The future of cities – will they be smart, human and sustainable?
The team at Fast Future take a look at the future technology that will shape our smart cities
The team at Fast Future take a look at the future technology that will shape our smart cities
Rohit Talwar, Steve Wells and Alexandra Whittington from Fast Future take a look at the future technology that will shape our smart cities
The world’s premier cities are already competing to build highly interconnected smart environments where people, government and business operate in symbiosis with spectacular exponentially improving technologies such as big data, the Internet of Things (IoT), cloud computing, hyperconnectivity, artificial intelligence (AI), robots, drones, autonomous green vehicles, 3D/4D printing and renewable energy.
Future smart cities promise to harmonise the benefits of these key disruptive technologies for society and provide a high quality of life by design. At the same time, they assume that pervasive surveillance and data capture are permissible to city residents. Some have already begun implementing smart city mechanisms and, as the concepts, experiences and success stories spread, the pursuit of smart will become a key driver in the evolving future of cities as communities and economic centres.
The evidence to date from smart city initiatives around the world is that the best results come when we have a clear sense of what the end goal is.
However, it can be hard to develop a clear future vision and strategy when every sector is being disrupted and all our assumptions are being challenged. Yet, that’s exactly what we have to do. City governments must create inclusive processes that inform citizens about the forces shaping the future and the possibilities and challenges on the horizon and then engage the population in dialogue about the kind of future we want to create.
We need to articulate a clear vision and direction around education, environment, public services, access to justice, city administration, and civic engagement. These pillars then provide the guiding requirements which will influence the design of the physical, digital and human elements of a smart city infrastructure.
Smart cities are designed to inform decisions by capturing massive amounts of data about the population and its patterns, such as water use and traffic flows. This information gathering results in big data, and it is essentially gathered via surveillance. There can also be voluntary efforts to collect information, but the ease and affordability of sensors, AI and advanced analytics in the future will mean this function can be completely automated.
The data can be collated from a constantly evolving and expanding IoT – encompassing traffic lights and cameras, pollution sensors, building control systems, and personal devices – all literally feeding giant data stores held in the cloud. What’s more, the ability to crunch all this data is becoming easier due to rampant growth in the use of devices algorithms, AI, and predictive software – all running on networks of high performance computing and storage devices.
Singapore is a leading example of a smart city, and is constantly evolving its ‘city brain’, a backbone of technologies used to help control pollution, monitor traffic, allocate parking, communicate with citizens, and even issue traffic fines. The behavioural aspect is not to be overlooked. Singapore’s ‘brain’ is attempting to modify human behaviour; for example, one system rewards drivers for using recommended mapped routes, and punishes those who do not. Ultimately, Singapore’s planners hope to discourage driving, and guide most commuters to making greater use of public transportation.
The city is planning for 100 million “smart objects” including smart traffic lights, lamp posts, sensors, and cameras on its roadways, which will be used to monitor and enforce laws.
Smart cities rest on advanced technology to make sense of massive collections of information. Indeed, the amount of information on the internet is expected to grow exponentially as a result of the Internet of Things (IoT). Essentially IoT means that everything (“things”) – and potentially everyone – will become beacons and data collection devices, gathering data on ambient and behavioural patterns from its surroundings and from the information it is fed—and networking all this data via the cloud. Hence, after data, the IoT is the second driving force behind the rise of smart infrastructure; for everything from air conditioning to parking meters to function in a smart city, the use of microphones, sensors, voice recognition, and all sorts of other high-tech gadgetry must be hooked up to the IoT.
Companies and planners are already beginning to explore the possibilities. For example, a case study from India suggests that light poles along the highways can offer both smart city and connectivity solutions. In addition to helping monitor road conditions, the light poles could be fitted as high-speed data connections. Data is a critical element of the smart city/smart road future. However, because this option will further expand the relationship between internet service providers, surveillance, and private business including advertisers, there are several issues around privacy to be considered.
Within and between the smart cities of the future, smart roads are where planners can put into effect the ultra-efficient mechanisms that will characterize the modern smart city. In general, the concepts around smart cities, smart roads, and smart infrastructure are becoming less visionary and more strategic and sustainable by the day. As a smart infrastructure future unfolds, three important new technologies—big data, the IoT and renewable energy—are working in tandem to transform the day-to-day.
For example, South Korea is planning an entire network of smart roads by 2020, including battery-charging stations for electric vehicles (EVs) as well as infrastructure to handle autonomous vehicles. Autonomous vehicles will require roads to transform into information superhighways; the vehicles will need to communicate not only with each other, but also with the city infrastructure. The need for ubiquitous data is a critical step in the evolution toward self-driving cars. Mapping, traffic signals, and safety regulations, for instance, are all parts of the physical and digital infrastructure that will have to become highly coordinated for autonomous vehicles to function.
All this data and awareness will enable decisions that make the best possible use of space, fuel, energy, water, electricity, and all resources, with an emphasis on sustainability. For example, a clear priority is being able to anticipate big traffic jams and provide alternate routes to save time, fuel, and reduce impact on the city infrastructure itself. Limiting waste is a very logical outcome and benefit of the merging of big data, AI and IoT which feeds into the rise of smart infrastructure.
Electric vehicles are growing their market foothold, hence the charging concerns related to EVs are gaining urgency in the eyes of many policy-makers and planners. One of the biggest hurdles to electric vehicle adoption is keeping a charge across long distances. To help address this challenge, UK researchers are testing out smart road technology that charges electric cars while they are being driven. The achievement of smart infrastructures could drive the required policy and behavioural tweaks to enable wide adoption of today’s renewable resources.
Another smart technology involves pavement surfaces prepared with panels that capture solar energy allowing streets to power themselves, which has been tested in the U.S. and the Netherlands. Meanwhile, a special powder that gathers sunlight and glows at night has shown promise, but not in the wet climates of northern Europe—it washes off with excessive rain.
A futuristic concept that would not require sunshine is the capture of renewable energy with piezoelectric crystals installed beneath asphalt on busy highways. Theoretically, the crystals could capture the energy released by vehicles driving over the asphalt, which could then be stored or used for powering highway infrastructure. Piezoelectric crystal pilot programs, though so far unsuccessful, provide a fresh perspective on renewable options for gathering energy to power our infrastructure and roads.
The smart city movement now afoot has the potential to transform the organisation of people and physical objects in a way that transcends urban development as we know it.
The shift to smart infrastructure is not simply fashionable or aspirational; in many ways, it appears to be a critical enabler of the future sustainability of cities. It can be argued that the future of human life on the planet rests on a smooth transition to cities that are more efficient, less wasteful, and more conscious of the impacts of the individual upon the greater good.
This may include a range of new negotiations along the boundaries of freedom and privacy; for example, allowing self-driving cars to replace human drivers in the hope of preventing death and injury in auto accidents, increasing traffic efficiency and removing environmental impacts. Similarly, we might have to agree to invasive monitoring of waste generation, energy and water use in the home to reach municipal conservation goals. These are the kinds of tensions that future planners will need to wrestle with on a continuous basis.
A well thought through vision, enabled by a robust and well-executed smart city model could provide a foundation stone for the next stage of our development, where science and technology are genuinely harnessed in service of creating a very human future.
ABOUT THE AUTHORS
Rohit Talwar, Steve Wells and Alexandra Whittington are from Fast Future which publishes books from future thinkers around the world exploring how developments such as AI, robotics and disruptive thinking could impact individuals, society and business and create new trillion-dollar sectors. Fast Future has a particular focus on ensuring these advances are harnessed to unleash individual potential and ensure a very human future. See: www.fastfuture.com.