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Smart City Opportunities: Infrastructure, Systems, Materials 2019-2029
Urban independence, safety and quality of life transformed. Materials and system opportunities
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The term smart city originally meant little beyond using much more information technology IT. Indeed, statements were made about IT becoming the key enabling technology of a city and sensors on everything: big data. Then there was some extension to incrementally improving facilities from transport to healthcare and education. Wrong. The IDTechEx report, "Smart City Opportunities: Infrastructure, Systems, Materials 2019-2029" explains that much more dramatic changes are both required and possible. They reflect the strong trends to people living mainly in cities and localism, where caring, empowered communities harness new infrastructure, systems and materials and radically change the way they operate. Examples include "silent city" banning private cars and providing free public transport. The report reveals how cities will even achieve independence in water, food and energy with retailing and transport reinvented and no emissions or traffic congestion. It is full of detailed new infograms, roadmaps, forecasts and project comparisons.
Learn how infrastructure will often vanish, including electric vehicle chargers, power stations and land-grabbing solar and wind farms. Many devices will be used less, including batteries, but many billion dollar businesses will be created. For instance, they will provide cognizant self-powered buildings and smart roads that automatically deice and charge moving vehicles using self-generated electricity. This is a world of nearby wave and tidal power without infrastructure and marine aquaculture, for most of the large cities are on the sea. It embraces aeroponics, hydroponics and other indoor farming. Cities must now defend against cyberattack but independent systems in houses and buildings will make that easier and that empowerment means costs will be better controlled and changing needs met more promptly. The report uniquely covers this big picture and the huge range of new materials and systems required. Surprisingly, the report shows how most of these things are happening somewhere in the world already. There are forecasts and technology roadmaps for many of the materials and systems required including internet of things, sensors and radically new forms of IT.
The Executive Summary and Conclusions addresses definitions, technologies, examples and progress so far including such things as democratisation of Artificial Intelligence, expansion of Mobile Platform Services, Proximity Marketing and Ubiquitous Sensors. Many materials opportunities are identified. The Introduction looks at the cities of the world and how they will be reinvented, explaining the digital transformation and the decline of much infrastructure as such things as self-sufficient buildings and energy independent vehicles arrive. Learn what and when and see the pictures. Chapter 3 details Cognitive and Self-powered Buildings and Roads and Chapter 4 focuses on Reinventing Last Mile Delivery of People and Things. Wireless Connectivity in Smart Cities is covered in Chapter 5. See Chapter 6 for Convergence of On Line and Physical Retailing, Chapter 7 for Smart Urban Farming and Chapter 8 for Water Independence: Zero Emission Desalination and Water Treatment. The report "Smart City Opportunities: Infrastructure, Systems, Materials 2019-2029" ends with an extensive Chapter 9 on Key Enabling Technologies with detailed analysis of materials and systems needed, gaps in the market and routes to many billion dollar opportunities.
Examples of radical smart city advances
Source: IDTechEx
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| 1. | EXECUTIVE SUMMARY AND CONCLUSIONS |
| 1.1. | The smart city concept |
| 1.1.1. | Original idea and objective of this report |
| 1.1.2. | Localism |
| 1.1.3. | Defensive and unquantifiable aspects |
| 1.1.4. | Drivers of change |
| 1.1.5. | Reinventing the city |
| 1.1.6. | Smart city embraces radical advances |
| 1.1.7. | Moveable cities |
| 1.2. | Examples of radical advances already coming in |
| 1.3. | Examples of energy independent cities |
| 1.3.1. | Babcock Ranch in Florida |
| 1.3.2. | Sustainable city Dubai |
| 1.4. | Water independence |
| 1.5. | Food independence |
| 1.6. | Cognitive responsive infrastructure |
| 1.7. | Robotics and reinvented transport |
| 1.8. | Ubiquitous sensors and IoT in cities |
| 1.9. | Democratisation of AI: back to the future |
| 1.9.1. | The three waves of artificial intelligence |
| 1.9.2. | Deep neural networks enabling AI advances |
| 1.9.3. | Basics of artificial intelligence & democratization of AI |
| 1.10. | Who delivers smart city? |
| 1.11. | Materials opportunities |
| 1.12. | IDTechEx market forecasts for smart city services and networks |
| 1.12.1. | Mobile platform services |
| 1.12.2. | Proximity marketing |
| 1.12.3. | RFID sensor tags and systems ($ million) |
| 1.13. | Total connections by year by application 2018-2029 |
| 1.14. | Total connections by year for NB-IoT, LTE, LoRa and Others 2018-2029 |
| 1.15. | Total connections by year 2018 - 2029: Unlicensed vs Licensed |
| 1.16. | Asset tracking market for low power networks 2018-2029 |
| 1.17. | Smart home, consumer electronics and home utilities: low power connections 2018-2029 |
| 1.18. | Smart city low power connections 2018-2029 |
| 1.19. | IDTechEx forecasts for smart city major hardware |
| 1.19.1. | Solar road forecast $ billion |
| 1.19.2. | Road sensing, non-solar harvesting, allied harvesting forecast |
| 1.19.3. | Smart glass |
| 1.19.4. | Off grid harvesting systems of which smart cities are an increasingly important part |
| 1.20. | 20-year market forecasts (2018 to 2038) for agricultural robots and drones segmented by 16 technologies |
| 1.20.1. | 2018-2038 market forecasts in unit numbers segmented by level of agri-robot function |
| 1.20.2. | Rise of small agri-robots 2018-2038: value market forecasts segmented by functionality |
| 2. | INTRODUCTION |
| 2.1. | Cities face disruptive major changes |
| 2.2. | Radical changes essential |
| 2.3. | Smart city driving forces, dreams and threats |
| 2.3.1. | Background |
| 2.3.2. | Smart city functions |
| 2.3.3. | Trend to less or no infrastructure |
| 2.4. | Digital Transformation and Exponential Organizations |
| 2.4.1. | Overview |
| 2.4.2. | Digital transformation: why now? |
| 2.4.3. | AI, the IoT & the Digital to Quantum transformation |
| 2.4.4. | Self-powered cities: photovoltaics cheaper than large onshore wind in 2020 |
| 2.5. | The Anatomy of a Smart City |
| 3. | ENERGY INDEPENDENCE AND COGNITIVE INFRASTRUCTURE |
| 3.1. | Buildings have a major impact on city energy consumption |
| 3.2. | Active smart glass in buildings |
| 3.2.1. | Market drivers |
| 3.2.2. | Active and passive glass darkening materials |
| 3.2.3. | Samsung OLED window |
| 3.3. | Digital transformation and building automation |
| 3.4. | Technology toolkits enabling cognitive buildings |
| 3.4.1. | Impact |
| 3.4.2. | Opportunities |
| 3.4.3. | The emerging "building as a service" model |
| 3.5. | Wireless, self-powered building controls: EnOcean and 8Power |
| 3.6. | Making zero emission electricity where you need it |
| 3.6.1. | Overview |
| 3.6.2. | Very different Levelised Cost of Electricity LCOE targets |
| 3.6.3. | "Zero Genset" opportunity: Transportable and available at the touch of a button |
| 3.6.4. | Modular, zero emission diesel genset and grid replacement - $100Bn+ "Zero Genset" market |
| 3.6.5. | Ground turbine wind power does not downsize well: physics and poorer wind |
| 3.7. | Smart roads and surroundings |
| 3.7.1. | Overview |
| 3.7.2. | Gantry vs road surface |
| 3.7.3. | Highway barriers: Eindhoven University of Technology |
| 3.7.4. | Solar Roadways and Missouri Department of Transportation |
| 3.7.5. | Solar roads, parking, paths, barriers compared |
| 3.7.6. | Bouygues Colas France |
| 3.7.7. | Solar road Pavenergy China |
| 3.7.8. | Integral monitoring, EV charging roads Israel, USA, Europe |
| 3.7.9. | Solar road with integral lit markers - concept |
| 3.7.10. | Dharan Saudi Arabia solar car park provides total 10.5 MW power for high rise office block |
| 4. | REINVENTING LAST MILE DELIVERY OF PEOPLE AND THINGS |
| 4.1. | Introduction |
| 4.1.1. | Definitions and issues |
| 4.1.2. | Last mile travel for goods and people are closely allied |
| 4.1.3. | Last mile vehicle needs and challenges |
| 4.1.4. | Electric vehicles have a major part to play |
| 4.1.5. | Examples of last mile LM and allied EVs currently in use |
| 4.1.6. | EVs carried in or on long range vehicles |
| 4.1.7. | Experimental LM EVs |
| 4.1.8. | Tightening legal constraints |
| 4.1.9. | Main solutions compared |
| 4.1.10. | Unmanned autonomous vehicles: operational, technical, ethical challenges |
| 4.1.11. | Insurance challenges |
| 4.1.12. | Societal impact |
| 4.1.13. | Amazon beating Wal-Mart by solving Last Mile? |
| 4.1.14. | DHL Germany |
| 4.1.15. | First Transit: first commercially operated driverless vehicle? UK, USA |
| 4.1.16. | PonyZero technology Italy |
| 4.1.17. | Terra Motors Japan |
| 4.1.18. | Moby Mart, Japan |
| 4.1.19. | Tesco supermarkets UK: one hour EV delivery |
| 4.1.20. | Mobility for the disabled |
| 5. | WIRELESS CONNECTIVITY IN SMART CITIES |
| 5.1. | Smart city mesh networks |
| 5.2. | The Wi-Sun alliance |
| 5.3. | Silver Spring networks in smart cities |
| 5.4. | LPWAN trends in smart cities |
| 5.5. | Smart City Trends: Parking |
| 5.6. | Car parking assisted by IoT |
| 5.7. | Smart City Trends: Waste |
| 5.8. | Smart city trends: street lights |
| 5.9. | Libelium nodes utilising LPWAN technology |
| 5.10. | Case Study: San Diego |
| 5.11. | LPWAN deployment across India |
| 5.12. | Internet connected fire hydrants |
| 5.13. | People as sensor nodes |
| 5.14. | LPWAN on a university campus |
| 5.15. | Canal systems in the Netherlands make use of LPWAN technology |
| 5.16. | LPWAN network coverage in Australia and New Zealand |
| 5.17. | LPWAN in contingency planning |
| 6. | CONVERGENCE OF ON LINE AND PHYSICAL RETAILING |
| 6.1. | Overview |
| 6.2. | Digital transformation and retail |
| 6.2.1. | Background & drivers |
| 6.3. | amazon's key automation initiatives |
| 6.4. | Walmart's key automation initiatives |
| 6.5. | Digital and robotic transformation in retail |
| 6.5.1. | Impact |
| 6.5.2. | Electronic shelf labels & proximity marketing |
| 6.6. | Smart city retail and restaurants boost certain vehicles |
| 7. | FOOD INDEPENDENCE: SMART URBAN FARMING |
| 7.1. | Food independence |
| 7.2. | Growing population and growing demand for food |
| 7.3. | Major crop yields are plateauing using conventional approaches |
| 7.4. | The young shun farming |
| 7.5. | Ultra precision agriculture coming via the variable rate technology route |
| 7.6. | Ultra precision farming will cause upheaval |
| 7.7. | Agriculture is one the last major industries to digitize |
| 7.8. | RaaS or equipment sales |
| 7.9. | Transition towards to swarms of small, slow, cheap robots |
| 7.10. | Market and technology readiness by agricultural activity |
| 7.11. | Autonomous robotics for greenhouses and nurseries |
| 8. | WATER INDEPENDENCE: ZERO EMISSION DESALINATION AND WATER TREATMENT |
| 8.1. | Background |
| 8.2. | Middle East |
| 8.3. | Best practice small ZE off grid desalination: MIT USA in Puerto Rico etc. |
| 8.4. | A history of last resort, big is beautiful but vulnerable |
| 8.5. | Onerous requirements for large desalination plants may force rethink |
| 8.6. | Solar RO desalination winning in number of ZE plants |
| 8.7. | Roadmap for ZE off grid desalination 2019-2029 |
| 8.8. | Competing on price is easier than it seems |
| 9. | KEY ENABLING TECHNOLOGIES: CYBERSECURITY, IOT, SENSORS, ENERGY HARVESTING |
| 9.1. | Cybersecurity |
| 9.2. | Internet of things and allied technologies |
| 9.2.1. | Definitions and scope |
| 9.2.2. | IoT infrastructure |
| 9.2.3. | Smart cities and IoT practicality |
| 9.2.4. | IoT value chain and bias vs IoP |
| 9.2.5. | IOT and wireless sensor/ actuator applications in future smart cities: examples |
| 9.2.6. | Losing privacy, committing crime, solving crime |
| 9.2.7. | Wider deployment means compromises and new challenges |
| 9.2.8. | Some megatrends favour IoT: others do not |
| 9.2.9. | Examples of IoT opportunities and suppliers |
| 9.3. | Smart sensors for smart cities |
| 9.3.1. | Introduction |
| 9.3.2. | Fixed vs mobile sensing networks |
| 9.3.3. | Personal vs private networks |
| 9.3.4. | Current city wide pollution monitoring programmes |
| 9.3.5. | Current smart city air monitoring projects |
| 9.3.6. | Calculated air quality measurements |
| 9.3.7. | Transport based sensing of environmental pollutants |
| 9.3.8. | Airborne pollution sensing |
| 9.3.9. | Mobile monitoring: sensors on bicycles |
| 9.3.10. | Traffic monitoring with gas sensors |
| 9.3.11. | Array of things project - Chicago |
| 9.3.12. | Anatomy of an outdoor sensor node |
| 9.3.13. | Challenges for smart city monitoring |
| 9.3.14. | Future opportunities for environmental sensors in smart cities |
| 9.3.15. | Materials for gas sensors |
| 9.4. | Energy harvesting microwatt to megawatt |
| 9.4.1. | Definition, systems design, future |
| 9.4.2. | Market drivers for energy harvesting |
| 9.4.3. | Characteristics of energy harvesting |
| 9.4.4. | Low power vs high power EH features |
| 9.4.5. | EH transducer principles and materials |
| 9.4.6. | EH technologies progressing very rapidly in performance and potential applications |
| 9.4.7. | New examples of low power harvesting by power level |
| 9.4.8. | Energy independent cities: US, Canada, Dubai |
Report Statistics
| Slides | 236 |
|---|---|
| Forecasts to | 2029 |