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{{Chapter
{{Chapter
| Public Safety-Resilience and Regeneration of Communities
|image=Extreme_heat.jpg
| sectors = Extreme Heat
|poc=Jiri Skopek
| authors = Jiri Skopek
|authors=Jiri Skopek
| poc = Jiri Skopek
|blueprint=Resilience
| email = jiri@skopek.ca
|sectors=Resilience
| image = https://opencommons.org/images/e/ec/Extreme_heat.jpg
|summary=The previous chapter focused on technology development to support whole community planning for disaster recovery, with emphasis on the requirements for multi-agency planning and decision -making involving an entire community and its physical, economic, and social resources. Technology development strategies to enhance City (or Community) Resilience are closely aligned with capabilities for disaster recovery, insofar as they involve the entire scope of community functions.
| summary = Extreme heat and heatwaves are becoming a significant concern for many world cities and communities, and it's rapidly worsening due to the impact of climate change. Extreme heat events have severe impacts on ecosystems, infrastructure, human health, and economies. These heatwaves are not only a consequence of escalating global temperatures, but they also symbolize an acute emergency for urban environments worldwide In several locations the extreme heat is exacerbated by poor air quality caused by smoke from wildfires.
|email=jiri@skopek.ca
}}
}}
Extreme heat and heatwaves are becoming a significant concern for many world cities and communities, and it's rapidly worsening due to the impact of climate change. Extreme
However, developing a technology strategy for enhancing the resilience of a community or region involves
Urban areas, characterized by their dense populations and significant infrastructural development, have become epicenters for extreme heat impacts. This phenomenon is exacerbated by the Urban Heat Island (UHI) effect, wherein the lack of vegetation and high prevalence of heat-absorbing materials lead to significantly warmer conditions in cities compared to their rural surroundings. The interplay of climate change, urbanization, and socio-economic factors means that heat risks in cities are escalating at an alarming rate.  
more than focusing on disaster response or recovery (or disaster resistance, as it is sometimes called), or
even on the single issue of public safety as traditionally defined. A holistic appro ach to resilience and
community sustainability involves the broad spectrum of human activities and interactions within the
community as the sum of relationships between four interconnected systems:
#The natural environment of geography, climate and weather;
#The built environment of the city habitat, its engineered systems, and physical infrastructure;
#The social environment of human population, communities and socio-economic activities; and
#An information ecosystem that provides the means for understanding, interacting with, and managing the relationships between the natural, built, and human environments.
As the nation and its communities become more connected, networked, and technologically
sophisticated, new challenges and opportunities arise that demand a rethinking of current approaches to
public safety and emergency management. An integrated approach to city and community resilience holds
the potential to greatly enhance overall public safety, emergency response, and disaster recovery, while
addressing new and emerging threats to public safety and security.


The consequences of increasing urban heat are manifold and far-reaching. heatwaves pose considerable threats to urban infrastructure, disrupting essential services, exacerbating energy demands, and straining resources. Simultaneously, health concerns range from heat stress and heat-related illnesses to exacerbated chronic conditions and increased mortality rates. The ripple effects of extreme heat events can thus perpetuate socio-economic disparities, destabilize local economies, and compromise overall urban sustainability.
Community resilience-building is effectively an aspect of mitigation planning. Figure 12 illustrates the
range and relationships among the hazards that community resilience programs in the public safety arena
may need to address.


In this section, we will show how to identify the severity of extreme heat events and identify how to implement actionable adaptive and mitigative strategies to reduce risk and increase resilience. We will present case studies from cities across the globe, demonstrating the universal nature of this crisis and the range of strategies combining infrastructural changes, policy interventions, technological advancements, and community engagement currently being deployed.
[[File:Examples of Threats and Hazards Facing Communities (DHS National Mitigation Framework).jpeg|center|1000px|thumb|Figure 12. Examples of Threats and Hazards Facing Communities (DHS National Mitigation Framework)]]


Monitoring and Benchmarking Extreme Heat- KPIs
After nearly a decade of research, planning, policy development, and implementation, there is no
Temperature- Metric: (°C/°F) is the most obvious indicator of the warming planet. NOAA National Centers for Environmental Information https://www.ncei.noaa.gov/access/monitoring/climate-at-a-glance/global/mapping provides detailed information on both local and global temperature variation. Since the dawn of the industrial age the global average temperature had risen by approximately 1.1 degrees Celsius (about 2 degrees Fahrenheit) above pre-industrial levels. The consequences of this warming include more frequent and intense heatwaves and changes in weather patterns.
shortage of models, frameworks, and guidance documents for developing and establishing a community
Mean or peak daytime temperature Metric: Mean or peak daytime local temperature by direct measurement, PET calculation or modelling (°C), or by PMV-PPD calculation (unitless value) Green urban infrastructure can significantly affect climate change adaptation by reducing air and surface temperatures with the help of shading and through increased evapotranspiration. Conversely, green urban infrastructure can also provide insulation from cold and/or shelter from wind, thereby reducing heating requirements (Cheng, Cheung, & Chu, 2010). By moderating the urban microclimate, green infrastructure can support a reduction in energy use and improved thermal comfort (Demuzere et al., 2014). https://unalab.eu/system/files/2020-02/d31-nbs-performance-and-impact-monitoring-report2020-02-17.pdf
resilience program. (By way of example, simply conduct an online search for “community resilience
Heatwave Risk Metric: number of combined hot nights (>20°C) and hot days (>35°C) Heatwave is a period of prolonged abnormally high surface temperatures relative to those normally expected. Heatwaves can be characterized by low humidity, which may exacerbate drought, or high humidity, which may exacerbate the health effects of heat-related stress such as heat exhaustion, dehydration and heatstroke. Heatwaves in Europe are associated with significant morbidity and mortality. Furthermore, climate change is expected to increase average summer temperatures and the frequency and intensity of hot days (Russo et al., 2014).
frameworks,” or “smart city.”) Widely accepted strategies include [[Media:43291_sendaiframeworkfordrren.pdf|Sendai Framework for Disaster Risk Reduction 2015 - 2030]] or [[Media:City-Resilience-Framework-2015.pdf|Rockefeller 100 Resilient Cities program]].
Urban Heat Island (UHI) effect Metric: (°C/°F) This indicator focuses on the urban heat island (UHI) effect, wherein a significant difference is observed in air temperature between the city and its surroundings. The UHI effect is caused by the absorption of sunlight by (stony) materials, reduced evaporation and the emission of heat caused by human activities. The UHI effect is greatest after sunset and reported to reach up to 9°C in some cities, e.g., Rotterdam (Van Hove et al., 2015).
 
Strategies.
Resilience as defined by the Sendai Framework is the ability of a system, community, or society exposed
Reducing extreme heat and heatwaves in urban areas is an urgent task for many cities and communities given the increasing intensity of heatwaves as a result of climate change. Below are some strategies cities can consider:
to hazards to resist, absorb, accommodate, adapt to, transform and recover from the effects of a hazard
Urban Greening: Increasing the number of trees, plants, and green spaces in a city can help to reduce temperatures. This is because vegetation reduces heat through a process known as "evapotranspiration” and provides shade that cools the surrounding areas. Additionally, green roofs and walls can be used to cool buildings and further reduce temperatures. Urban forests also contribute to carbon sequestration, thus mitigating climate change.
in a timely and efficient manner, including through the preservation and restoration of its Essential basic
Urban Planning and Design: Implement strategies to reduce the heat island effect. This includes constructing buildings with cool or green roofs, using lighter-coloured materials in pavements and other urban infrastructure to reflect more sunlight, and ensuring that buildings are adequately spaced to allow for airflow.
structures and functions through risk management. Increasingly, in the context of cities resilience is
Water Features: The introduction of water features such as ponds, fountains, and artificial lakes can help to reduce urban heat through evaporative cooling.
framed around the ability to withstand and bounce back from both acute shocks (natural and manmade)
Improved Building Design: Increasing the energy efficiency of buildings can reduce the need for air conditioning, which is a significant contributor to urban heat. Passive cooling strategies such as natural ventilation, shading, and insulation can be very effective in this regard.
such as floods, earthquakes, hurricanes, wild-fires, chemical spills, power outages, as well as chronic
Community Education and Behavior Change: Educating residents about the impacts of heatwaves and how to stay cool can help to mitigate the health impacts of extreme heat. Encouraging behavioral changes such as reducing energy use during peak times can also help to reduce heat production.
stresses occurring over longer time scales, such as groundwater depletion or deforestation, or socio-economic issues such as homelessness and unemployment.
Infrastructure Adaptation: Adopting heat-resilient infrastructure such as thermally comfortable public transportation, cooling centers, and shaded public spaces can protect vulnerable populations during heatwaves.
 
Early Warning Systems and Heat-Health Action Plans: Implementing robust heat-health warning systems can alert the public when heatwaves are expected, allowing them to take precautions. These systems need to be linked to heat-health action plans that detail how to respond to these warnings.
The United Nations Disaster Resilience Scorecard for Cities is a recommended starting point for cities to
Climate-sensitive Urban Development: New development projects must take into consideration future climate conditions including rising temperatures and frequent heatwaves.
self-assess their preparedness. This Scorecard is structured around the “Ten Essentials for Making Cities
Engagement with stakeholders: Partnering with local communities, businesses, non-profits, and other stakeholders to implement these measures can ensure they are successful and tailored to local needs.
Resilient”, first developed as part of the Hyogo Framework for Action in 2005, and then updated to
Policy Interventions: City governments can implement a range of policy interventions to promote these strategies, such as requiring green roofs on new buildings, offering incentives for energy-efficient design, or creating zoning laws that promote the creation of green spaces.
support implementation of the Sendai Framework for Disaster Risk Reduction: 2015-2030.
It is important to take a holistic approach to reducing urban heat, as these strategies can often have additional benefits such as improving air quality, enhancing biodiversity, and improving residents' well-being.
 
[[File:10 essentials image.jpg|center|800px|thumb|Figure 13: The Ten Essentials of Making Cities Resilient from the Sendai Framework]]
 
As shown in Figure 13, the Ten Essentials for Making Cities Resilient offer a broad coverage of the many issues cities need to address to become more disaster resilient:
*Essentials 1-3 cover governance and financial capacity;
*Essentials 4-8 cover the many dimensions of planning and disaster preparation;
*Essentials 9-10 cover the disaster response itself and post-event recovery.
=Planning Strategies=
A city is a system of systems, with each of those systems (e.g. communications, water, sanitation, energy,
healthcare, welfare, law and order, education, businesses, social and neighborhood systems) potentially
having separate owners and stakeholders. Resilience needs consideration within and across each of these
systems and therefore can only be achieved through effective collaboration.
 
A range of actors —whether government, private business, community groups, academic institutions,
other organizations or individuals—have roles to play in maintaining and improving city resilience. Ideally,
local government authorities (which often have the best convening power) should take the lead in
conducting the assessments of the Scorecard. A multi -stakeholder dialogue and approach between key
city stakeholders will be necessary to complete the Scorecard, and is essential in the push towards more
resilient cities.
 
Local governments that have used the Scorecard have found it useful at a range of levels:
*As a high-level survey, often via a 1 or 2-day workshop – this can be supported by questionnaires that participants fill out in advance. Sometimes an average or consensus score is applied at the level of each of the “Ten Essentials,” rather than for each individual criteria / assessment;
*As a limited exercise focusing on some individual Essentials, to create an in-depth review of some specific aspects of resilience, e.g. community-level preparedness;
*As a detailed review of the city’s entire resilience position, likely to take one to several months to complete.
*In light of user feedback, the Scorecard now offers the potential for scoring at two levels:
**Level 1: Preliminary level, responding to key Sendai Framework targets and indicators, and with some critical sub-questions. This approach is suggested for use in a 1 to 2-day city multi-stakeholder workshop. In total, there are 47 questions / indicators, each with a 0 – 3 score;
**Level 2: Detailed assessment. This approach is a multi-stakeholder exercise that may take 1–4 months and can be a basis for a detailed city resilience action plan. The detailed assessment includes 117 indicator criteria, each with a score of 0 – 5. Note that the criterion in the detailed assessment may serve as helpful discussion prompts for a preliminary level workshop.
 
Some intentional overlap exists between the preliminary and detailed assessments. [[Media:UNDRR_Disaster resilience%20 scorecard for cities_Detailed_English.pdf|Cities completing the
detailed assessment]] should find it easier if they have already completed the preliminary. The detailed
assessment is designed to build on the preliminary, but prompts deeper thought, review and consultation.
 
While the Scorecard aims to be systematic, individual scores may unavoidably be subjective –
use judgment to decide which scores apply most closely to your level of disaster resilience.
Recording your justification for each evaluation score will enable validation, as well as future
revisions and tracking of progress;
*Disaster risk reduction and building resilience needs to be a collaborative effort. Some aspects of disaster resilience may not be under the control of local governments (for example, the city’s electricity supply or phone system may be operated by a separate agency or private utility, or there may be a provincial or neighboring government that also needs to be involved). The Scorecard should be completed in consultation with these other organizations. The consultation process will also help to engage and build understanding, ownership and alignment with these other organizations;
*Consulting citizen groups as you complete the Scorecard will improve the validity of your results;
*Being as accurate and realistic as possible will help identify areas of vulnerability, enabling their prioritization for attention and funding;
*The Scorecard may not address all the disaster resilience issues facing your city. If in doubt, take advice from an expert in risk management or another relevant discipline.
*The Scorecard provides an aspirational definition of disaster resilience – it is unlikely that any city will score maximum points, and most will not score more than 50%. The intention of the Scorecard is to guide cities towards improved disaster risk reduction, and to challenge complacency.
*The scores are not normative and therefore not comparable across different cities. The Scorecard was not designed to facilitate competition between cities, but to identify and promote sharing of knowledge.
=Considerations for Technology Development and Insertion=
The challenges or threats to public safety and security depicted in Figure 12 offer opportunities for introducing technology advancements to improve the resilience and sustainability of the overa ll community ecosystem. RDT&E of advanced technologies would, for example, include such priorities as:
*Design and integration of intelligent infrastructure—including embedded sensors, IoT, wireless information technologies, and real-time data capture and analysis;
*Improvements in environmental monitoring and predictive analytics that could contribute to public health monitoring, as well as the monitoring of geological and environmental conditions;
*Resilient infrastructure design with emphasis on electrical grid and telecommunications systems that can sustain public communications and connectivity during emergencies and disasters;
*Enhanced data analytics leading to better modeling and display of decision-making within multi-agency and multi-disciplinary team systems, that are appropriate to Blue-Sky city management and daily operations, but which can transition seamlessly to high-criticality decision-making under the stress of Dark-Sky disasters and civil emergencies.
 
In this regard, the technology development projects within GCTC member communities exemplify the
range of technologies and concepts with potential for improving the overall community resilience.
Currently, the SuperClusters are organized into five areas of research and development for technology
insertion:
*Transportation
*Utilities (Energy/Water/Waste Management)
*City Data Platform
*Public Wireless / Broadband
*Cybersecurity and Privacy
*Public Safety
*Agriculture and Rural
*Smart Buildings
*Education
*Health and Thriving Communities
Collectively, these SuperClusters represented over 120 participating city and technology developer teams,
and a portfolio of over 130 Smart City Applications, each of which contributes to some aspect of improving
the resilience, health, safety, or quality of life within a connected community.
 
The next section offers a general approach for designing and implementing a Smart Public Safety Program
within a Smart and Connected Community. Like this Blueprint, itself, the approach is based on the initial
work of the PSSC during its first year, and will be expanded with input from PSSC member communities
and Action Clusters, based on the real-world experience of developing, piloting, and implementing smart
technology applications for public safety, disaster response and recovery, and community resilience.

Latest revision as of 23:40, January 24, 2024


Resilience
Resilience
Sectors Resilience
Contact Jiri Skopek
Topics
Activities
Morgenstadt Framework.jpg Framework for Enhancing Disaster Mitigation and Regeneration of Community Capacity
Establishment of a framework that fosters collaborative efforts between diverse public, private, and academic partners to enhance disaster mitigation, community resilience and economic growth.
First responder.jpg Information for First Responders on Maintaining Operational Capabilities During a Pandemic
First responders have a critical role in pre-hospital emergency care and must continue to provide this essential service and fill the many emergency response roles in a community.
FlashFloodTexas.jpg Next Generation Resilient Warning Systems for Tornados and Flash Floods
The project aims to revolutionize severe weather warnings through Next Gen communications and networking. Focusing on hyper-local, user-driven, context-aware alerts, it leverages mobile phones and hyper-local data for customized warnings, enhancing response and outcomes.
Vanport1947.jpg Regenerative Urbanism Vanport
Vanport, Oregon was a temporary housing project built in 1942 to address a wartime housing shortage in Portland.
Buchman School.jpg School Organized Locally Assisted Community Emergency‐Management
The School Organized Locally Assisted Community Emergency‐Management (SOLACE) project focused on the use of a community school as a community resilience hub for its surrounding community. Community Resilience Hubs (CRHs) can be defined as community‐serving facilities augmented to support residents and coordinate resource distribution of resources and services to the surrounding community. This project focused specifically on the use of a CRM to support community member needs before, during, or after a natural hazard event and on developing a community‐led sociotechnical infrastructure framework for adapting a public school (Buckman Elementary School) as the pilot CRH. In 2022, this project received a NSF Planning Grant.
Authors

JiriSkopek.jpeg

The previous chapter focused on technology development to support whole community planning for disaster recovery, with emphasis on the requirements for multi-agency planning and decision -making involving an entire community and its physical, economic, and social resources. Technology development strategies to enhance City (or Community) Resilience are closely aligned with capabilities for disaster recovery, insofar as they involve the entire scope of community functions.

However, developing a technology strategy for enhancing the resilience of a community or region involves more than focusing on disaster response or recovery (or disaster resistance, as it is sometimes called), or even on the single issue of public safety as traditionally defined. A holistic appro ach to resilience and community sustainability involves the broad spectrum of human activities and interactions within the community as the sum of relationships between four interconnected systems:

  1. The natural environment of geography, climate and weather;
  2. The built environment of the city habitat, its engineered systems, and physical infrastructure;
  3. The social environment of human population, communities and socio-economic activities; and
  4. An information ecosystem that provides the means for understanding, interacting with, and managing the relationships between the natural, built, and human environments.

As the nation and its communities become more connected, networked, and technologically sophisticated, new challenges and opportunities arise that demand a rethinking of current approaches to public safety and emergency management. An integrated approach to city and community resilience holds the potential to greatly enhance overall public safety, emergency response, and disaster recovery, while addressing new and emerging threats to public safety and security.

Community resilience-building is effectively an aspect of mitigation planning. Figure 12 illustrates the range and relationships among the hazards that community resilience programs in the public safety arena may need to address.

Figure 12. Examples of Threats and Hazards Facing Communities (DHS National Mitigation Framework)

After nearly a decade of research, planning, policy development, and implementation, there is no shortage of models, frameworks, and guidance documents for developing and establishing a community resilience program. (By way of example, simply conduct an online search for “community resilience frameworks,” or “smart city.”) Widely accepted strategies include Sendai Framework for Disaster Risk Reduction 2015 - 2030 or Rockefeller 100 Resilient Cities program.

Resilience as defined by the Sendai Framework is the ability of a system, community, or society exposed to hazards to resist, absorb, accommodate, adapt to, transform and recover from the effects of a hazard in a timely and efficient manner, including through the preservation and restoration of its Essential basic structures and functions through risk management. Increasingly, in the context of cities resilience is framed around the ability to withstand and bounce back from both acute shocks (natural and manmade) such as floods, earthquakes, hurricanes, wild-fires, chemical spills, power outages, as well as chronic stresses occurring over longer time scales, such as groundwater depletion or deforestation, or socio-economic issues such as homelessness and unemployment.

The United Nations Disaster Resilience Scorecard for Cities is a recommended starting point for cities to self-assess their preparedness. This Scorecard is structured around the “Ten Essentials for Making Cities Resilient”, first developed as part of the Hyogo Framework for Action in 2005, and then updated to support implementation of the Sendai Framework for Disaster Risk Reduction: 2015-2030.

Figure 13: The Ten Essentials of Making Cities Resilient from the Sendai Framework

As shown in Figure 13, the Ten Essentials for Making Cities Resilient offer a broad coverage of the many issues cities need to address to become more disaster resilient:

  • Essentials 1-3 cover governance and financial capacity;
  • Essentials 4-8 cover the many dimensions of planning and disaster preparation;
  • Essentials 9-10 cover the disaster response itself and post-event recovery.

Planning Strategies

A city is a system of systems, with each of those systems (e.g. communications, water, sanitation, energy, healthcare, welfare, law and order, education, businesses, social and neighborhood systems) potentially having separate owners and stakeholders. Resilience needs consideration within and across each of these systems and therefore can only be achieved through effective collaboration.

A range of actors —whether government, private business, community groups, academic institutions, other organizations or individuals—have roles to play in maintaining and improving city resilience. Ideally, local government authorities (which often have the best convening power) should take the lead in conducting the assessments of the Scorecard. A multi -stakeholder dialogue and approach between key city stakeholders will be necessary to complete the Scorecard, and is essential in the push towards more resilient cities.

Local governments that have used the Scorecard have found it useful at a range of levels:

  • As a high-level survey, often via a 1 or 2-day workshop – this can be supported by questionnaires that participants fill out in advance. Sometimes an average or consensus score is applied at the level of each of the “Ten Essentials,” rather than for each individual criteria / assessment;
  • As a limited exercise focusing on some individual Essentials, to create an in-depth review of some specific aspects of resilience, e.g. community-level preparedness;
  • As a detailed review of the city’s entire resilience position, likely to take one to several months to complete.
  • In light of user feedback, the Scorecard now offers the potential for scoring at two levels:
    • Level 1: Preliminary level, responding to key Sendai Framework targets and indicators, and with some critical sub-questions. This approach is suggested for use in a 1 to 2-day city multi-stakeholder workshop. In total, there are 47 questions / indicators, each with a 0 – 3 score;
    • Level 2: Detailed assessment. This approach is a multi-stakeholder exercise that may take 1–4 months and can be a basis for a detailed city resilience action plan. The detailed assessment includes 117 indicator criteria, each with a score of 0 – 5. Note that the criterion in the detailed assessment may serve as helpful discussion prompts for a preliminary level workshop.

Some intentional overlap exists between the preliminary and detailed assessments. Cities completing the detailed assessment should find it easier if they have already completed the preliminary. The detailed assessment is designed to build on the preliminary, but prompts deeper thought, review and consultation.

While the Scorecard aims to be systematic, individual scores may unavoidably be subjective – use judgment to decide which scores apply most closely to your level of disaster resilience. Recording your justification for each evaluation score will enable validation, as well as future revisions and tracking of progress;

  • Disaster risk reduction and building resilience needs to be a collaborative effort. Some aspects of disaster resilience may not be under the control of local governments (for example, the city’s electricity supply or phone system may be operated by a separate agency or private utility, or there may be a provincial or neighboring government that also needs to be involved). The Scorecard should be completed in consultation with these other organizations. The consultation process will also help to engage and build understanding, ownership and alignment with these other organizations;
  • Consulting citizen groups as you complete the Scorecard will improve the validity of your results;
  • Being as accurate and realistic as possible will help identify areas of vulnerability, enabling their prioritization for attention and funding;
  • The Scorecard may not address all the disaster resilience issues facing your city. If in doubt, take advice from an expert in risk management or another relevant discipline.
  • The Scorecard provides an aspirational definition of disaster resilience – it is unlikely that any city will score maximum points, and most will not score more than 50%. The intention of the Scorecard is to guide cities towards improved disaster risk reduction, and to challenge complacency.
  • The scores are not normative and therefore not comparable across different cities. The Scorecard was not designed to facilitate competition between cities, but to identify and promote sharing of knowledge.

Considerations for Technology Development and Insertion

The challenges or threats to public safety and security depicted in Figure 12 offer opportunities for introducing technology advancements to improve the resilience and sustainability of the overa ll community ecosystem. RDT&E of advanced technologies would, for example, include such priorities as:

  • Design and integration of intelligent infrastructure—including embedded sensors, IoT, wireless information technologies, and real-time data capture and analysis;
  • Improvements in environmental monitoring and predictive analytics that could contribute to public health monitoring, as well as the monitoring of geological and environmental conditions;
  • Resilient infrastructure design with emphasis on electrical grid and telecommunications systems that can sustain public communications and connectivity during emergencies and disasters;
  • Enhanced data analytics leading to better modeling and display of decision-making within multi-agency and multi-disciplinary team systems, that are appropriate to Blue-Sky city management and daily operations, but which can transition seamlessly to high-criticality decision-making under the stress of Dark-Sky disasters and civil emergencies.

In this regard, the technology development projects within GCTC member communities exemplify the range of technologies and concepts with potential for improving the overall community resilience. Currently, the SuperClusters are organized into five areas of research and development for technology insertion:

  • Transportation
  • Utilities (Energy/Water/Waste Management)
  • City Data Platform
  • Public Wireless / Broadband
  • Cybersecurity and Privacy
  • Public Safety
  • Agriculture and Rural
  • Smart Buildings
  • Education
  • Health and Thriving Communities

Collectively, these SuperClusters represented over 120 participating city and technology developer teams, and a portfolio of over 130 Smart City Applications, each of which contributes to some aspect of improving the resilience, health, safety, or quality of life within a connected community.

The next section offers a general approach for designing and implementing a Smart Public Safety Program within a Smart and Connected Community. Like this Blueprint, itself, the approach is based on the initial work of the PSSC during its first year, and will be expanded with input from PSSC member communities and Action Clusters, based on the real-world experience of developing, piloting, and implementing smart technology applications for public safety, disaster response and recovery, and community resilience.

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