensing procedures). 72 DIGITAL SOLUTIONS FOR RESILIENCE (c) Crisis Mapping Since amendment of Civil Aeronautics Act in December 2015, there have been restrictions as a general rule on flying drones in Densely Inhabited Districts (DID) in Japan. During a disaster, municipalities are allowed to fly drones as a special measure, but not private organizations. Therefore, it is important for municipalities and private organizations to finalize a disaster agreement beforehand in order to have private organizations fly drones on behalf of municipalities. Crisis Mappers Japan sets flight routes with the approval of municipalities in normal times, so that it can start aerial shooting within an hour after a disaster strikes through automatic operation on a preliminarily defined flight route. The municipalities that have entered into an agreement with Crisis Mappers include Yamato City, Kanagawa Prefecture, and Chofu City and Komae City, Tokyo78. System Costs (a) Heli-Sat System Capital Costs: As a ballpark estimate, the development cost is about JPY 200 million per aircraft79. A total of 14 aircraft are currently in operation. The national government owns seven of these aircraft, distributed across different prefectures: the MIC owns five (located in Tokyo, Kyoto, Saitama, Miyagi, and Kochi prefectures) and the MLIT owns 2 (in Fukuoka and Osaka80). O&M Costs: Not disclosed (b) Disaster Damage Map Capital Costs: Expenses related to the system such as introduction cost and maintenance cost are not known. This is because the total expenses contributed by related companies have not been calculated. Administration is financed with membership fees from corporate groups that agree with this activity81. Since the map is created by volunteers now, the cost is lower compared to owning the systems outright. In that case, the license fee for ArcGIS online (approx. JPY 0.1 million per year) and operation staff costs would be required. O&M Costs: Essentially free of charge because it is based on contributions from cooperating companies. (c) Crisis Mapping Capital Costs: Approximately JPY 100 – 300 million, for purchasing drones82, GPS loggers, and drone control applications. O&M Costs: Essentially free of charge because it is based on open source services. 78 For more information, see Appendix Table F.2.4. 79 Based on inputs from Hyogo prefecture 80 For more information, see: https://www.projectdesign.jp/201510/new-disaster-prevention-measures/002465.php 81 The above corporate groups include data providers: PASCO, NTT Spatial Information Corporation, Global Survey Corporation Ltd., and other navigation companies. 82 Crisis Mappers Japan currently owns a fleet of about 30 drones. DISASTER INFORMATION MANAGEMENT SYSTEMS: GIS-Based Disaster MIS 73 4.4 Tokushima DIMS: Disaster Information Management System 4.4.1 Tokushima DIMS: System Overview After a disaster, logistical issues, including sharing information across organizations to coordinate response activities, pose a challenge. Tokushima Prefecture’s Disaster Information Management System (“Tokushima DIMS” hereafter) is a platform for disaster information sharing covering the entire prefecture. The Tokushima DIMS is used by about 500 organizations (as of September 2017), including the prefectural government and all municipalities, all hospitals, electricity companies, Japan Self-Defense Forces (JSDF), fire departments, and police departments. The Tokushima DIMS centrally manages damage information, disaster assistance activities, and services necessary to carry out the rescue and recovery operations efficiently, and to share the disaster response information quickly and accurately to the public. The Tokushima DIMS was created incrementally. It began as a system for sharing information needed to confirm personal safety, disaster response, and relief activities. Then, it was integrated with existing external systems, starting from EMIS. It finally expanded into its current version as more and more individual organizations joined the system. The Tokushima DIMS was designed with an easy-to-use interface; anyone in the organizations which have adopted the system can view or input information in the Tokushima DIMS through PCs, smartphones, or tablets. This data is collected in a unified format and can be easily accessed, reducing the burden on municipalities of collecting and sharing large amounts of dynamic information necessary for effective disaster response operations. In Japan, municipal governments are responsible for on-site disaster responses based on the “Disaster Countermeasures Basic Act83.” In the case of large disasters which incapacitate municipal governments, responsibility shifts to the prefecture: if the prefecture is also overwhelmed then national agencies coordinate the response. NGOs, NPOs, and private companies increasingly also play an important role in Japanese disaster response. Previously, disaster responses conducted by Tokushima prefecture focused on reporting to the central government (FDMA) damage information and the progress of responses by municipalities via telephone, FAX, and email, which created a heavy burden for municipalities. The efficacy of the response was also hampered by the presence of two distinct ICT systems84 which were not communicating efficiently with each other. Development of the Tokushima DIMS was started by integrating the EMIS system already operated by the medical department with the disaster information system owned by the Disaster Prevention Department, so that life-saving activities could be appropriately carried out85. The Tokushima DIMS was developed to streamline information transfer and sharing among concerned organizations, and to standardize disaster response work. It has three main features: 1) Disaster information entry; 2) Assessment roll-up: to illustrate risk levels and response levels visually on a GIS map; and 3) Missions management: disaster response task management system (see Appendix G, Table G.2.1). It has been successfully used in disaster response in the prefecture, including during the 2014 floods (see Appendix G.1). 83 Typically, the status of damage in affected areas is reported by municipal governments to the local (prefectural) government, which reports it to the National Government (the Fire and Disaster Management Agency (FDMA)). See Appendix Figure G.2.1 for a visualization of disaster information collection and aggregation in Japan. 84 Developed independently by the Disaster Prevention Department and the Medical Department. 85 For a timeline of the development of DIMS in Tokushima Prefecture, see Appendix G, Table G.2.3. 74 DIGITAL SOLUTIONS FOR RESILIENCE Key adopters Disaster Management Department of of the Tokushima Prefecture solution Beneficiaries 499 organizations, including Tokushima (Users of the prefectural government and all database) municipalities in Tokushima prefecture, all hospitals, utility companies, Japan Self- Defense Forces (JSDF), local fire department, and police departments (as of September 2017) System Development: SiteBridge Inc. Developers Maintenance service: Tec Information Corp. Development for system enhancement: Falcon Corp. (Since 2017) Year of 2012 Launch Costs Development cost86: 45 million JPY Cost of System Enhancement87: 106 million JPY Operation and maintenance cost: About 11 million JPY / year Source: Developed by the authors based on inputs from Tokushima prefecture. 86 29 million Yen borne by Tokushima prefecture, and 16 million Yen funded by Ministry of Health, Labour and Welfare 87 63 million Yen was allocated in 2014 (17 million Yen borne by Tokushima prefecture, and 46 million Yen subsidized by Ministry of Internal Affairs and Communications), and 43 million Yen was allocated in 2016 (10 million Yen borne by Tokushima prefecture, and 33 million Yen subsidized by Ministry of Internal Affairs and Communications) 75 4.4.2 Tokushima DIMS: Lessons and Recommendations • Awareness - Awareness and education initiatives encourage people to contribute information to DIMSs. If the stakeholders are not fully aware of the direct benefit of DIMSs, in the event of a disaster they are unlikely to input data given other urgent priorities. In fact, lack of awareness in the past has been a key barrier to the effective operation of DIMSs to function effectively in post- disaster situations. EMIS was officially launched in 1996 based on lessons from the 1995 Great Hanshin-Awaji Earthquake, but staff members at hospitals were busy responding to injured people and the system was not effectively utilized for a long time. In 2005, the Disaster Medical Assistance Team (DMAT)88 started to use EMIS as a management system during operations on site, and to implement annual trainings for DMAT staff around Japan, which has led to effective use of the system and helped information centralization including sharing and reporting information. For the Tokushima DIMS, the problem of information input has been overcome by creating annual trainings at both the prefecture and municipality levels. Communicating the system’s benefit to the prefecture has also helped improve participation among stakeholders. Linking the system with EMIS has also increased participation by preventing the need to input information twice. In general, it is important to clarify and raise awareness on the merits of using DIMSs (i.e. more effective use of disaster information and time-saving potential during disaster times) and inform relevant parties accordingly. • Centralization - Centralized DIMSs can reduce clerical work, but should communicate with existing systems. Clerical work for mass communication was reduced by the Tokushima DIMS. Before the system was introduced, the Disaster Prevention Department was required to regularly summarize the status of damage from each department within the agency and related organizations in order to respond to the mass media. Since the introduction of the system, the Disaster Prevention Department needs only to summarize the latest information, because information from each organization is updated in real-time. Thus, the burden of organizing information at each department for corresponding with mass media decreased, while the disaster management department no longer has to contact each department to compile data. Similarly, linking EMIS to the Tokushima DIMS eliminated duplicate inputs, as information in the system was automatically reflected in EMIS. When designing consolidated systems elsewhere, the ways disaster information is already managed should be considered, to ensure they can integrate with existing programs. • On-demand relief - Decentralized requests systems can contribute to the quick and targeted fulfillment of post disaster needs, with possibilities of partnering with the private sector. The Tokushima DIMS is capable of collaborating with an Amazon wish list, which allows evacuees to receive support with what they want, and relieves municipal officials from the burden of procuring materials for evacuees. Representatives of evacuation centers compile the type and number of supplies needed and enter information on the desired list from the website. Then, the supporter buys the goods through Amazon, and the goods are sent to the evacuation center. This means staff of the prefecture can assess a situation by linking the Amazon wish list information with the prefecture DIMS. Other systems should consider the advantages of linking post-disaster needs and logistics to reduce the burden on heavy centralized systems. 88 Disaster Medical Assistance Team (DMAT) consists of doctors, nurses, and coordinators (medical staff other than doctors and nurses and administrative staff). They are specially trained and have mobility for acting in the acute phase (generally within 48 hours after a disaster occurs) on the scene, such as a large-scale disaster and accidents where multiple people are seriously injured. 76 DIGITAL SOLUTIONS FOR RESILIENCE • Cross-level support - DIMSs should be designed to permit support across government levels to assist local governments when they are overcome by the demands of a disaster. For example, when Mashiki Town was heavily damaged by the Kumamoto earthquake and did not have enough capacity to input real-time damage and needs data, staff of Kumamoto Prefecture (who had a duty to report to the Emergency Operation Center (EOC) at the national government) entered the data and substituted for the town staff. In Shizuoka Prefecture, the system has been pre-established to substitute for municipalities If they are incapacitated by a disaster. The prefecture was divided into four areas, each with assigned prefectural officials prepared to support one another in the case of a disaster. A large-scale disaster can easily overwhelm the resources of a municipality or other local government; establishing systems like these at the regional or national scale to support local governments can help cope with expanded needs during emergency times. Similarly, resource or staff-sharing agreements between municipalities themselves can also be important, allowing people responsible for operating specific DIMS in one municipality to aid with that system in another municipality when a disaster occurs. • Existing infrastructure - DIMSs which use preexisting ICT infrastructures can reduce development costs and implementation time. With Tokushima’s DIMS, municipalities and utility companies can send information using standard mobile devices and an internet connection. Receivers of information similarly require only widely-used devices (such as mobile phones, radios, PC, and landline telephones) and an internet connection. Thus, the Tokushima DIMS works with the existing internet connections or the mobile communication lines without requiring any dedicated line services or special terminals. When developing DIMS, using pre-existing ICT infrastructures rather than creating special new infrastructures can make these systems more easily applicable, even in developing countries. • Pre-disaster planning - DIMSs require pre-disaster planning, training, and relationship-building through the development of a Standard Operating Procedure (SOP) and/or Business Continuity Plan (BCP). Since the system is designed to effectively perform response and recovery efforts and resource management after a disaster occurs, it is necessary to clarify the work to be carried out in advance. Therefore, the system development requires a Standard Operating Procedure (SOP) integrated within the municipal government and/or institutions disaster response manual and/ or business continuity plan (BCP). It is also important that the disaster response governance mechanisms and cooperation procedures are discussed, agreed, and endorsed in advance between relevant sectoral government agencies at the municipal and national level, private sector, and local communities, regarding their specific roles and responsibilities. • Redundancy - Redundancy increases the resilience of the system by ensuring uninterrupted use of DIMSs during a disaster. Because it is inevitable that terminal equipment may fail, the Tokushima DIMS can be accessed from any device via authorization with a user ID and password. While the Tokushima DIMS normally uses internet for information transmission, it is also possible to connect via the disaster prevention radio communication system owned by municipalities. The web service is implemented on servers located on the premises and via a cloud service (located in eastern Kanto) with a failover option. It is also being considered using multiple cloud services at various locations to ensure server functionality. 77 4.4.3 Tokushima DIMS: ICT Systems and Context Systems and Infrastructures The Tokushima DIMS hosts the following features89: • Disaster Information Entry: Hosts information input by various levels of government and organizations. This includes data such as government buildings damage, headquarters setup for disaster control in municipalities, evacuation information (such as evacuation advisory and evacuation order, etc.), situation of shelters (such as number of evacuees, surplus or shortage of relief supplies, etc.), METHANE90 information, blackouts, traffic restrictions, river levels, amount of precipitation, and information relating to medical service availability. • Assessment Roll-up: Summarizes and shows assessment items at a selected summary level, such as municipalities, areas, and shelters. Assessment items are shown in colors to indicate response status, which helps users find areas needing assistance or materials to be provided. • Missions Management: manages the response status for items needed for assistance. Items to be managed include Assistance category, Conducting entity and its name, Deadline, Status, Description of mission. Since the system original software is based on an open source program, the codes could be used for free by other governments to develop similar systems (except for the GPL licensed codes91). Figure 4-9 Disaster management system information entry screen (Map View) Source: Based on materials provided by Tokushima Prefecture Note: * Damage severities are shown with different colors of icons and letters so that the overall situation can be grasped at a glance. * Colors indicate severities: blue for not damaged, yellow for partially damaged, and red for functions lost 89 For a detailed description of hardware, software, linkage and network components of the system see Appendix Table G.3. 90 METHANE is the acronym for the following information which is needed by each unit of disaster sites: My call-sign, Exact Location, Type of incident, Hazards, Access to the sites, Number and severity of casualties, and Emergency services. 91 GNU General Public License 78 DIGITAL SOLUTIONS FOR RESILIENCE The Tokushima DIMS relies on cloud servers inside the prefecture building as well as external cloud servers, which ensure redundancy. The Tokushima DIMS normally uses Internet connections for communication, but it is also possible to connect using the disaster prevention radio communication system owned by municipalities. The Tokushima DIMS can be accessed from any device via authorization with a user id and password, in order to ensure usability. User IDs are assigned to each user with different access rights. The information collected by the Tokushima DIMS can be transferred to the press and the media, and broadcast for further distribution. The system also allows for coordination with external systems including weather, earthquake, medical information, and data from other portions of the Tokushima prefectural government (see Figure 4-10). Disaster information collected in this system is disseminated to residents via the Tokushima integrated map service system and the Safe-Tokushima website. Furthermore, information on emergency alarms and evacuation is delivered by EAM or L-ALERT. For a more detailed description of system components see Appendix G, Table G.2.2. Tokushima Prefecture External Data Amazon center (IDC) [1] Terminal [2] Cloud servers in the [17] Amazon wish list PCs prefectural building Seven Eleven [18] SEVEN VIEWS (5) Disaster Information Sharing System Private Data Ctr. JWA (6) Assessment roll-up [24] [21] Tokushima (7) Missions Internet integrated map [13] Meteorological service system management information services [3] External Cloud (8) Shelter management Servers (9) Secondary Tokushima Pref. HALEX emergency medical care information system [22] Safe-Tokushima [24] website [14] Meteorological Internet (10) Safety confirmation data services system (Web API) (11) Emergency Alert Mail transmission system USGS [4] General Terminal [15] Earthquake Devices (browing only) Information [23] LAN Mobile carriers Registered MHLW [26] [25] Users IP-VPN [19] Emergency [16] EMIS VPN Alert Mails • If the seismic intensity is 6.5 [12] Tokushima Disaster or more, information is sent Information Management to registered users via [27] FMMC System Commons e-mail. VPN [20] L-Alert Figure 4 ‑10 System Diagram Source: Based on material from Tokushima Prefecture DISASTER INFORMATION MANAGEMENT SYSTEMS: Tokushima DIMS 79 [2] Municipalities • Conduct damage status surveys in the municipality • Enter damage and response status information into the system [3] Hospitals & Welfare facilities [1] Tokushima Prefecture Relevant organizations [4] Schools • Operates and maintains the Disaster • Carry out disaster response activities, • Conduct damage surveys on Management System transmit information, and provide assistance hospitals, facilities and schools based on the shared information • Conducts status surveys on damage status • Enter damage and response in Tokushima prefecture status information into the system • Enters damage and response status [10] Fire department information into the system [5] Utilities Companies • Analyze and assess the damage status • Enter damage and response • Share the information with other concerned [10] Police department status information into the system organizations regarding facilities, service operation and recovery status, etc. [10] Japan Self-Defense Forces [6] Japan Weather Association [7] HALEX [10] Press and the media The Disaster Management System • Provide weather information Collects and shares disaster-related information covering the entire [10] Municipalities and other territory of Tokushima prefecture. organizations [8] Seven-Eleven • Enter the operational status (open/close, power outage, no batteries, communication line disturbance, delayed deliveries, delivery impossible) [9] Residents and private companies • Enter information in the system (using SNS service “Sudachi-kun” for safety confirmation) Figure 4 ‑11 Institutional overview of the Tokushima DIMS Source: Based on information provided by Tokushima Prefecture Institutional Framework About 500 organizations were given permission to use (for information entry and view) the Tokushima DIMS, including Tokushima prefecture and all municipalities, all hospitals, electricity companies, JSDF, fire department and police department of Tokushima prefecture. The roles of these organizations are shown in Figure 4-11, and detailed descriptions of organizational roles can be found in Appendix G, Table G.2.4. 80 DIGITAL SOLUTIONS FOR RESILIENCE 4.4.4 Tokushima DIMS: Enabling Environment Policy and Legislation The Tokushima DIMS has benefitted from prefectural and national programs which have supported its development. Since 2004, Tokushima has been working towards improving public and private communication infrastructure in the prefecture, and under the ‘e-Tokushima Promotion Plan.’ The 2014- 2018 “ICT Tokushima Creation Strategies” which fall under this plan include considerations for disaster events such as a projected Nankai Trough megathrust earthquake. The Tokushima DIMS is one of these strategies, aiming to enhance information sharing across the prefecture by increasing the number of organizations within the network (Tokushima Prefectural Government, 2014). In addition to support at the prefectural level, the Tokushima DIMS received support from the national government as a feasibility study project for enhancing the disaster information sharing infrastructure in the Geospatial city development project, which is an initiative led by the MIC. Through this study project, new applications were developed including a safety confirmation system called “Sudachi-kun”, which is a platform to collect damage information from citizens; floods; medicine demand forecast for prolonged shelter life based on “medicine delivery result” analyses; and relief goods procurement system using an Amazon wish list. Furthermore, the Tokushima DIMS was connected to the Tokushima “Integrated map service system” and to “L-ALERT” in order to help disaster information be effectively provided to residents in affected areas92. System Costs The functionality of the Tokushima DIMS continues to be upgraded: from 2012-2015, JPY 151 million had been spent on development, of which JPY 95 million was subsidized by the national government. The Tokushima DIMS can be accessed using ordinary devices such as smartphones, tablets, and PCs through a regular internet connection (no dedicated line is required). The estimated Operation and Maintenance Costs for 2017 was JPY 11 million93. 92 For more information, see: http://www.soumu.go.jp/menu_seisaku/ictseisaku/ictriyou/geo-spatial_ict/g-city/project/p04.html 93 Based on inputs provided by Tokushima prefecture. DISASTER INFORMATION MANAGEMENT SYSTEMS: Tokushima DIMS 81 4.5 K-DIS: DIMS for Utilities 4.5.1 K-DIS: System Overview During a disaster, power supply can be lost due to damage to facilities, such as electric generation plants, substations, and transmission and distribution lines. Electric power companies need to promptly resume the power supply, but it is very difficult in an emergency to rapidly acquire information on the damage. The Kansai Electric Power Co. Inc. (Kansai94) recognized this issue after the 1995 Great Hanshin-Awaji Earthquake. By 1998 the company introduced a DIMS to collect damage and recovery information within its service areas and share it among all employees as soon as possible. Kansai has constantly improved its disaster information system, and operation of the current K-DIS system started officially in June 2016. Organizations Kansai Electric Power Co. K-DIS is a disaster information system for integrated adopting this Inc. (KANSAI) data management to collect information on the solution status of damage of electric infrastructure such as Beneficiaries All employees of KANSAI, substations and transmission lines, as well as power (Users of the especially at Emergency database) Operation Center for outages and recovery status, ensuring the utility’s disaster response optimal resource allocation. System Not disclosed K-DIS was developed by Kansai separately from the Developers company’s central information management system, Year of 2016 which monitors electric power services such as Launch electricity generation but not the extent of damage Costs Capital Costs: Not disclosed by equipment, the time required for recovery, and the Operation and Maintenance Costs: Not disclosed implementation of restoration measures. Source: Created by the authors based on inputs from KANSAI K-DIS is based on WebEOC95 to provide centralized management of the status of damage and responses. K-DIS provides visual information about the afflicted areas through a Map Display Board (see Figure 4-12), which helps grasping the operation status of various power plants, power outage areas etc. Activity logs in the program record the tasks carried out by different groups in chronological order. K-DIS is used not only for major disasters but also for minor incidents such as outages due to lightning in regular operations. Map Viewer Figure 4‑12 Image of K-DIS features (Map Display Board) Contents: Operational status of hydropower, thermal power and nuclear power plants; Damage information on electric distribution networks, hydropower plants, Legend dams, and thermal power In operation plants; Power outage areas; The displayed power outage areas are based on the press During power up Operational status of generator announcement as of at 17:30 Checking ability of cars, helicopters and vessels etc.; on May 6, 2016. Therefore, power up there is a possibility that the Registered information such as Unable to power up road conditions latest status is not reflected. The area is displayed in units Out of service of municipalities. Source: Based on materials provided by KANSAI Map Contents · Operational status of hydropower, thermal power and nuclear power plants · Damage information on electric distribution networks, hydropower plants, dam and thermal power plants 94 Kansai Electric Power Co. Inc. provides power generation, transmission, distribution, and retail. See Appendix H.2 for details. · Power outage areas · Operational status of generator cars, helicopters and vessels etc. · Registered information such as road conditions 95 WebEOC is an emergency management system for emergency measures deployed on the Web. It is adopted in 40 states in the US, many companies, and public institutions, and is the de-facto standard worldwide. K-DIS is the first case of a disaster information system 82 using WebEOC. DIGITAL SOLUTIONS FOR RESILIENCE 4.5.2 K-DIS: Lessons and Recommendations • Central management - Creating a system of centrally managed and company-wide open disaster information can serve as a real-time decision-support system for utility companies, allowing them to make quick and informed disaster mitigation and management actions in a fast-changing environment. K-DIS provides great information visibility to decision makers by centrally managing all disaster information (damage, restoration, and response status) collected by various departments within the utility company, and by summarizing important information in the Company-wide Activities Log. In past incidents, the Company-wide Activities Log functioned as an excellent tool for monitoring the response status of important operations, and the Map Display Board has also been effective in providing visual information about afflicted areas. Having this information at their fingertips in real-time allows decision makers to move-quickly in rapidly- evolving disaster situations. • Data security - DIMSs for power companies should prioritize data security due to the sensitive nature of infrastructure information. K-DIS is tailored to the needs of the Kansai power company which operates in the Kansai Region. Since the utility handles confidential information, to protect this data K-DIS uses in-house telecommunication networks rather than external systems. K-DIS follows procedures outlined in Kansai’s “Disaster Management Plan,” which is based on Japan’s 1962 Disaster Countermeasures Basic Act. Sharing information about sensitive infrastructure can be risky, and in other countries the local context should determine the optimal system by weighing the extent of information sharing with confidentiality concerns. • Cooperation - Managing disaster information for public utilities requires interdepartmental and interagency cooperation. To provide disaster status information to Kansai, K-DIS receives also information from other groups including police and fire departments, customers, and municipalities. Kansai also shares information with the Japan Self-Defense forces, national government ministries, and other power sources via its Emergency Operation Center (EOC). K-DIS is a good example of the importance of coordinating disaster information across different agencies and levels of governance, particularly for public utilities which are critically interconnected with other government agencies. • Standard Operating Procedure - Roles and responsibilities in a system like K-DIS should be defined by a Standard Operating Procedure (SOP) integrated within the institution’s disaster response manual and/or Business Continuity Plan (BCP). The SOP should include at least the following procedures: during a disaster, who sends what kind of information to whom; how to process; how to output; and who (which department) gets what kind of information. K-DIS and its SOP were developed in alignment with Kansai’s “Disaster Management Plan,” which defines the procedures to be followed during an emergency, and was developed following Article 39 of the Disaster Countermeasures Basic Act96. • Activity Log - DIMSs can be used not only to record and share information about a disaster status, but also about response activities. A key component of K-DIS is the company-wide activities log, as well as activity logs for individual divisions within K-DIS. The activity log records critical response-related activities from different groups in a chronological format. This structure allows a quick assessment of current progress and identification of areas that might need additional support. The critical response-related activities recorded in a chronological order could also be used by decision makers to find areas of improvement for future disaster response activities. 96 For more information, see: http://law.e-gov.go.jp/htmldata/S36/S36HO223.html 83 4.5.3 K-DIS: ICT Systems and Context Institutional Framework Information to be centrally managed by K-DIS in the event of a disaster includes internal information gathered by Kansai such as status of damage and status of recovery of its facilities and status of power outages, and information from various sources, including national and local governments, police, fire department, Japan Self-Defense Forces, etc., as shown in Figure 4‑13; for further details of organizational roles, see Appendix H, Table H.2.2. During a disaster, recovery actions need to be coordinated among relevant organizations, including government, police, fire department, media organizations, etc. Arrangements are made with other electric power companies for electric supply, equipment for recovery, human resources, etc. K-DIS provides the relevant organizations information needed for these activities. When a disaster occurs, each group enters the records of its activities as an “Activities log” in the system. The logs are recorded in the “Communication note” in chronological order. The most important records to be shared throughout Kansai are transferred in chronological order to the “Company-wide activities log” and centrally managed. Details of usage of K-DIS in past events are provided in Appendix H.1. RELEVANT AGENCIES Ministries and National Agencies • Share the EOC deployment status, and ask Kansai to report the damage status of their facilities Municipalities EOC in Kansai Kansai generation, transmission & distribution asset departments • Share the EOC deployment • Sets up immediately after severe status, and ask Kansai to dispatch disasters, and takes control over the • Upon receiving directives from the a liaison range of tasks to be carried out by EOC through the Communication Notes, each group using the Communica- executes assigned tasks, and records tion Notes the activities Police and Fire Department • Provides information and asks for • Primary tasks are to monitor the assistance from external damage situations and the power • Report the tra c restrictions and organizations supply status, and to request assistance blaze situations • Enters the information received by as needed telephone or fax from external Self-Defense Forces organizations Kansai Logistics Support • Share the request for SDF dispatch from municipalities with department Kansai • Upon receiving directives from the EOC through the Communication Notes, Customers K-DIS supplies daily commodities, such as Collecting and sharing internal transportation, accommodation, and • Report facility damages and and external information fuel. power outages to Kansai Other electric power providers (e.g. TEPCO) • Report facility damages and Broadcasters power outages to Kansai • Broadcast the information received from Kansairegard- Other sources of power ing power outages and response statuses • Provide information concerning the availability and support capacities of electric power, etc Figure 4 ‑13 Institutional overview of the K-DIS Source: Based on material provided by Kansai 84 DIGITAL SOLUTIONS FOR RESILIENCE Systems and Infrastructures The components of K-DIS are connected to each other by dedicated in-house communication lines97, and operation of K-DIS is enabled through the same PCs used by employees in normal times. In addition to K-DIS, Kansai owns a weather alert system, A-BIS to manage failures of transmission and distribution lines, and AccESS to manage power outage information. Information stored in these systems is also available from K-DIS, which is entered in to K-DIS at Kansai’s Emergency Operations Center (EOC). The resilience of the system is ensured by duplicating servers and communication lines. For a detailed description of the K-DIS components, see Appendix H, Table H.2.1. In terms of software, K-DIS includes the following key components: • Facility Damage Situation Board: summarizes the status of damage of each facility based on damage information entered on the board (entry screen) by each group. This information is interfaced with the Map Display (See Appendix H, Figure H.2.2). • Map Display: shows the status of damage on the map based on information summarized on the Damage Situation Board. Information includes, among the others: Operating status of power stations (e.g. thermal, hydro, and nuclear); Status of damage to dams and power stations; Blackout areas; Operating status of electric generator vehicles, helicopters, ships, etc.; Traffic status. • Communication Notes: used for various communication, such as announcements, requests, etc., and task management. EOC issues a communication note on the information or requests to be shared, and based on the note, each group records the tasks they carried out. EOC uses these notes to understand the response status. Important records are copied to the Company-wide Activities Log, shown in the “Company-wide Timeline” screen in chronological order (See Appendix H, Figure H.2.3). • Company-wide Activities Logs: summarizes critical issues from communication notes, and from group activity logs, and displays summary information in chronological order (Company-wide Time Line) (See Appendix H Figure H.2.4). 4.5.4 K-DIS: Enabling Environment Policy and Legislation Kansai has defined processes to be followed at the time of a disaster in its “Disaster Management Plan,” following Article 39 of the Disaster Countermeasures Basic Act98, which mandates designated public institutions to create disaster management plans99 (Kansai, 2018). In addition to the disaster management processes, the disaster management plan developed by Kansai incorporates the “Promotion of special provision for Nankai Trough Earthquake”, which includes disaster management plans specifically designed for the future Nankai Trough earthquakes, and the “Enhancement program for disaster prevention against large-scale earthquakes”, which prescribes the measures and plans required to strengthen disaster management for large-scale earthquakes in general. The disaster management plan specifies criteria to set up the EOC and its roles, and communication channels for directives and information both inside and outside Kansai. K-DIS was developed in alignment with this plan. System Costs Neither capital costs nor O&M costs have been disclosed. 97 Kansai generation, transmission and distribution asset departments 98 The Disaster Countermeasures Basic Act was promulgated in 1961 and enforced in 1962. For more information, see: http://law.e- gov.go.jp/htmldata/S36/S36HO223.html 99 For more information, see: http://www.KEPCO.co.jp/corporate/notice/20140922_1.html DISASTER INFORMATION MANAGEMENT SYSTEMS: K-DIS 85 4.6 Hyogo Asset Management System: DIMS for Infrastructure 4.6.1 Hyogo Asset Management System: System Overview The Asset Management System was developed to manage ledgers of infrastructure facilities (called “the facilities ledger”) and facility inspection results in an integrated fashion. In normal times, it is used as an asset management system for infrastructure facilities (roads, bridges, rivers, harbors, sewerage, etc.) in Hyogo prefecture, and can be used for superimposing hazard maps and facility maps. This system also functions as a DIMS100, in conjunction with the asset ledger system, in order to collect and assess damage and response status. As a disaster management system, it has functionalities to identify bridges to be prioritized for restoration, especially those located on roads designated as emergency goods transportation routes, to calculate alternative routes based on the status of damage and to make plans for restoring roadways based on the status of damage. Organizations Public Works and Development adopting this Department, Hyogo prefectural The Asset Management System has wide solution government accessibility, including the Internet via the Beneficiaries Department of Land Development prefectural network (WAN), or solely via the (Users of the and relevant departments of Internet for auxiliary organizations, and using the database) Hyogo prefecture, and Hyogo mobile network from construction and inspection Construction Technology Center sites. for Regional Development System Development: Fujitsu Limited The development of the system responds to Developers Operation and maintenance: the challenges of maintaining and managing Fujitsu Social Infrastructure social infrastructure with limited budgets and Management System Group human resources, while facing a severe fiscal (2012-2016), Fujitsu Lease (since situation, deterioration of infrastructure facilities 2017) built during rapid economic growth, and staff Year of 2013 Launch shortages. One of the most critical issues Costs Not disclosed. in Hyogo prefecture, which experienced the Source: Developed by the authors based on inputs from Hyogo Hanshin-Awaji Earthquake in 1995, is to ensure prefecture. the safety of infrastructure. However, it had been difficult for the prefecture to carry out an overall review of asset status and asset maintenance costs, due to segmented management by types of facility, such as bridges, harbors, and sewerage. To address these issues, Hyogo prefecture developed the Asset Management System, an integrated system which can control various infrastructure data, allowing the prefecture to carry out infrastructure management more efficiently101. 100 Although there has not been a disaster event for which the Asset Management system was used, it is expected to be effective because the same system can be used for both normal and disaster operations. 101 For more information, see: http://pr.fujitsu.com/jp/news/2013/01/29.html 86 DIGITAL SOLUTIONS FOR RESILIENCE 4.6.2 Hyogo Asset Management System: Lessons and Recommendations • Ordinary use – ICT systems can be designed with both ordinary and DRM functions. During non-disaster times, the Asset Management System serves as a ledger of municipal infrastructure facilities, allowing for integrated management of social infrastructures across Hyogo prefecture communities. This functionality makes facility management efficient and safe across the prefecture102. The system’s cloud service (created through private data centers) is designed with a high level of disaster resilience, so it can also be used for disaster response. This combination of both disaster and non-disaster uses also means that users are more familiar with the system when a disaster does happen. Other ICT for DRM systems might consider how to be leveraged during non-disaster times. Existing ICT systems which might take on DRM functions require stable power supply and disaster-resistant infrastructures. • Training – Training and guidelines are required to effectively use the system, especially during a disaster. The basis of the Asset Management System is facility ledger management. Therefore, it is necessary to develop a mechanism and capacity (i.e. through personnel training) to properly manage the facility ledger. Developing guidelines has helped the effective use of this system to become more widespread. In other countries, it is important to consider not only the ICT strategy for DIMS, but also how users will be educated and motivated to participate. • Low bandwidth – The use of mobile networks and terminals allows users to update DIMSs from the field; however, some functions may be too data-intensive for mobile users. The Asset Management System does not require a large bandwidth, and all its features are available over the mobile network. Therefore, the system can be used from construction and inspection sites using mobile terminals, such as smartphones or tablet PCs to browse or update ledger information and to enter additional information with attachments of photographic images etc. 102 http://pr.fujitsu.com/jp/news/2013/01/29.html 87 4.6.3 Hyogo Asset Management System: ICT Systems and Context Institutional Framework The Hyogo Construction Technology Center for Regional Development (CTC) enters infrastructure facilities data, which are available to prefectural staff, into the system. At the time of a disaster, the status of damage to infrastructure facilities can be entered from afflicted areas or engineering offices (see Figure 4-14 as well as Appendix I, Table I.1.3 for details). To solve issues associated with lack of guidelines, personnel not following guidelines, and lack of knowledge transfer to new staff, general guidelines and mandatory rules (for example, setting up responsible positions in business flows) were developed in addition to consolidating registration tasks at CTC. Hyogo Construction Technology Center for Regional Development • Enters infrastructure facilities data into the Internet Data Center Facility Ledger system Hyogo Infrastructure Facility Integrated Management System Hyogo Prefecture Facility Ledger system • Delivers landslide disaster warning information and flood forecasts for designated rivers Assets management system • [Normal operations] Carries out inspections, diagnoses, assessments of GIS system infrastructure facilities, makes plans for and reviews repairs and renewals of facilities, and implements repairs and renewals Requests and complaints based on the plan management system • [Disaster operations] Manages the damage situation and response status in conjunction with the facility ledger system Photo-storage system • [Disaster operations] Identifies bridges to be prioritized for restoration, based on Mobile system designated emergency transportation routes • [Disaster operations] Calculates alternative routes for the emergency transportation based on damage status Figure 4 ‑14 Institutional overview of the Asset Management System Source: Based on material provided by Hyogo Prefecture Systems and Infrastructures The operating process of the Asset Management System is summarized below. 1. The facility ledgers are generated and updated by contractors for new and repair constructions or for maintenance inspections, and then they are delivered to Hyogo prefecture. The centrally managed Facility Ledger System103 records data about 22 types of infrastructure including bridges, roads, seawalls, and parks104. 2. The ledgers are forwarded from the prefecture to CTC, where ledger data are entered into the Asset Management System105. Ledger data in the system are available to staff of the Department of Land Development of Hyogo prefecture and civil engineering offices to output data in files or to print hard-copy. 103 See Appendix I, Figure I.1.1 for an overview of the Facilities Ledger System interface. 104 See Appendix I, Table I.1.1 for a list of infrastructure facilities included in the ledger. 105 See Appendix I, Figure I.1.2 for an overview of the Asset Management System interface. 88 DIGITAL SOLUTIONS FOR RESILIENCE 3. The linked Geographic Information System enables users to check the location of facilities and analyze data by overlaying information maps. 4. The Requests/Complaints Management System106 can store requests and complaints from residents for effective regular maintenance processes. The person in charge of the facility enters resident feedback as well as response status and actions taken. 5. Photographs taken on site, such as status of disaster and patrol observations, are archived in the Photograph Storage System107 and are instantly available to various organizations including afflicted sites, engineering offices, and the main prefectural office. The following figure shows the system diagram of the Asset Management System; for additional details on system components see Appendix I, Table I.1.2. Hyogo Construction Cloud Hyogo Infrastructure Facility Technology Center for Service Integrated Management System Regional Development Servers for the systems Terminal for GIS system browsing and Internet inputting Facility Ledger system Assets management system Hyogo Prefecture Terminal for Requests and complaints browsing and management system LAN inputting Photo storage system Location Mobile system Mobile Information communication Smartphone networks and tablet PC Figure 4 ‑15 System diagram Source: Based on information provided by Hyogo Prefecture The Asset Management System has the following additional features: • Both hardware and software are located at private Internet data centers (“IDCs” hereafter), to contain operating costs and because of the center’s data security in case of earthquakes and other disasters. Another advantage of IDCs is information sharing over the Internet with related organizations including MLIT. • The GIS stores, in addition to facility locations, layers of drawings from legal ledgers’ appendixes of public facilities such as schools, emergency transportation routes and urban planning, and ledgers of roads and rivers. • A new code is introduced to identify infrastructure facilities. The code is used as a control number that is common to all facility categories, which ensures the flexibility and scalability of databases. 106 See Appendix I, Figure I.1.3 for an overview of the Requests/Complaints Management System. 107 See Appendix I, Figure I.1.4 for an overview of the Photograph Storage System. DISASTER INFORMATION MANAGEMENT SYSTEMS: Hyogo Asset Management System 89 There are multiple ways to access the Asset Management System, including the Internet via the prefectural network (WAN), or through the Internet for auxiliary organizations, or using the mobile network from construction and inspection sites. This broad accessibility was achieved by installing all hardware and software in IDCs. 90 DIGITAL SOLUTIONS FOR RESILIENCE 4.6.4 Hyogo Asset Management System: Enabling Environment Policy and Legislation The Asset Management System was developed by Hyogo prefecture to collect infrastructure data and analyses and evaluation results to elaborate the prefecture’s 10-year infrastructure maintenance plan for extending infrastructure life by reducing maintenance costs and optimizing the budget for social infrastructure. Hyogo prefecture has been working on the plan since 2011, along with developing and enhancing the Asset Management System. The system was developed by local governments in part because they already had a facility ledger, and municipal government staff are mandated to manage and update them in Japan. DISASTER INFORMATION MANAGEMENT SYSTEMS: Hyogo Asset Management System 91 92 DIGITAL SOLUTIONS FOR RESILIENCE [5] Key Takeaways and Next Steps on ICT for DRM Image: Disaster information management drill in preparation for major power outage (Jun. 2019). Source: Kyodo News Images. 93 Key Takeaways and Next Steps on ICT for DRM In this report, several ICT solutions for DRM in Japan are surveyed and analyzed through EWSs and DIMSs case studies. Conclusions and lessons that may be of relevance to policy makers in other countries are discussed below. Ensure effective data management – ICT for DRM must be supported by accepted rules, procedures, and relationships that encourage, facilitate, and guide the production, sharing, analysis and use of data in response to disasters. Access to reliable, detailed, and timely information at all levels of society is crucial immediately before, during, and after a disaster. An effective emergency response can be provided only if disaster information data are readily collected, processed, analyzed, and shared. Effective data management enhances scalability and interoperability of EWSs and DIMSs. As observed in most of the ICT solutions covered in this report, cloud computing helps ensuring effective data management. It offers resiliency and redundancy with its off-premise nature, and changes the finance structure from CAPEX-based to OPEX-based, increasing the financial flexibility of public institutions. Design for today and the future – ICT for DRM should be designed taking into consideration the existing ICT context and planned or projected future conditions. The specific ICT utilized in Japan for EWS and DMIS may not necessarily be appropriate for other countries, especially because the systems strongly depend on robust telecommunications infrastructure. For example, in the case of EWS, it is desirable to maximize the transmission routes using systems familiar to residents, which may be different depending on the country. In every country, the solutions must be based on the existing communication infrastructure, as well as future development plans. In particular, in developing countries ICT for DRM should also consider the current and projected economic conditions to select economically feasible systems which can also be maintained over time. For example, EAM (section 3.4) was developed due to the wide diffusion of mobile phones in Japan, projected to increase in the future. Since the mobile penetration rate in developing countries is also relatively high, and it is likely to continue to increase, systems similar to EAM may be effective. However, it is important to note that the participation of mobile carriers in Japan is facilitated by their roles as public institutions based on the Disaster Countermeasures Basic Act. On the other hand, installing equipment equivalent to Disaster Administrative Radios Systems in developing countries may not be realistic because of the high cost. It would be more effective to take advantage of existing widespread equipment, such as speakers already installed at religious facilities such as mosques or churches, where people get together on a regularly basis and can be effective to disseminate information. In many areas the places of worship are also designated as (or serve informally as) evacuation facilities. However, the possibility of implementation depends on the specific social contexts and inclusivity of these institutions. Solutions based on broadcasting networks should not be considered in a developing country if radios and televisions are relatively uncommon, unless their penetration is projected to increase. Widely diffused radios and televisions can be very effective dissemination tools. Agree on the details in advance – Roles and responsibilities, priority actions, and terms of cooperation need to be defined in advance of a disaster by developing SOP, pre-arranged agreements, and business continuity plans. ICT solutions including EWS and DIMS cannot be developed unless the following procedures are clearly defined: who inputs what kind of information to whom; how information is processed; and how information is output. Without an SOP, it is unclear who is responsible for installing and operating the ICT solution, and it will not be effective during a disaster. SOPs were fundamental to the development of many of the systems described in this report: for ICTs like K-DIS (section 4.5), an SOP clearly identifies roles and responsibilities. Legislation also helps to define roles within ICT for DRM systems, including which parts of government are responsible for specific warning and response activities. For example, the responsibilities of different government agencies associated with J-ALERT (section 3.3) are shaped by several acts including the Meteorological Service Act and the Disaster Countermeasures Basic Act. J-ALERT’s operational processes are more specifically outlined in “The Provisions for Operation Process of the National Early Warning System (J-ALERT108).” Use the system during normal times – ICT for DRM systems that can be utilized in normal times will be more effective during a disaster. It is difficult to make effective use of a system during a disaster unless it has been used in normal times. Everyday utilization allows both official users and citizens to become familiar with the system’s operation; for example, the system can be used to respond to the small-scale disasters which occur every year, for everyday information management, and by providing periodic training.For example, L-ALERT (section 4.2) can be used to transmit information on administrative procedures, welfare and education, and special events for tourists during normal times, which improves operation of and user familiarity with the system. Similarly, Hyogo Prefecture’s Asset Management System (AMS) (section 4.6) is used for maintaining facilities in the prefecture and preparing updated plans in normal times. At the time of a disaster it is possible to share images of disaster areas with the same system. For GIS- based disaster MIS (section 4.3), maps created during normal times provide a foundation for analyzing disaster status. When designing new DIMSs, potentials for non-disaster use and incentivization of use should be integrated into the system. Practices makes perfect – Awareness and training ensure that stakeholders are familiar with specific ICT for DRM before a disaster strikes, and can leverage them quickly and effectively during an emergency. An effective EWS or DIMS requires not only well-designed digital and physical infrastructure. It also requires that the users understand how it works and are able to play their roles even when a disaster disrupts the status quo. Possible users must first be aware that the system exists, which can be achieved through outreach or awareness programs. If more specialized information is required to engage with the system, training ensures that the users have the proper knowledge and skills. For example, public education and drills to prepare for earthquake, including an annual disaster prevention day, ensure that recipients of early warnings—both the general public and officials—know how to respond immediately (i.e., shelter in place or send out a notification). In the case of the Tokushima DIMS, training and outreach highlighting the system’s benefit to the prefecture has increased participation. 108 Created in 2010, updated in 2016 https://www.fdma.go.jp/mission/protection/item/protection001_05_J-ALERT_gyomu_ kitei_280322.pdf 95 Conclusion ICT for DRM is a rapidly evolving field and Japan, as a country at the cutting edge of many technologies and vast experience with frequent disasters, provides a good testing ground for its development. While the cases studied here are specific to the context of Japan, the high-level lessons extracted will be useful for other countries looking to develop or improve these types of systems. Key considerations include: planning considering both existing and future ICTs; establishing Standard Operating Procedures; considering both daily and disaster utilization; and integrating education and awareness-building into system development. As global technology continues to advance, new frontiers will emerge for DRM technologies. Rapid urbanization, technological development, and climate change are also changing the nature and scope of DRM. Developing ICT for DRM which are well-adapted to local contexts and adaptable to a changing world will be essential to improve disaster preparedness and resilience for citizens around the world. Image: Disaster drill conducted assuming Kyushu Shinkansen made an emergency stop through EEWS (Jan. 2011). Source: Kyodo News Images. 97 Appendix APPENDIX OF ADDITIONAL TECHNICAL DETAILS 99 Appendix A: High Level Technology Development in Japan: Historical Review Table A.1 History of Earthquakes and ICT Development in Japan: Evolution of Early Warning Systems (EWSs) and Disaster Information Management Systems (DIMSs) across Four Major Earthquake Events Major Great Hanshin- Niigata Prefecture The Great East Kumamoto Disasters Awaji Earthquake Chuetsu Earthquake Japan Earthquake Earthquake Date of Jan. 17, 1995 Oct. 23, 2004 Mar. 11, 2011 Apr. 16, 2016 occurrence Magnitude109 Mj 7.3 (Mw 6.9) Mj 6.8 (Mw 6.6) Mj 8.4 (Mw 9.0) M 7.3 Number of dead/missing 6,437 68 2,211110 228 people Approx. peak number of 320,000 1,200 470,000 180,000 evacuees Number of totally/ partially 249,180 16,985 400,326 42,734 destroyed buildings Approx. direct economic 10 3 17 2.4-4.6 damage (trillion yen) 109 There are two magnitude scales used by JMA to express the size of earthquakes: JMA magnitude (Mj) and moment magnitude (Mw). Mj is calculated from the maximum amplitude of seismic waves as observed by seismometers recording strong motion with a period of up to approximately five seconds. Mw is based on the total moment release of the earthquake, estimates over a wider range of earthquake sizes and is applicable globally. 110 As of March 2017 100 DIGITAL SOLUTIONS FOR RESILIENCE ICT Context Major fixed communication technology Subscribed Subscribed Subscribed Subscribed Fixed telephone using telephone using telephone using telephone using communication PSTN111 ISDN112 ISDN, and IP ISDN, and IP (including IP telephone telephone telephone) Penetration rate of fixed phone113 48.9% 53.0% 52.9% 51.7% Major cellular technology Second-generation Major cellular Major cellular Major cellular cellular technology technology: third technology: Mostly technology: 3G and (2G) generation cellular third generation LTE technology (3G) cellular technology (3G), and LTE (Long Mobile Term Evolution) communication started to penetrate Japanese market Penetration rate of mobile phone 130.9% 96.4% 3.5% 67.8% (Smartphone: (Smartphone: 14.6%) 56.8%) Major form of internet access Dial-up Connection ADSL , and Optical 114 ADSL, and Optical Optical Fixed communication communication communication Broadband Penetration rate of fixed broadband 0% 12.47% 27.6% 31.3% Major form of TV broadcasting system Terrestrial Terrestrial Terrestrial Terrestrial broadcasting broadcasting broadcasting/ broadcasting/Data TV broadcasting One seg115 Penetration rate of TV116 98.9% 99.0% 89.2% 98.1% Major types of radio broadcasting systems utilized for disaster information Temporary disaster Temporary disaster Temporary disaster Temporary disaster broadcasting broadcasting broadcasting broadcasting stations/ stations/ stations/ stations/ Community radio/ Community radio/ Community radio/ Community radio/ Municipal disaster Municipal disaster Municipal disaster Municipal disaster prevention radio prevention radio prevention radio prevention radio Radio communication communication communication communication network network network network Number of Temporary disaster broadcasting stations at the time of the disaster 1 3 32 4 Penetration rate of disaster prevention radio communication systems among municipalities117 57.5% 70.1% 76.2% 78.9% 111 Public Switched Telephone Network 112 Integrated Services Digital Network 113 Calculated based on the population data and the number of subscribers 114 Asymmetric Digital Subscriber Line 115 Japanese terrestrial digital broadcasting service for mobile devices 116 Based on the consumer’s behavior survey available at e-Stat: https://www.e-stat.go.jp/stat-search/ files?page=1&layout=datalist&toukei=00100405&tstat=000001014549&cycle=0&tclass1=000001107575&tclass2=000001114115&second2=1 117 Based on: http://www.tele.soumu.go.jp/j/adm/system/trunk/disaster/change/index.htm APPENDIX A 101 Table A.2. Comparison of JMA Intensity Scale to the Modified Mercalli Intensity (MMI) Scale and Medvedev-Sponheuer-Karnik (MSK) Scale JMA Definition of the JMA Intensity Levels MMI Scale MSK Scale Intensity Scale 0 Imperceptible to people. I. Not felt I. Imperceptible 1 Felt slightly by some people keeping quiet in II. Weak II. Very light buildings. 2 Felt by most people keeping quiet in buildings. III. Weak III. Light IV. Light IV. Moderate 3 Felt by almost all people inside buildings. V. Moderate V. Fairly strong 4 Almost all people are startled. Hanging objects VI. Strong VI. Strong such as lights sway significantly. Unstable objects/ VII. Very strong VII. Very strong figurines may fall. 5 Lower Most people feel the need to hold onto something VIII. Severe VIII. Damaging stable. Objects such as dishes or books on shelves may fall. Unsecured furniture may move and unstable objects may topple over. 5 Upper Walking is difficult without holding onto something IX. Violent IX. Destructive stable. More objects such as dishes or books on shelves fall. Unreinforced concrete block walls, etc. may collapse. 6 Lower It is difficult to remain standing. Most unsecured X. Devastating furniture moves and some may topple over. Wall tiles and windows may sustain damage and fall. For wooden houses with low earthquake resistance, roof tiles may fall, and the houses may tilt or collapse. 6 Upper People need to crawl to move, and may be thrown X. Extreme through the air. Almost all unsecured furniture moves and more start toppling over. Large cracks may form in the ground, and largescale landslides and massive collapse may occur. 7 There are more cases of wooden houses with low XI. Catastrophic earthquake resistance tilting or collapsing. Even XII. Very buildings with high earthquake resistance could catastrophic tilt. More reinforced concrete buildings with low seismic resistance collapse. Note: The three scales shown here—MMI (used in many countries, including the United States and Republic of Korea), MSK (used in India, Israel, the Russian Federation, and throughout the Commonwealth of Independent States), and JMA—have slight differences in the way they classify intensities. Source: Created based on World Bank (2016) 102 DIGITAL SOLUTIONS FOR RESILIENCE EWS and DIMS Challenges, Achievements, Advancements, and legislation developed in response to the disaster 1. Great Hanshin-Awaji Earthquake EWS Challenges • Very limited seismic warning system caused significant loss and damages (e.g., to roads and rails). • In 1992, Tohoku Shinkansen installed a preliminary seismic detection and EWS called “Urgent Earthquake Detection and Alarm System” or UrEDAS (Watanabe et al., 2009), designed to automatically stop or slow down high-speed rails. However, UrEDAS was not installed in the area where the 1995 EQ occurred. During the 1995 EQ, although there were no passenger fatalities, damages were significant including 16 lines derailed and 32 fallen bridges. Post-Disaster Advancements • The severe damages led to a complete renewal of Japan’s seismic risk management approach. • Japan’s seismic observational and research infrastructure was entirely revamped and development of earthquake early warning system was initiated. • UrEDAS was improved (as Compact UrEDAS) and installed in other high-speed and local rail lines. DIMS Challenges • The Municipal Disaster Management Radio Communication System (MDMRCS) was established at national, prefectural, and municipal levels to gather and deliver disaster information during emergencies. These systems consist of VHF/UHF radio communication link, microwave communication link and satellite communication link, and are comprised of fixed systems, simultaneous communication systems, and mobile systems. • However, at the time of the EQ, only 20% of local governments in Hyogo Prefecture, and only 53.6% of local governments nationally had installed the system. Therefore, significant delays and barriers were faced to collect and disseminate disaster information such as on damage and relief status (Satoru Ishigaki, 2011). • Information for vulnerable groups including the elderly and people with disabilities were insufficient, causing them disproportionate casualties. Legislation 1995: • Act on Special Measures for Earthquake Disaster Countermeasures • Act on Promotion of the Earthquake-proof Retrofit of Buildings • Amendment of Disaster Countermeasures Basic Act • Amendment of Act on Special Measures for Large-scale Earthquakes 1996: • Act on Special Measures for Preservation of Rights and Profits of the Victims of Specified Disasters APPENDIX A 103 1997: • Act on Promotion of Disaster Resilience Improvement in Densely Inhabited Areas 1998: • Act on Support for Livelihood Recovery of Disaster Victims 2. Niigata Prefecture Chuetsu Earthquake EWS Challenges • Due to disruption of the MDMRSC system, seismic observation information was lost for a certain period. Furthermore, repeated aftershocks caused data congestion. • Compact UrEDAS system was activated and the emergency breaks slowed down the Shinkansen/ high-speed rails (by cutting power transmissions). At the time of the earthquake, four Shinkansen were passing through the EQ-affected area. Three out of four trains were able to safely slow down and stop. One train, which was moving at 200 km/hr with 154 passengers slowed down but derailed118. Since the line was passing through an area close to the epicenter, the time between detection and emergency break was less than one second (Hitotsubashi University Railway Study Group, 2011). Post-Disaster Advancements • Based on this experience, improvements were made to shorten the time from EQ detection to activation of emergency breaks119. DIMS Challenges • NTT lines and MDMRCS were disconnected in certain areas causing information isolation. • Blackout caused disruption to communication through MDMRSC. • Mobile communication was disrupted due to increased communication volume. • GIS system certainly played an important role, which enabled the sharing of geographic information in real time to support disaster response activities Post-Disaster Advancements • In order to secure alternative communication channels during disasters, satellite phones were established for municipal governments. • Partnerships with private communication companies to send disaster information (i.e. through mass emails) were further explored120. Legislation 2005: • Amendment of Act on Promotion of the Earthquake-proof Retrofit of Buildings 2006: • Amendment of Act on the Regulation of Residential Land Development 118 For more information, see: http://port80japan.net/bosai/bosai_1_1_3.htm 119 For more information, see: http://www.jreast.co.jp/safe/jishin.html 120 For more information, see: http://www.soumu.go.jp/main_sosiki/joho_tsusin/policyreports/chousa/jyuyou-t/pdf/080118_1_si4-6.pdf 104 DIGITAL SOLUTIONS FOR RESILIENCE 3. The Great East Japan Earthquake EWS Achievements • The EEWS of JMA (launched in Oct. 2007 for common use and 2004 for advanced use) issued warnings 18 times, delivered via J-ALERT (launched in Feb. 2007) and EAM (launched in Dec. 2007), effectively delivering the alert through multiple channels. The municipalities who had installed receivers of the J-ALERT (46%) reported the effectiveness of the early warnings • UrEDAS activated emergency brakes to slow down 27 Shinkansen high-speed rails that were in operation during the earthquake. All lines came to a safe stop. Although five trains were destroyed after the tsunami that followed shortly after, there were no casualties as passengers were safely evacuated121. Legislation 2011: • Act on Promotion of Tsunami Countermeasures • Act on Development of Areas Resilient to Tsunami Disasters 2012: • Amendment of Disaster Countermeasures Basic Act • Act for Establishment of the Nuclear Regulation Authority 2013: • Amendment of Disaster Countermeasures Basic Act • Act on Reconstruction from Large-Scale Disasters • Amendment of the Act on Promotion of the Earthquake-proof Retrofit of Buildings • Amendment of the Flood Control Act and River Act • Act on Special Measures for Land and Building Leases in Areas Affected by Large-scale Disaster • Basic Act for National Resilience Contributing to Preventing and Mitigating Disasters for Developing Resilience in the Lives of the Citizenry 4. Kumamoto Earthquake EWS Achievements • The earthquake early warnings were issued 19 times, exhibiting remarkable performance. Receivers of the J-ALERT were installed in most municipalities (above 99%), and this contributed to delivering the alert effectively. • However, in four cases, the system issued inaccurate warnings. In order to address over-prediction and under-prediction, JMA plans to implement the integrated particle filter (IPF) and propagation of local undamped motion (PLUM) methods122. Challenges • Given that the epicenter of the EQ was close to urban centers, the EQ EWS was unable to prevent derailment, although it did activate the emergency breaks. 121 For more information, see: http://www.jreast.co.jp/safe/jishin.html 122 For comprehensive analysis of the performance of the earthquake early warning system during the Kumamoto Earthquake, see Kodera et al. (2016) APPENDIX A 105 DIMS Challenges • Impacts to ICT as well as critical infrastructure such as energy due to EQ and tsunami caused significant disruptions to ICT systems after the disasters. 385 NTT buildings became non- functional, 6,300 km of cables along the coastlines were damaged/destroyed, and approximately 1.9 million access lines (to connect users to communication network) were cut. More than 29,000 mobile phones and PHS hubs stopped functioning (MIC, 2016c). • Furthermore, due to increased communication demand of 50-60 times more than normal, the mobile communication lines were congested and had very poor connection. • On the other hand, data/internet-based communication via smartphones was possible. Furthermore, satellite phones were found to be reliable communication tools in the event of disasters. • Disaster information was collected and shared among relevant organizations mostly using emergency municipal radio communication systems, phone, fax, and wireless transceiver. The information was delivered to affected areas using radio broadcasting systems, public trucks with speakers, e-mails, TV, community radio, and social media platforms (Inomo et al., 2012). • Nevertheless, citizens were dissatisfied with the dissemination of disaster information by the public sector. Local governments also recognized the need to improve provision of quick, accurate, and continuous disaster information (MIC, 2014). Post-Disaster Advancements • New legislation ensuring that citizens can obtain accurate disaster information through utilization of Geospatial information systems and ICT. Initiated development of Public Information Commons (later called L-Alert System) and Public Wireless LAN, etc. to secure multiple channels to access disaster information. Started discussions on pre-arranged agreements to utilize public and private information communication infrastructure as well as ensuring information access and dissemination to people with disabilities (MIC, 2014). Legislation 2016: • Amendment of Act on Special Measures concerning Preservation of Rights and Interests of Victims of Specified Disaster 106 DIGITAL SOLUTIONS FOR RESILIENCE APPENDIX A 107 Appendix B: Earthquake Early Warning System B.1 Examples of Application During Disaster Events • At the time of the 2011 Great East Japan Earthquake, Early Warning Systems enabled people to take actions moments before the earthquake struck. However, the P- and S-waves in areas close to the hypocenter struck almost immediately after one another, and so some people failed to find adequate shelter. • During the 2016 Kumamoto Earthquake, information was delivered via mobile phones, smartphones, TV, and other means. This timely dissemination of critical information proved effective in helping people. For example, approximately 80% of residents were able to obtain information related to the earthquake, and approximately 40% were able to take some form of preventative action to reduce injuries and damage (JMA, 2017). B.2 Earthquake Early Warning System: ICT Systems and Context Systems and Infrastructures  108 DIGITAL SOLUTIONS FOR RESILIENCE Table B.2.1. Major Operational Earthquake Early Warning Systems Around the World Country Start of Operation Reason for Development China Issuing public Development initiated after devastating impacts of 2008 Sichuan warnings since Earthquake (approx. 70,000 deaths) 2017 Italy Development and An EEWS was developed given the country experience of destructive implementation earthquakes including the 1980 Irpinia earthquake (approximately 2,500 started in 2005 in deaths). Furthermore, there is a significant probability of a M > 5.5 southern Italy earthquake occurring in the next decade. Japan Issuing public EEWS initially developed in 1992 for slowing and stopping high-speed warnings since trains (shinkansen) prior to strong shaking. The success of that program, in 2007 addition to the devastating effects of the 1995 Kobe earthquake (approx. 5,100 deaths), paved the way for building a nationwide early warning system. Mexico In operation since After the losses resulting from the 1985 Michoacan earthquake (approx. 1991 in Mexico 10,000 killed), the Centro de Instrumentación y Registro Sísmico (CIRES) City developed an EEWS with the aim to provide a 60-second warning for earthquakes that occur off the country’s coast. Romania Vrancea Early After the 1977 Vrancea earthquake (approx. 1,500 killed), the Romanian Warning System EEWS started its development as a common project between the National project started in Institute for Earth Physics (NIEP) and Karlsruhe University in 2000. It was 2003 designed only for Bucharest and allows a lead time (the time interval between the arrival of the damaging waves and alert notification) of 21-28 sec depending of the earthquake’s depth. Taiwan Using EEWS since Developed after the 1999 Chi Chi earthquake (approx. 2,400 killed). With 2001 the implementation of a real-time strong-motion network by the Central Weather Bureau (CWB), EEWS has been developed in Taiwan. In order to shorten the earthquake response time, a virtual sub-network method based on the regional early warning approach was utilized at first stage. Since 2001, this EEWS has responded to a total of 225 events with magnitudes greater than 4.5 that occurred both inland and off the coast of Taiwan. The system is capable of issuing an earthquake report within 20 seconds of its occurrence with good magnitude estimations for events up to magnitude 6.5. Currently, a P-wave method is adopted by the CWB system. Turkey Development initiated after the 1999 Izmit earthquake (approx. 17,000 killed) U.S.A. A demonstration Since 2000, according to a plan requested by Congress, the USGS and its EEWS (ShakeAlert) partners have been developing the ANSS, with one of the end-goals of began sending the completed system being to provide earthquake early warnings, given test notifications the significant earthquake risk in the United States. Estimates show that in California in more than 75 million people in 39 States are at direct physical risk from 2012 earthquakes. FEMA has estimated that direct earthquake losses average more than $5 billion each year, and indirect economic impacts are even greater. Three-quarters of these risks are concentrated on the West Coast, where California has a 99.7 percent chance of a magnitude 6.7 or larger earthquake occurring in the next 30 years, and Oregon and Washington have a 10 percent chance of a magnitude 8-to-9 earthquake in the Cascadia subduction zone. Source: Developed by the authors based on material of U.S. Department of the Interior: https://www.doi.gov/ocl/hearings/113/ earthquakeearlywarning_061014 APPENDIX B 109 EARTHQUAKE Estimating the focus, magnitude, and seismic intensities using data JMA from one seismograph Immediately after P-Wave S-Wave Estimating the focus, magnitude, and seismic intensities using data from two or three JMA seismographs [more accurate] After 10 seconds P-Wave S-Wave Estimating the focus, magnitude, and seismic intensities using data from three to five seismographs [more After 20 JMA accurate] seconds P-Wave S-Wave Figure B.2.1. Overview of Warning System Seismic Intensities Calculation Processes Source: Based on material of JMA: http://www.jma.go.jp/jma/en/Activities/eew1.html 110 DIGITAL SOLUTIONS FOR RESILIENCE Table B.2.2. Components of Earthquake Early Warning Systems No. Name Administration Description Hardware (1) Seismometers JMA - Installed at about 270 locations across Japan (See Figure B.2.2) (2) Seismometers NIED - Installed at about 800 locations across Japan (See Figure B.2.2) - Upon detecting an earthquake, observation data is transferred to JMA (3) Receiver unit JMA - Consisting of servers to receive observation data from seismometers - (3) Receiver unit and (4) Analyzing unit are parts of (7) EPOS (4) Analyzing unit JMA Consisting of servers to calculate the scale of an earthquake and the location of the epicenter based on observation data received, and then to send out emergency earthquake early warnings if necessary. When a quake is detected by more than two stations, the following actions are carried out automatically: - the location of the hypocenter (latitude, longitude, and depth), magnitude, and distribution of local intensities are calculated - an alert is sent out to areas when the maximum intensity calculated goes level 5-Lower or greater (5) General Residents - General devices to receive emergency earthquake communication early warnings devices (6) Dedicated Companies - Terminal PCs to receive the estimated intensity or receivers the arrival time of the main pulse at any location - Equipped with a countdown feature to show differences in arrival times of the main pulse from an embedded clock - Data obtained is used by companies for in-house announcements or for controlling factory machinery Software (7) Earthquake JMA - To make real-time calculations of observation Phenomena data from seismometers across Japan, then release Observation emergency earthquake early warnings System (EPOS) - Real-time calculations are also for observation Software data of tsunamis, and release tsunami warnings - Programs of EPOS are installed in a receiver unit and analyzing unit as noted in (3) and (4) above APPENDIX B 111 Network (8) Digital Access JMA, NIED - Communication lines to transfer observation data (DA) Network from seismometers (9) Mobile phone Mobile Carriers - Communication lines to transfer observation data networks from seismometers to JMA (10) Satellite LASCOM (Local - Communication lines to transfer observation data communication Authorities from seismometers lines Satellite Communications Organization) (11) Dedicated JMA - Communication lines to connect JMA with private communication companies that distribute earthquake warnings lines (12) Mobile phone Mobile Carriers - Mobile carriers offer their regular communication networks lines free of charge to transfer warnings to mobile phones in earthquake hazard areas (13) Broadcasting Broadcasters - To transfer earthquake early warnings on TVs or networks radios (14) Disaster Municipalities - To transfer earthquake early warnings to outside prevention radio loudspeakers or individual receivers for detached communication houses networks (Broadcasting system) (15) Internet Internet service - Communication lines to connect JMA with providers JMBSC, Weather Service Providers, and dedicated receivers. Source: Based on material of JMA: http://www.data.jma.go.jp/svd/eew/data/nc/shikumi/shikumi.html; and material from NEC Figure B.2.2. Seismometer Locations for Emergency Earthquake Early Warnings (as of 1st April 2016) Source: Based on material of JMA: http://www.data.jma.go.jp/svd/eew/data/nc/shikumi/shikumi.html Note: Seismographs used for the Earthquake Early Warning System are installed at a depth of at least 100m (up to 1,000 m in some cases) in Japan. Because the system uses differences in speeds of P- and S-waves, a greater distance from the epicenter means more time to transfer information. 112 DIGITAL SOLUTIONS FOR RESILIENCE Institutional Framework Table B.2.3. Organizational Roles Related to Earthquake Early Warning Systems No. Name of Organization Roles (1) Japan Meteorological JMA is the organization in charge of the Early Warning System. Its Agency (JMA) responsibilities include installation and maintenance of seismometers (about 270 stations across Japan as of April 2016), managing the automatic calculation system and improving calculation algorithms for enhancing accuracy. (2) National Research NIED provides JMA with seismic data using the High-Sensitivity Institute for Earth Seismograph Network, which comprises about 800 seismometer-equipped Science and Disaster stations across Japan. Each seismometer is installed at the bottom of a Resilience (NIED) borehole at a depth of at least 100 meters. (3) Mobile Carriers Mobile carriers provide communication lines free-of-charge to transfer earthquake early warnings to communication devices such as mobile phones. (4) Broadcasters Broadcasters transmit earthquake early warnings on TVs and radios. (5) Municipalities Municipalities transmit earthquake early warnings over their own Disaster Prevention Radio Communication Network (J-ALERT). (6) Japan Meteorological JMBSC is an organization connecting JMA to weather service companies, Business Support Center providing meteorological data owned by JMA both on and off line. JMBSC (JMBSC) distributes emergency earthquake early warnings (alerts and notices) from JMA to weather service companies. (7) Weather Service Weather service providers disseminate emergency earthquake early Provider warnings to users who own dedicated receivers. Distribution of forecasts or warnings on weather or earthquakes is restricted to companies having a license based on Japan’s Meteorological Services Act. (8) People in warning areas Upon receiving information, people take action to ensure their safety before strong shaking starts. Companies receive earthquake early warnings using dedicated receivers, which are then used for in-house announcements or for controlling elevators and factory machinery. Source: Based on material of JMA: http://www.data.jma.go.jp/svd/eew/data/nc/shikumi/shikumi.html APPENDIX B 113 Table B.2.4. Relationship Between Earthquake Early Warnings and JMA Forecasts/Warnings JMA Category Service name used by Contents licensed organizations Emergency Emergency earthquake An alert for a risk of disastrous damage in areas where warning/ early warning (Warning)” the anticipated maximum intensity exceeds level 5-lower Warning of or “Earthquake early on the Japanese seismic scale based on the analysis of earthquake warning” data from more than 2 observation points. ground motion Forecast of “Emergency earthquake A notice for a risk of disastrous damage in areas where earthquake early warning (Forecast)” the estimated magnitude is 3.5 or more, or the predicted ground motion maximum intensity is 3 or more. Source: Based on material of JMA: http://www.data.jma.go.jp/svd/eew/data/nc/shikumi/shousai.html#2 B.3. Earthquake Early Warning System: Enabling Environment Limitations of Earthquake Early Warning System Issues and limitations of the Warning System are listed below: • Originally developed for alleviating the impacts of damage caused by subduction zone earthquakes, which can provide effective warnings for areas far from the hypocenter. Because the Early Warning System predicts the S-waves arrival time based on the observations of P-waves, there is not enough time to transfer information to areas very close to the hypocenter. Especially in the case of epicenter-type earthquakes, it may not be possible to deliver a warning before the ground starts shaking. In addition, if multiple earthquakes occur in close proximity and within a short time interval, the calculation results would become prone to error. • The time interval is ten seconds to a few tens of seconds at most from the time a warning is received until the time designated areas are hit by strong quakes. • The calculation errors range ±1 in terms of earthquake intensity. 114 DIGITAL SOLUTIONS FOR RESILIENCE May 2007 35.5 48.9 15.6 (n=2,037) Do you know about the Sep. 2007 60.6 32.8 6.6 “Earthquake Early Warning System” ? (n=2,001) Mar. 2009 66.1 30.5 3.4 (n=3,503) Do you know that an “Earthquake Early Warning” is di erent from earthquake information? The former information is generated immediately Nov. 2012 77.3 22.7 After the beginning of an earthquake, and is (n=5,490) Delivered before tremors are felt. 0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100% Yes, I know Have heard of it No, I don't Figure B.3.1. Awareness of Earthquake Early Warning Systems Source: Based on JMA, 2012. APPENDIX B 115 Appendix C: J-Alert: Nationwide Instantaneous Warning/ Alert System C.1 Examples of Application During Disaster Events The Great East Japan Earthquake on 11th March 2011 provided the first large-scale, real-world test of the J-ALERT system. At the time, J-ALERT was still in the process of adoption by municipalities. According to FDMA, J-ALERT issued early warnings to 35 municipalities at around 14:46, the time at which the Great East Japan Earthquake occurred. Directly after that, at around 14:50, J-ALERT gave a major tsunami warning to 52 municipalities, which was about 25 minutes prior to the maximum wave first hitting Ofunato city, Iwate Prefecture. At the time, 773 municipalities had adopted the J-ALERT receiver, or 45.7% of the total, and 382 municipalities had adopted the trigger controller (22.6% of the total number). The major tsunami warning issued by J-ALERT triggered the decision to evacuate 16% of evacuees: others relied upon prior knowledge, acquaintances and neighbors, or other means [see figure below]. Affected municipalities that had introduced both the receiver and the trigger controller reported that J-ALERT was effective for the protection of lives, as disaster prevention radio communication systems were automatically triggered to announce the danger of a major tsunami during the confusion that followed the main earthquake. 0% 10% 20% 30% 40% 50% 60% According to preliminary knowledge 48% Prompted from acquaintance 20% Saw/Heard the Major tsunami warning 16% Saw neighborhood evacuating 15% Prompted from fire fighters 8% According to past experience 8% Saw/Heard in TV or Radio 7% Prompted from company or colleague 5% (Reasons less than 5% is omitted) Other 16% Cannot remember 2% Figure C.1.1. Trigger of Evacuations During the Great East Japan Earthquake Source: Based on material of the Cabinet Office: http://www.bousai.go.jp/jishin/tsunami/hinan/tyousakekka.html 116 DIGITAL SOLUTIONS FOR RESILIENCE Municipalities (As of May 1, 2016) utilizing… (n=1,741 municipalities) Three or More Automatic 641 641 36.8% Distribution Method Three or More Automatic Distribution Two Automatic Method 22.2% 641 36.8% 387 387 Distribution Method One Automatic 713 713 41.0% Distribution Method Two Automatic Distribution Method 387 22.2% 0 100 200 300 400 500 600 700 800 ( Municipalities ) Figure C.1.2. Status of Diversification of J-ALERT Automatic Dissemination Channels123 by One Automatic Municipalities (as of August 1, 2017) 713 41.0% Distribution Method Source: Based on FDMA, 2017 0 100 200 300 400 500 600 700 800 (Municipalities) Table C.1.1. Past Level A Warnings Disseminated by J-ALERT Based on material from FDMA “Overview of J-ALERT (2016),” a study has found the following warnings (Level A) were disseminated by J-ALERT. Category Description 1. Civil protection information Dec. 2012: Missiles from North Korea Feb. 2016: Missiles from North Korea 2. Earthquake early warnings 2011: Great East Japan Earthquake and other (many times) 2012: Off-shore Fukushima Prefecture Earthquake and other (15 times) 2013: Awaji Island Earthquake and other (8 times) 2014: Iyonada Earthquake and other (5 times) 2015: South Tokushima Prefecture Earthquake and other (6 times) 2016: Kumamoto Earthquake and other (many times) 3. Major tsunami warnings Mar. 2011: Great East Japan Earthquake 4. Tsunami warnings Nov. 2016: Off-shore Fukushima Prefecture Earthquake 7. Meteorological emergency Jul. 2014: Typhoon No. 8 (Okinawa Pref.) warnings Aug. 2014: Typhoon No. 11 (Mie Pref.) Sep. 2014: Heavy rain (Hokkaido) Sep. 2015: Typhoon No. 18 (Ibaraki Pref., Tochigi Pref., Miyagi Pref.) Oct. 2016: Typhoon No. 18 (Okinawa Pref.) Source: Based on material of FDMA: https://www.fdma.go.jp/html/intro/form/pdf/kokuminhogo_unyou/kokuminhogo_unyou_main/J- ALERT_gaiyou_h28.pdf 123 Automatic Dissemination Channels included: Municipal Disaster Prevention Radio Communication Systems, cable TV, community FM radios, subscription email services, dedicated terminals, and other wireless/wired systems. Mobile phones and national network broadcasts (not cable TVs) are not included in this figure given that they are not controlled by municipalities. The figure shows that almost all municipal governments are connected to at least one means of automatic distribution, which is the Municipal disaster prevention radio communication system, in line with the MIC guidance. The figure also shows that more than 50% of municipalities have two or more additional means – including subscription email services, dedicated terminals, wired systems (loudspeaker), community FM radios, other wireless systems, and cable TV (listed in order of uptake). APPENDIX C 117 C.2 J-ALERT: ICT Systems and Context Systems and Infrastructures  Cabinet FDMA Municipalities Secretariat [3] J-ALERT receiver [5] FDMA Transmission [7] Satellite [1] Input terminal system [4] Trigger controller JMA [6] Central Disaster Prevention Radio Network [8] LGWAN [1] Input terminal [2] Control terminal Broadcast radio Outdoor control desk loudspeaker [9] Disaster management radio communication network Figure C.2.1. System Diagram of J-ALERT Source: Based on material of FDMA: https://www.fdma.go.jp/html/intro/form/pdf/kokuminhogo_unyou/kokuminhogo_unyou_main/J- ALERT_gaiyou_h28.pdf 118 DIGITAL SOLUTIONS FOR RESILIENCE Table C.2.1. Components of J-ALERT No. Name Administration Description Hardware (1) Input Terminal Cabinet Office To enter information to be disseminated by J-ALERT Secretariat  JMA, FDMA (2) Control Terminal FDMA Controls the FDMA transmission system. (3) J-ALERT Receiver Municipalities Receives data via satellite, analyze, then sends it to the trigger controller of the disaster prevention radio communications system, depending on the analysis of results. (4) Trigger Controller Municipalities Automatically triggers the disaster prevention radio communications system upon receiving data from the J-ALERT receiver Software (5) FDMA FDMA - Transmits information from the Cabinet Transmission Secretariat or JMA to municipalities using satellite System and terrestrial communication (LGWAN). - In case of communication trouble with the Cabinet Office Secretariat, FDMA can use the transmission system to enter civil protection information on its behalf - Monitors the J-ALERT receiver status, and provides software updates when needed. Network (6) Central Disaster Cabinet Office To connect the Cabinet Office with central Prevention Radio government ministries, and other related Network organizations (including NTT, NHK, and 52 electric power companies) (7) Satellite LASCOM (Local Local satellite communications operated by Communication Authorities LASCOM is used as the main transmission line for Network Satellite J-ALERT. Communications Organization) (8) LGWAN (Local J-LIS (Japan Dedicated communication network for local Government Agency for governments. It connects to the national Wide Area Local Authority government network that enables information Network) Information transmission from FDMA to municipalities. Systems) (9) Disaster Municipalities - Broadcasting system owned by municipalities to Prevention Radio make announcements about disasters or provide Communications administrative information using loudspeakers Network installed outside or inside houses. (Broadcasting - Voice inputs and modulation are carried out at system) the main station, then transmitted to loudspeakers. - For extended areas of service, relay stations are required to be installed. - It is up to the municipality to decide the system structure and technical specifications of the radio, which causes considerable differences in automatic triggering times. Source: Based on material of FDMA: https://www.fdma.go.jp/html/intro/form/pdf/kokuminhogo_unyou/kokuminhogo_unyou_main/J- ALERT_gaiyou_h28.pdf APPENDIX C 119 Warning Types Table C.2.2. Information Dissemination by J-ALERT Information category Level* Information category Level* 1 Civil protection A 12 Volcanic eruption warnings B information (ballistic (near the crater) missiles, large-scale terrorism, etc.) 2 Earthquake early A 13 Meteorological warnings B warnings 3 Major tsunami warnings A 14 Landslide alert information B 4 Tsunami warnings A 15 Tornado advisories B 5 Volcanic eruption A 16 Record torrential shower C warnings (for residential information areas) 6 Volcanic eruption early A 17 Flood forecast of C warnings designated river 7 Meteorological A 18 Seismic research C emergency warnings information on Tokai Earthquake 8 Tokai Earthquake B 19 Seismic source and intensity C Prediction Information information 9 Tokai Earthquake B 20 Volcanic eruption forecasts C Cautionary Information 10 Seismic intensity B 21 Other weather advisories C information 11 Tsunami Advisories B Description of Levels: Level Trigger control requirements A Automatically trigger the dissemination system as mandatory B Automatically trigger the dissemination system as municipality’s option C Manually trigger the dissemination system Source: Based on material of FDMA: https://www.fdma.go.jp/html/intro/form/pdf/kokuminhogo_unyou/kokuminhogo_unyou_main/J- ALERT_gaiyou_h28.pdf 120 DIGITAL SOLUTIONS FOR RESILIENCE C.3 J-ALERT: Enabling Environment System Costs Capital Costs The development cost of J-ALERT was about JPY 472 million, developed from fiscal year124 2004 to 2007. Initially, there were only a limited number of voice messages recorded for automatic broadcast by the disaster prevention radio communication system. To enable more efficient messaging, especially for civil protection-related information, FDMA modified J-ALERT in 2009 to automatically convert text files sent from the Cabinet Secretariat or JMA into audio files to be broadcast by disaster prevention radio communication systems. At the same time, it installed terrestrial lines for communication from the FDMA transmission system to J-ALERT receivers owned by municipalities. FDMA also modified the system to enable remote operations for monitoring the status of receivers and updating software during this period. The cost for these modifications totaled approximately JPY 900 million. The costs include the development of the core J-ALERT system, owned by FDMA. It contains the function to collect warning information and dispatch it to the government satellite communication network (operated by LASCOM) and LGWAN (operated by J-LIS), in the originally optimized data format. With the exception of the above core system (covered by the costs in Table C.3.1), all receivers (including those in municipalities) require a receiver environment set which costs an average of JPY 7 million. These investments are encouraged through subsidies issued by the central government (MIC). Table C.3.1. Development and Enhancement Costs Fiscal year Costs Development Costs 2004-2007 About JPY 472 million Enhancement Costs 2009 About JPY 900 million In addition, Japan’s central government provided subsidies to promote adoption of J-ALERT by municipalities. In particular, the government invested about JPY 14 billion after the Great East Japan Earthquake to accelerate implementation of J-ALERT in municipalities, bearing 50% of implementation costs. Moreover, the government deployed JPY 773 million in 2013 to cover the cost of installing trigger controllers in 62 municipalities that could not develop by themselves due to financial constraints. Operation and Maintenance (O&M) Costs The O&M costs related to above FDMA-owned system amounts to approximately JPY 300-400 million a year. According to the public project review of MIC’s budget, the following O&M costs were incurred and outsourced to vendors. • Application O&M: JPY 269 million • System upgrade and modification: JPY 120 million • Other (training, etc.): JPY 0.3 million The O&M cost for J-ALERT receivers (approx. JPY 0.2 million per unit/year), trigger controllers (approx. JPY 0.2 million per unit/year) and systems connected to the trigger controller (depend on cases) may have to be borne by municipalities. 124 Japanese fiscal year, which is from April to March. APPENDIX C 121 Appendix D: Emergency Alert Mail (Cell Broadcast Early Warning System) D.1 Examples of Application During Disaster Events Results from a post disaster survey conducted to analyze the effectiveness of the Alert service after the 2016 Kumamoto Earthquake highlighted that EAM was effective in delivering the earthquake early warning message to a large portion of the affected population, while further challenges remained to translate the warnings into protective measures and actions. The results showed that: 85.1% of residents first received information regarding earthquake early warnings via EAM; 52.1% reported that “the warning message from the Alert service helped them prepare for the tremors to come”; and 17.1% claimed that “it helped them take action to protect themselves.” (JMA, 2017). 122 DIGITAL SOLUTIONS FOR RESILIENCE D.2 Emergency Alert Mail: ICT Systems and Context Systems and Infrastructures  Table D.2.1. Organizational Roles Related to the Cell Broadcast Early Warning System No. Name of Organization Role (1) Japan Meteorological Agency - Deliver earthquake and tsunami early warnings automatically (JMA) - Deliver early warnings related to weather (heavy rain, storms, storm surges, landslide, and others) and volcanic eruptions - Issue early warnings related to natural disasters (2) Ministry of Land, - Issue flood forecasts for designated rivers Infrastructure, Transport and Tourism (MLIT) (Regional Development Bureau) (3) Fire and Disaster - Send information related to civil protection for the protection of Management Agency (FDMA) citizens from missile attacks, terrorist attacks, etc. (4) Municipalities - Deliver evacuation instructions based on disaster-related information from MLIT and JMA, local conditions, etc. (As of September 1, 2016, 99.4% of municipalities across Japan were using EAM offered by multiple carriers: NTT Docomo, KDDI, and SoftBank) (5) Mobile carriers - Provide communication lines free-of-charge to transfer Emergency Alert Mails to mobile phones (6) People in warning areas - Take actions for their own safety and protection based on the information received Source: Based on mobile carriers’ website and material provided by NEC Corporation Ltd. Third Generation Partnership Project (3GPP125) Technical Specification 22.168 V8.1.0 (2008) 3GPP Technical Specification (TS) 22.168 “Earthquake and Tsunami Warning System (ETWS)” is the standard defined for ETWS, which is adopted by the mobile carriers in Japan for their EAM services. NTT Docomo contributed to the development of the standardized TS. The TS defines the set of requirements seen primarily from the users’ and service providers’ points of view. The TS also includes information applicable to network operators, service providers, terminal and network manufacturers, in case of deployment of ETWS126. 125 3GPP is the abbreviation of Third Generation Partnership Project and is a standardization project for developing specifications of the third-generation mobile phone (3G) system, fourth-generation mobile communication (4G) system, etc. 3GPP TS 22.168 is one of the technical standards in 3GPP. 126 For more information on the technical specification, see: http://www.qtc.jp/3GPP/Specs/22168-810.pdf APPENDIX D 123 Table D.2.2. Components of the Cell Broadcast Early Warning System No. Name Administration Description Hardware (1) Seismometers JMA, NIED, - JMA seismometers are installed at Universities approximately 280 locations, and those operated by other organizations are installed at approximately 1,180 locations - These seismometers are used to detect seismic waves, calculate the location of the seismic source, and the scale (magnitude) of the earthquake (2) Seismic intensity JMA, NIED, - A seismic intensity meter is a device to measure meters Municipalities the strength of ground motions (the intensity) - JMA seismic intensity meters are installed at approximately 660 locations; those operated by other organizations at approximately 3,700 locations (3) Strain meters (Tokai JMA, Shizuoka - 27 meters (Two managed by Shizuoka area) prefecture prefecture) (4) Tsunami JMA, Ports - Tide gauges: approx. 180 (JMA: approx. 80, observation and Harbors Other organizations: approx. 100) facilities Bureau of MLIT, - GPS buoys and Seabed Tsunami Sensors: JAMSTEC, NIED approx. 50 (JMA: approx. 10, Other organizations: approx. 40) (5) Input terminal JMA, Regional - Terminal devices to enter messages for Development Emergency Alert Mails Bureau in - Possible to send messages to selected areas in MLIT, FDMA, units of municipality Municipalities Note: National agencies and municipalities determine the necessity of early warnings based on the observations and forecasted precipitation amount, water level, etc. and send Emergency Alert Mail by operating the input terminal. (6) Emergency Mobile Carriers - The servers send disaster information to mobile distribution servers holders via mobile network in the warning areas. (7) Wireless network Mobile Carriers - Transfer disaster data from Component (6) to management mobile base stations in warning areas devices 124 DIGITAL SOLUTIONS FOR RESILIENCE Software (8) Earthquake and JMA - ETWS is software that distributes disaster Tsunami Warning information to cellphone holders via a mobile System (ETWS) network - Is being developed by 3GPP based on area mail technology owned by NTT DOCOMO, which can dramatically increase transfer speed in comparison to conventional systems such as Cell Broadcast Service (CBS) or Broadcast SMS (BC-SMS) (9) Earthquake JMA - To make real-time calculations of observation Phenomena data from earthquake and tsunami observation Observation System facilities across Japan (EPOS) - Tsunami and earthquake warnings and advisories are promptly disseminated to disaster prevention and media organizations. Network (10) Dedicated line JMA - Communication cables to connect public agencies such as JMA with mobile carriers (main line) (11) Internet Protocol JMA - Communication cables to connect public Virtual Private agencies such as JMA with mobile carriers (sub- Network (IP-VPN) line) and Wide-area Ethernet (12) Mobile Carrier Mobile Carriers - Carriers offer their communication lines free Network of charge to transfer warnings to mobile phones only in impacted areas Source: Based on interview with JMA and material provided by NEC Corporation Ltd. Note: JAMSTEC: Japan Agency for Marine-Earth Science and Technology, NIED: National Research Institute for Earth Science and Disaster Resilience, 3GPP: Third Generation Partnership Project The information delivered through EAM is specified as the following 12 types. Warning Types Table D.2.3. Types of Information Delivered through Emergency Alert Messages No. Type of information Sender 1 Evacuation information Municipalities (Prefectural 2 Evacuation advisory governments act as their proxy, as required) 3 Evacuation order 4 Information on restricted areas MLIT, JMA 5 Tsunami advisory JMA 6 Tsunami warning 7 Major tsunami warning 8 Volcanic eruption alert (Only for volcanic alert level above 4127) 9 The Tokai Earthquake128 prediction information 10 Landslide disaster warning information JMA and Prefectural governments 11 Flood forecasts of designated rivers (Except for inundation MLIT warning information) 12 Civil protection warning (e.g. air attack, mass terrorism, Cabinet Secretariat etc.) Source: Based on material provided by NTT Docomo Inc. 127 Depending on the volcanic activity, there are five Volcanic Alert Levels based on the circumstance of target areas, and actions to be taken by residents are shown corresponding to each level. 128 The Tokai Earthquake is a possible large earthquake affecting the area around the Tokai area, and a prediction system has been prepared for it under a special act established in 1978. The Tokai earthquake could be a magnitude 8 class, and according to the damage estimate of the Cabinet Office, this earthquake could cause up to 110,000 deaths. Since only the Tokai Earthquake was thought to be predictable, a warning was planned to be issued when the risk increased to mitigate the potential damage. APPENDIX D 125 Appendix E: L-ALERT E.1 Examples of Application During Disaster Events L-ALERT’s announcement feature worked effectively in the recovery phase of the 2016 Kumamoto Earthquake. The following table shows how L-ALERT was used at the time. Table E.1.1. Number of Alerts and Information Dispatches Handled by L-ALERT after the Kumamoto Earthquake From Apr. 14 Apr. 24 May 4 May 15 May 24 Jun. 4 Category To Apr. 23 May 3 May 13 May 23 Jun. 3 Jun. 13 Evacuation advisories and directives 126 39 35 7 4 12 Information 1 0 98 79 57 37 Source: Based on FMMC, 2016. In the case of the 2016 Kumamoto Earthquake, local government officers saved time by inputting information into L-ALERT instead of providing the information to multiple organizations individually. Furthermore, media and service providers received information from L-ALERT directly, instead of dispatching staff to the municipality office. E.2 L-ALERT: ICT Systems and Context Systems and Infrastructures  In February 2008, MIC set up a working group to discuss the concept of a new information platform for safety and security in local communities. The working group suggested developing a shared infrastructure for communication between senders (such as municipalities) and distributors of information (such as broadcasters). Feasibility studies were carried out in the Tokai area in February 2009, and in the Kinki and Tokai areas from February to March in 2010. The system commenced operations on 13th June 2011 under the name “Public information commons” as a shared communication platform to simultaneously transfer disaster information from municipalities to press and media companies. The initial number of prefectural and municipal governments that adopted the system was low (it was installed at only 21 government entities including Tokyo and Osaka). In 2014, MIC changed the name of the system to “L-ALERT” and waged a vigorous promotional campaign to meet the target of 100% adoption by the end of 2015. To date, all municipalities have introduced L-ALERT. The system is operated by the Foundation for MultiMedia Communications (“FMMC” hereafter), a public organization that participated in the working group and feasibility studies. 126 DIGITAL SOLUTIONS FOR RESILIENCE Table E.2.1. Components of L-ALERT No. Name Administration Description Hardware (1) National node Foundation for - One of the node systems of L-ALERT, installed MultiMedia and operated by FMMC Communications - To be connected over LGWAN or Internet, and (FMMC) using the commons VPN. LGWAN is available for municipalities only (2) Users’ node Users (senders of - User-side node system to be installed and information) operated by users approved by FMMC to access node system programs - Same functionality as National node - To be connected over LGWAN only (3) Input terminal Senders of - Prefectural and municipal governments that information have installed the interface of L-ALERT in their disaster prevention system can enter data from disaster prevention system terminals - Those that have not installed the interface use the commons tool (commons editor) on their terminal PC (4) PC Distributors of - To receive emails sent to registered email information addresses from L-ALERT - Received e-mail will be disseminated via newspaper, websites, etc. Software (5) Commons Node FMMC - Receive information from senders sent out System via the commons editor or interfaces from their systems, including J-ALERT and Japan Meteorological Business Support Center (JMBSC) - Convert data from sources into various formats accommodating systems owned by distributors (SOAP, RSS/HTML, email, etc.) - Transfer converted data to distributors (6) Cooperative system Users (senders - Installed at both senders and distributors and distributors of information, and can transmit and receive of information) information in cooperation with the Public Information Commons - After receiving information in cooperative system, it will be disseminated via TV, smart phone applications, websites, etc. (7) Commons tool FMMC - The commons tool software is provided by Public Information Commons Center, and it includes “commons editor” for inputting information (transmission) and “commons viewer” for viewing information (receiving) - After receiving information by commons tool (commons viewer), it will be disseminated via TV, smart phone applications, newspaper, websites, etc. (8) Commons editor FMMC A desktop application to send information to L-ALERT and to manage information already sent out to L-ALERT including: - evacuation advisory and directive - shelter information - disaster management office status - announcements - events (9) Commons viewer FMMC - Receive information from L-ALERT - Store data received in a local database (Microsoft Access) - Search past information in the database - Information received from commons tool will be disseminated via TV, smart phone applications, newspapers, websites, etc. APPENDIX E 127 Network (10) Commons Network Japan Agency for - Communication network dedicated to local (LGWAN; Local Local Authority governments. It connects to the national Government WAN) Information government network Systems (J-LIS) - Communication lines used by municipalities to connect to L-ALERT (11) Commons VPN Public - Used by non-LGWAN users to connect to Information L-ALERT Commons - FMMC performs the work and bears the costs Center in FMMC of implementing and operating VPN - Implementation and operation of the communication lines to connect VPN are the responsibility of users (12) Internet Internet Service - The Internet is used by non-LGWAN users to Providers connect to L-ALERT - Costs of internet service borne by users Source: Based on FMMC, 2017 Dissemination Table E.2.2. Number of Alerts or Information Dispatches Received via L-ALERT during FY2015 Category Number Redirection of Civil protection information 2 Establishment of disaster countermeasures HQ 3,248 Evacuation alerts, evacuation information 2,102 Shelter information 6,967 Damage information 744 Redirection of Emergency Alert Mail 202 Other information 4,013 Event information 1,290 Water level information 158,370 Rainfall information 158,366 Tide height information 49,377 Source: Based on FMMC, 2017 128 DIGITAL SOLUTIONS FOR RESILIENCE Institutional Framework Table E.2.3. Organizational Roles related to L-ALERT No. Name of Organization Roles (1) Foundation for MultiMedia - Operate and manage L-ALERT Communications (FMMC) - Define and update communication protocols (2) Municipalities [Senders] - Disseminate evacuation advisories, directives, announcements, etc. (3) Prefectural governments [Senders] - Disseminate disaster prevention information, announcements, etc. - Distribute evacuation-related information on behalf of municipalities in case of any difficulties (4) Ministries and national [Senders] agencies - FDMA disseminates J-ALERT information - JMA disseminates meteorological information - Cabinet Office disseminates general disaster prevention information (5) Utilities / transportation [Senders] - To disseminate service status of telecommunication, electricity, gas, transportation, and commodities (daily necessities) (6) TV broadcasters (terrestrial [Distributors] and cable) - Data broadcasting on digital TV (text display) (7) Radio broadcasters [Distributors] - Emergency radio broadcasting (text reading) (8) Internet service providers [Distributors] - Distribution on the Internet (text display) (9) Mobile carriers [Distributors] - Dissemination of Emergency Alert Mails to mobile and smartphones - Data distribution on disaster prevention applications (10) Other service providers [Distributors of information] (digital signage, car - Distribution via various services such as digital signage and car navigation systems, etc.) navigation systems (11) Local communities and - Take appropriate actions based on information received private sector Source: Based on FMMC, 2017 APPENDIX E 129 Appendix F: GIS-based Disaster Management Information System F.1 Examples of Application During Disaster Events In the wake of several major disasters, Helicopter Satellite Communication Systems have been deployed to collect important information of the impacted areas. The Disaster Damage Map has been used to provide visual information such as aerial photographs of the Hiroshima landslide disaster (2014), which was the first case of its use, as well as the volcanic eruption of Kuchinoerabu-jima (2015), the Kanto/Tohoku heavy rains (2015) and the Kumamoto earthquake (2016). At the time of the Kumamoto earthquake, just three days after the earthquake on 17th April, images before and after the disaster were developed. The Disaster Damage Map helped not only to compare images pre and post-disaster, but also to grasp the extent and scope of building damage, as red frames on the map outline the shapes of buildings. To date, no municipality that has signed the disaster agreement has been hit by a disaster in which crisis mapping has been used. One nonprofit organization created crisis maps by using drones in the aftermath of the Kumamoto Earthquake. 130 DIGITAL SOLUTIONS FOR RESILIENCE F.2 GIS-Based DIMS: ICT Systems and Context Systems and Infrastructures Table F.2.1. Components for Collecting and Sharing Systems of Geospatial Information in Affected Areas No. Name Administration Description Hardware (1) Base Station Regional - Consists of satellite antenna, modem, Development decoder, and management unit Bureau of MLIT - The satellite antenna can track helicopters automatically (2) Helicopter Airborne Regional - Consists of external equipment and cabin Station Development equipment Bureau of MLIT - External equipment consists of an antenna and a Radio Frequency Unit (RFU), which is a device to control the transmission and reception of radio signals from an antenna to communication satellite - Cabin equipment consists of RFU, modem, antenna control unit, and encoder (3) Terminal PC Owners of the - Set area and notify data providers PC (4) Aerial surveying Surveying - Take aerial images of affected areas aircraft companies/GSI (5) Storage Media NTT GEOSPACE - Provide detailed maps data using storage Corp. media such as USB memory, HDD, CD-R, etc. (6) Drones Crisis Mappers - Drones used for crisis mapping are aircraft- Japan shaped. This enables them to fly longer and faster than “multi-copter” drones, and can take photographs of larger areas per flight - Crisis Mappers Japan currently owns approx. 30 drones (7) GPS Logger Crisis Mappers - Tool for recording flight routes using a (for Crisis Mapping) Japan satellite, loaded into drones APPENDIX F 131 Software (8) ArcGIS Online Esri Japan Corp. - ArcGIS Online is a cloud service that provides (for MMDIN: a location information portal environment Disaster Damage enabling anyone to create, share, and use Map) maps with Esri Japan (dependent on internet connectivity) - Quick usage without installing a server or software, many available map data and applications, and advanced security requirements (9) Detailed map data NTT GEOSPACE - GEOSPACE is a highly accurate electronic (for MMDIN: map prepared on the basis of public surveying Disaster Damage results such as urban planning diagrams, Map) forest basic diagrams and forest drawings provided by NTT space information. The map covers the whole territory of Japan (10) OpenStreetMap OSM Foundation - Project initiated by the OSM Foundation (OSM) to provide geographical information free of charge - Copyright-free map data, available for use by anyone, is widely available on the internet. Downloaded data can be used offline and freely edited for any purpose (11) OpenDroneMap (open source - Open source toolkit for processing aerial tool) drone imagery - Used by the Drone Bird team of Crisis Mappers Japan for orthographic processing images taken from drones (12) OpenAerialMap Humanitarian - Open service for providing access to common OpenStreetMap open licensed imagery and map layer services. Team’s Open - After orthographic processing, images taken Imagery from drones can be overlapped with OSM by Network (OIN) loading the OpenAerialMap (13) GitHub GitHub Inc. - Development platform: Web service based on GIT technology that enables people around the world to store and publish their own data (program codes or design data). - After the images taken from drones are loaded into the OpenAerialMap they are automatically synchronized and shared in GitHub - GIT is a distributed system for recording and tracking modification histories of program source codes. Network (14) Internet Internet Service - The internet enables use of Disaster Damage Providers Maps and crisis mapping (15) Mobile Mobile Carriers Communication Network (16) Satellite Service Providers - Connects a helicopter and base stations Communication - When ground communication lines cannot be Network used in affected areas, satellite communication is ensured Source: Based on websites of JBP and MMDIN, and interviews with Dr. Hayashi (president of NIED), Prof. Furuhashi (Aoyama Gakuin University), and Mitsubishi Electric Corporation Ltd. 132 DIGITAL SOLUTIONS FOR RESILIENCE Table F.2.2. Comparison of Still and Moving Image Technologies for Collecting Information in Affected Areas City Cameras129 Helicopter Satellite Drone Field angle Narrow Medium Wide Narrow - Medium Areas covered Small Medium - Large Large Small - Medium Start-up time Immediately 30 minutes ~ 2 hours ~ A few hours ~ Impact of Almost none Susceptible None None (depending on weather the airframe type) Aircraft - Necessary Not necessary Necessary operation Replay and Possible to some Difficult Easy Difficult Update degree Night operation Possible with night Most likely possible Always in Possible as no vision cameras with lights, but night operation regulation is in place operations may be in Japan restricted130 in some cases in Japan Advantages - Low cost - Highly mobile and - Possible to shoot - Highly mobile and flexible for moving wider areas flexible for moving - Easy to around to shoot around to shoot implement - Possible to shoot - Possible to transfer in bad weather or - Relatively low cost - Possibility data in real-time at night using SAR of aircraft compared of constant using satellite to helicopters and monitoring - Possible to shoot communications satellites at the same place regardless of repeatedly, so it is geographic easy to compare interference such as images of the isolated islands or same place mountains Disadvantages - Limitation in - Highly susceptible - Limited shooting - Limited operating shooting areas to the weather, and time due to the areas due to not available in satellites’ orbits*1 regulations*2 severe weather - Need for - Smaller areas - Night operations expertise to covered by a single may be restricted in process SAR drone (up to one some cases in Japan images municipality) Source: Based on interview with Prof. Furuhashi (Aoyama Gakuin University). Note: *1 Because shooting time is limited with satellites operated by a country, there are some international cooperation agreements, such as “Sentinel Asia” and “International Disaster Charter,” based on which images of affected areas are taken by satellites of multiple countries and provided to the affected country free of charge. *2 This issue can be resolved by making agreements with municipalities beforehand to collect information in affected areas on behalf of the municipality. 129 Many municipal governments in Japan have placed city cameras on high rise public buildings and communication towers in order to visually record, monitor, assess, and communicate conditions and damages during and after natural disasters. 130 Japanese Civil Aeronautics Act essentially prohibits operation at night. APPENDIX F 133 Table F.2.3. Drones Used by Crisis Mappers Japan131 Name SenseFly eBee Parrot Disco Maximum Flight Time: 50 minutes 45 minutes Regular Flight Speed 40 km/h About 40 km/h Areas for automatic About 3 km About 2 km operation Loaded camera 18.2 mega pixels 1080p Batteries LiPo 11.1V, 2150 mAh LiPo 11.1V, 2700 mAh Cost About JPY 2.5 million About JPY 13 thousand Other information Autopilot and flights Autopilot and flights outside covered areas are outside covered areas are available with predefined available with predefined programs programs Figure F.2.1. Images of Drones Used by Crisis Mappers Japan SenseFly eBee Parrot Disco 131 Based on: https://www.sensefly.com/drones/ebee.html and; https://www.parrot.com/jp/doron/parrot-disco-fpv 134 DIGITAL SOLUTIONS FOR RESILIENCE Institutional Framework Table F.2.4. Municipalities with Agreements with Crisis Mappers Japan Municipality, Date of Name of Description agreement agreement Yamato City, Agreement on To use drones to assess damage, such as the collapse of Kanagawa Prefecture. investigations and roads and other structures. 20th September 2016 support in Yamato City at the time of a disaster Chofu City and Komae Agreement on In the event of a large-scale disaster in Chofu City or City, Tokyo. assistance using Komae City, for which urgent assistance is needed, 31th March 2017 drones at the time Crisis Mappers conducts the following activities based of a disaster on the government’s requests: - Damage assessments using drones - Provision of photographic images taken by drones - Generation of Disaster Damage Maps based on image data obtained - Provision of Disaster Damage Maps, and release of map data on the Internet Source: Based on the websites of Yamato City (Kanagawa Prefecture), and Chofu City and Komae City (Tokyo). APPENDIX F 135 Appendix G: Tokushima Prefecture: Disaster Information Management System (DIMS) G.1 Examples of Application During Disaster Events The Disaster Information Management System (DIMS) has been used in several disaster situations, especially for the issuance of critical alerts, the provision of important information and better use of human resources in disaster response. In 2014, for instance, DIMS was used to share information among municipalities affected by severe flooding. Inputting and browsing data on terminal PCs Summary information shown in a large display Figure G.1.1. Disaster Drills for Operation of the DIMS Source: Based on material provided by Tokushima Prefecture 136 DIGITAL SOLUTIONS FOR RESILIENCE G.2 GIS-Based DIMS: ICT Systems and Context Systems and Infrastructures Muncipalities Prefectures National Government Agencies OSM Collect and report information about damage Agreggagate the information Centralize the information Disaster a ected areas Prefecture A City A FDMA National Prefecture B Headquarters Government Town B Prefecture C Figure G.2.1. Flow of Collection and Aggregation of Damage Information in the Japanese Disaster Response System Source: Based on the Disaster Countermeasures Basic Act (1961) Table G.2.1 Three Main Features of Tokushima Prefecture’s DIMS Features Description Disaster Information To enter and share disaster information collected by organizations Entry Assessment Roll-up To determine risk levels using a pre-determined threshold, and show the risk level of each municipality, area, shelter, etc. on a GIS map. It also shows response levels in different colors, so that coordinators and experts can see the overall situation at a glance. Missions Management Centralized management of disaster response status by sharing tasks to be conducted by each organization Source: Based on material provided by Tokushima Prefecture APPENDIX G 137 Table G.2.2. Components of Tokushima Prefecture’s DIMS No. Name Administration Description Hardware (1) Terminal PCs for Tokushima - Terminal PCs for data entries DIMS prefecture (2) Cloud servers in Tokushima - Servers to control DIMS, consisting of the the prefectural prefecture following: building (a) Web server (Main servers) (b) Batch server (c) Database server (d) Load balancing server for EMIS (e) Map server - Duplicated by synchronizing the servers in the prefectural building and those of the external cloud service (3) External Private data center - External cloud servers, to be synchronized cloud servers with servers in the prefectural building (2) (outside of the - To be used for transferring information to prefectural external organizations building) (Backup servers) (4) General terminal Owners of the - Access DIMS by entering an ID and devices device password - Access to the system is controlled with IDs, which means access can be independent from the terminal. 138 DIGITAL SOLUTIONS FOR RESILIENCE Software (5) Disaster Tokushima - To operate and manage cloud servers in the Information prefecture prefectural building Sharing System - To access external systems in order to collect information - To store information collected, and to show data on the terminal PC screen - Disaster information managed in the system includes: Government building damage, situation of setting up headquarters for disaster management in municipalities, evacuation information (such as evacuation advisories and evacuation orders, etc.), situation of shelters (such as number of evacuees, surplus or shortage of relief supplies, etc.), METHANE information and blackouts Government building damage, situation of setting up headquarters for disaster management in municipalities, traffic restrictions, river levels, amount of precipitation, and METHANE information. Information related to medical service availability (for all hospitals located in the prefecture) (6) Assessment Tokushima - Functionality to summarize and show roll-up prefecture assessment items needed for bodies at a summary level, such as municipalities, areas, and shelters - Assessment items are shown in colors to indicate response status, which helps users find areas in need of assistance or materials to be provided (blue for completed, yellow in progress, and red not responded yet) (7) Missions Tokushima - Functionality to manage the response status management prefecture for items needed for assistance. - Items to be managed include assistance category, conducting entity and its name, deadline, status, and description of mission (8) Shelter Tokushima - Functionality to manage the availability of management prefecture shelters, their occupancies, and necessary materials (9) Secondary Tokushima - To enter the operating status of high-level emergency prefecture medical institutions in the prefecture, and to medical care interface data with EMIS information - To receive updated data from EMIS system - To apply the data format called “ebML” (10) Safety Tokushima - To send emails to registered email confirmation prefecture addresses of staff to confirm their safety system - To receive and summarize responses from staff regarding damage severity. (11) Emergency Mobile carriers - To enter information on a special screen for Alert Mail sending Emergency Alert Mail transmission system APPENDIX G 139 External (12) Tokushima DIMS Tokushima - To retrieve data by accessing DIMS from system prefecture cloud servers in the prefectural building (2) linkage - To obtain dam water levels, river levels, precipitation, and tide levels - To copy data to external cloud servers (3) (13) Meteorological HALEX - To trigger a Web API in a batch server, which data services is provided by the DreamAll service of Halex Inc. (Web API) to retrieve data. Then, generate a map image to show precipitation status every square kilometer - To obtain data such as rainfall intensity, precipitation amount per 10 minutes and hourly - To apply the data format determined in the specifications by DreamAll (14) Earthquake USGS - To obtain atom data from the URL set in the information USGS email management by accessing USGS from cloud servers in the prefectural building (2) - To send emails to registered users when earthquakes seismic intensity is 5 Upper or more (15) EMIS Ministry of Health, - To interface with medical information from Labor and Welfare the disaster management system (MHLW) - Managed by the Ministry of Health, Labor and Welfare. - To interfaced with the secondary emergency medical care information system (7) to view the operating status of medical institutions outside Tokushima prefecture - MHLW makes arrangements for wide-area assistance based on the status of medical institutions from other prefectures (16) Meteorological Japan Weather - To obtain updated meteorology data from information Association (JWA) the Japan Weather Association Website services - To obtain information such as meteorological warnings, sediment slide warnings, earthquake early warnings, tsunami warnings, and tsunami information - To apply XML definitions (17) Amazon wish list Amazon.com, Inc. - To show the quantity of each good to be supplied against already supplied quantities by referencing wish list items entered by each shelter using shelter management functionality (8) - To obtain goods on an Amazon wish list, and their supply status - The data obtained can be shown on the wish list summary screen at shelters - Data display in HTML, searching for “id” starting with “itemMain” in
element (18) SEVEN VIEWS Seven Eleven - To send operating status to DIMS (open/ (convenience close, power outage, no batteries (stock), stores) communication line disturbance, delayed deliveries, delivery impossible) (19) Emergency Alert Mobile carriers - To enter information to be sent to mobile Mail carriers from external cloud servers (3) (20) L-ALERT FMMC - To enter information on the deployment status of municipalities, evacuation and shelter status on a special screen to send it to L-ALERT from the external cloud server (3) - To apply XML definitions specified as “Public information Commons XML definitions” (21) Tokushima Private data - DIMS data interface with the Tokushima integrated map centers integrated map service system through service system external servers (3) (22) Safe-Tokushima Tokushima - The web server hosting the Safe-Tokushima website prefecture website accesses external cloud servers (3) to obtain meteorological warnings and sediment slide warnings - The data obtained is shown on the home page of the Safe-Tokushima website 140 DIGITAL SOLUTIONS FOR RESILIENCE Network (23) LAN in the Tokushima - LAN for business operations in the prefectural prefecture prefectural building building (24) Internet Internet service - DIMS is available to external users other provider than prefectural staff through external cloud servers (25) VPN Telecommunication - VPN connection is used to access EMIS carriers (26) IP-VPN (Internet Mobile Carriers - Used to connect to mobile carriers Protocol Virtual Private Network) (27) CommonsVPN Public Information - Used by non-LGWAN users (private data Commons Center center) to connect to L-ALERT in FMMC Source: Based on material provided by Tokushima Prefecture Deployment Table G.2.3. Timeline of DIMS’s Development in Tokushima Prefecture August, 2008 Following the Emergency Medical Information System (EMIS) system as a model, conceptual design process for development of DIMS began 2009 Development of a safety confirmation service began May, 2010 A safety confirmation service was launched August, 2011 Trial operation of DIMS October, 2012 Dual-server environment approach using a cloud service began April, 2013 DIMS was launched for regular operations by all municipalities September, 2013 All hospitals in the prefecture were connected to DIMS (integration with EMIS was completed) 2014 Other organizations such as the fire department, police, and Japan Self-Defense Forces (JSDF) were given view-only access to DIMS 2015 Development began to improve DIMS functionality related to information sharing with health and welfare coordinators APPENDIX G 141 Institutional Framework Table G.2.4. Organizational Roles within DIMS No. Name of organization Roles (1) Tokushima prefecture [Disaster Management Department HQ of Tokushima Prefecture] - Conduct surveys on the status of damage in Tokushima prefecture - Enter status of damage and response status information in the system - Analyze and assess the status of damage - Share information with other relevant organizations [Concerned divisions of the prefecture] - Conduct surveys on the status of damage and enter the information in the system (2) 24 Municipalities in - Conduct surveys on the status of damage in their municipality Tokushima Prefecture - Enter status of damage and response status information in the system (8 cities, 15 towns, and 1 village) (3) Hospitals & Welfare - Conduct surveys on the status of damage incurred to hospitals, facilities facilities, and schools - Enter status of damage and response status information in the system (4) Schools (5) Utilities companies - Enter information in the system on status of damage to facilities, service operations, and recovery status, etc. (6) Japan Weather Association - Provide weather information (7) HALEX (a private weather information company) (8) Seven-Eleven (convenience - Enter operation status (store open/close, power outages, no batteries store) (stock), communication line disturbances, delayed deliveries, stoppage of deliveries) (9) Residents and companies - Enter information in the system (using SNS service, called “Sudachi- kun”, for confirming safety) (10) Fire department - Share information (read-only) Police department - Carry out disaster response activities, transmit information, and Japan Self-Defense Forces provide assistance based on shared information Source: Based on material provided by Tokushima Prefecture 142 DIGITAL SOLUTIONS FOR RESILIENCE APPENDIX G 143 Appendix H: K-DIS: DIMS for Utilities H.1 Examples of Application During Disaster Events K-DIS has been used in many cases, as it is used for both major disasters and minor incidents. According to an interview with Kansai Electric Power Co. Inc., this system is used almost every year, due to the need to restore facilities during the typhoon season. K-DIS has proven to be very effective, specifically with regards to the following areas: • Information sharing among internal organizations • Centralized management of restoration work teams on site in the EOC When restoration work groups are on site, they need to share information such as group location and group status, all of which must be centrally managed by the EOC. K-DIS enables the effective delivery of supplies such as equipment and food to each site, and streamlines support for on-site activities. As such, K-DIS shortens the recovery time for affected facilities, ultimately reducing the economic damage incurred from blackouts. H.2 K-DIS: ICT Systems and Context Systems and Infrastructures Table H.2.1 Components of K-DIS No. Name Administration Description Hardware (1) K-DIS server Kansai - Servers to operate and manage K-DIS (2) Input Terminals Kansai - PCs used by employees in normal times (3) Terminals Kansai - Terminal PCs to browse information in external to browse systems or on the internet external system information 144 DIGITAL SOLUTIONS FOR RESILIENCE Software (4) Shortcuts to Kansai - To show data from other systems owned by Kansai other systems (5) Facility Damage KKansai - To summarize the status of damage of each facility Situation Board based on damage information entered on the board (entry screen) by each group - Summarized information through the board is interfaced with the map display module (6) Map Display Kansai - To show the status of damage on the map based on information summarized on the Damage Situation Board, including: • Operating status of power stations (heat, hydro, and nuclear) • Status of damage to dams, power stations (heat and hydro), and the grid • Blackout areas • Operating status of electric generator vehicles, helicopters, ships, etc. • Traffic status (7) Communication Kansai - To be used for various communications, such Notes as announcements, requests, etc., and task management - EOC issues a communication note on the information or requests to be shared, and based on the notes, each group records the tasks they carried out. EOC uses these notes to understand the response status. - Important records are copied to the company-wide activities log from communication notes and from the activity history summary by each group, so that important issues for the entire company are shown in the “company-wide timeline” screen in chronological order (8) Company-wide Kansai - To summarize critical issues from communication Activities Logs notes, and from group activity logs, and to display summary information in chronological order (company-wide timeline) (9) Other systems in Kansai - Weather alert system Kansai - A-BIS (to manage failures of transmission and distribution lines) - Power Supply Information (to manage the status of power supply and generators - AccESS (to manage power outage information) - Simultaneous Messaging/Safety Confirmation System (to summarize employees’ safety and attendance) (10) External systems MLIT (Ministry To browse site images taken from helicopters, and of Land, river and road monitoring cameras operated by MLIT Infrastructure, Transport and Tourism) Network (11) LAN Kansai - Communication lines for K-DIS - To connect to other systems in Kansai, and make its information available to K-DIS as well (12) Telephone, FAX Communication - To communicate with external organizations Carriers - Information obtained by telephone or FAX is entered manually in K-DIS at EOC (13) Internet Internet service - Communication lines to connect to the Internet provider Source: Based on material provided by Kansai APPENDIX H 145 Thermal Nuclear Hydropower Hub facilities Fuel facilities Power Information service power plant power plant plant (Operation (Operation (Operation Damage Damage outage / Facilities /damage status) /damage status) /damage status) Status Status information Damage Status Command o ce/ EOC G 2015/11/23 15:00 G P A Z / U P Z P P P P P A A A P A A A Z Z Z Z Z Z / / / / / U U U U / U P P P U P P P Z Z Z Z Z Z Thermal Div. Fuel Div. (Gas Div.) Fuel Div. Information communications Div. Nuclear Hydropower Related engineering organizations Information- Thermal power power plants plants Construction Div. (transformer, overhead communications plants (incl. gas power transmission, underground power Group facilities) transmission, control) / construction / civil engineering Figure H.2.2. Schematic of K-DIS Features (Facility Damage Situation Board) Source: Based on material provided by Kansai. Activity Activity Activity Activity log log log log 5 Important items are displayed in chronological order company- wide (Company-wide Command Engineering Network Div. Thermal power basis information o ce Div. Div. on key processes) 1 Management of - Communication and task (Command and control information) 3 Recording important Company-wide basis items Activities log Company-wide basis Activities log 4 Recording individual course summary information Information and Material Div. Network Div. Wakayama Electric communications Div. Power Corp. Div. 2 Input activity log by each division Activity Activity Activity Activity (Individual course log log log log summary information) Figure H.2.3. Schematic of K-DIS Features (Communication Notes) Source: Based on material provided by Kansai 146 DIGITAL SOLUTIONS FOR RESILIENCE - Head O ce EOC Command O ce Company-wide basis Communication processing Activities logs chart (sharing and requests) Sharing important items Sharing Requests and (by sharing individual report Sharing important items course summary (by sharing communication information) processing chart) Regional EOC Input Activity log for each division Communication processing chart (sharing and requests) Sharing Requests and report Related organizations Input Activity log for each division Communication processing chart (sharing and requests) Figure H.2.4. Schematic of K-DIS Features (Company-wide Activities Log) Source: Based on material provided by Kansai Institutional Framework Overview of Kansai Electric Power, as of March 31, 2016 Company name: The Kansai Electric Power Company, Incorporated Headquarters: 3-6-16 Nakanoshima, Kita-ku, Osaka 530-8270 Date of establishment: May 1, 1951 Paid-in capital: JPY 489,300 million Main business: Electric power, heat supply, telecommunications, gas supply Number of group companies: 65 consolidated subsidiaries Number of employees: 21,817 (non-consolidated) Electricity sales: 127,516 million kWh Capacity of power-generating facilities: 36.57GW Operating revenues: JPY 2,868,200 million (non-consolidated) Source: Based on website of Kansai: http://www.kepco.co.jp/english/corporate/info/profile/outline.html APPENDIX H 147 Table H.2.2. Organizational Roles related to the K-DIS No. Name of Roles organization (1) Emergency - Immediately set up after a severe disaster, and take control Operation Center of the full range of tasks to be carried out by each group using (EOC) in Kansai communication notes - Provide information and manage request assistance from external organizations - Enter information in K-DIS from external organizations shown in (4) by telephone or FAX (2) Facility - Execute assigned tasks and record activities upon receiving management directives from the EOC through communication notes department in - Monitor the status of damage and the status of the power supply, Kansai and request assistance (3) Logistic support - Supply daily commodities such as transportation, accommodation, department in and fuel upon receiving directives from the EOC through Kansai communication notes (4) External - [Ministries] Share the EOC deployment status, and request Kansai to organizations report the status of damage to their facilities (Ministries, - [Municipalities] Share the EOC deployment status, and request municipalities, Kansai to dispatch a liaison police and fire department, Self- - [Police and Fire department] Report traffic restrictions and status of Defense Forces, fires customers, electric - [Self-Defense Forces] Share requests for dispatching SDF from power providers, municipalities with Kansai and broadcasters) - [Customers] Report facility damage and status of power outages to Kansai - [Other electricity suppliers or retailers] Report facility damage and status of power outages to Kansai - [Other power producers] Inform availability and support capacities of electric power, etc. - [Broadcasters] Broadcast information on power outages and response status upon receiving it from Kansai - [Other relevant agencies] Provide support as requested by Kansai Source: Based on material provided by Kansai 148 DIGITAL SOLUTIONS FOR RESILIENCE APPENDIX H 149 Appendix I: Hyogo Asset Management System for Resilience: DIMS for Infrastructure I.1 Hyogo Asset Management System: ICT Systems and Context Systems and Infrastructures Table I.1.1. Infrastructure Facilities Subject to the Maintenance Plan No Category Total number of No Category Total number of facilities facilities 1 Bridges 4,654 12 Dams 18 2 Paved roads 4,100 km 13 Seawalls 193.4 km 3 Tunnels Lining 99 14 Pier mooring facilities 420 (quay wall, etc.) Equipment 91 15 Outlying facilities 602 (breakwater, etc.) 4 Underpass 16 16 Erosion control 2,412 facilities 5 Pedestrian Pedestrian 207 17 Landslide prevention 87 crossing bridges, crossing facilities etc. bridges Sidewalks 12.1 km 18 Rapid slope erosion 822 control facilities 6 Road appendages 18,386 19 Sewerage Treatment 8 (roadside lamps, plants etc.) 7 Road slopes 16,285 Drains 51.8 km 8 Drainage pump 49 20 Park facilities 14 stations 9 Water gates, weirs 56 21 Flight runways 53,300 m² 10 Sluice gates, 1,817 22 Other facilities Rain gauges, water- Floodwall gates level gauges, snow blowers, etc. 11 Sheet-pile 92.4 km bulkhead Source: Based on material provided by Hyogo Prefecture 150 DIGITAL SOLUTIONS FOR RESILIENCE Facility Ledger system Browsing/Downloading Interface components: User Browsing - year of construction entry (at construction/ Registration/Correction - structure specification entry inspection site) - search tool User (at o ce) - list of facilities entry Figure I.1.1. Overview of Facility Ledger System: this system enables users to browse, register and correct facility and inspection ledger data. Source: Based on material provided by Hyogo Prefecture Facility Ledger system Asset Management subsystem Distribution of the soundness of bridges data linking Facility Information registration / correction aggregation/output Inspection Information Asset Management system The status management table Date of construction List of facilities information of the Hyogo 10-year Infrastructure and aging information Maintenance Plan Figure I.1.2. Overview of Asset Management System: this system enables users to estimate the future maintenance costs of facilities. Source: Based on material provided by Hyogo Prefecture APPENDIX I 151 Local residents Information Output input User (at o ce) Record Registration of location information User (at construction/ Photograph inspection site) Figure I.1.3. Overview of Requests/Complaints Management System: this system stores the requests and complaints of local residents and supports efficient daily maintenance work. Source: Based on material provided by Hyogo Prefecture Disaster site A Central o ce check Patrol site B O ce Figure I.1.4. Overview of Photograph Storage System: this system stores the locations where photographs (disaster, patrol, etc.) were taken. It enables users to share information between disaster sites, local offices and the central office. Source: Based on material provided by Hyogo Prefecture 152 DIGITAL SOLUTIONS FOR RESILIENCE Table I.1.2. Components of the Asset Management System No. Name Administrator Description Hardware (1) Terminal for browsing Users (relevant - To browse status of damage and enter inspection and inputting agencies) data for facilities, such as roads and bridges (2) Servers for the Hyogo - Servers for the Facility Ledger System (shown systems prefecture under the sections on “Software” in this table) (3) Smartphone and Hyogo - Terminal devices to browse and enter tablet PC prefecture information on site Software (4) Facility Ledger System Hyogo - To manage ledgers of facilities and their prefecture inspection results - Equipped with search functions to retrieve specifications of assets (year of construction, structure, etc.), along with data output options to generate Excel or PDF files containing ledger data (5) Asset Management Hyogo - To assist in formulating the “Plan for Infrastructure System prefecture Life Extension” using basic data to estimate future costs of maintenance or renewal, such as number of facilities, year of construction, and deterioration levels - Simulates costs of maintenance and management in the medium and long term by entering years of operating life, repairs, and renewal costs - Has a summary function to consolidate plans of 22 categories, which helps the prefecture make a cross-sectional review throughout the processes, or to optimize budgets for each category (6) Geographic Hyogo - To organize facility locations on maps including Information System prefecture hazard maps on a scale of 1/2500 (GIS) - Linked to the facilities ledger system, and it is possible to show records of register data including emergency transportation routes, shelters, city hall, hospitals, railways, etc. which are provided with National Land Numerical Information [1] of National Spatial Planning and Regional Policy Bureau - Serves as an integrated GIS system that enables the prefectural government and civil engineering offices to work on the same drawing (7) Requests/Complaints Hyogo - Stores requests and complaints from residents Management System prefecture for regular maintenance processes - The person in charge of a facility enters requests or complaints from residents; response status reported from the engineering office or the site to record data on actions taken to address an issue (8) Photograph Storage Hyogo - Stores photographs taken on site, such as System prefecture status of disaster and patrol observations. - Each photographic image is stored with its location information, and is instantly available to various organizations including afflicted sites, engineering offices, and the main prefectural office (9) Mobile System Hyogo - Launched in March 2017, to enable access prefecture from tablet devices for simplified request/ complaint data entry and display, disaster situation photographic image data loading, and the facilities ledger browsing APPENDIX I 153 Network (10) Local area network Hyogo - LAN in Hyogo prefectural government (LAN) prefecture buildings (11) Internet Internet - Communications to access the system hosted service by IDCs from relevant organizations except the providers prefectural government (12) Mobile Mobile - Used to access the mobile system from communication carriers construction/inspection sites network Source: Based on material provided by Hyogo Prefecture Institutional Framework Table I.1.3 Organizational Roles related to the Asset Management System No. Name of organization Roles (1) Hyogo Construction - Enter infrastructure facilities data into the system including Technology Center for emergency response and restoration status Regional Development (Note: CTC is an affiliated organization of Hyogo Prefecture. Although (CTC) there are input terminals at the headquarters and engineering offices of prefectural government, data input is done by CTC to reduce the burden on the staff of the prefectural office and maintaining the quality of the contents) (2) Hyogo prefecture - Develop and maintain the Asset Management System - [Normal operations] Carry out inspections, diagnoses and assessments of infrastructure facilities; plan and review repairs and renewals of facilities; and implement repairs and renewals based on the plan - [Disaster operations] Manage status of damage and responses in conjunction with the facility ledger system - [Disaster operations] Identify bridges to prioritize for restoration located on roads designated as emergency goods transportation routes - [Disaster operations] Calculate alternative routes for emergency transportation based on the status of damage (3) Internet Data Center (IDC) - All hardware and software of the Asset Management System are installed at private Internet Data Centers (IDCs) - It is possible to share information with municipalities and contractors in Hyogo prefecture over the internet Source: Based on material provided by Hyogo Prefecture 154 DIGITAL SOLUTIONS FOR RESILIENCE APPENDIX I 155 References Executive Summary United Nations. 2016. “Report of the Open-ended Intergovernmental Expert Working Group on Indicators and Terminology Relating to Disaster Risk Reduction”. 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Power Point presentation, Tokyo: METI. http://www.cicc.or.jp/japanese/kouenkai/pdf_ppt/pastfile/h27/151013-1jp.pdf MIC (Ministry of Internal Affairs and Communications). 2008. “Japan’s ICT Strategy”. [in Japanese.] Tokyo: MIC. www.soumu.go.jp/main_sosiki/joho_tsusin/policyreports/chousa/vigor/pdf/080212_2_si4.pdf REFERENCES 157 MIC (Ministry of Internal Affairs and Communications). 2017b. 2017 White paper on information and communications in Japan. [in Japanese.] Tokyo: MIC. http://www.soumu.go.jp/johotsusintokei/whitepaper/ eng/WP2017/2017-index.html MIC (Ministry of Internal Affairs and Communications). 2017c. Playbook for Investment in “Quality ICT Infrastructure”. Tokyo: MIC. http://www.soumu.go.jp/english/gisb/pdf/115748_2.pdf MIC (Ministry of Internal Affairs and Communications). 2017d. “Basic Plan for the Advancement of Utilizing Geospatial Information”. [in Japanese.] Tokyo: MIC. http://www.soumu.go.jp/main_content/000574484.pdf National Institute of Informatics. 2012. “Challenges in ICT and the Legal System”. [in Japanese.] National Institute of Informatics News, 55, 9 - 10. https://www.nii.ac.jp/userdata/results/pr_data/NII_Today/55/all. pdf United Nations. 2016. “Report of the Open-ended Intergovernmental Expert Working Group on Indicators and Terminology Relating to Disaster Risk Reduction”. New York: United Nations. https://www. preventionweb.net/files/50683_oiewgreportenglish.pdf UNISDR (United Nations International Strategy for Disaster Risk Reduction). 2013. “Information and Knowledge Management for Disaster Risk Reduction (IKM4DRR) Framework and Scorecard”. Geneva: UNISDR.https://www.unisdr.org/files/35238_ikm4drrframeworkscorecard.pdf World Bank. 2002. “Information and Communication Technologies: A WORLD BANK GROUP STRATEGY”. Washington, DC: World Bank. http://siteresources.worldbank.org/ EXTINFORMATIONANDCOMMUNICATIONANDTECHNOLOGIES/Resources/SSPwithAnnexes.pdf World Bank. 2017. “Modernization of Japan’s Hydromet Services: A Report on Lessons Learned for Disaster Risk Management”. Washington, DC: World Bank. http://pubdocs.worldbank.org/en/355891472179524146/ DRMHubTokyo-Japan-Hydromet-Summary.pdf Chapter 3 Doughty, K. 2000. “Business continuity planning: protecting your organization’s life”. Auerbach Publications. FDMA (Fire and Disaster Management Agency). 2009. “Increase of J-ALERT information receiving organizations”. [in Japanese.] Tokyo: FDMA. http://www.fdma.go.jp/ugoki/h2103/2103_1-32-2-10.pdf FMMC (Foundation for MultiMedia Communications). 2016. “Usage and Challenges of L-ALERT during Kumamoto Earthquake”. [in Japanese] Tokyo: FMMC. https://www.fmmc.or.jp/Portals/0/images/commons/ publish/commons_advisory183.pdf Ito, Y. 2007. “Emergency Warning Broadcasting System”. The Journal of the Institute of Image Information and Television Engineers, 61(6), 761-763 Tanaka, I., Aoyagi, K., Umesh, A., Hapsari, W. A. 2009. “Advanced warning message distribution platform for the next-generation mobile communication network”. NTT DoCoMo Technical Journal, 11(3), 20-26. MIC (Ministry of Internal Affairs and Communications). 2016a. “Communications Usage Trend Survey”. [in Japanese.] Tokyo: MIC. http://www.soumu.go.jp/johotsusintokei/statistics/statistics05b1.html MIC (Ministry of Internal Affairs and Communications). 2016b. “2016 White paper on information and communications in Japan”. [in Japanese.] Tokyo: MIC. http://www.soumu.go.jp/johotsusintokei/whitepaper/ ja/h28/pdf/28honpen.pdf MIC (Ministry of Internal Affairs and Communications). 2019. “Local government information management summary”. [in Japanese.] Tokyo: MIC. http://www.soumu.go.jp/main_content/000610588.pdf 158 DIGITAL SOLUTIONS FOR RESILIENCE Chapter 4 Kansai (Kansai Electric Power Company). 2018. “Disaster Management Plan”. [in Japanese] Osaka: Kansai https://www.kepco.co.jp/corporate/notice/notice_pdf/20180822_1_01.pdf Tokushima Prefectural Government. 2014. “ICT Tokushima Creation Strategies”. [in Japanese] Tokushima: Tokushima Prefectural Government https://www.pref.tokushima.lg.jp/file/attachment/143423.pdf FMMC (Foundation for MultiMedia Communications). 2017. “L-ALERT Technology Seminar”. [in Japanese] Tokyo: FMMC. https://www.fmmc.or.jp/Portals/0/images/commons/publish/commons_ document20180725_1.pdf MIC (Ministry of Internal Affairs and Communications). 2015a. “Deployment Status of L-ALERT”. [in Japanese.] Tokyo: MIC. http://www.kantei.go.jp/jp/singi/it2/senmon_bunka/bousai/dai8/siryou3.pdf MIC (Ministry of Internal Affairs and Communications). 2015b. “For Further Deployment of L-ALERT”. [in Japanese.] Tokyo: MIC. http://www.soumu.go.jp/main_content/000352090.pdf Appendices FDMA (Fire and Disaster Management Agency). 2017. “ 2017 White Paper on Fire Service”. Tokyo: FDMA. http://www.kaigai-shobo.jp/pdf/White_Paper29_eng.pdf Hitotsubashi University Railway Study Group. 2011. “Disasters and Railway”. [in Japanese] Tokyo: Hitotsubashi University. https://www.ikkyo-tekken.org/studies/2011/2011_all.pdf JMA (Japan Meteorological Agency). 2012. “Survey on current status and actual utilization of Earthquake Early Warning System”. [in Japanese.] Tokyo: JMA. https://www.jma.go.jp/jma/ press/1212/14b/24manzokudo_data.pdf MIC (Ministry of Internal Affairs and Communications). 2014. “Challenges and Future Perspectives of Communication Measures During Disasters” [in Japanese] Tokyo: MIC. http://www.soumu.go.jp/main_ content/000324270.pdf MIC (Ministry of Internal Affairs and Communications). 2016c. “Report of Study Group on Emergency Communication Means at the time of Large Scale Disaster”. [in Japanese] Tokyo: MIC. http://www.soumu. go.jp/main_content/000427271.pdf Satoru Ishigaki. 2011. “Evolution of Disaster Management Radio Systems”. JRC Review, 60, 40-46. Watanabe, A. Honma, Y. Oba, K. Okutomi, T. 2009. “The development of the early earthquake detection and alarm system for bullet-train (Shinkansen)”. MITSUBISHI SPACE SOFTWARE technology Information, 19, 12-16. World Bank. 2016. “Preparedness Map for Community Resilience: Earthquakes – Experience of Japan”. Washington, DC: World Bank. http://pubdocs.worldbank.org/en/180521481856986238/121516- drmhubtokyo-Preparedness-Map-for-Community-Resilience-Earthquakes.pdf REFERENCES 159 World Bank DRM Hub, Tokyo The World Bank Tokyo Disaster Risk Management (DRM) Hub supports developing countries to mainstream DRM in national development planning and investment programs. As part of the Global Facility for Disaster Reduction and Recovery, the DRM Hub provides technical assistance grants and connects Japanese and global DRM expertise and solutions with World Bank teams and government officials. The DRM Hub was established in 2014 through the Japan-World Bank Program for Mainstreaming DRM in Developing Countries – a partnership between Japan’s Ministry of Finance and the World Bank. GFDRR The Global Facility for Disaster Reduction and Recovery (GFDRR) is a global partnership that helps developing countries better understand and reduce their vulnerabilities to natural hazards and adapt to climate change. Working with over 400 local, national, regional, and international partners, GFDRR provides grant financing, technical assistance, training, and knowledge sharing activities to mainstream disaster and climate risk management in policies and strategies. Managed by the World Bank, GFDRR is supported by 36 countries and 10 international organizations. Contact World Bank Disaster Risk Management Hub, Tokyo Phone: +81-3-3597-1320 Email: drmhubtokyo@worldbank.org Website: http://worldbank.org/drmhubtokyo This publication is printed on recycled paper 160 DIGITAL SOLUTIONS FOR RESILIENCE