11 reasons computers can’t understand or solve our problems without human judgement

(Photo by Matt Gidley)

(Photo by Matt Gidley)

Why data is uncertain, cities are not programmable, and the world is not “algorithmic”.

Many people are not convinced that the Smart Cities movement will result in the use of technology to make places, communities and businesses in cities better. Outside their consumer enjoyment of smartphones, social media and online entertainment – to the degree that they have access to them – they don’t believe that technology or the companies that sell it will improve their lives.

The technology industry itself contributes significantly to this lack of trust. Too often we overstate the benefits of technology, or play down its limitations and the challenges involved in using it well.

Most recently, the idea that traditional processes of government should be replaced by “algorithmic regulation” – the comparison of the outcomes of public systems to desired objectives through the measurement of data, and the automatic adjustment of those systems by algorithms in order to achieve them – has been proposed by Tim O’Reilly and other prominent technologists.

These approaches work in many mechanical and engineering systems – the autopilots that fly planes or the anti-lock braking systems that we rely on to stop our cars. But should we extend them into human realms – how we educate our children or how we rehabilitate convicted criminals?

It’s clearly important to ask whether it would be desirable for our society to adopt such approaches. That is a complex debate, but my personal view is that in most cases the incredible technologies available to us today – and which I write about frequently on this blog – should not be used to take automatic decisions about such issues. They are usually more valuable when they are used to improve the information and insight available to human decision-makers – whether they are politicians, public workers or individual citizens – who are then in a better position to exercise good judgement.

More fundamentally, though, I want to challenge whether “algorithmic regulation” or any other highly deterministic approach to human issues is even possible. Quite simply, it is not.

It is true that our ability to collect, analyse and interpret data about the world has advanced to an astonishing degree in recent years. However, that ability is far from perfect, and strongly established scientific and philosophical principles tell us that it is impossible to definitively measure human outcomes from underlying data in physical or computing systems; and that it is impossible to create algorithmic rules that exactly predict them.

Sometimes automated systems succeed despite these limitations – anti-lock braking technology has become nearly ubiquitous because it is more effective than most human drivers at slowing down cars in a controlled way. But in other cases they create such great uncertainties that we must build in safeguards to account for the very real possibility that insights drawn from data are wrong. I do this every time I leave my home with a small umbrella packed in my bag despite the fact that weather forecasts created using enormous amounts of computing power predict a sunny day.

(No matter how sophisticated computer models of cities become, there are fundamental reasons why they will always be simplifications of reality. It is only by understanding those constraints that we can understand which insights from computer models are valuable, and which may be misleading. Image of Sim City by haljackey)

We can only understand where an “algorithmic” approach can be trusted; where it needs safeguards; and where it is wholly inadequate by understanding these limitations. Some of them are practical, and limited only by the sensitivity of today’s sensors and the power of today’s computers. But others are fundamental laws of physics and limitations of logical systems.

When technology companies assert that Smart Cities can create “autonomous, intelligently functioning IT systems that will have perfect knowledge of users’ habits” (as London School of Economics Professor Adam Greenfield rightly criticised in his book “Against the Smart City”), they are ignoring these challenges.

A blog published by the highly influential magazine Wired recently made similar overstatements: “The Universe is Programmable” argues that we should extend the concept of an “Application Programming Interface (API)” – a facility usually offered by technology systems to allow external computer programmes to control or interact with them – to every aspect of the world, including our own biology.

To compare complex, unpredictable, emergent biological and social systems to the very logical, deterministic world of computer software is at best a dramatic oversimplification. The systems that comprise the human body range from the armies of symbiotic microbes that help us digest food in our stomachs to the consequences of using corn syrup to sweeten food to the cultural pressure associated with “size 0” celebrities. Many of those systems can’t be well modelled in their own right, let alone deterministically related to each other; let alone formally represented in an accurate, detailed way by technology systems (or even in mathematics).

We should regret and avoid the hubris that leads to the distrust of technology by overstating its capability and failing to recognise its challenges and limitations. That distrust is a barrier that prevents us from achieving the very real benefits that data and technology can bring, and that have been convincingly demonstrated in the past.

For example, an enormous contribution to our knowledge of how to treat and prevent disease was made by John Snow who used data to analyse outbreaks of cholera in London in the 19th century. Snow used a map to correlate cases of cholera to the location of communal water pipes, leading to the insight that water-borne germs were responsible for spreading the disease. We wash our hands to prevent diseases spreading through germs in part because of what we would now call the “geospatial data analysis” performed by John Snow.

Many of the insights that we seek from analytic and smart city systems are human in nature, not physical or mathematical – for example identifying when and where to apply social care interventions in order to reduce the occurrence of  emotional domestic abuse. Such questions are complex and uncertain: what is “emotional domestic abuse?” Is it abuse inflicted by a live-in boyfriend, or by an estranged husband who lives separately but makes threatening telephone calls? Does it consist of physical violence or bullying? And what is “bullying”?

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(John Snow’s map of cholera outbreaks in 19th century London)

We attempt to create structured, quantitative data about complex human and social issues by using approximations and categorisations; by tolerating ranges and uncertainties in numeric measurements; by making subjective judgements; and by looking for patterns and clusters across different categories of data. Whilst these techniques can be very powerful, just how difficult it is to be sure what these conventions and interpretations should be is illustrated by the controversies that regularly arise around “who knew what, when?” whenever there is a high profile failure in social care or any other public service.

These challenges are not limited to “high level” social, economic and biological systems. In fact, they extend throughout the worlds of physics and chemistry into the basic nature of matter and the universe. They fundamentally limit the degree to which we can measure the world, and our ability to draw insight from that information.

By being aware of these limitations we are able to design systems and practises to use data and technology effectively. We know more about the weather through modelling it using scientific and mathematical algorithms in computers than we would without those techniques; but we don’t expect those forecasts to be entirely accurate. Similarly, supermarkets can use data about past purchases to make sufficiently accurate predictions about future spending patterns to boost their profits, without needing to predict exactly what each individual customer will buy.

We underestimate the limitations and flaws of these approaches at our peril. Whilst Tim O’Reilly cites several automated financial systems as good examples of “algorithmic regulation”, the financial crash of 2008 showed the terrible consequences of the thoroughly inadequate risk management systems used by the world’s financial institutions compared to the complexity of the system that they sought to profit from. The few institutions that realised that market conditions had changed and that their models for risk management were no longer valid relied instead on the expertise of their staff, and avoided the worst affects. Others continued to rely on models that had started to produce increasingly misleading guidance, leading to the recession that we are only now emerging from six years later, and that has damaged countless lives around the world.

Every day in their work, scientists, engineers and statisticians draw conclusions from data and analytics, but they temper those conclusions with an awareness of their limitations and any uncertainties inherent in them. By taking and communicating such a balanced and informed approach to applying similar techniques in cities, we will create more trust in these technologies than by overstating their capabilities.

What follows is a description of some of the scientific, philosophical and practical issues that lead inevitability to uncertainty in data, and to limitations in our ability to draw conclusions from it:

But I’ll finish with an explanation of why we can still draw great value from data and analytics if we are aware of those issues and take them properly into account.

Three reasons why we can’t measure data perfectly

(How Heisenberg’s Uncertainty Principle results from the dual wave/particle nature of matter. Explanation by HyperPhysics at Georgia State University)

1. Heisenberg’s Uncertainty Principle and the fundamental impossibility of knowing everything about anything

Heisenberg’s Uncertainty Principle is a cornerstone of Quantum Mechanics, which, along with General Relativity, is one of the two most fundamental theories scientists use to understand our world. It defines a limit to the precision with which certain pairs of properties of the basic particles which make up the world – such as protons, neutrons and electrons – can be known at the same time. For instance, the more accurately we measure the position of such particles, the more uncertain their speed and direction of movement become.

The explanation of the Uncertainty Principle is subtle, and lies in the strange fact that very small “particles” such as electrons and neutrons also behave like “waves”; and that “waves” like beams of light also behave like very small “particles” called “photons“. But we can use an analogy to understand it.

In order to measure something, we have to interact with it. In everyday life, we do this by using our eyes to measure lightwaves that are created by lightbulbs or the sun and that then reflect off objects in the world around us.

But when we shine light on an object, what we are actually doing is showering it with billions of photons, and observing the way that they scatter. When the object is quite large – a car, a person, or a football – the photons are so small in comparison that they bounce off without affecting it. But when the object is very small – such as an atom – the photons colliding with it are large enough to knock it out of its original position. In other words, measuring the current position of an object involves a collision which causes it to move in a random way.

This analogy isn’t exact; but it conveys the general idea. (For a full explanation, see the figure and link above). Most of the time, we don’t notice the effects of Heisenberg’s Uncertainty Principle because it applies at extremely small scales. But it is perhaps the most fundamental law that asserts that “perfect knowledge” is simply impossible; and it illustrates a wider point that any form of measurement or observation in general affects what is measured or observed. Sometimes the effects are negligible,  but often they are not – if we observe workers in a time and motion study, for example, we need to be careful to understand the effect our presence and observations have on their behaviour.

2. Accuracy, precision, noise, uncertainty and error: why measurements are never fully reliable

Outside the world of Quantum Mechanics, there are more practical issues that limit the accuracy of all measurements and data.

(A measurement of the electrical properties of a superconducting device from my PhD thesis. Theoretically, the behaviour should appear as a smooth, wavy line; but the experimental measurement is affected by noise and interference that cause the signal to become "fuzzy". In this case, the effects of noise and interference - the degree to which the signal appears "fuzzy" - are relatively small relative to the strength of the signal, and the device is usable)

(A measurement of the electrical properties of a superconducting device from my PhD thesis. Theoretically, the behaviour should appear as a smooth, wavy line; but the experimental measurement is affected by noise and interference that cause the signal to become “fuzzy”. In this case, the effects of noise and interference – the degree to which the signal appears “fuzzy” – are relatively small compared to the strength of the signal, and the device is usable)

We live in a “warm” world – roughly 300 degrees Celsius above what scientists call “absolute zero“, the coldest temperature possible. What we experience as warmth is in fact movement: the atoms from which we and our world are made “jiggle about” – they move randomly. When we touch a hot object and feel pain it is because this movement is too violent to bear – it’s like being pricked by billions of tiny pins.

This random movement creates “noise” in every physical system, like the static we hear in analogue radio stations or on poor quality telephone connections.

We also live in a busy world, and this activity leads to other sources of noise. All electronic equipment creates electrical and magnetic fields that spread beyond the equipment itself, and in turn affect other equipment – we can hear this as a buzzing noise when we leave smartphones near radios.

Generally speaking, all measurements are affected by random noise created by heat, vibrations or electrical interference; are limited by the precision and accuracy of the measuring devices we use; and are affected by inconsistencies and errors that arise because it is always impossible to completely separate the measurement we want to make from all other environmental factors.

Scientists, engineers and statisticians are familiar with these challenges, and use techniques developed over the course of more than a century to determine and describe the degree to which they can trust and rely on the measurements they make. They do not claim “perfect knowledge” of anything; on the contrary, they are diligent in describing the unavoidable uncertainty that is inherent in their work.

3. The limitations of measuring the natural world using digital systems

One of the techniques we’ve adopted over the last half century to overcome the effects of noise and to make information easier to process is to convert “analogue” information about the real world (information that varies smoothly) into digital information – i.e. information that is expressed as sequences of zeros and ones in computer systems.

(When analogue signals are amplified, so is the noise that they contain. Digital signals are interpreted using thresholds: above an upper threshold, the signal means “1”, whilst below a lower threshold, the signal means “0”. A long string of “0”s and “1”s can be used to encode the same information as contained in analogue waves. By making the difference between the thresholds large compared to the level of signal noise, digital signals can be recreated to remove noise. Further explanation and image by Science Aid)

This process involves a trade-off between the accuracy with which analogue information is measured and described, and the length of the string of digits required to do so – and hence the amount of computer storage and processing power needed.

This trade-off can be clearly seen in the difference in quality between an internet video viewed on a smartphone over a 3G connection and one viewed on a high definition television using a cable network. Neither video will be affected by the static noise that affects weak analogue television signals, but the limited bandwidth of a 3G connection dramatically limits the clarity and resolution of the image transmitted.

The Nyquist–Shannon sampling theorem defines this trade-off and the limit to the quality that can be achieved in storing and processing digital information created from analogue sources. It determines the quality of digital data that we are able to create about any real-world system – from weather patterns to the location of moving objects to the fidelity of sound and video recordings. As computers and communications networks continue to grow more powerful, the quality of digital information will improve,  but it will never be a perfect representation of the real world.

Three limits to our ability to analyse data and draw insights from it

1. Gödel’s Incompleteness Theorem and the inconsistency of algorithms

Kurt Gödel’s Incompleteness Theorem sets a limit on what can be achieved by any “closed logical system”. Examples of “closed logical systems” include computer programming languages, any system for creating algorithms – and mathematics itself.

We use “closed logical systems” whenever we create insights and conclusions by combining and extrapolating from basic data and facts. This is how all reporting, calculating, business intelligence, “analytics” and “big data” technologies work.

Gödel’s Incompleteness Theorem proves that any closed logical system can be used to create conclusions that  it is not possible to show are true or false using the same system. In other words, whilst computer systems can produce extremely useful information, we cannot rely on them to prove that that information is completely accurate and valid. We have to do that ourselves.

Gödel’s theorem doesn’t stop computer algorithms that have been verified by humans using the scientific method from working; but it does mean that we can’t rely on computers to both generate algorithms and guarantee their validity.

2. The behaviour of many real-world systems can’t be reduced analytically to simple rules

Many systems in the real-world are complex: they cannot be described by simple rules that predict their behaviour based on measurements of their initial conditions.

A simple example is the “three body problem“. Imagine a sun, a planet and a moon all orbiting each other. The movement of these three objects is governed by the force of gravity, which can be described by relatively simple mathematical equations. However, even with just three objects involved, it is not possible to use these equations to directly predict their long-term behaviour – whether they will continue to orbit each other indefinitely, or will eventually collide with each other, or spin off into the distance.

(A computer simulation by Hawk Express of a Belousov–Zhabotinsky reaction,  in which reactions between liquid chemicals create oscillating patterns of colour. The simulation is carried out using “cellular automata” a technique based on a grid of squares which can take different colours. In each “turn” of the simulation, like a turn in a board game, the colour of each square is changed using simple rules based on the colours of adjacent squares. Such simulations have been used to reproduce a variety of real-world phenomena)

As Stephen Wolfram argued in his controversial book “A New Kind of Science” in 2002, we need to take a different approach to understanding such complex systems. Rather than using mathematics and logic to analyse them, we need to simulate them, often using computers to create models of the elements from which complex systems are composed, and the interactions between them. By running simulations based on a large number of starting points and comparing the results to real-world observations, insights into the behaviour of the real-world system can be derived. This is how weather forecasts are created, for example. 

But as we all know, weather forecasts are not always accurate. Simulations are approximations to real-world systems, and their accuracy is restricted by the degree to which digital data can be used to represent a non-digital world. For this reason, conclusions and predictions drawn from simulations are usually “average” or “probable” outcomes for the system as a whole, not precise predictions of the behaviour of the system or any individual element of it. This is why weather forecasts are often wrong; and why they predict likely levels of rain and windspeed rather than the shape and movement of individual clouds.

(Hello)

(A simple and famous example of a computer programme that never stops running because it calls itself. The output continually varies by printing out characters based on random number generation. Image by Prosthetic Knowledge)

3. Some problems can’t be solved by computing machines

If I consider a simple question such as “how many letters are in the word ‘calculation’?”, I can easily convince myself that a computer programme could be written to answer the question; and that it would find the answer within a relatively short amount of time. But some problems are much harder to solve, or can’t even be solved at all.

For example, a “Wang Tile” (see image below) is a square tile formed from four triangles of different colours. Imagine that you have bought a set of tiles of various colour combinations in order to tile a wall in a kitchen or bathroom. Given the set of tiles that you have bought, is it possible to tile your wall so that triangles of the same colour line up to each other, forming a pattern of “Wang Tile” squares?

In 1966 Robert Berger proved that no algorithm exists that can answer that question. There is no way to solve the problem – or to determine how long it will take to solve the problem – without actually solving it. You just have to try to tile the room and find out the hard way.

One of the most famous examples of this type of problem is the “halting problem” in computer science. Some computer programmes finish executing their commands relatively quickly. Others can run indefinitely if they contain a “loop” instruction that never ends. For others which contain complex sequences of loops and calls from one section of code to another, it may be very hard to tell whether the programme finishes quickly, or takes a long time to complete, or never finishes its execution at all.

Alan Turing, one of the most important figures in the development of computing, proved in 1936 that a general algorithm to determine whether or not any computer programme finishes its execution does not exist. In other words, whilst there are many useful computer programmes in the world, there are also problems that computer programmes simply cannot solve.

(A set of Wang Tiles, and a pattern created by tiling them so that tiles are placed next to other tiles so that their edges have the same colour. Given any particular set of tiles, it is impossible to determine whether such a pattern can be created by any means other than trial and error)

(A set of Wang Tiles, and a pattern of coloured squares created by tiling them. Given any random set of tiles of different colour combinations, there is no set of rules that can be relied on to determine whether a valid pattern of coloured squares can be created from them. Sometimes, you have to find out by trial and error. Images from Wikipedia)

Five reasons why the human world is messy, unpredictable, and can’t be perfectly described using data and logic

1. Our actions create disorder

The 2nd Law of Thermodynamics is a good candidate for the most fundamental law of science. It states that as time progresses, the universe becomes more disorganised. It guarantees that ultimately – in billions of years – the Universe will die as all of the energy and activity within it dissipates.

An everyday practical consequence of this law is that every time we act to create value – building a shed, using a car to get from one place to another, cooking a meal – our actions eventually cause a greater amount of disorder to be created as a consequence – as noise, pollution, waste heat or landfill refuse.

For example, if I spend a day building a shed, then to create that order and value from raw materials, I consume structured food and turn it into sewage. Or if I use an electric forklift to stack a pile of boxes, I use electricity that has been created by burning structured coal into smog and ash.

So it is literally impossible to create a “perfect world”. Whenever we act to make a part of the world more ordered, we create disorder elsewhere. And ultimately – thankfully, long after you and I are dead – disorder is all that will be left.

2. The failure of Logical Atomism: why the human world can’t be perfectly described using data and logic

In the 20th Century two of the most famous and accomplished philosophers in history, Bertrand Russell and Ludwig Wittgenstein, invented “Logical Atomism“, a theory that the entire world could be described by using “atomic facts” – independent and irreducible pieces of knowledge – combined with logic.

But despite 40 years of work, these two supremely intelligent people could not get their theory to work: “Logical Atomism” failed. It is not possible to describe our world in that way.

One cause of the failure was the insurmountable difficulty of identifying truly independent, irreducible atomic facts. “The box is red” and “the circle is blue”, for example, aren’t independent or irreducible facts for many reasons. “Red” and “blue” are two conventions of human language used to describe the perceptions created when electro-magnetic waves of different frequencies arrive at our retinas. In other words, they depend on and relate to each other through a number of sophisticated systems.

Despite centuries of scientific and philosophical effort, we do not have a complete understanding of how to describe our world at its most basic level. As physicists have explored the world at smaller and smaller scales, Quantum Mechanics has emerged as the most fundamental theory for describing it – it is the closest we have come to finding the “irreducible facts” that Russell and Wittgenstein were looking for. But whilst the mathematical equations of Quantum Mechanics predict the outcomes of experiments very well, after nearly a century, physicists still don’t really agree about what those equations mean. And as we have already seen, Heisenberg’s Uncertainty Principle prevents us from ever having perfect knowledge of the world at this level.

Perhaps the most important failure of logical atomism, though, was that it proved impossible to use logical rules to turn “facts” at one level of abstraction – for example, “blood cells carry oxygen”, “nerves conduct electricity”, “muscle fibres contract” – into facts at another level of abstraction – such as “physical assault is a crime”. The human world and the things that we care about can’t be described using logical combinations of “atomic facts”. For example, how would you define the set of all possible uses of a screwdriver, from prising the lids off paint tins to causing a short-circuit by jamming it into a switchboard?

Our world is messy, subjective and opportunistic. It defies universal categorisation and logical analysis.

(A Pescheria in Bari, Puglia, where a fish-market price information service makes it easier for local fisherman to identify the best buyers and prices for their daily catch. Photo by Vito Palmi)

3. The importance and inaccessibility of “local knowledge” 

Because the tool we use for calculating and agreeing value when we exchange goods and services is money, economics is the discipline that is often used to understand the large-scale behaviour of society. We often quantify the “growth” of society using economic measures, for example.

But this approach is notorious for overlooking social and environmental characteristics such as health, happiness and sustainability. Alternatives exist, such as the Social Progress Index, or the measurement framework adopted by the United Nations 2014 Human Development Report on world poverty; but they are still high level and abstract.

Such approaches struggle to explain localised variations, and in particular cannot predict the behaviours or outcomes of individual people with any accuracy. This “local knowledge problem” is caused by the fact that a great deal of the information that determines individual actions is personal and local, and not measurable at a distance – the experienced eye of the fruit buyer assessing not just the quality of the fruit but the quality of the farm and farmers that produce it, as a measure of the likely consistency of supply; the emotional attachments that cause us to favour one brand over another; or the degree of community ties between local businesses that influence their propensity to trade with each other.

Sharing economy” business models that use social media and reputation systems to enable suppliers and consumers of goods and services to find each other and transact online are opening up this local knowledge to some degree. Local food networks, freecycling networks, and land-sharing schemes all use this technology to the benefit of local communities whilst potentially making information about detailed transactions more widely available. And to some degree, the human knowledge that influences how transactions take place can be encoded in “expert systems” which allow computer systems to codify the quantitative and heuristic rules by which people take decisions.

But these technologies are only used in a subset of the interactions that take place between people and businesses across the world, and it is unlikely that they’ll become ubiquitous in the foreseeable future (or that we would want them to become so). Will we ever reach the point where prospective house-buyers delegate decisions about where to live to computer programmes operating in online marketplaces rather than by visiting places and imagining themselves living there? Will we somehow automate the process of testing the freshness of fish by observing the clarity of their eyes and the freshness of their smell before buying them to cook and eat?

In many cases, while technology may play a role introducing potential buyers and sellers of goods and services to each other, it will not replace – or predict – the human behaviours involved in the transaction itself.

(Medway Youth Trust use predictive and textual analytics to draw insight into their work helping vulnerable children. They use technology to inform expert case workers, not to take decisions on their behalf.)

4. “Wicked problems” cannot be described using data and logic

Despite all of the challenges associated with problems in mathematics and the physical sciences, it is nevertheless relatively straightforward to frame and then attempt to solve problems in those domains; and to determine whether the resulting solutions are valid.

As the failure of Logical Atomism showed, though, problems in the human domain are much more difficult to describe in any systematic, complete and precise way – a challenge known as the “frame problem” in artificial intelligence. This is particularly true of “wicked problems” – challenges such as social mobility or vulnerable families that are multi-faceted, and consist of a variety of interdependent issues.

Take job creation, for example. Is that best accomplished through creating employment in taxpayer-funded public sector organisations? Or by allowing private-sector wealth to grow, creating employment through “trickle-down” effects? Or by maximising overall consumer spending power as suggested by “middle-out” economics? All of these ideas are described not using the language of mathematics or other formal logical systems, but using natural human language which is subjective and inconsistent in use.

The failure of Logical Atomism to fully represent such concepts in formal logical systems through which truth and falsehood can be determined with certainty emphasises what we all understand intuitively: there is no single “right” answer to many human problems, and no single “right” action in many human situations.

(An electricity bill containing information provided by OPower comparing one household’s energy usage to their neighbours. Image from Grist)

5. Behavioural economics and the caprice of human behaviour

Behavioural economics” attempts to predict the way that humans behave when taking choices that have a measurable impact on them – for example, whether to put the washing machine on at 5pm when electricity is expensive, or at 11pm when it is cheap.

But predicting human behaviour is notoriously unreliable.

For example, in a smart water-meter project in Dubuque, Iowa, households that were told how their water conservation compared to that of their near neighbours were found to be twice as likely to take action to improve their efficiency as those who were only told the details of their own water use. In other words, people who were given quantified evidence that they were less responsible water user than their neighbours changed their behaviour. OPower have used similar techniques to help US households save 1.9 terawatt hours of power simply by including a report based on data from smart meters in a printed letter sent with customers’ electricity bills.

These are impressive achievements; but they are not always repeatable. A recycling scheme in the UK that adopted a similar approach found instead that it lowered recycling rates across the community: households who learned that they were putting more effort into recycling than their neighbours asked themselves “if my neighbours aren’t contributing to this initiative, then why should I?”

Low carbon engineering technologies like electric vehicles have clearly defined environmental benefits and clearly defined costs. But most Smart Cities solutions are less straightforward. They are complex socio-technical systems whose outcomes are emergent. Our ability to predict their performance and impact will certainly improve as more are deployed and analysed, and as University researchers, politicians, journalists and the public assess them. But we will never predict individual actions using these techniques, only the average statistical behaviour of groups of people. This can be seen from OPower’s own comparison of their predicted energy savings against those actually achieved – the predictions are good, but the actual behaviour of OPower’s customers shows a high degree of apparently random variation. Those variations are the result of the subjective, unpredictable and sometimes irrational behaviour of real people.

We can take insight from Behavioural Economics and other techniques for analysing human behaviour in order to create appropriate strategies, policies and environments that encourage the right outcomes in cities; but none of them can be relied on to give definitive solutions to any individual person or situation. They can inform decision-making, but are always associated with some degree of uncertainty. In some cases, the uncertainty will be so small as to be negligible, and the predictions can be treated as deterministic rules for achieving the desired outcome. But in many cases, the uncertainty will be so great that predictions can only be treated as general indications of what might happen; whilst individual actions and outcomes will vary greatly.

(Of course it is impossible to predict individual criminal actions as portrayed in the film “Minority Report”. But is is very possible to analyse past patterns of criminal activity, compare them to related data such as weather and social events, and predict the likelihood of crimes of certain types occurring in certain areas. Cities such as Memphis and Chicago have used these insights to achieve significant reductions in crime)

Learning to value insight without certainty

Mathematics and digital technology are incredibly powerful; but they will never perfectly and completely describe and predict our world in human terms. In many cases, our focus for using them should not be on automation: it should be on the enablement of human judgement through better availability and communication of information. And in particular, we should concentrate on communicating accurately the meaning of information in the context of its limitations and uncertainties.

There are exceptions where we automate systems because of a combination of a low-level of uncertainty in data and a large advantage in acting autonomously on it. For example, anti-lock braking systems save lives by using automated technology to take thousands of decisions more quickly than most humans would realise that even a single decision needed to be made; and do so based on data with an extremely low degree of uncertainty.

But the most exciting opportunity for us all is to learn to become sophisticated users of information that is uncertain. The results of textual analysis of sentiment towards products and brands expressed in social media are far from certain; but they are still of great value. Similar technology can extract insights from medical research papers, case notes in social care systems, maintenance logs of machinery and many other sources. Those insights will rarely be certain; but properly assessed by people with good judgement they can still be immensely valuable.

This is a much better way to understand the value of technology than ideas like “perfect knowledge” and “algorithmic regulation”. And it is much more likely that people will trust the benefits that we claim new technologies can bring if we are open about their limitations. People won’t use technologies that they don’t trust; and they won’t invest their money in them or vote for politicians who say they’ll spend their taxes on it.

Thankyou to Richard Brown and Adrian McEwen for discussions on Twitter that helped me to prepare this article. A more in-depth discussion of some of the scientific and philosophical issues I’ve described, and an exploration of the nature of human intelligence and its non-deterministic characteristics, can be found in the excellent paper “Answering Descartes: Beyond Turing” by Stuart Kauffman published by MIT press.

12 simple technologies for cities that are Smart, open and fair

(Fritz Lang’s 1927 dystopian film Metropolis pictured a city that exploited futuristic technologies, but only on behalf of a minority of its citizens. Image by Breve Storia del Cinema)

Efficiency; resilience; growth; vitality. These are all characteristics that cities desire, and that are regularly cited as the objectives of Smarter City programmes and other forward-looking initiatives.

But, though it is less frequently stated, a more fundamental objective underlies all of these: fairness.

The Nobel Prize-winning economist Joseph Stiglitz has written extensively about the need to prioritise fairness as a policy and investment objective in a world that in many areas – and in many cities – is becoming more unequal. That inequality is demonstrated by the difference in life expectancy of 20 years or so that exists between the poorest and richest parts of many UK cities.

I think the Smart Cities movement will only be viewed as a success by the wider world if it contributes to redressing that imbalance.

So how do we design Smart City systems that employ technology to make cities more successful, resilient and efficient; in a way that distributes resources and creates opportunities more fairly than today?

One answer to that question is that the infrastructures and institutions of such cities should be open to citizens and businesses: accessible, understandable, adaptable and useful.

Why do we need open cities?

In the wonderful “Walkable City“, Jeff Speck describe’s the epidemiologist Richard Jackson’s stark realisation of the life-and-death significance of good urban design. Jackson was driving along a notorious 2 mile stretch of Atlanta’s 7-lane Buford highway with no pavements or junctions:

There, by the side of the road, in the ninety-five degree afternoon, he saw a woman in her seventies, struggling under the burden of two shopping bags. He tried to relate her plight to his own work as an epidemiologist. “If that poor woman had collapsed from heat stroke, we docs would have written the cause of death as heat stroke and not lack of trees and public transportation, poor urban form, and heat-island effects. If she had been killed by a truck going by the cause of death would have been “motor vehicle trauma”, and not lack of sidewalks and transit, poor urban planning and failed political leadership.”

(Pedestrian’s attempting to cross Atlanta’s notorious Buford Highway; a 7-lane road with no pavements and 2 miles between junctions and crossings. Photo by PBS)

Buford Highway is an infrastructure fit only for vehicles, not for people. It allows no safe access along or across it for the communities it passes through – it is closed to them, unless they risk their lives.

At the same time that city leaders are realising more and more that better planning is needed to create more equal cities, so it  is imperative that the digital infrastructures we deploy in cities are accessible and useful to citizens, not as dangerous to them as Buford Highway.

Unfortunately, there are already examples of city infrastructures using technologies that are poorly designed, that fail to serve the needs of  communities, or that fail in operation.

For instance, a network of CCTV cameras in Birmingham were eventually dismantled after it was revealed they had been erected to gather evidence of terrorist activities in Birmingham’s Muslim communities, rather than in support of their safety. And there have been many examples of the failure of both public sector agencies and private companies to properly safeguard the data they hold about citizens.

Market failures can result in the benefits of technology being more accessible to wealthier communities than poorer communities. For example,  private sector network providers will not deploy connectivity in areas which are insufficiently economically active for them to make a profit, and Government funding is not yet sufficient to close the gap. And community lenders, who typically offer loans at one-tenth to one-hundredth the cost of payday lenders, have so far lacked the resources to invest in the online technology that makes some payday loans so easy to take out – though this is starting to change.

One of the technology industry’s most notorious failures, the Greyhound Lines bus company’s 1993 “Trips” reservations system, made a city service – bus transport – unusable. The system was intended to make it quicker and easier for ticket agents to book customers onto Greyhound’s buses. But it was so poorly designed and operated so slowly that passengers missed their buses whilst they stood in line waiting for their tickets; were separated from their luggage; and in some cases were stranded overnight in bus terminals.

In the 21st Century, badly applied digital technology will create bad cities, just as badly designed roads and buildings did in the last century.

(The SMS for Life project uses the cheap and widely used SMS infrastructure to create a dynamic, collaborative supply chain for medicines between pharmacies in Africa. Photo by Novartis AG)

Smart Cities for the digitally disconnected

It’s possible to benefit from Smart city infrastructures without being connected to the internet or having skills in digital technology – Stockholm’s road-use charging scheme reduces congestion and pollution for everyone in the city, for example.

But the benefits of many Smart systems are dependent on being connected to the internet and having the skills to use it. From the wealth of educational material now available online (from the most sophisticated Harvard University courses to the most basic tutorials on just about any subject available on YouTube), to the increasing role of technology in high-paid careers, it’s absolutely obvious that the ability to access and use the internet and digital technologies in the future will be a crucial component of a successful life.

Smart cities won’t be fair cities if we take connectivity and skills for granted. Worldwide, fully one-third of the population has never been online; and even in as rich and advanced a country as the United Kingdom, 18% of adults – a fifth of the voting population – have never used the internet. At the risk of generalising a complex issue, many of those people will be those that Smart City services should create benefits for if they are to contribute to making cities fairer.

After legal challenges from private sector providers, the UK Government’s plan to assist cities in funding the deployment of ubiquitous broadband connectivity has been replaced by a voucher scheme that subsidises businesses connecting to existing networks. The scheme will not now directly help to improve broadband coverage in those areas that are poorly served because they are economically relatively inactive – precisely the areas that need the most help.

There’s been a lot of discussion of “net neutrality” recently – the principle that on the Internet, all traffic is equal, and that there is no way to pay for certain data to be treated preferentially. The principle is intended to ensure that the benefits of the internet are equally available to everyone.

But net neutrality is irrelevant to those who can’t access the internet at all; and the free market is already bypassing it in some ways. Network providers who control the local infrastructures that connect homes and businesses to the internet are free to charge higher prices for faster connections. Wealthy corporations and governments can bypass parts of the internet entirely with their own international cable networks through which they can route traffic between users on one continent and content on another.

Governments in emerging economies are building new cities to house their rapidly urbanising populations with ubiquitous, high-speed connectivity from the start. The Australian government is investing the profits from selling raw materials to support that construction boom in providing broadband coverage across the entire country. The least wealthy areas of European cities will be further disadvantaged compared to them unless we can find ways to invest in their digital infrastructure without contravening the European Union’s “State aid” law.

Technology as if people mattered

The UK’s Government Digital Service employ an excellent set of agile, user-centric design principles that are intended to promote the development of Smarter, digitally-enabled services that can be accessed by anyone anywhere who needs them, regardless of their level of skill with digital technology or ability to access the Internet.

The principles include: “Start with needs”; “Do the hard work to make it simple”; “Build for inclusion”; “Understand context”; and “Build digital services, not websites”.

(An electricity bill containing information provided by OPower comparing one household’s energy usage to their neighbours. Image from Grist)

A good example of following these principles and designing excellent, accessible digital services using common sense is the London Borough of Newham. By concentrating on the delivery of services through mobile telephones – which are much more widely owned than PCs and laptops – and on contexts in which a friend or family member assists the ultimate service user, Newham have achieved a remarkable shift to online services in one of London’s least affluent boroughs, home to many communities and citizens without access to broadband connectivity or traditional computers.

Similar, low-tech innovations in designing systems that people find useful can be found in some smart meter deployments.

In principle, the analytic technology in smart meters can provide insights that helps households and businesses reduce energy usage – identifying appliances that are operating inefficiently, highlighting leaks, and comparing households’ energy usage to that of their neighbours.

But most people don’t want to look at smart meter displays or consult a computer before they put the washing on or have a shower.

In one innovative project in the village of Chale, these issues were overcome by connecting analytic technology to a glow globe in the lounge – the globe simply glows red, orange or green depending on whether too much energy is being used compared to that expected for the time of day and year. A similarly effective but even more down-to-earth approach was adopted by OPower in the US who reported that they have helped households save 1.9 terawatt hours of power simply by including a report based on data from smart meters in a printed letter sent with customers’ electricity bills.

There are countless other examples. During peak traffic periods, Dublin’s “Live Drive” radio station plays a mixture of 80s pop music and traffic information derived from sophisticated analytics developed by IBM’s Smarter Cities Research team based on data from road sensors and GPS beacons in the city’s buses. And in India’s rural Karnataka region, which lacks internet infrastructure and where many workers lack literacy skills, let alone access to computers and smartphones, the benefits of online job portals have been recreated using “spoken web” technology using the existing traditional analogue telephone network.

(The inspirational Kilimo Salama scheme that uses

(The inspirational Kilimo Salama scheme that uses “appropriate technology” to make crop insurance affordable to subsistence farmers. Photo by Burness Communications)

In Kenya, Kilimo Salama has made crop insurance affordable for subsistence farmers by using remote weather monitoring to trigger payouts via Safaricom’s M-Pesa mobile payments service, rather than undertaking expensive site visits to assess claims. And the SMS for Life project in Tanzania uses the cheap and widely used SMS infrastructure to create a dynamic, collaborative supply chain for medicine between rural pharmacists.

These are all examples of what was originally described as “Intermediate Technology” by the economist Ernst Friedrich “Fritz” Schumacher in his influential work, “Small is Beautiful: Economics as if People Mattered“, and is now known as Appropriate Technology.

12 “appropriate technologies” for Smart Cities

Schumacher’s views on technology were informed by his belief that our approach to economics should be transformed “as if people mattered”. He asked:

What happens if we create economics not on the basis of maximising the production of goods and the ability to acquire and consume them – which ends up valuing automation and profit – but on the Buddhist definition of the purpose of work: “to give a man a chance to utilise and develop his faculties; to enable him to overcome his ego-centredness by joining with other people in a common task; and to bring forth the goods and services needed for a becoming existence.”

Schumacher pointed out that the most advanced technologies, to which we often look to create value and growth, are in fact only effective in the hands of those with the resources and skills required to use them- i.e. those who are already wealthy; and that by emphasising efficiency, output and profit they tend to further concentrate economic value in the hands of the wealthy – often specifically by reducing the employment of people with less advanced skills and roles.

In contrast, Schumacher felt that the most genuine “development ” of our society would occur when the most possible people were employed in a way that gave them the practical ability to earn a living ; and that also offered a level of human reward – much as Maslow’s “Hierarchy of Needs” first identifies our most basic requirements for food, water, shelter and security; but next relates the importance of family, friends and “self-actualisation” (which can crudely be described as the process of achieving things that we care about).

This led him to ask:

What is that we really require from the scientists and technologists? I should answer:

We need methods and equipment which are:

    • Cheap enough so that they are accessible to virtually everyone;
    • Suitable for small-scale application; and
    • Compatible with man’s need for creativity

(Maslow’s Hierarchy of Needs, image by Factoryjoe via Wikimedia Commons)

I can’t think of a more powerful set of tools that reflect these characteristics than the digital technologies that have emerged over the past decade, such as social media, smartphones, Cloud computing and Open Data. They provide a digital infrastructure of appropriate technologies that are accessible to everyone, but that connect with the large scale city infrastructures that support millions of urban lives; and they give citizens, communities and businesses the ability to adapt city infrastructures to their own needs.

I can think of at least 12 such technologies that are particularly important; and that fall into the categories of “Infrastructures that matter”; “Technologies for everyone”; and “The keys to the city”.

Infrastructures that matter

1.Broadband connectivity

I’ve covered the importance of broadband connectivity, and the challenges involved in providing it ubiquitously, already, so I won’t go into detail again here. But whether it’s fixed-line, mobile or wi-fi, its benefits are becoming so significant that it can’t be omitted.

2. Cloud computing

Before Cloud computing, anyone who wanted to develop a computing system for others to use had to invest up-front in an infrastructure capable of operating the service to a reasonable level of reliability. Cloud computing provides a much easier, cheaper alternative: rent a little bit of someone else’s infrastructure. And if your service becomes popular, don’t worry about carrying out complex and costly upgrades, just rent a little more.

Cloud computing has helped to democratise digital services by making it  it dramatically easier and cheaper for anyone to create and offer them.

Technologies for everyone

3. Mobile and Smart phones

In 2013, the number of cellphone subscriptions worldwide surpassed the number of people who have ever owned fixed line telephones.

In the developed world, we’re conscious of the increasing power of Smartphones; and Councils such as Newham are exploiting the fact that many people who lack the desire or resources to purchase a computer and a broadband connection possess and use relatively sophisticated Smartphones through which they access digital services and content.

But in some countries in the developing world, the real story is simply the availability of the first basic infrastructure – voice calls and SMS – that’s available to almost everyone, everywhere. According to one report, access to a basic mobile phone is more common than access to a toilet with proper drainage. In his TEDGlobal 2013 talk, Toby Shapshak described how entire business infrastructures and supply chains are being built upon SMS and similiarly “appropriate” technologies – to the extent that 4o% of Kenya’s GDP now passes through the M-Pesa mobile payments service offered by Safaricom. Banks, technology entrepreneurs, governments and others in the developed world are looking to this wave of innovation as a source of new ideas.

4. Social media

In his 2011 book “Civilization“, Niall Fergusson comments that news of the Indian Mutiny in 1857 took 46 days to reach London, travelling in effect at 3.8 miles an hour. By Jan 2009 when US Airways flight 1549 crash landed in the Hudson river, Jim Hanrahan’s message on Twitter communicated the news to the entire world four minutes later; it reached Perth, Australia at more than 170,000 miles an hour.

Social media is the tool that around a quarter of the world’s population now simply uses to stay in touch with friends and family at this incredible speed.

At a recent Mayoral debate on Smarter Cities, Ridwan Kamil, Mayor of Bandung, Indonesia, described how he has nurtured an atmosphere of civic engagement, trust and transparency by encouraging his staff to connect with the city’s 2.3 million Twitter-using citizens through social media. By encouraging citizens to report issues online and by publishing details of city spending, Mayor Kami has helped to combat corruption and improve public services. Montpellier in France is engaging with citizens through social media in a similar way, asking them to explore data about their city and suggest ways to improve it. And the ambitious control room set up in Rio de Janeiro by Mayor Eduardo Paes to help manage the city during the current World Cup uses social media not just as one of the information feeds that provides insight into what is happening in the city, but to keep citizens as well informed as possible.

The “Community Lovers Guide“, of which 60 editions have now been published across the world, contains stories of people and projects that have improved their communities. The guide is not concerned directly with technology; but many of the initiatives that it describes have used social media as a tool for engaging with stakeholders and supporters.

And we increasingly use social media to conduct business. From e-Bay to Uber, social media is being used to create “sharing economy” business models that replace traditional sales channels and supply chains with networks of peer-to-peer transactions in industries from financial services to agriculture to distribution to retail. Nearly 2 billion of us now regularly use the technologies that allow us to participate in those trading networks.

5. The touchscreen

Three years ago, I watched my then 2-year-old son teach himself how to use a touchscreen tablet to watch cartoons from around the world. He is a member of the first generation to grow up with the world’s information literally at their fingertips before they can read and write.

The simplicity of the touchscreen has already led to the adoption of tablet computers by huge numbers of people who would never have so willingly chosen to use a laptop computer and keyboard. As touchscreens and the devices that use them become cheaper and cheaper, many more people who currently don’t choose to access online content and services will do so without realising it, simply by interacting with the world around them.

We will rapidly develop even more intimate interfaces to technology. Three years ago, scientists at the University of Berkely used computers attached to an MRI scanner to recreate moving images from the magnetic field created by the brain of a person inside the scanner watching a film on a pair of goggles. And last year, scientists at the University of Washington used similar technology to allow one of them to move the other’s arm simply by thinking about it. Whilst it will take time for these technologies to become widely available – and there are certainly ethical issues concerning their use that must be addressed in the process – eventually they will make an important contribution to making information and the ability to communicate widely even more accessible than today.

6. Open Source software

Open Source software is one of the very few technologies that is free in principle to anyone with the time to understand how to use it. It is not free in the medium or long-term – most organisations that use it pay for some form of support or maintenance to be carried out on their Open Source systems. But it is free to get started, and the Open Source community is a great place to get help and advice whilst doing so.

My colleagues around the world work very hard to ensure that IBM’s technologies support open source technology, from interoperating with the MySQL database and CKAN open data portal; to donating IBM-developed technologies such as Eclipse, MQTT and Node-RED to the Open Source community; to IBM’s new “BlueMix” Cloud computing platform for developers which is built from Open Source technology and offers developers 50 pre-built services for inclusion in their Apps, many of which are open source.

Not all technology is Open Source, and there are good reasons why many technology companies large and small invest in developing products and services for cities that use proprietary software – often, simply to protect their investment. For as long as those products and services offer valuable capabilities that are not available as open source software, cities will use them.

But it is vital that city systems incorporating those technologies are nevertheless open for use by open source software, simply to make them as widely accessible as possible for people who need to adapt them to their own needs.

7. Intelligent hardware

The emergence of the internet as a platform for enabling sales, marketing and logistics over the last decade has enabled small and micro-businesses to reach markets across the world that were previously accessible only to much larger organisations with international sales and distribution networks.

More recently, the emergence and maturation of technologies such as 3D printingopen-source manufacturing and small-scale energy generation are enabling small businesses and community initiatives to succeed in new sectors by reducing the scale at which it is economically viable to carry out what were previously industrial activities – a trend recently labelled by the Economist magazine as the “Third Industrial Revolution“.

Arduino, an Open Source electronics prototyping platform, and the Raspberry Pi, a cheap and simple computer intended to simplify the process of teaching programming skills, provide very easy introductions to these technologies; and organisations such as Hub Launchpad and TechShop make it possible for entrepreneurs and small businesses to explore them in more depth.

The keys to the city

8. Open APIs 

An “API” is an “Application Programming Interface“: it is a tool that allows one computer system – such as an Open Source “app” written by an entrepreneur or social innovator – to use the information and capabilities of another computer system – such as a traffic information system for a city’s transport network.

For example, Amazon make an API available to developers that exposes all of the capabilities of Amazon Marketplace – from listing products, to changing prices to despatching goods to customers. Whilst these features are not free to use, they offer one way for businesses to create new online shops extremely quickly,  linked to a fulfilment operation to support them.

Open APIs are a tool that can make digital city infrastructures open to local innovation, and allow citizens, businesses and communities to adapt them to their own needs. For instance, Birmingham’s Droplet, a SmartPhone payment service that encourages local economic growth by making it easy to pay for goods and services from local merchants, offer a developer API to allow their fast, cheap payments system to be included in other city services.

A Smarter City infrastructure whose IT systems offer APIs to citizens, communities and businesses can be accessed and adapted by them. It is the very opposite of Atlanta’s Buford Highway.

(The UK’s Open Data Institute’s 2013 Summit. The ODI promotes open data in the UK and shares best practise internationally. Photo by the ODI)

9. Open Data

The Open Data movement champions the principle that any non-sensitive data from public services and infrastructures should be freely and openly available. Most such data is not currently available in this form – either because the organisations operating those services have yet to adopt the principle, or because the computer systems they use simply were not designed to make data available.

There are many reasons to support the idea of Open Data. McKinsey estimate its economic value to be at least $3 trillion per year, for example.

But perhaps more importantly, Open Data is a fundamental tool for democracy and transparency in a digital age. Niall Firth’s November 2013 editorial for the New Scientist magazine describes how citizens of developing nations are using open data to hold their governments to account, from basic information about election candidates to the monitoring of government spending.

The “Dublinked” information sharing partnership, in which Dublin City Council, three surrounding local authorities and  service providers to the city share information and make it available to their communities as “open data”, is a good example of the benefits that openness can bring. Dublinked now makes 3,000 datasets available to local authority analysts; to researchers from IBM Research and the National University of Ireland; and to businesses, entrepreneurs and citizens. The partnership is identifying new ways for the city’s public services and transport, energy and water systems to work; and enabling the formation of new, information-based businesses with the potential to export the solutions they develop in Dublin to cities internationally. It is putting the power of technology and of city information not only at the disposal of the city authority and its agencies, but also into the hands of communities and innovators.

10. Open Standards

Open Data and Open APIs will only be widely used and effective in cities across the world if they conform to Open Standards that mean that everyone, everywhere can use them in the same way.

In order to do something as simple as changing a lightbulb, we rely on open standards for the levels of voltage and power from our electricity supply; the physical dimensions of the socket and bulb and the characteristics of their fastenings; specifications of the bulb’s light and heat output; and the tolerance of the bulb and the fitting for the levels of moisture found in bathrooms and kitchens. Cities are much more complicated than lightbulbs; and many more standards will be required on order for us to connect to and re-configure their systems easily and reliably.

Open standards are also an important tool in avoiding city systems becoming “locked-in” to any particular supplier. By specifying common characteristics that all systems are required to demonstrate, it becomes more straightforward to exchange one supplier’s implementation for another.

Some standards that Smarter City infrastructures can use are already in place – for example, Web services and REST that specify the general ways in which computer systems interact, and the Common Alerting Protocol which is more specific to interactions between systems that monitor and control the physical world. But many others will need to be invented and encouraged to spread. The City Protocol Society is one organisation seeking to develop those new standards; and the British Standards Institute recently published the first set of national standards for Smarter Cities in the UK, including a standard for the interoperability of data between Smart City systems.

(Photo of the Brixton Pound by Charlie Waterhouse)

11. Local and virtual currencies and trading systems

Local trading systems use paper or electronic currencies that are issued and accepted within a particular place or region. They influence people and businesses to spend the money that they earn locally, thereby promoting regional economic synergies.

Examples include the Bristol Pound; the Droplet smartphone payment scheme in Birmingham; and schemes based on the bartering of goods, money, time and services, such as time banking. Some schemes combine both elements – in Switzerland, a complementary currency, the Wir , has contributed to economic stability over the last century by allowing some debt repayments to be bartered locally when they cannot be repaid in universal currency.

As these schemes develop – and in particular as they adopt technologies such as smartphones and Open APIs – they are increasingly being used as an infrastructure for Smarter City projects in domains such as transport, food supply and energy.

Smarter Cities will succeed at scale when we discover the business models that convert financial payments and investments into social, economic and environmental improvements in the places where we live and work. I can’t think of a more directly applicable tool for designing those business models than flexible, locally focussed currencies and payment infrastructures.

12. Identity stores

In order to use digital services, we have to provide personal information online. What happens to that personal information once we have finished using the service?

Social networks such as Facebook regularly cause controversy when they experiment with new ways to use the data that we freely share with them; often granting them extensive rights over that data in the process.

Our use of technologies such as social media, Smartphones and APIs creates a mass of data about us that is often retained by the operators of the services we use. Sometimes this is as a result of deliberate actions:  when we share geo-tagged photos through social media, for example. In other cases, it is incidental. The location and movement of GPS sensors in our smartphones is anonymised by our network providers and aggregated with that of others nearby who are moving similarly. It is then sold to traffic information services, so that they can sell it back to us through the satellite navigation systems in our cars to help us to avoid traffic congestion.

Organisations of all types and sizes are competing for the new markets and opportunities of the information economy that are created, in part, by this increased availability of personal information. That is simply the natural consequence of the emergence of a new resource in a competitive economy. But it is also true that as the originators of much of that information, and as the ultimate stakeholders in that economy, we should seek to establish an equitable consensus between us for how our information is used.

A different approach is being taken by organisations such as MyDex. MyDex are a Community Interest Company (CIC) who have created a platform that allows users to securely share personal information with digital service providers when they need to; but to revoke access when they have finished using the service.

Incorporation as a Community Interest Company allows MyDex:

“… to be sustainable and requires it be run for community benefit. Crucially, the CIC assets and the majority of any profits must be used for the community purposes for which Mydex is established. Its assets cannot be acquired by another party to which such restrictions do not apply.”

(From the MyDex website, http://mydex.org/about/ensuring-trust/).

As a result of both the security of their technology solution and the clarity with which personal and community interests are reflected in their business model, MyDex’s platform is now being used by a variety of public sector and community organisations to offer a personal data store to the people they support.

MyDex’s approach to creating trust in the use of personal data is not the only one, but it is a good example of a business model that explicitly addresses and prioritises the interests of the individual.

(The town plan for Edinburgh’s New Town, clearly showing the grid structure that gives rise to the adaptability that it is famous for showing for the past 250 years. Image from the JR James archive)

Smart Digital Urbanism

Architects and city planners such as Kelvin Campbell, founder of the Smart Urbanism movement and Jan Gehl, who inspired the “human-scale cities” movement have been identifying the fine-grained physical characteristics of large-scale urban environments that encourage vibrant communities and successful economies through the daily activities of people, families, communities and businesses.

A good example is provided by Edinburgh’s “New Town”, regarded as a masterpiece of urban planning that has proved adaptable and successful through the economic and social changes of the past 250 years. It has frequent road crossings, junctions and side-streets that slow down traffic; provides stopping opportunities for traffic and crossing opportunities for people, encouraging businesses to thrive; and has a mixture of small and large premises for a variety of businesses to occupy.

Smarter cities will not be fairer cities unless we identify and employ technologies for building them that create similar openness and accessibility for digital services and information. That’s precisely what I think Open Data, mobile phones, virtual currencies and the other technologies I’ve described in this article can achieve.

I can’t think of a more exciting idea than using them to address the economic, social and environmental challenge of our time and to build better cities and communities for tomorrow.

What’s the risk of investing in a Smarter City?

(The two towers of the Bosco Verticale in Milan will be home to more than 10,000 plants that create shade and improve air quality. But to what degree do such characteristics make buildings more attractive to potential tenants than traditional structures, creating the potential to create financial returns to reward more widespread investment in this approach? Photo by Marco Trovo)

(Or “how to buy a Smarter City that won’t go bump in the night”)

There are good reasons why the current condition and future outlook of the world’s cities have been the subject of great debate in recent years. Their population will double from 3 billion to 6 billion by 2050; and while those in the developing world are growing at such a rate that they are challenging our ability to construct resilient, efficient infrastructure, those in developed countries often have significant levels of inequality and areas of persistent poverty and social immobility.

Many people involved in the debate are convinced that new approaches are needed to transport, food supply, economic development, water and energy management, social and healthcare, public safety and all of the other services and infrastructures that support cities.

As a consequence, analysts such as Frost & Sullivan have estimated that the market for “Smart City” solutions that exploit technology to address these issues will be $1.5trillion by 2020.

But anyone who has tried to secure investment in an initiative to apply “smart” technology in a city knows that it is not always easy to turn that theoretical market value into actual investment in projects, technology, infrastructure and expertise.

It’s not difficult to see why this is the case. Most investments are made in order to generate a financial return, but profit is not the objective of “Smart Cities” initiatives: they are intended to create economic, environmental or social outcomes. So some mechanism – an investment vehicle, a government regulation or a business model – is needed to create an incentive to invest in achieving those outcomes.

Institutions, Business, Infrastructure and Investment

Citizens expect national and local governments to use their tax revenues to deliver these objectives, of course. But they are also very concerned that the taxes they pay are spent wisely on programmes with transparent, predictable, deliverable outcomes, as the current controversy over the UK’s proposed “HS2” high speed train network and previous controversies over the effectiveness of public sector IT programmes show.

Nevertheless, the past year has seen a growing trend for cities in Europe and North America to invest in Smart Cities technologies from their own operational budgets, on the basis of their ability to deliver cost savings or improvements in outcomes.

For example, some cities are replacing traditional parking management and enforcement services with “smart parking” schemes that are reducing congestion and pollution whilst paying for themselves through increased enforcement revenues. Others are investing their allocation of central government infrastructure funds in Smart solutions – such as Cambridge, Ontario’s use of the Canadian government’s Gas Tax Fund to invest in a sensor network and analytics infrastructure to manage the city’s physical assets intelligently.

The providers of Smart Cities solutions are investing too, by implementing their services on Cloud computing platforms so that cities can pay incrementally for their use of them, rather than investing up-front in their deployment. Minneapolis, Minnesota and Montpelier, France, recently announced that they are using IBM’s Cloud-based solutions for smarter water, transport and emergency management in this way. And entrepreneurial businesses, backed by Venture Capital investment, are also investing in the development of new solutions.

However, we have not yet tapped the largest potential investment streams: property and large-scale infrastructure. The British Property Federation, for example, estimates that £14 billion is invested in the development of new property in the UK each year. For the main part, these investment streams are not currently investing  in “Smart City” solutions.

To understand why that is the case – and how we might change it – we need to understand the difference in three types of risk involved in investing in smart infrastructures compared with traditional infrastructures: construction risk; the impact of operational failures; and confidence in outcomes.

(A cyclist’s protest in 2012 about the disruption caused in Edinburgh by the overrunning construction of the city’s new tram system. Photo by Andy A)

Construction Risk

At a discussion in March of the financing of future city initiatives held within the Lord Mayor of the City of London’s “Tommorrow’s Cities” programme, Daniel Wong, Head of Infrastructure and Real Estate for Macquarie Capital Europe, said that only a “tiny fraction” – a few percent – of the investable resources of the pension and sovereign wealth funds often referred to as the “wall of money” seeking profitable long-term investment opportunities in infrastructure were available to invest in infrastructure projects that carry “construction risk” – the risk of financial loss or cost overruns during construction.

For conventional infrastructure, construction risk is relatively well understood. At the Tomorrow’s Cities event, Jason Robinson, Bechtel’s General Manager for Urban Development, said that the construction sector was well able to manage that risk on behalf of investors. There are exceptions – such as the delays, cost increases and reduction in scale of Edinburgh’s new tram system – but they are rare.

So are we similarly well placed to manage the additional “construction risk” created when we add new technology to infrastructure projects?

Unfortunately, research carried out in 2013 by the Standish Group on behalf of Computerworld suggests not. Standish Group used data describing 3,555 IT projects between 2003 and 2012 that had labour costs of at least $10 million, and found that only 6.4% were wholly successful. 52% were delivered, but cost more than expected, took longer than expected, or failed to deliver everything that was expected of them. The rest – 41.4% – either failed completely or had to be stopped and re-started from scratch. Anecdotally, we are familiar with the press coverage of high profile examples of IT projects that do not succeed.

We should not be surprised that it is so challenging to deliver IT projects. They are almost always driven by requirements that represent an aspiration to change the way that an organisation or system works: such requirements are inevitably uncertain and often change as projects proceed. In today’s interconnected world, many IT projects involve the integration of several existing IT systems operated by different organisations: most of those systems will not have been designed to support integration. And because technology changes so quickly, many projects use technologies that are new to the teams delivering them. All of these things will usually be true for the technology solutions required for Smart City projects.

By analogy, then, an IT project often feels like an exercise in building an ambitiously new style of building, using new materials whose weight, strength and stiffness isn’t wholly certain, and standing on a mixture of sand, gravel and wetland. It is not surprising that only 6.4% deliver everything they intend to, on time and on budget – though it is also disappointing that as many as 41.4% fail so completely.

However, the real insight is that the characteristics of uncertainty, risk, timescales and governance for IT projects are very different from construction and infrastructure projects. All of these issues can be managed; but they are managed in very different ways. Consequently, it will take time and experience for the cultures of IT and construction to reconcile their approaches to risk and project management, and consequently to present a confident joint approach to investors.

The implementation of Smart Cities IT solutions on Cloud Computing platforms  by their providers mitigates this risk to an extent by “pre-fabricating” these components of smart infrastructure. But there is still risk associated with the integration of these solutions with physical infrastructure and engineering systems. As we gain further experience of carrying out that integration, IT vendors, investors, construction companies and their customers will collectively increase their confidence in managing this risk, unlocking investment at greater scale.

(The unfortunate consequence of a driver who put more trust in their satellite navigation and GPS technology than its designers expected. Photo by Salmon Assessors)

Operational Risk

We are all familiar with IT systems failing.

Our laptops, notebooks and tablets crash, and we lose work as a consequence. Our television set-top boxes reboot themselves midway through recording programmes. Websites become unresponsive or lose data from our shopping carts.

But when failures occur in IT systems that monitor and control physical systems such as cars, trains and traffic lights, the consequences could be severe: damage to property, injury; and death. Organisations that invest in and operate infrastructure are conscious of these risks, and balance them against the potential benefits of new technologies when deciding whether to use them.

The real-world risks of technology failure are already becoming more severe as all of us adopt consumer technologies such as smartphones and social media into every aspect of our lives (as the driver who followed his satellite navigation system off the roads of Paris onto the pavement, and then all the way down the steps into the Paris Metro, discovered).

The noted urbanist Jane Jacobs defined cities by their ability to provide privacy and safety amongst citizens who are usually strangers to each other; and her thinking is still regarded today by many urbanists as the basis of our understanding of cities. As digital technology becomes more pervasive in city systems, it is vital that we evolve the policies that govern digital privacy to ensure that those systems continue to support our lives, communities and businesses successfully.

Google’s careful exploration of self-driving cars in partnership with driver licensing organisations is an example of that process working well; the discovery of a suspected 3D-printing gun factory in Manchester last year is an example of it working poorly.

These issues are already affecting the technologies involved in Smart Cities solutions. An Argentinian researcher recently demonstrated that traffic sensors used around the world could be hacked into and caused to create misleading information. At the time of installation it was assumed that there would never be a motivation to hack into them and so they were configured with insufficient security. We will have to ensure that future deployments are much more secure.

Conversely, we routinely trust automated technology in many aspects of our lives – the automatic pilots that land the planes we fly in, and the anit-lock braking systems that slow and stop our cars far more effectively than we are able to ourselves.

If we are to build the same level of trust and confidence in Smart City solutions, we need to be open and honest about their risks as well as their benefits; and clear how we are addressing them.

(Cars from the car club “car2go” ready to hire in Vancouver. Despite succeeding in many cities around the world, the business recently withdrew from the UK after failing to attract sufficient customers to two pilot deployments in London and Birmingham. The UK’s cultural attraction of private car ownership has proved too strong at present for a shared ownership business model to succeed. Photo by Stephen Rees).

Outcomes Risk

Smart infrastructures such as Stockholm’s road-use charging scheme and London’s congestion charge were constructed in the knowledge that they would be financially sustainable, and with the belief that they would create economic and environmental benefits. Subsequent studies have shown that they did achieve those benefits, but data to predict them confidently in advance did not exist because they were amongst the first of their kind in the world.

The benefits of “Smart” schemes such as road-use charging and smart metering cannot be calculated deterministically in advance because they depend on citizens changing their behaviour – deciding to ride a bus rather than to drive a car; or deciding to use dishwashers and washing machines overnight rather than during the day.

There are many examples of Smart Cities projects that have successfully used technology to encourage behaviour change. In a smart water meter project in Dubuque, for example, households were given information that told them whether their domestic appliances were being used efficiently, and alerted to any leaks in their supply of water. To a certain extent, households acted on this information to improve the efficiency of their water usage. But a control group who were also given a “green points” score telling them how their water conservation compared to that of their near neighbours were found to be twice as likely to take action to improve their efficiency.

However, these techniques are notoriously difficult to apply successfully. A recycling scheme that adopted a similar approach found instead that it lowered recycling rates across the community: households who learned that they were putting more effort into recycling than their neighbours asked themselves “if my neighbours aren’t contributing to this initiative, then why should I?”

The financial vehicles that enable investment in infrastructure and property are either government-backed instruments that reward economic and social outcomes such as reductions in carbon footprint or the creation of jobs ; or market-based instruments  based on the creation of direct financial returns.

So are we able to predict those outcomes confidently enough to enable investment in Smart Cities solutions?

I put that question to the debating panel at the Tomorrow’s Cities meeting. In particular, I asked whether investors would be willing to purchase bonds in smart metering infrastructures with a rate of return dependent on the success of those infrastructures in encouraging consumers to  reduce their use of water and energy.

The response was a clear “no”. The application of those technologies and their effectiveness in reducing the use of water and electricity by families and businesses is too uncertain for such investment vehicles to be used.

Smart Cities solutions are not straightforward engineering solutions such as electric vehicles whose cost, efficiency and environmental impacts can be calculated in a deterministic way. They are complex socio-technical systems whose outcomes are emergent and uncertain.

Our ability to predict their performance and impact will certainly improve as more are deployed and analysed, and as University researchers, politicians, journalists and the public assess them. As that happens, investors will be more willing to fund them; or, with government support, to create new financial vehicles that reward investment in initiatives that use smart technology to create social, environmental and economic improvements – just as the World Bank’s Green Bonds, launched in 2008, support environmental schemes today.

(Recycling bins in Curitiba, Brazil. As Mayor of Curitaba Jaime Lerner started one of the world’s earliest and most effective city recycling programmes by harnessing the enthusiasm of children to influence the behaviour of their parents. Lerner’s many initiatives to transform Curitaba have the characteristic of entrepreneurial leadership. Photo by Ana Elisa Ribeiro)

Evidence and Leadership

The evidence base need to support new investment vehicles is already being created. In Canada, for example, a collaboration between Canadian insurers and cities has developed a set of tools to create a common understanding of the financial risk created by the effects of climate change on the resilience of city infrastructures.

More internationally, the “Little Rock Accord” between the Madrid Club of former national Presidents and Prime Ministers and the P80 group of pension funds agreed to create a task force to increase the degree to which pension and sovereign wealth funds invest in the deployment of technology to address climate change issues, shortages in resources such as energy, water and food, and sustainable, resilient growth. My colleague the economist Mary Keeling has been working for IBM’s Institute for Business Value to more clearly analyse and express the benefits of Smart approaches – in water management and transportation, for example. And Peter Head’s Ecological Sequestration Trust and Robert Bishop’s International Centre for Earth Simulation are both pooling international data and expertise to create models that explore how more sustainable cities and societies might work.

But the Smart City programmes which courageously drive the field forward will not always be those that demand a complete and detailed cost/benefit analysis in advance. Writing in “The Plundered Planet”, the economist Paul Collier asserts that any proposed infrastructure of reasonable novelty and significant scale is effectively so unique – especially when considered in its geographic, political, social and economic context – that an accurate cost/benefit case simply cannot be constructed.

Instead, initiatives such as London’s congestion charge and bicycle hire scheme, Sunderland’s City Cloud and Bogota’s bikeways and parks were created by courageous leaders with a passionate belief that they could make their cities better. As more of those leaders come to trust technology and the people who deliver it, their passion will be another force behind the adoption of technology in city systems and infrastructure.

What’s the risk of not investing in a Smarter City?

For at least the last 50 years, we have been observing that life is speeding up and becoming more complicated. In his 1964 work “Notes on the Synthesis of Form“, the town planner Christopher Alexander wrote:

“At the same time that the problems increase in quantity, complexity and difficulty, they also change faster than ever before. New materials are developed all the time, social patterns alter quickly, the culture itself is changing faster than it has ever changed before … To match the growing complexity of problems, there is a growing body of information and specialist experience … [but] not only is the quantity of information itself beyond the reach of single designers, but the various specialists who retail it are narrow and unfamiliar with the form-makers’ peculiar problems.”

(Alexander’s 1977 work “A Pattern Language: Towns, Buildings, Construction” is one of the most widely read books on urban design; it was also an enormous influence on the development of the computer software industry).

The physicist Geoffrey West has shown that this process is alive and well in cities today. As the world’s cities grow, life in them speeds up, and they create ideas and wealth more rapidly, leading to further growth. West has observed that, in a world with constrained resources, this process will lead to a catastrophic failure when demand for fresh water, food and energy outstrips supply – unless we change that process, and change the way that we consume resources in order to create rewarding lives for ourselves.

There are two sides to that challenge: changing what we value; and changing how we create what we value from the resources around us.

(...)

(“Makers” at the Old Print Works in Balsall Heath, Birmingham, sharing the tools, skills, contacts and ideas that create successful small businesses in local communities)

The Transition movement, started by Rob Hopkins in Totnes in 2006, is tackling both parts of that challenge. “Transition Towns” are communities who have decided to act collectively to transition to a way of life which is less resource-intensive, and to value the characteristics of such lifestyles in their own right – where possible trading regionally, recycling and re-using materials and producing and consuming food locally.

The movement does not advocate isolation from the global industrial economy, but it does advocate that local, alternative products and services in some cases can be more sustainable than mass-produced commodities; that the process of producing them can be its own reward; and that acting at community level is for many people the most effective way to contribute to sustainability. From local currencies, to food-trading networks to community energy schemes, many “Smart” initiatives have emerged from the transition movement.

We will need the ideas and philosophy of Transition to create sustainable cities and communities – and without them we will fail. But those ideas alone will not create a sustainable world. With current technologies, for example, one hectare of highly fertile, intensively farmed land can feed 10 people. Birmingham, my home city, has an area of 60,000 hectares of relatively infertile land, most of which is not available for farming at all; and a population of around 1 million. Those numbers don’t add up to food self-sufficiency. And Birmingham is a very low-density city – between one-half and one-tenth as dense as the growing megacities of Asia and South America.

Cities depend on vast infrastructures and supply-chains, and they create complex networks of transactions supported by transportation and communications. Community initiatives will adapt these infrastructures to create local value in more sustainable, resilient ways, and by doing so will reduce demand. But they will not affect the underlying efficiency of the systems themselves. And I do not personally believe that in a world of 7 billion people in which resources and opportunity are distributed extremely unevenly that community initiatives alone will reduce demand significantly enough to achieve sustainability.

We cannot simply scale these systems up as the world’s population grows to 9 billion by 2050, we need to change the way they work. That means changing the technology they use, or changing the way they use technology. We need to make them smarter.

Six ways to design humanity and localism into Smart Cities

(Birmingham’s Social Media Cafe, where individuals from every part of the city share their experience using social media to promote their businesses and community initiatives. Photograph by Meshed Media)

The Smart Cities movement is sometimes criticised for appearing to focus mainly on the application of technology to large-scale city infrastructures such as smart energy grids and intelligent transportation.

It’s certainly vital that we manage and operate city services and infrastructure as intelligently as possible – there’s no other way to deal with the rapid urbanisation taking place in emerging economies; or the increasing demand for services such as health and social care in the developed world whilst city budgets are shrinking dramatically; and the need for improved resilience in the face of climate change everywhere.

But to focus too much on this aspect of Smart Cities and to overlook the social needs of cities and communities risks forgetting what the full purpose of cities is: to enable a huge number of individual citizens to live not just safe, but rewarding lives with their families.

Maslow’s Hierarchy of Needs identifies our most basic requirements to be food, water, shelter and security. The purpose of many city infrastructures is to answer those needs, either directly (buildings, utility infrastructures and food supply chains) or indirectly (the transport systems that support us and the businesses that we work for).

Important as those needs are, though – particularly to the billions of people in the world for whom they are not reliably met – life would be dull and unrewarding if they were all that we aspired to.

Maslow’s hierarchy next relates the importance of family, friends and “self-actualisation” (which can crudely be described as the process of achieving things that we care about). These are the more elusive qualities that it’s harder to design cities to provide. But unless cities provide them, they will not be successful. At best they will be dull, unrewarding places to live and work, and will see their populations fall as those can migrate elsewhere. At worst, they will create poverty, poor health and ultimately short, unrewarding lives.

A Smart City should not only be efficient, resilient and sustainable; it should improve all of these qualities of life for its citizens.

So how do we design and engineer them to do that?

(Maslow’s Hierarchy of Needs, image by Factoryjoe via Wikimedia Commons)

Tales of the Smart City

Stories about the people whose lives and businesses have been made better by technology tell us how we might answer that question.

In the Community Lover’s Guide to Birmingham, for example, Nick Booth describes the way his volunteer-led social media surgeries helped the Central Birmingham Neighbourhood Forum, Brandwood End Cemetery and Jubilee Debt Campaign to benefit from technology.

Another Birmingham initiative, the Northfield Ecocentre, crowdfunded £10,000 to support their “Urban Harvest” project. The funds helped the Ecocentre pick unwanted fruit from trees in domestic gardens in Birmingham and distribute it between volunteers, children’s centres, food bank customers and organisations promoting healthy eating; and to make some of it into jams, pickles and chutneys to raise money so that in future years the initiative can become self-sustaining.

In the village of Chale on the Isle of Wight, a community not served by the national gas power network and with significant levels of fuel poverty, my colleague Andy Stanford-Clark has helped an initiative not only to deploy smart meters to measure the energy use of each household; but to co-design with residents how they will use that technology, so that the whole community feels a sense of ownership and inclusion in the initiative. The project has resulted in a significant drop in rent arrears as residents use the technology to reduce their utility bills, in some cases by up to 50 percent. Less obviously, the sense of shared purpose has extended to the creation of a communal allotment area in the village and a successful compaign to halve bus fares in the area.

There are countless other examples. Play Fitness “gamify” exercise to persuade children to get fit, and work very hard to ensure that their products are accessible to children in communities of any level of wealth.  Casserole Club use social media to introduce people who can’t cook for themselves to people who are prepared to volunteer to cook for others. The West Midlands Collaborative Commerce Marketplace uses analytics technology to help it’s 10,000 member businesses win more than £4billion in new contracts each year. … and so on.

None of these initiatives are purely to do with technology. But they all use technologies that simply were not available and accessible as recently as a few years ago to achieve outcomes that are important to cities and communities. By understanding how the potential of technology was apparent to the stakeholders in such initiatives, why it was affordable and accessible to them, and how they acquired the skills to exploit it, we can learn how to design Smart Cities in a way that encourages widespread grass-roots, localised innovation.

(Top: Birmingham's Masshouse Circus roundabout, part of the inner-city ringroad that famously impeded the city's growth. Bottom: This pedestrian roundabout in Lujiazui, China, constructed over a busy road junction, is a large-scale city infrastructure that balances the need to support traffic flows through the city with the importance that Jane Jacobs first described of allowing people to walk freely about the areas where they live and work. Photo by ChrisUK)

(Top: Birmingham’s Masshouse Circus roundabout, part of the inner-city ringroad that famously impeded the city’s growth until it was demolished. Photo by Birmingham City Council. Bottom: Pedestrian roundabout in Lujiazui, China, constructed over a busy road junction, is a large-scale city infrastructure that balances the need to support traffic flows through the city with the importance that Jane Jacobs first described of allowing people to walk freely about the areas where they live and work. Photo by ChrisUK)

A tale of two roundabouts

History tells us that we should not assume that it will be straightforward to design Smart Cities to achieve that objective, however.

A measure of our success in building the cities we know today from the generations of technology that shaped them – concrete, cars and lifts – is the variation in life expectancy across them. In the UK, it’s common for life expectancy to vary by around 20 years between the poorest and richest parts of the same city.

That staggering difference is the outcome of a complex set of issues including the availability of education and opportunity, lifestyle factors such as diet and exercise, and the accessibility of city services. But a significant influence on many of those issues is the degree to which the large-scale infrastructures built to support our physiological needs and the demands of the economy also create a high-quality environment for daily life.

The photograph on the right shows two city transport infrastructures that are visually similar, but that couldn’t be more different in their influence on the success of the cities that they are part of.

The picture at the top shows Masshouse Circus in Birmingham in 2001 shortly before it was demolished. It was constructed in the 1960s as part of the city’s inner ring-road, intended to improve connectivity to the national economy through the road network. However, the impact of the physical barrier that it created to pedestrian traffic can be seen by the stark difference in land value inside and outside the “concrete collar” of the ring-road. Inside the collar, land is valuable enough for tall office blocks to be constructed on it; whilst outside it is of such low value that it is used as a ground-level carpark.

In contrast, the pedestrian roundabout in Lujiazui, China pictured at the bottom, constructed over a busy road junction, balances the need to support traffic flows through the city with the need for people to walk freely about the areas in which they live and work. As can be seen from the people walking all around it, it preserves the human vitality of an area that many busy roads flow through. 

We should take insight from these experiences when considering the design of Smart City infrastructures. Unless those infrastructures are designed to be accessible to and usable by citizens, communities and local businesses, they will be as damaging as poorly constructed buildings and poorly designed transport networks. If that sounds extreme, then consider the dangers of cyber-stalking, or the implications of the gun-parts confiscated from a suspected 3D printing gun factory in Manchester last year that had been created on general purpose machinery from digital designs shared through the internet. Digital technology has life and death implications in the real world.

For a start, we cannot take for granted that city residents have the basic ability to access the internet and digital technology. Some 18% of adults in the UK have never been online; and children today without access to the internet at home and in school are at an enormous disadvantage. As digital technology becomes even more pervasive and important, the impact of this digital divide – within and between people, cities and nations – will become more severe. This is why so many people care passionately about the principle of “Net Neutrality” – that the shared infrastructure of the internet provides the same service to all of its users; and does not offer preferential access to those individuals or corporations able to pay for it.

These issues are very relevant to cities and their digital strategies and governance. The operation of any form of network requires physical infrastructure such as broadband cables, wi-fi and 4G antennae and satellite dishes. That infrastructure is regulated by city planning policies. In turn, those planning policies are tools that cities can and should use to influence the way in which technology infrastructure is deployed by private sector service providers.

(Photograph of Aesop’s fable “The Lion and the Mouse” by Liz West)

Little and big

Cities are enormous places in which what matters most is that millions of individually small matters have good outcomes. They work well when their large scale systems support the fine detail of life for every one of their very many citizens: when “big things” and “little things” work well together.

A modest European or US city might have 200,000 to 500,000 inhabitants; a large one might have between one and ten million. The United Nations World Urbanisation Prospects 2011 revision recorded 23 cities with more than 10 million population in 2011 (only six of them in the developed world); and predicted that there would be nearly 40 by 2025 (only eight of them in the developed world – as we define it today). Overall, between now and 2050 the world’s urban population will double from 3 billion to 6 billion. 

A good example of the challenges that this enormous level of urbanisation is already creating is the supply of food. One hectare of highly fertile, intensively farmed land can feed 10 people. Birmingham, my home city, has an area of 60,000 hectares of relatively infertile land, most of which is not available for farming at all; and a population of around 1 million. Those numbers don’t add up to food self-sufficiency; and Birmingham is a very low-density city – between one-half and one-tenth as dense as the growing megacities of Asia and South America Feeding the 7 to 10 billion people who will inhabit the planet between now and 2050, and the 3 to 6 billion of them that will live in dense cities, is certainly a challenge on an industrial scale. 

In contrast, Casserole Club, the Northfield Eco-Centre, the Chale Project and many other initiatives around the world have demonstrated the social, health and environmental benefits of producing and distributing food locally. Understanding how to combine the need to supply food at city-scale with the benefits of producing it locally and socially could make a huge difference to the quality of urban lives.

The challenge of providing affordable broadband connectivity throughout cities demonstrates similar issues. Most cities and countries have not yet addressed that challenge: private sector network providers will not deploy connectivity in areas which are insufficiently economically active for them to make a profit, and Government funding is not yet sufficient to close the gap.

In his enjoyable and insightful book “Smart Cities: Big Data, Civic Hackers, and the Quest for a New Utopia“, Anthony Townsend describes a grass-roots effort by civic activists to provide New York with free wi-fi connectivity. I have to admire the vision and motivation of those involved, but – rightly or wrongly; and as Anthony describes – wi-fi has ultimately evolved to be dominated by commercial organisations.  

As technology continues to improve and to reduce in price, the balance of power between large, commercial, resource-rich institutions and small, agile, resourceful  grassroots innovators will continue to changeTechnologies such as Cloud Computing, social media, 3D printing and small-scale power generation are reducing the scale at which many previously industrial technologies are now economically feasible; however, it will remain the case for the foreseeable future that many city infrastructures – physical and digital – will be large-scale, expensive affairs requiring the buying power and governance of city-scale authorities and the implementation resources of large companies.

But more importantly, neither small-scale nor large-scale solutions alone will meet all of our needs. Many areas in cities – usually those that are the least wealthy – haven’t yet been provided with wi-fi or broadband connectivity by either.  

(Cars in Frederiksberg, Copenhagen wishing to join a main road must give way to cyclists and pedestrians)

(A well designed urban interface between people and infrastructure. Cars in Frederiksberg, Copenhagen wishing to join a main road must give way to cyclists and pedestrians passing along it)

We need to find the middle ground between the motivations, abilities and cultures of large companies and formal institutions on one hand; and those of agile, local innovators and community initiatives on the other. The pilot project to provide broadband connectivity and help using the internet to Castle Vale in Birmingham is a good example of finding that balance.

And I am optimistic that we can find it more often. Whilst Anthony is rightly critical of approaches to designing and building city systems that are led by technology, or that overlook the down-to-earth and sometimes downright “messy” needs of people and communities for favour of unrealistic technocratic and corporate utopias; the reality of the people I know that are employed by large corporations on Smart City projects is that they are acutely aware of the limitations as well as the value of technology, and are passionately committed to the human value of their work. That passion is often reflected in their volunteered commitment to “civic hacking“, open data initiatives, the teaching of technology in schools and other activities that help the communities in which they live to benefit from technology.

But rather than relying on individual passion and integrity, how do we encourage and ensure that large-scale investments in city infrastructures and technology enable small-scale innovation, rather than stifle it?

Smart urbanism and massive/small innovation

I’ve taken enormous inspiration in recent years from the architect Kelvin Campbell whose “Massive / Small” concept and theory of “Smart Urbanism” are based on the belief that successful cities emerge from physical environments that encourage “massive” amounts of “small”-scale innovation – the “lively, diversified city, capable of continual, close- grained improvement and change” that Jane Jacobs described in “The Death and Life of Great American Cities“.

We’ll have to apply similar principles in order for large-scale city technology infrastructures to support localised innovation and value-creation. But what are the practical steps that we can take to put those principles into practise?

Step 1: Make institutions accessible

There’s a very basic behaviour that most of us are quite bad at – listening. In particular, if the institutions of Smart Cities are to successfully create the environment in which massive amounts of small-scale innovation can emerge, then they must listen to and understand what local activists, communities, social innovators and entrepreneurs want and need.

Many large organisations – whether they are local authorities or private sector companies – are poor at listening to smaller organisations. Their decision-makers are very busy; and communications, engagement and purchasing occur through formally defined processes with legal, financial and confidentiality clauses that can be difficult for small or informal organisations to comply with. The more that we address these barriers, the more that our cities will stimulate and support small-scale innovation. One way to do so is through innovations in procurement; another is through the creation of effective engagements programmes, such as the Birmingham Community Healthcare Trust’s “Healthy Villages” project which is listening to communities expressing their need for support for health and wellbeing. This is why IBM started our “Smarter Cities Challenge” which has engaged hundreds of IBM’s Executives and technology experts in addressing the opportunities and challenges of city communites; and in so doing immersed them in very varied urban cultures, economies, and issues.

But listening is also a personal and cultural attitude. For example, in contrast to the current enthusiasm for cities to make as much data as possible available as “open data”, the Knight Foundation counsel a process of engagement and understanding between institutions and communities, in order to identify the specific information and resources that can be most usefully made available by city institutions to individual citizens, businesses and social organisations.

(Delegates at Gov Camp 2013 at IBM’s Southbank office, London. Gov Camp is an annual conference which brings together anyone interested in the use of digital technology in public services. Photo by W N Bishop)

In IBM, we’ve realised that it’s important to us to engage with, listen to and support small-scale innovation in its many forms when helping our customers and partners pursue Smarter City initiatives; from working with social enterprises, to supporting technology start-ups through our Global Entrepreneur Programme, to engaging with the open data and civic hacking movements.

More widely, it is often talented, individual leaders who overcome the barriers to engagement and collaboration between city institutions and localised innovation. In “Resilience: why things bounce back“, Andrew Zolli describes many examples of initiatives that have successfully created meaningful change. A common feature is the presence of an individual who shows what Zolli calls”translational leadership“: the ability to engage with both small-scale, informal innovation in communities and large-scale, formal institutions with resources.

Step 2: Make infrastructure and technology accessible

Whilst we have a long way to go to address the digital divide, Governments around the world recognise the importance of access to digital technology and connectivity; and many are taking steps to address it, such as Australia’s national deployment of broadband internet connectivity and the UK’s Urban Broadband Fund. However, in most cases, those programmes are not sufficient to provide coverage everywhere.

Some businesses and social initiatives are seeking to address this shortfall. CommunityUK, for example, are developing sustainable business models for providing affordable, accessible connectivity, and assistance using it, and are behind the Castle Vale project in Birmingham. And some local authorities, such as Sunderland and Birmingham, have attempted to provide complete coverage for their citizens – although just how hard it is to achieve that whilst avoiding anti-competition issues is illustrated by Birmingham’s subsequent legal challenges.

We should also tap into the enormous sums spent on the physical regeneration of cities and development of property in them. As I first described in June last year, while cities everywhere are seeking funds for Smarter City initiatives, and often relying on central government or research grants to do so, billions of Pounds, Euros, and Dollars are being spent on relatively conventional property development and infrastructure projects that don’t contribute to cities’ technology infrastructures or “Smart” objectives.

Local authorities could use planning regulations to steer some of that investment into providing Smart infrastructure, basic connectivity, and access to information from city infrastructures to citizens, communities and businesses. Last year, I developed a set of “Smart City Design Principles” on behalf a city Council considering such an approach, including:

Principle 4: New or renovated buildings should be built to contain sufficient space for current and anticipated future needs for technology infrastructure such as broadband cables; and of materials and structures that do not impede wireless networks. Spaces for the support of fixed cabling and other infrastructures should be easily accessible in order to facilitate future changes in use.

Principle 6: Any development should ensure wired and wireless connectivity is available throughout it, to the highest standards of current bandwidth, and with the capacity to expand to any foreseeable growth in that standard.

(The Birmingham-based Droplet smartphone payment service, now also operating in London, is a Smart City start-up that has won backing from Finance Birmingham, a venture capital company owned by Birmingham City Council)

Step 3: Support collaborative innovation

Small-scale, local innovations will always take place, and many of them will be successful; but they are more likely to have significant, lasting, widespread impact when they are supported by city institutions with resources.

That support might vary from introducing local technology entrepreneurs to mentors and investors through the networks of contacts of city leaders and their business partners; through to practical assistance for social enterprises, helping them to put in place very basic but costly administration processes to support their operations.

City institutions can also help local innovations to thrive simply by becoming their customers. If Councils, Universities and major local employers buy services from innovative local providers – whether they be local food initiatives such as the Northfield Ecocentre or high-tech innovations such as Birmingham’s Droplet smartphone payment service – then they provide direct support to the success of those businesses.

In Birmingham,for example, Finance Birmingham (a Council-owned venture capital company) and the Entrepreneurs for the Future (e4F) scheme provide real, material support to the city’s innovative companies; whilst Bristol’s Mayor George Ferguson and Lambeth’s Council both support their local currencies by allowing salaries to be paid in them.

It becomes more obvious  why stakeholders in a city might become involved in collaborative innovation when they have the opportunity to co-create a clear set of shared priorities. Those priorities can be compared to the objectives of innovative proposals seeking support, whether from social initiatives or businesses; used as the basis of procurement criteria for goods, services and infrastructure; set as the objectives for civic hacking and other grass-roots creative events; or even used as the criteria for funding programmes for new city services, such as the “Future Streets Incubator” that will shortly be launched in London as a result of the Mayor of London’s Roads Task Force.

In this context, businesses are not just suppliers of products and services, but also local institutions with significant supply chains, carbon and economic footprints, purchasing power and a huge number of local employees. There are many ways such organisations can play a role in supporting the development of an open, Smarter, more sustainable city.

The following “Smart City Design Principles” promote collaborative innovation in cities by encouraging support from development and regeneration initiatives:

Principle 12: Consultations on plans for new developments should fully exploit the capabilities of social media, virtual worlds and other technologies to ensure that communities affected by them are given the widest, most immersive opportunity possible to contribute to their design.

Principle 13: Management companies, local authorities and developers should have a genuinely engaging presence in social media so that they are approachable informally.

Principle 14: Local authorities should support awareness and enablement programmes for social media and related technologies, particularly “grass roots” initiatives within local communities.

Step 4: Promote open systems

A common principle between the open data movement; civic hacking; localism; the open government movement; and those who support “bottom-up” innovations in Smart Cities is that public systems and infrastructure – in cities and elsewhere – should be “open”. That might mean open and transparent in their operation; accessible to all; or providing open data and API interfaces to their technology systems so that citizens, communities and businesses can adapt them to their own needs. Even better, it might mean all of those things.

The “Dublinked” information sharing partnership, in which Dublin City Council, three surrounding County Councils and  service providers to the city share information and make it available to their communities as “open data”, is a good example of the benefits that openness can bring. Dublinked now makes 3,000 datasets available to local authority analysts; to researchers from IBM Research and the National University of Ireland; and to businesses, entrepreneurs and citizens. The partnership is identifying new ways for the city’s public services and transport, energy and water systems to work; and enabling the formation of new, information-based businesses with the potential to export the solutions they develop in Dublin to cities internationally. It is putting the power of technology and of city information not only at the disposal of the city authority and its agencies, but also into the hands of communities and innovators.

(I was delighted this year to join Innovation Birmingham as a non-Executive Director in addition to my role with IBM. Technology incubators – particularly those, like Innovation Birmingham and Sunderland Software City, that are located in city centres – are playing an increasingly important role in making the support of city institutions and major technology corporations available to local communities of entrepreneurs and technology activists)

In a digital future, the more that city infrastructures and services provide open data interfaces and APIs, the more that citizens, communities and businesses will be able to adapt the city to their own needs. This is the modern equivalent of the grid system that Jane Jacobs promoted as the most adaptable urban form. A grid structure is the basis of Edinburgh’s “New Town”, often regarded as a masterpiece of urban planning that has proved adaptable and successful through the economic and social changes of the past 250 years, and is also the starting point for Kelvin Campbell’s work.

But open data interfaces and APIs will only be widely exploitable if they conform to common standards. In order to make it possible to do something as simple as changing a lightbulb, we rely on open standards for the levels of voltage and power from our electricity supply; the physical dimensions of the socket and bulb and the characteristics of their fastenings; specifications of the bulb’s light and heat output; and the tolerance of the bulb and the fitting for the levels of moisture found in bathrooms and kitchens. Cities are much more complicated than lightbulbs; and many more standards will be required on order for us to connect to and re-configure their systems easily and reliably.

Open standards are also an important tool in avoiding city systems becoming “locked-in” to any particular supplier. By specifying common characteristics that all systems are required to demonstrate, it becomes more straightforward to exchange one supplier’s implementation for another.

Some standards that Smarter City infrastructures can use are already in place – for example, Web services and REST that specify the general ways in which computer systems interact, and the Common Alerting Protocol which is more specific to interactions between systems that monitor and control the physical world. But many others will need to be invented and encouraged to spread. The City Protocol Society is one organisation seeking to develop those new standards; and the British Standards Institute recently published the first set of national standards for Smarter Cities in the UK, including a standard for the interoperability of data between Smart City systems.

Some open source technologies will also be pivotal; open source (software whose source code is freely available to anyone, and which is usually written by unpaid volunteers) is not the same as open standards (independently governed conventions that define the way that technology from any provider behaves). But some open source technologies are so widely used to operate the internet infrastructures that we have become accustomed to – the “LAMP” stack of operating system, web server, database and web progamming language, for example – that they are “de facto” standards that convey some of the benefits of wide usability and interoperability of open standards. For example, IBM recently donated MQTT, a protocol for connecting information between small devices such as sensors and actuators in Smart City systems to the open source community, and it is becoming increasingly widely adopted as a consequence.

Once again, local authorities can contribute to the adoption of open standards through planning frameworks and procurement practises:

Principle 7: Any new development should demonstrate that all reasonable steps have been taken to ensure that information from its technology systems can be made openly available without additional expenditure. Whether or not information is actually available will be dependent on commercial and legal agreement, but it should not be additionally subject to unreasonable expenditure. And where there is no compelling commercial or legal reason to keep data closed, it should actually be made open.

Principle 8: The information systems of any new development should conform to the best available current standards for interoperability between IT systems in general; and for interoperability in the built environment, physical infrastructures and Smarter Cities specifically.

(The town plan for Edinburgh’s New Town, clearly showing the grid structure that gives rise to the adaptability that it is famous for showing for the past 250 years. Image from the JR James archive)

Finally, design skills will be crucial both to creating interfaces to city infrastructures that are truly useful and that encourage innovation; and in creating innovations that exploit them that in turn are useful to citizens.

At the technical level, there is already a rich corpus of best practise in the design of interfaces to technology systems and in the architecture of technology infrastructures that provide them.

But the creativity that imagines new ways to use these capabilities in business and in community initiatives will also be crucial. The new academic discipline of “Service Science” describes how designers can use technology to create new value in local contexts; and treats services such as open data and APIs as “affordances” – capabilities of infrastructure that can be adapted to the needs of an individual. In the creative industries, “design thinkers” apply their imagination and skills to similar subjects.

Step 5: Provide common services

At the 3rd EU Summit on Future Internet, Juanjo Hierro, Chief Architect for the FI-WARE “future internet platform” project, identified the specific tools that local innovators need in order to exploit city information infrastructures. They include real-time access to information from physical city infrastructures; tools for analysing “big data“; and access to technologies to ensure privacy and trust.

The Dublinked information sharing partnership is already putting some of these ideas into practise. It provides assistance to innovators in using, analysing and visualising data; and now makes available realtime data showing the location and movements of buses in the city. The partnership is based on specific governance processes that protect data privacy and manage the risk associated with sharing data.

As we continue to engage with communities of innovators in cities, we will discover further requirements of this sort. Imperial College’s “Digital Cities Exchange” research programme is investigating the specific digital services that could be provided as enabling infrastructure to support innovation and economic growth in cities, for example. And the British Standards Institute’s Smart Cities programme includes work on standards that will enable small businesses to benefit from Smart City infrastructure.

Local authorities can adapt planning frameworks to encourage the provision of these services:

Principle 9: New developments should demonstrate that they have considered the commercial viability of providing the digital civic infrastructure services recommended by credible research sources.

Step 6: Establish governance of the information economy

From the exponential growth in digital information we’ve seen in recent years, to the emergence of digital currencies such as Bitcoin, to the disruption of traditional industries by digital technology; it’s clear that we are experiencing an “information revolution” just as significant as the “industrial revolution” of the 18th and 19th centuries. We often refer to the resulting changes to business and society as the development of an “information economy“.

But can we speak in confidence of an information economy when the basis of establishing the ownership and value of its fundamental resource – digital information – is not properly established?

(Our gestures when using smartphones may be directed towards the phones, or the people we are communicating with through them; but how are they interpreted by the people around us? “Oh, yeah? Well, if you point your smartphone at me, I’m gonna point my smartphone at you!” by Ed Yourdon)

A great deal of law and regulation already applies to information, of course – such as the European Union’s data privacy legislation. But practise in this area is far less established than the laws governing the ownership of physical and intellectual property and the behaviour of the financial system that underlie the rest of the economy. This is evident in the repeated controversies concerning the use of personal information by social media businesses, consumer loyalty schemes, healthcare providers and telecommunications companies.

The privacy, security and ownership of information, especially personal information, are perhaps the greatest challenges of the digital age. But that is also a reflection of their importance to all aspects of our lives. Jane Jacobs’ description of urban systems in terms of human and community behaviour was based on those concepts, and is still regarded as the basis of our understanding of cities. New technologies for creating and using information are developing so rapidly that it is not only laws specifically concerning them that are failing to keep up with progress; laws concerning the other aspects of city systems that technology is transforming are failing to adapt quickly enough too.

A start might be to adapt city planning regulations to reflect and enforce the importance of the personal information that will be increasingly accessed, created and manipulated by city systems:

Principle 21: Any information system in a city development should provide a clear policy for the use of personal information. Any use of that information should be with the consent of the individual.

The triumph of the commons

I wrote last week that Smarter Cities should be a “middle-out” economic investment – in other words, an investment in common interests – and compared them to the Economist’s report on the efforts involved in distributing the benefits of the industrial revolution to society at large rather than solely to business owners and the professional classes.

One of the major drivers for the current level of interest in Smarter Cities and technology is the need for us to adapt to a more sustainable way of living in the face of rising global populations and finite resources. At large scale, the resources of the world are common; and at local scale, the resources of cities are common too.

For four decades, it has been widely assumed that those with access to common resources will exploit them for short term gain at the expense of long term sustainability – this is the “tragedy of the commons” first described by the economist Garrett Hardin. But in 2009, Elinor Ostrum won the Nobel Prize for economics by demonstrating that the “tragedy” could be avoidedand that a community could manage and use shared resources in a way that was sustainable in the long-term.

Ostrum’s conceptual framework for managing common resources successfully is a set of criteria for designing “institutions” that consist of people, processes, resources and behaviours. These need not necessarily be formal political or commercial institutions, they can also be social structures. It is interesting to note that some of those criteria – for example, the need for mechanisms of conflict resolution that are local, public, and accessible to all the members of a community – are reflected in the development over the last decade of effective business models for carrying out peer-to-peer exchanges using social media, supported by technologies such as reputation systems.

Of course, there are many people and communities who have championed and practised the common ownership of resources regardless of the supposed “tragedy” – not least those involved in the Transition movement founded by Rob Hopkins, and which has developed a rich understanding of how to successfully change communities for the better using good ideas; or the translational leaders described by Andrew Zolli. But Elinor Ostrum’s ideas are particularly interesting because they could help us to link the design, engineering and governance of Smarter Cities to the achievement of sustainable economic and social objectives based on the behaviour of citizens, communities and businesses.

Combined with an understanding of the stories of people who have improved their lives and communities using technology, I hope that the work of Kelvin Campbell, Rob Hopkins, Andrew Zolli, Elinor Ostrum and many others can inspire technologists, urban designers, architects and city leaders to develop future cities that fully exploit modern technology to be efficient, resilient and sustainable; but that are also the best places to live and work that we can imagine, or that we would hope for for our children.

Cities created by people like that really would be Smart.

Creating successful Smart Cities in 2014 will be an economic, financial and political challenge, not an engineering accomplishment

Why insurers, pension funds and politics will be more important to Smart Cities in 2014 than “Living Labs” or technology.

(The 2nd Futurama exhibition at the 1964 New York World’s Fair. In 50 years’ time, how will we perceive today’s visions of Smart Cities? Photo by James Vaughan)

I hope that 2014 will be the year in which we see widespread and large-scale investments in future city technology infrastructures that enable sustainable, equitably distributed economic and social growth. The truth is that we are still in the very early stages of that process.

In 2012 I spoke with a Director at a financial consultancy who’d performed a survey of European Smart City initiatives. She confirmed something that I suspected at the time: that the great majority of Smart City initiatives up to that point in the mature markets of Europe and North America had been financed by research funding, rather than on a commercial basis.

Four trends characterised the subsequent development of Smart Cities throughout 2013. Firstly, emerging markets continued to invest in supporting the rapid urbanisation they are experiencing; and businesses, Universities and national governments in developed nations recognised the commercial opportunity for them to supply that market with “Smart” solutions.

Secondly, it remains the case that the path to growth for undeveloped nations is still extremely slow and complex; so whilst there is private sector and national government interest in investing in those nations – IBM’s new Research centre in Nairobi being an example – many “smart” initiatives are carried out at small scale by local innovators, the third sector or development agencies.

In Europe and North America, a third trend was the continuing announcement of investments by the European Union and national governments in the applied research and innovation agenda in cities – such as the EU’s Horizon 2020 programme, for example.

Perhaps most importantly, though, the final trend was for cities in Europe and North America to start to make investments in the underlying technology platforms for Smart Cities from their own operational budgets, on the basis of their ability to deliver cost savings or improvements in outcomes. For example, some cities are replacing traditional parking management and enforcement services with “smart parking” schemes that are reducing congestion and pollution whilst paying for themselves through improved revenues. Others are investing their allocation of central government infrastructure funds in Smart solutions – such as Cambridge, Ontario’s use of the Canadian government’s Gas Tax Fund to invest in a sensor network and analytics infrastructure to manage the city’s physical assets intelligently.

This trend to create business cases for investment from normal operating budgets or infrastructure investment programmes is important not only because it shows that these cities are developing the business models to support investment in “Smart” solutions locally, where the finances associated with rapid economic growth and urbanisation are not present; but also because (at the risk of simplifying a challenging and complex issue) some of those business models might serve as a template for self-sustainable adoption in less developed nations.

(Downtown Cambridge, Ontario. Photo by Justin Scott Campbell)

Whilst the idea of a “Smart City” has been capturing the imagination for several years now, the reality is that many cities are still deciding what that idea might mean for them. For example, London’s “Smart London Board” published it’s Smart London plan in December, following Birmingham’s Smart City Commission report earlier in the year. And most cities who are considering such plans now or who have recently published them are still determining how to put the finance in place to carry them out.

Will “Living Labs” be the death of Smart Cities?

A concept that I see in many such plans that is intended to assist in securing finance, but that I think risks being a distraction from addressing it properly, is the “Living Lab”. 

Living labs emerged as a set of best practises for carrying out applied research into consumer or citizen services with a focus on collaborative, user-centred design and co-creation. Many cities are now seeking to win funding for their Smarter Cities initiatives by offering themselves as “Living Labs” in which consortia constructing proposals for applied research funding can carry out their activities.

The issue is not that Living Lab’s aren’t a good idea – on the contrary, they are undoubtably a very good set of prescriptions for carrying out such research and design successfully. The problem is that there are now so many cities intending to follow this approach that it no longer makes them stand out as particularly effective environments in which to perform research.

Research programmes will continue to fund the first deployments of new Smart City ideas and technology; but competition for those funds will be fierce. Cities, universities and companies that bid for them will invest many months – often more than a year – in developing their proposals; and in competitions, most entrants do not win.

The real need in cities is for the development and regeneration of infrastructure. There are certainly research topics concerning infrastructure that will attract funding from national and international government bodies; but those funds will not support the rollout of citywide infrastructure to every city in every country.

(Birmingham's new city-centre tram)

(Birmingham’s new city-centre tram is an infrastructure investment that will contribute to the same objectives as the city’s Smart City vision.)

The big questions for European and American cities in 2014 are then:

Will they continue to invest resources competing for applied research and innovation funding, limiting the speed at which the widespread deployment of new infrastructure will take place?

Or will they focus on developing independently viable business cases for investment in the infrastructure to support their
Smarter City visions?

There’s a real need for clarity about these issues. Whilst the enormous level of innovation funding being made into smart buildings, smart transport and smart cities by the EU Horizon 2020 programme and national equivalents such as the UK’s Technology Strategy Board will stimulate the field and fund important demonstration projects that deliver real value, these bodies will not pay for all of our cities to become Smarter.

The same is true for the research investments made by commercial organisations including technology companies such as IBM. Commercial research investments fund the first attempts to apply technology to solve problems or achieve objectives in new ways; those that succeed are subsequently deployed elsewhere on a commercial basis.

The risk is that in seeking investment from research programmes, we become distracted from addressing the real challenge: how to make the case for private sector investment in new technology infrastructures based on the economic and social improvements they will enable; or on the direct financial returns that they will generateIn the UK, for example, a specialist body in Government, Infrastructure UK, coordinates private sector funding for public infrastructure. And if we can persuade property developers of the value of “Smart” technologies, then cities could benefit from the enormous investments made in property every year that currently don’t result in the deployment of technology – the British Property Federation, for example, estimate that £14 billion is invested in the development of new space in the UK each year.

(This pedestrian roundabout in Lujiazui, China, constructed over a busy road junction, is a large-scale city infrastructure that balances the need to support traffic flows through the city with the importance that Jane Jacobs first described of allowing people to walk freely about the areas where they live and work. Photo by ChrisUK)

This is an opportunity we should treat with urgency. Whilst public sector finances are under immense pressure, the vast wealth held in private investment funds is seeking new opportunities following the poor returns that many traditional forms of investment have yielded over the last few years. There is a lot of work to do between the stakeholders in cities, government and finance before these investment sources can be exploited by Smart Cities – not least in agreeing reasonable expectations for how the risks and returns will be measured and shared. But I personally believe that until we do so, we will not be able to properly finance the development of our next generation of cities.

As Jane Jacobs wrote in her seminal 1961 work “The Death and Life of Great American Cities“:

“Private investment shapes cities, but social ideas (and laws) shape private investment. First comes the image of what we want, then the machinery is adapted to turn out that image. The financial machinery has been adjusted to create anti-city images because, and only because, we as a society thought this would be good for us. If and when we think that lively, diversified city, capable of continual, close-grained improvement and change, is desirable, then we will adjust the financial machinery to get that.”

Overcoming these challenges won’t be easy, and doing so will require each of the various stakeholder organisations facing them to take bold steps this year.

Local Government

Whilst their finances throughout the developed world have been under severe pressure for a long time now, local government bodies are still responsible for procuring a significant volume of goods and services. Smart Cities will only become a reality when local authority visions for the future are reflected in procurement practises and scoring criteria for contracts issued today. It’s only very recently that procurements for contracts to build, update and manage physical infrastructures such as roads and pavements have been based on outcomes such as minimising congestion or increasing the overall quality of performance throughout the lifetime of the asset within the contract value, rather than on securing the maximum volume of concrete (or number of traffic wardens).

Outcomes-based procurements are challenging to be sure, both for the purchaser and the provider; especially so when they are for such new solutions. But service and infrastructure providers will only be motivated to propose and deliver innovative, smart solutions when they’re rewarded for doing so.

Local authorities can also exploit indirect mechanisms such as planning and development frameworks. I worked last year with one authority which asked how its planning framework should evolve in order to promote the development of a “Smart City”, and published a set of 23 “Design principles for a Smarter City” as a result. They require that investments in property also deliver technology infrastructures such as wi-fi, broadband, open-data, and multi-channel self-service access.

(An analysis based on GPS data from mobile phones of end-to-end journeys undertaken by users of Abidjan’s bus services. By comparing existing bus routes to end-to-end journey requirements, the analysis identified four new bus routes and led to changes in many others. As a result, 22 routes now show increased ridership, and city-wide journey times have decreased by 10%. The techniques and technologies behind the project build on those developed for projects in Dubuque, Istanbul and Dublin.)

Private Sector

The technology companies associated with Smart Cities have sometimes been criticised for focussing too much on the technology that can be applied to city infrastructures, and not enough on the improvements to people’s work and lives that technology can enable, or on the business cases for investing in it.

To make the business case clearer, my colleague the economist Mary Keeling has been working for IBM’s Institute for Business Value to more clearly analyse and express the benefits of Smart approaches – in water management and transportation, for example. And I’ll be contributing along with representatives from many of the other companies that provide technology and infrastructure for Smart Cities to the TSB’s Future Cities Catapult’s finance initiative.

But we also need to respect the principles of Living Labs and the experience of urban designers – not least the writing of Jane Jacobs – which reflect that our starting point for thinking about Smart Cities should be the everyday lives and experiences of individual citizens in their family lives; at work; and moving through cities. In one sense, this is business as usual in the technology industry – “user-centered design“, “use cases” and “user stories” have been at the heart of software development since the 1980s. So one of our challenges is simply to communicate that approach more clearly within our descriptions of Smart Cities. This is a topic I’ve written about in many articles on this blog that you can find described in “7 Steps to a Smarter City“; and that I tried to address in IBM’s new Smarter Cities video.

The other challenge is for technology companies to become more familiar and expert in the disciplines associated with good quality urban design – town planning, architecture, social science and the psychology of human behaviour, for example. This is one of the reasons why IBM started the “Smarter Cities Challenge” programme through which we have donated our technology expertise to 100 cities worldwide to help them address the opportunities and challenges they face; and in so doing become more familiar with their very varied cultures, economies, issues and capabilities. It’s also why I joined the Academy of Urbanism, along with representatives of several other technology companies.

We also need to embrace the “Smart Urbanism” thinking exemplified by Kelvin Campbell. Kelvin’s “Massive / Small” approach is intended to design large-scale urban infrastructures that encourage and support “massive” amounts of “small-scale” innovation. I think that’s an extremely powerful idea that we should embrace in Smarter Cities; and that translates directly to the practise of providing open-standard, public interfaces to city technology infrastructures – open data feeds and APIs (“Application Programming Interfaces”), for example – that not only reduce the risk that city systems become “locked-in” to any proprietary provider; but that also open up the power of large scale technology systems and “big data” sources so that local businesses, innovators and communities are able to adapt public infrastructures to their own needs. I think of these interfaces as creating an “innovation boundary” between a city’s infrastructure and its stakeholders.

(George Ferguson, Mayor of Bristol, one of the few cities in the UK with an elected Mayor with significant authority and responsibility. His salary is paid in the city’s local currency, the Bristol Pound, rather than in the national currency. His red trousers are famous. Photo by PaulNUK)

Central Government

In most countries in the developed world – i.e. those which are not being driven by rapid urbanisation today because they urbanised during the Industrial Revolution – the majority of Smart City initiatives that have momentum are driven by Mayors convening city stakeholders and institutions to co-create, finance and deliver those initiatives. Correspondingly, in countries without strong mayoral systems – such as the UK – progress can be slower. Worryingly, Centre for Cities’ recent Outlook 2014 report pointed out that only 17% of funding for UK cities comes from locally administered taxation, as opposed to the OECD average of 55%.

To risk stating the obvious, every city is different, and different in very many important ways, from its geographical situation to its linkage to national and international transport infrastructure; from its economic and business capabilities to the skills and wealth of its population; from its social challenges and degree of social mobility to its culture and heritage. Successful Smart City initiatives are specific, not generic; and the greater degree of autonomy that cities are allowed in setting strategy and securing financing, the greater their capability to pursue those initiatives. Programmes such as “City Deals” and the recent reforms resulting from Lord Heseltine’s “No Stone Unturned” report are examples of progress towards greater autonomy for the UK’s cities, but they are not enough.

Central government will always have a significant role in funding the infrastructures that cities rely on, of course; whether that’s national infrastructures that connect cities (such as the planned “HS2” high-speed train network in the UK, or Australia’s national deployment of broadband internet connectivity), or specific infrastructures within cities, such as Birmingham’s new city-centre tram. And so just as local governments should consider how they can use procurement practises and planning frameworks to encourage investments in property and infrastructure that deliver “Smart” solutions, so central government should consider how the funding programmes that it administers can contribute to cities’ “Smart” objectives.

Financial Services

If the challenge is to unlock investment in new assets and outcomes, then we should turn to banks, insurers and investors to help us shape the new financial vehicles that we will require to do so. In Canada, for example, a collaboration between Canadian insurers and cities has developed a set of tools to create a common understanding of the financial risk created by the effects of climate change on the resilience of city infrastructures. These tools are the first step towards creating investment and insurance models for city infrastructures that will be exposed to new levels of risk; that will need to exhibit new levels of resilience; and that in turn may require Smart solutions to achieve them.

(Luciana Berger, Shadow Minister for Energy and Climate Change pictured talking to Northfield, Birmingham resident Abraham Weekes and James McKay, Birmingham City Council’s Cabinet Member for a Green, Safe and Smart city. Abraham lives in the house pictured, which has been fitted with exterior house covering, solar panels and energy efficient windows through the Birmingham Energy Savers scheme. Photo by Birmingham City Council)

More internationally, the “Little Rock Accord” between the Madrid Club of former national Presidents and Prime Ministers and the P80 group of pension funds agreed to create a task force to increase the degree to which pension and sovereign wealth funds invest in the deployment of technology to address climate change issues, shortages in resources such as energy, water and food, and sustainable, resilient growth. And more locally, I’m proud to note that my home city of Birmingham is a pioneer in this area through the Birmingham Energy Savers project, financed through a mixture of prudential borrowing and private sector investment.

It has taken us too long to get to this point, but I’m encouraged that several initiatives are now convening discussions between the traditionally understood stakeholders in Smart Cities – local authorities, technology companies, universities and built-environment companies – and the financial sector. For example, in addition to the Future Cities Catapult’s financing programme, on March 13th, I’ll be speaking at an event organised by the Lord Mayor of the City of London to encourage the City’s financial institutions and UK city authorities to undertake a similar collaboration to develop new financing models for future city infrastructures.

Are Smarter Cities a “middle out” economic intervention?

In his 2011 Presidential Campaign speech Barack Obama promised an economic strategy based on “middle-out” economics – the philosophy that equitable, sustainable growth is driven by the spending power of middle class consumers, as an alternative to “trickle-down” economics – the philosophy that growth is best created when very rich “wealth-creators” are free to become as successful as possible.

As this analysis in “The Atlantic” shows, job creation does depend on the investments of the wealthiest; but also on the spending power of the masses; and on a lot of very hard work making sure that a reasonable portion of the profits created by both of those activities are used to invest in making skills, education and opportunity available to all. The Economist magazine made the same point in a recent article by reminding us of the enormous investments made into public institutions in the past in order to distribute the benefits of the Industrial Revolution to society at large rather than concentrate them on behalf of business owners and the professional classes; though with only partial success.

(The discussion group at the #SmartHack event in Birmingham)

(The discussion group at the #SmartHack event in Birmingham, described in “Tea, trust and hacking – how Birmingham is getting Smarter“, photographed by Sebastian Lenton)

 Those ideas are reflected in what it takes to craft an investment in a technology-enabled Smart City initiative that successfully creates social and economic improvements in a city.

Whilst a huge number of effective “Smart” ideas will be created “bottom-up” by innovators and social entrepreneurs intimately familiar with specific local communities and context, those ideas will not succeed as well or rapidly as we need them to without significant investment in new infrastructures – such as wi-fi, broadband and realtime open data – that are deployed everywhere, not just in the most economically active areas of cities that reward commercial investment most quickly. Accessibility to these infrastructures creates the “innovation boundary” between city institutions and infrastructures, and local innovators and communities.

This is not an abstract concept; it is an idea that some cities are making very real today. For example, the “Dublinked” information-sharing partnership between Dublin County Council, three surrounding County Councils and the National University of Ireland now makes available 3,000 city datasets as “open data” – including a realtime feed showing the location of buses in the city. That’s a resource that local innovators can use to create their own new applications and services. Similarly, in Birmingham the “West Midlands Open Data Forum” has emerged as a community in which city local businesses and innovators can negotiate access to data held by city institutions and service providers.

(David Willets, MP, Minister for Universities and Science, launches the UK Government’s Smart Cities Forum)

At launch of the UK Government’s “Smart Cities Forum” last year, I remarked that we were not inviting key stakeholders to the Smarter Cities debate – specifically, banks, investors, insurers and entrepreneurs. Some of the initiatives I’ve described in this article are starting to address that omission; and to recognise that the most significant challenges are to do with finance, politics, social issues and economics, not engineering and technology.

And those are challenges that all of us should focus on. No-one is going to pay for our cities to become Smarter, more successful, more sustainable and fairer: we will have to figure out how to pay for  those things ourselves.

Three mistakes we’re still making about Smart Cities

(David Willets, MP, Minister for Universities and Science, launches the UK Government’s Smart Cities Forum)

(I was asked this week to contribute my view of the present state of the Smart Cities movement to the UK Government’s launch of it’s Smart Cities forum, which will report to the Government’s Information Economy Council. This article is based on my remarks at the event).

One measure of how successfully we have built today’s cities using the technologies that shaped them over the last century – concrete, steel and the internal combustion engine – is the variation of life expectancy within them. In the UK, people born in the poorest areas of our large cities can expect to live lives that are two decades shorter than those born in the wealthiest areas.

We need to do much better than that as we apply the next generation of technology that will shape our lives – digital technology.

The market for Smart Cities, which many define as the application of digital technology to city systems, is growing. Entrepreneurial businesses such as Droplet and Shutl are delivering new city services, enabled by technology. City Councils, service providers and transport authorities are investing in Smart infrastructures, such as Bradford’s City Park, whose fountains and lights react to the movements of people through it. Our cities are becoming instrumented, interconnected and intelligent, creating new opportunities to improve the performance and efficiency of city systems.

But we are still making three mistakes that limit the scale at which truly innovative Smart City projects are being deployed.

1. We don’t use the right mix of skills to define Smart City initiatives

Over the last year, I’ve seen a much better understanding develop between some of the creative professions in the Smart Cities domain: technologists, design thinkers, social innovators, entrepreneurs and urban designers. Bristol’s “Hello Lamppost” is a good example of a project that uses technology to encourage playful interaction with an urban environment, thereby bringing the life to city streets that the urbanist Jane Jacobs‘ taught us is so fundamental to healthy city communities.

Internationally, cities have a great opportunity to learn from each others’ successes: smart, collective, sustainable urbanism in Scandinavia, as exemplified by Copenhagen’s Nordhavnen district; intelligent city planning and management in Asia and increasingly in the United States, where cities such as Chicago have also championed the open data movement; and the phenomenal level of small-scale, non-institutional innovation in communities in UK cities.

But this debate does not extend to some important institutions that are also beginning to explore how they can contribute towards the social and environmental wellbeing of cities and communities. Banks and investors, for example, who have the funds to support large-scale initiatives, or the skills to access them; or supermarkets and other retailers who operate across cities, nations and continents; but whose operational and economic footprint in cities is significant, and whose supply chains support or contribute to billions of lives.

It’s important to engage with these institutions in defining Smart City initiatives which not only cut across traditional silos of responsibility and budgets in cities, but also cut across the traditional asset classes and revenue streams that investors understand. A Smart City initiative that is crafted without their involvement will be difficult for them to understand, and they will be unlikely to support it. Instead, we need to craft Smart initiatives with them.

(The masterplan for Copenhagen’s regeneration of Nordhavnen, which was co-created with local residents and communities. Photo by Thomas Angermann)

2. We ask researchers to answer the wrong challenges

University research is a great source of new technologies for creating Smart solutions. But our challenge is rarely the availability of new technology – we have plenty of that already.

The real challenge is that we are not nearly exploiting the full potential of the technology already available to us; and that’s because in many cases we do not have a quantified evidence base for the financial, social, economic and environmental benefits of applying technology in city systems. Without that evidence, it’s hard to create a business case to justify investment.

This is the really valuable contribution that research could make to the Smart Cities market today: quantify the benefits of applying technology in city systems and communities; identify the factors that determine the degree to which those benefits can be realised in specific cities and communities; align the benefits to the financial and operating models of the public and private institutions that operate city services and assets; and provide the detailed data from which clear businesses cases with quantified risks and returns can be constructed.

3. We don’t listen to the quiet voices that matter

It’s my experience that the most powerful innovations that make a difference to real lives and communities occur when “little things” and “big things” work well together.

Challenges such as transport congestion, social mobility, responsible energy usage or small business growth are often extremely specific to local contexts. Successful change in those contexts is usually created when the people, community groups and businesses involved create, or co-create, initiatives to improve them.

But often, the resources available locally to those communities are very limited. How can the larger resources of institutional organisations be made available to them?

In “Resilience: why things bounce back“, Andrew Zolli describes many examples of initiatives that have successfully created meaningful change; and characterises the unusual qualities of the “translational leaders” that drive them – people who can engage with both small-scale, informal innovation in communities and large-scale, formal institutions with resources.

It’s my hope that we can enable more widespread changes not by relying only on such rare individuals, but by changing the way that we think about the design of city infrastructures. Rather than designing the services that they deliver, we should design what Service Scientists call the “affordances” they offer. An affordance is a capability of an infrastructure that can be adapted to the needs of an individual.

An example might be a smart grid power infrastructure that provides an open API allowing access to data from the grid. Developers, working together with community groups, could create schemes specific to each community which use that information to encourage more responsible energy usage. My colleagues in IBM Research explored this approach in partnership with the Sustainable Dubuque partnership resulting in a scheme that improved water and energy conservation in the city.

We can also apply this approach to the way that food is supplied to cities. The growing and distribution of food will always be primarily a large-scale, industrial operation: with 7 billion people living on a planet with limited resources, and with more than half of them living in dense cities, there is no realistic alternative. An important challenge for the food production and distribution industry, and for the technology industry, is to find ways to make those systems more efficient and sustainable.

But we can also act locally to change the way that food is processed, prepared and consumed; and in doing so create social capital and economic opportunity in some of the places that need it most. A good example is “Casserole Club“, which uses social media as the basis of a peer-to-peer model which connects people who are unable to cook for themselves with people who are willing to cook for, and visit, others.

These two movements to improve our food systems in innovative ways currently act separately; what new value could we create by bringing them together?

We’re very poor at communicating effectively between such large-scale and small-scale activities. Their cultures are different; they use different languages, and those involved spend their working lives in systems focussed on very different objectives.

There’s a very simple solution. We need to listen more than we talk.

We all have strong opinions and great ideas. And we’re all very capable of quickly identifying the aspects of someone else’s idea that mean it won’t work. For all of those reasons, we tend to talk more than we listen. That’s a mistake; it prevents us from being open to new ideas, and focussing our attention on how we can help them to succeed.

New conversations

By coincidence, I was asked earlier this year to arrange the agenda for the annual meeting of IBM’s UK chapter of our global Academy of Technology. The Academy represents around 500 of IBM’s technology leaders worldwide; and the UK chapter brings 70 or so of our highest achieving technologists together every year to share insights and experience about the technology trends that are most important to our industry, and to our customers.

(Daden's visualisation of the new Library of Birmingham, created before construction started and used to familiarise staff with the new building they would be working in. Taken from Daden's brochure describing the work more fully).

(Daden’s visualisation of the new Library of Birmingham, created before construction started and used to familiarise staff with the new building they would be working in. Taken from Daden’s brochure describing the work more fully).

This year, I’m bringing them to Innovation Birmingham for two days next week to explore how technology is changing Britain’s second city. We’ll be hearing about Birmingham City Council’s Smart City Strategy and Digital Birmingham‘s plans for digital infrastructure; and from research initiatives such as the University of Birmingham’s Liveable Cities programme; Aston University’s European Bio-Energy Research Institute; and Birmingham City University’s European Platform for Intelligent Cities.

But we’ll also be hearing from local SMEs and entrepreneurs creating innovations in city systems using technology, such as Droplet‘s smartphone payment system; 3D visualisation and analytics experts Daden, who created a simulation of Birmingham’s new Library; and Maverick Television whose innovations in using technology to create social value include the programmes Embarrassing Bodies and How to Look Good Naked. And we’ll hear from a number of social innovators, such as Localise West Midlands, a not-for-profit think-tank which promotes localisation for social, environmental and economic benefit, and Hub Launchpad, a business-accelerator for social enterprise who are building their presence in the city. You can follow our discussions next week on twitter through the hashtag #IBM_TCG.

This is just one of the ways I’m trying to make new connections and start new conversations between stakeholders in cities and professionals with the expertise to help them achieve their goals. I’m also arranging to meet some of the banks, retailers and supply-chain operators who seem to be most focussed on social and environmental sustainability, in order to explore how those objectives might align with the interests of the cities in which they operate. The British Standards Institute is undertaking a similar project to explore the financing of Smart Cities as part of their Smart Cities programme. I’m also looking at the examples set by cities such as Almere whose collaborative approach to urban design, augmented by their use of analytics and technology, is inspirational.

This will not be a quick or easy process; but it will involve exciting conversations between people with passion and expertise. Providing we remember to listen as much as we talk, it’s the right place to start.

A design pattern for a Smarter City: Local Currencies and Alternative Trading Systems

(Photo of the Brixton Pound by Charlie Waterhouse)

(In “Do we need a Pattern Language for Smarter Cities” I suggested that “design patterns“, a tool for capturing re-usable experience invented by the town-planner Christopher Alexander, might offer a useful way to organise our knowledge of successful approaches to “Smarter Cities”. I’m now writing a set of design patterns to describe ideas that I’ve seen work more than once. The collection is described and indexed in “Design Patterns for Smarter Cities” which can be found from the link in the navigation bar of this blog).  

Design Pattern: Local Currencies and Alternative Trading Systems

Summary of the pattern:

There are many definitions of a “smart city”, but they all incorporate the concept of innovations, enabled by technology, that change the relationships between the creation of financial and social value and the consumption of resources.

Money is our universal system for quantifying the exchange of value; but most of the systems which measure value using money do not incorporate social or environmental factors – externalities as they are known by economists. Consequently a variety of alternative systems of trading and exchange have emerged amongst online communities and in local ecosystems that are exploring new ways to create sustainable regional economic and social improvement.

Some of these schemes use paper or electronic currencies that are issued and accepted within a particular place or region; and that have the effect of influencing people and businesses to spend the money that they earn locally, promoting regional economic synergies. Last year, Bristol became the 5th UK town or city to operate its own currency using this model, and “Droplet” operate a local smartphone payment scheme in Birmingham and London.

Other schemes are based on the bartering of goods, money, time and services, such as time banking. And some schemes combine both elements – In Switzerland, a complementary currency, the Wir , has contributed to economic stability over the last century by allowing some debt repayments to be bartered locally when they cannot be repaid in universal currency.

As these schemes develop – and in particular as they adopt technologies such as smartphones and offer open APIs to allow developers to incorporate their capabilities in new services – they are increasingly being used as an infrastructure for Smarter City projects in domains such as transport, food supply and energy.

(The SMS for Life project uses the cheap and widely used SMS infrastructure to create a dynamic, collaborative supply chain for medicines between pharmacies in Africa. Photo by Novartis AG)

Such schemes exploit the potential for the combination of information technology and local currencies to calculate rates of exchange that compare the social, environmental and economic cost of goods and services to their immediate, contextual value to the participants in the transaction. The academic field of service science has evolved to study the ways in which such possibilities lead to business and service invocation.

This trend is particularly strong in some African nations where a lack of physical and transport infrastructure has led to a surge in business innovation supported by mobile payments schemes. For example, the Kilimo Salama scheme in Kenya provides affordable insurance to subsistence farmers by using remote weather monitoring to trigger payouts via mobile phones, rather than undertaking expensive site visits to assess claims.

City systems, communities and infrastructures affected:

(This description is based on the elements of Smarter City ecosystems presented in ”The new Architecture of Smart Cities“).

  • Goals: Wealth, health, opportunity, choice, sustainability
  • People: Any
  • Ecosystem: All
  • Soft infrastructures: Leadership and governance, networks and community organisations
  • City systems: Transport systems, health, culture, economy, retail, leisure; and potentially others
  • Hard infrastructures: Information and communication technology

Commercial operating models, alternatives and variations:

Four main types of commercial model exist, each constituting a variation of this pattern:

  • Local currencies operated as social enterprises within specific towns or cities, pursing local economic objectives, often issuing paper currencies. Examples include the Bristol, Brixton, Lewes, Stroud, and Totnes pounds. These schemes link to national and universal currency by offering defined processes and rates of exchange. Often the financial backing is provided by a credit union or other mutual financial organisation.
  • Smartphone payment schemes operated by private enterprises, usually entrepreneurial technology companies. These companies may not have local economic objectives as a primary focus, but will usually deploy their services and build businesses with a network of merchants in a specific city in order to create the critical mass necessary to persuade consumers to adopt the service. These schemes link to traditional payment systems either through direct integration to banking services, or though the billing systems offered by mobile network operators.
  • Recycling and bartering networks such as Freecycle which operate very informally and are locally focused as they involve people physically meeting to exchange goods or services. Such networks are often governed at least as much by codes of behaviour as they are by being legally constituted as formal bodies.
  • Local loyalty schemes operated by city councils or by businesses on behalf of local communities, and that encourage local businesses to collectively reward customers for using their products and services. Examples include the “Backing Birmingham” b-card; the not-for-profit “tag” scheme that operates in Durham, Manchester and Stockport; and Local Loyalty Powys.

In addition, it is likely that formal banking institutions and payments intermediaries will enter this market in some form. Many financial institutions started as or are now social enterprises, or express community objectives in their charters; credit unions, for example, or Hancock Bank, whose charter as a community bank led them to take powerful actions to assist the citizens of New Orleans to recover from hurricane Katrina in 2005 .

These institutions are increasingly exploring the role they can take in supporting Smarter Cities, both directly  or through supporting innovation facilities like the Future Cities programme at the Level39 incubator in London’s financial district.

Soft infrastructures, hard infrastructures and assets required:

Local currencies and trading schemes are formed where an entrepreneurial organisation – whether a private business or a social enterprise – works together with a community organisation – either an institution such as a city council, or a community such as a local business network. Trust and collaboration between the entrepreneur, institution and community are vital to success. In particular, city institutions can support the scheme by allowing employees to chose to be paid through it in whole or in part – Lambeth Council offers employees the choice to be paid in part in Brixton pounds; and Bristol’s mayor takes his entire salary in Bristol Pounds.

A Payments or billing service, or mechanisms to print local currency and govern its exchange for national currency are also required in order to integrate the local scheme with the traditional economy. The governance of these arrangements is crucial to convincing individuals and businesses to trust this new independent form of currency.

Schemes achieve the highest level of adoption where they are supported by strong local economic and business communities, such as Business Improvement Districts or campaigns such as Coffee Birmingham.

(The QR code that enabled Will Grant of Droplet to buy me a coffee at Birmingham Science Park Aston using Droplet’s local smartphone payment solution; and the receipt that documents the transaction)

Driving forces:

The factors that lead to the emergence of local currencies and alternative trading systems include:

  • The desire from local government, within local communities and amongst local businesses and entrepreneurs to support local economic and social growth.
  • Disillusion with traditional financial systems following the 2008 crash, recent banking scandals, and the reluctance of some banks to lend to small business; along with an awareness that alternative models are increasingly viable for some purposes.
  • The increasing availability of low-cost payment systems to support transactions in online marketplaces that exchange local resources, such as local food initiatives, community energy schemes, shared transport systems and timebanks.

Benefits:

Benefits of local currencies and alternative trading systems include:

  • The potential to link the formal economy with informal transactions, some of which are crucial to creating value in communities with the fewest resources.
  • The ability to include local externalities in the rate of exchange associated with transactions.
  • Reinforcement of local economic synergies.
  • The creation of brand value for towns and cities with flourishing local currencies.

Alternatives and variations:

Alternatives and variations of this pattern are described under “Commercial operating models, alternatives and variations” above.

Implications and risks:

Local currencies are not universally admired. Some merchants complain that it is inconvenient to accept payment in a currency with restrictions on spending, or that requires conversion to national currency; and some commentators have questioned whether they achieve anything that couldn’t be achieved through simpler means. Newspaper and BBC journalists have explored these issues in reports describing the Lewes Pound.

Local currency schemes must also offer some mechanism to protect the value of currency held by users of the scheme. This might be achieved if the currency is operated by a mutual financial organisation such as a credit union; or by depositing matching funds in national currency in a traditional bank account. Where printed notes are issued, steps must be taken to prevent them being easily reproduced fraudulently.

Finally, in order to succeed, local currencies need to achieve a critical mass of users and of accepting merchants. Lambeth Council accept payments of business rates in Brixton pounds, and allow employees to take part of their salaries in the currency. Both actions support growth in use of the currency. The presence of strong community groups amongst local businesses can also boost such schemes.

(George Ferguson, Bristol’s Mayor, whose salary is paid in Bristol Pounds . His red trousers are famous . Photo by PaulNUK)

Examples and stories:

The story of Hancock Bank’s actions to assist the citizens of New Orleans to recover from hurricane Katrina in 2005 is told in this video, and shares many of the values that local currencies are based on.

Hancock Bank’s actions were the result of senior management basing their decisions on the company’s purpose, expressed in its charter, to support the communities of the city. This is in contrast to the behaviour of Bob Diamond, who resigned as CEO of Barclays Bank following the Libor rate-manipulation scandal, who under questioning by parliamentary committee could not remember what the Bank’s founding principles, written by community-minded Quakers, stated.

Rose Goslinga tells the story of forming the Kilimo Salama micro-insurance scheme here.

Sources of information:

In addition to the sources already linked to in this pattern, Brett Scott’s “Heretic’s guide to global finance” explores a number of ways to adapt the traditional financial system to achieve social and environmental objectives.

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