The Learning City 1: Policy Transfer versus Mobile Urbanism

For city-to-city knowledge transfer, there are two slightly different conceptual models of how knowledge is transferred. First, there is the political science understanding of “policy transfer,” which describes an unstructured market of policy ideas that are adopted, transferred, or emulated to maximize reform goals (Peck and Theodore Reference Peck and Theodore2010). Put differently, policy transfer is a process in which “knowledge about how policies, administrative arrangements, institutions and ideas in one political setting (past or present) is used in the development of policies, administrative arrangements, institutions and ideas in another political setting” (Dolowitz and Marsh, Reference Dolowitz and Marsh2000: 5). The idea of policy transfer has increasingly been paired with the concept of learning in order to understand better how the information that is being transferred is shaped and used in the local context. This, in turn, has led to a discussion about different forms of learning, depending on the political pressure on, as well as the capacity of, policy-makers to adopt new ideas (Giest Reference Giest2016). Cohen and Levinthal (Reference Cohen and Levinthal1990) highlight that “learning capabilities involve the development of the capacity to assimilate existing knowledge” (quoted in Giest Reference Giest2016: 130). Learning also plays a role in related policy transfer models, such as Municipal International Cooperation (MIC) and city twinning. These are collaboration schemes among two or more cities aiming to transfer knowledge based on a formal relationship. By definition, MIC takes the form of a collaborative effort between local governments to stimulate knowledge exchange between their staff members, often on previously identified topics (van Edwijk et al. Reference van Edwijk, Baud, Bontenbal, Hordijk, van Lindert, Nijenhuis and van Westen2015). MIC tends to serve broader political goals, such as strengthening democracy and enabling city diplomacy relations, than city twinning. The idea of city twinning builds on a similar idea. Here, cities in distinct geographical and political areas are paired, mainly between North American or European cities and African or South American cities (Muggah Reference Muggah2014).

Next to policy transfer, there is a more recent approach referred to as “policy mobility” or “mobile urbanism.” This approach highlights the translational, networked, and multiscalar nature of urban policy (McCann and Ward Reference McCann and Ward2011). The main difference vis-à-vis policy transfer is that mobile urbanism includes a broader set of actors, going beyond policy-makers and bureaucrats to include players who can come from anywhere inside or outside the city. Examples include local policy-makers who use best practice cases from other places and global communities that are adapted to the local context. Here, practitioners emphasize the need to balance local impacts on the one hand and global flows of knowledge on the other (Dicken et al. Reference Dicken, Kelly, Olds and Wai-Chung Yeung2001; McCann and Ward Reference McCann and Ward2010).

When discussing urban policies in a digital age, the high degree of “mobility” of ideas is particularly relevant to data-driven innovation. Technology advances are fast paced, and if innovative solutions in a given city have proven successful, these can travel quickly to inspire policy-makers in other cities that face similar challenges. At the same time, this knowledge/policy transfer is often a highly political one, as there are struggles related to which policies are being framed as successes, thus empowering certain cities at the expense of others (Robinson Reference Robinson2006; McCann and Ward Reference McCann and Ward2010).

The Learning City 2: Knowledge Management within Cities

Before policies can travel between cities, the research and practice communities within a city play a crucial role in developing successful measures when it comes to introducing new routines and innovative practices (Mans and Meerow Reference Mans and Meerow2012). For big data applications, in particular, policy-makers are largely dependent on external advice and input from scientific institutions, technology companies, or related sets of experts to inform or guide decision-making. Knowledge or information management can thereby take various forms. In the urban context, researchers highlight the role of local citizens and their participatory role in the process of developing localized types of knowledge (Hordijk and Baud Reference Hordijk and Baud2006; Mancini and Súilleabháin Reference Mancini and Súilleabháin2016). With respect to big data applications in policy development, local governments have often relied on data collected by other actors in the city, or even at the national level. “The result,” they note, “is a highly fragmented and dispersed set of local level data” (Hordijk and Baud Reference Hordijk and Baud2006: 675). In addition, local knowledge is crucial for understanding how to account for biases in big data (that is, representativeness of the local community) and how to provide the required context for analysis (Taylor Reference Taylor, Gupta, Pfeffer, Verrest and Ros-Tonen2015). These necessities lead to an emphasis on building networks that connect the relevant stakeholders to enable a more critical reflection and improved understanding of the data, informed by local and contextual knowledge. As a report by the Aspen Institute (2012: 11) points out,

It is not enough to develop an infrastructure for transferring information and data. Cities need to invest proactively in a strategy that connects citizens and policy-makers to foster data-driven innovation. City authorities need to put in place a new type of digital communications environment and adequate mechanisms when integrating data-driven innovation as part of their operations and policy-making. Such changes can take the form of individuals, institutions, and/or technologies, as well as through importing models from other cities (Komninos Reference Komninos2002; Fuggetta Reference 236Fuggetta2012). In this process, it is important to account for the speed of innovation in data-related technology: it is increasingly difficult to keep a sufficiently up-to-date overview of all relevant developments, even if there are enough resources for a dedicated team of experts. Instead, city authorities increasingly have to rely on hybrid, international networks of experts that share best practices as these emerge from pilot projects around the globe (Verhulst Reference Verhulst2016).

Public Datasets

Although public datasets do not necessarily constitute a new type of data stream, digitization and the availability of new analytical capacities lead to an increased uptake of these data in policy-making processes. Data sources for policymaking now include, a.o. “real-time sensor data, public administration data (including open data), data from statistical offices, commercially traded data and several types of targeted or ad-hoc data” (Technopolis et al. 2015: n.p.). In addition, we observe the promotion of open data in the public sector and among NGOs, which leads to increased free availability of these datasets in machine-readable formats. The digital divide is still a major limiting factor in this form of data collection. Governments in non-OECD countries are generally much more reluctant – and less able – to make datasets publicly available.Footnote ³ Questions remain regarding the extent to which digital technologies can improve the collection of data in the developing world, and how much of this additional data will be made available for urban authorities (or other third parties) as a consequence.Footnote ⁴

Citizen Reporting

With access to mobile devices and the Internet on the rise, connecting to citizens is becoming cheaper, faster, and more reliable. This connectivity can be used for survey techniques based on Short Message Service (SMS), online feedback forms, and so forth. Collecting data in this way is often conducted through digital platforms, which can be run by public entities, private or community organizations, or as a joint effort. In various Kenyan cities for example, the NGO Sisi ni Amani applied SMS-based citizen reporting in order to reduce ethnic tensions across communities (Parker Reference Parker2011; Trujillo et al. Reference Trujillo, Elam, Shapiro and Clayton2013); other examples include violence monitoring at several protest sites in Bangkok throughout 2014, “in order to better understand the situation and track relevant developments” (Elva 2014: n.p.). Further, the Nairobi police have been experimenting with the use of cell phones to reach out to slum inhabitants in Mathare (Frilander et al. Reference Frilander, Lundine, Kutalek and Likaka2014). Even in such underserved areas of the city, mobile phone ownership is nearly universal, and approximately 50 percent of these devices are Internet enabled, which makes direct, real-time communication with citizens a possibility (whether by police or other public services agencies). Still, particular challenges can arise with regard to the validity and representativeness of the information provided by respondents in this style of big data collection (van der Windt, Reference Van der Windt, Livingstone and Walter-Drop2012).

Open Web Data

Online content has long been readily available in the form of websites, news archives, event reporting, and blog posts. This includes online platforms such as Global Dataset of Events, Language, and Tone (GDELT) or Armed Conflict Location & Event Data Project (ACLED) that provide event data,Footnote ⁵ or simply search engine tools that are available to any online reader.Footnote ⁶ New developments include a) an increasing number of methodologies making it possible to “scrape” the content of websites automatically without human oversight and b) the emergence of social media as an additional form of open web data. Popular platforms including Facebook, Twitter, Instagram, YouTube, and LinkedIn, as well as many other social platforms, offer various degrees of access to their customers’ data.

To be clear, the latter is a peculiar form of “open” data. Many of these sources are available to the general public, yet access to them is controlled by private entities. Depending on the aims and privacy restrictions that come with the use of this type of data stream, it is possible to derive relevant insights from what is posted online. These insights can be used for assessments of political preferences and social topics of interest extrapolated from Twitter messages (UN Global Pulse 2014), to verify flood damage across urban settlements using multiple social media platforms (Quaggiotto Reference Quaggiotto2014), or to analyze social patterns in relation to security/crime issues in the context of cities (Pfeffer et al. Reference Pfeffer, Verrest and Poorthuis2015). It is also to possible establish knowledge of social and political networks based on this data (O’Callaghan et al. Reference O’Callaghan, Prucha, Greene, Conway, Carthy and Cunningham2014; Bozdag et al. Reference 235Bozdag, Gao, Houben and Warnier2014). It is likely that many of today’s possibilities will evolve in the coming years. The key question is which open online data streams can be employed to gain relevant insights for users, and to what extent machine-readable is access granted?

Digital Breadcrumbs

The more people are connected to or work with digital technologies, the more they leave traces of what they do in their daily lives (Pentland Reference Pentland2012). This includes any type of consumption in digital form (supermarket purchases, cell phone airtime vouchers, or financial transfers). Even though this type of data is not necessarily representative, it can reach far beyond the middle class. For example, refugees receive vouchers in the form of e-cards that register what, when, and where people buy goods (WFP 2017; Flaemig et al. Reference Flaemig, Sandstrom, Caccavale, Bauer, Husain, Halma and Poldermans2017). To date, the most powerful form of these “breadcrumbs” are mobile phone data. There are a number of interesting experiments with cell phone data, for example, to detect crime hotspots in London (Bogomolov et al. Reference Bogomolov, Lepri, Staiano, Letouze, Oliver, Pianesi and Pentland2015) and understanding social ties across different communities in the Ivory Coast (Bucicovschi et al. Reference Bucicovschi, Douglass, Meyer, Ram, Rideout, Song, Blondel, de Cordes, Decuyper, Devlisse, Raguenez and Smoreda2013). Also, mobile phone data have been used in Afghanistan to determine changes in movement patterns after micro-violence, such as improvised explosive device (IED) explosions (World Bank 2014), and to develop new poverty monitoring methodologies in Senegal (Pokhriyal et al. Reference Pokhriyal, Dong and Govindaraju2015). However, digital breadcrumbs come with major caveats.On the one hand, these types of data streams are often proprietary and not accessible without prior negotiations with a commercial party, such as telecom providers or financial service providers. Second, the clients of these services do not generally know about (or consent to) their data being used (this is different, for example, than social media content, for which a certain degree of consent can be assumed). Even though analysis of digital breadcrumbs is generally done on an aggregated level without substantial risks of privacy infringements, full privacy does not exist: Most datasets that include personal data carry the risk that individuals can be reidentified (Berens et al. Reference Berens, Mans and Verhulst2016; OCHA 2016). Currently, standards for data sharing and data use simply do not exist to a degree that makes all stakeholders comfortable with experimentation with these types of datasets. However, sector-specific data use guidelines and related frameworks that help create trust and form new data collaboratives are likely to emerge over time (WEF 2015b; IDRG 2015; GovLab 2016).

Remote Sensing Data

Satellite images are a well-known source of data that are usually expensive, but are increasingly accessible, even for smaller organizations. This technology is based on sensors that have been placed in orbit, made possible only via monetary investments. The affordability of remote sensing has risen in part because common sensors are being placed nearly everywhere, from closed circuit television cameras to air quality sensors, track-and-trace devices in vehicles, and sensors required for the Internet of Things (for example, sensors in refrigerators, street lights, and so forth). An interesting example is the ability, through remote sensing, to “measure the quantity, timing, and locations of gunfire incidents with greater accuracy than do reported crime or 911 call data through sensors” (Carr and Doleac Reference Carr and Doleac2016: 4). This technology, called “Shotspotter,” is currently applied in the United States (ibid.). Shotspotter’s physical manifestation is a connected system of audio sensors on top of buildings that detects the sounds of gunfire and analyzes them for accuracy. If Shotspotter confirms the sound of gunfire, the program responds by sending a message to local police with the location of the shots fired. The data produced by Shotspotter – date, time, location, single/multiple gunshots – are publicly available.

Likewise, in the geospatial arena, the emergence of drones as a new type of cheap sensor increasingly impacts the way environmental data can be collected or verified. In disaster areas, for example, drones are already being used for quick damage assessments, and a growing number of experiments are underway to use drone-mounted cameras in the fields of agriculture or environmental protection in urban areas (see, for example, Meier Reference Meier2014). Affordable, high-resolution satellite imagery enables people to retrieve information about hard-to-reach places and conflict areas. For example, “Amnesty International requested the assistance of the Geospatial Technologies and Human Rights Project of the American Association for the Advancement of Science to investigate the veracity of reports of human rights violations stemming from the escalating conflict in Aleppo, Syria” (Amnesty International n.d.: n.p.).

These five types of data streams can have different applications in different contexts. Looking at the innovation landscape today, we see a number of cases that address aspects of urban violence, that is, policing, law and order, and related challenges. Examples of more structural approaches that use data-driven innovations to reduce inequality throughout the city are less common.Footnote ⁷ This is not a surprise, as many questions remain about the extent to which new data streams can complement classical data sources, especially in a developing country. Data are generally biased towards the digital haves and have-nots; we need to develop methodologies that make new data streams both representative and reliable. Table 11.1 gives an overview of the possible uses of these five new types of data streams for both the reduction of violence and inequality in urban contexts.

As discussed in the previous section, any of these applications requires a meaningful dialogue between those who work with the technology and those with contextual expertise regarding the location in which it will be applied. We are at the very beginning of the Data Revolution – much remains unexplored and untested; indeed, the use of new data streams in formulating city policies is far from mainstream. City authorities tend to start with existing data rather than tapping into new data streams. Moving forward, we need to improve our understanding of the underlying dynamics of knowledge transfers insofar as they relate to data-driven innovation. While still evolving, two examples, from Cali and Cape Town, highlight some of the lessons learned about knowledge transfer mechanisms that support data-informed policy.

Data-Informed Policy-Making

First, using big data is accompanied by risks of drawing misleading conclusions, such as assumptions about causes of violence that are drawn from public datasets, but do not apply to a specific region. Data analytics cannot simulate the complex picture of potential interactions of different policy domains, such as crime and infrastructure, or the dynamics among social groups in certain neighborhoods (Bollier Reference Bollier2010). The research community is skeptical of claims of universal urban experiences, stressing that contextual particularities and local experiences within places are important (Brenner and Schmid Reference Brenner and Schmid2015; Thakuriah et al. Reference Thakuriah, Tilahun and Zellner2015). It follows that conclusions drawn in cities with high crime rates do not automatically apply to other cities with similar statistics, but different local contexts. The example of Cali has shown that officials were too quick to assume that drug-related crime was driving up the homicide numbers when drug trafficking had only an indirect effect. However, the challenge is to strike an appropriate balance between automated analysis and contextual interpretation now that data are becoming more widely used.

The Politics of Data-informed Policy

Second, data can be political. When utilizing the information gained from data, political obstacles emerge in two ways. Data can bring to the surface insights that are uncomfortable to political stakeholders. Cape Town exemplifies a city uncooperative in data collection efforts, either because proposed data collection efforts were connected to regions in the hands of the political opposition or because data collection initiatives were branded as campaigns against the government (Consortium on Crime and Violence Prevention 2015). Furthermore, collaboration across political constituencies might prove difficult. Based on the insights from Cali and Cape Town, cross-stakeholder engagement emerges as a key dimension for deploying data-based initiatives in cities. Such engagement has been achieved in the form of regular meetings of heads of departments (Cali) or by involving citizens in data collection (Cape Town). Underlying this collaboration is the notion of trust – trusting that the data are put to good use by government, as well as trust in local stakeholders by the government. Moving towards more data-informed policies, city stakeholders will have to find meaningful ways to create mutual trust.

The elements discussed in this chapter call for a more thorough understanding of how advances in data-driven innovation could translate into new forms of urban policy-making – and how collaboration between various stakeholders and actors can be supported from the beginning to avoid inappropriate technology and policy designs. Much remains to be done to support decisions about which policies to adopt and when to be cautious in applying data-informed policy. From a research perspective, future studies should give clues about the interplay of additional, more detailed data being collected and the political repercussions this might have. If new data streams enable more accurate, but also more problematic, numbers for certain issues such as violence and poverty, the political opposition might outweigh the societal benefits that data-driven innovations provide. Overcoming these obstacles requires alignment between different stakeholders within the city, as well as paying attention to the timing and circumstances within which data-informed policies are developed.