2.1. Data justice

Taylor (Reference Taylor2017) operationalizes data justice as three pillars of fairness in the way people are made visible in and by data; how they engage with the technology around data and how they are treated as a result of the production of digital data. Key to this is sharing in the benefits of data use. However, identifying the parts of this process in order to enact justice is challenging. Dencik and Sanchez-Mondero (Reference Dencik and Sanchez-Monedero2022) underline that the complexity of data flows has made it impossible to identify where any one piece of data came from or has moved to, let alone who is accountable for its proper and just use. The users of the data can be located anywhere, and the subjects can be unaware of the use of their data.

Mann (Reference Mann2018) provides a vivid example of this, noting that data extraction from African-based organizations is often justified on the basis that it is being used for humanitarian purposes, while it in fact enables foreign companies to stake a claim on entire data ecosystems for future exploitation. This appropriation of data is not limited to specific geographies, nor of particular activities—virtually, any part of the everyday life that can be captured and repackaged as data is a potential venue for “data colonialism” (Couldry and Mejias, Reference Couldry and Mejias2019). On the flip side, those who are missing from data and thus invisible in datasets are equally disadvantaged (Milan and Treré, Reference Milan and Treré2020).

Inequity in data processes therefore can perpetuate inequities in society, much as bias in datasets can enhance bias in society when amplified by algorithmic effects. There is a considerable body of work regarding “fairness” in data and algorithms, but this largely focuses on improving access to or use of data, preventing biases within the data, and other principles for more ethical algorithms (e.g., Garcia, Reference Garcia2016; Wilkinson et al., Reference Wilkinson, Dumontier, Aalbersberg, Appleton, Axton, Baak, Blomberg, Boiten, da Silva Santos, Bourne and Bouwman2016). There is far less focus on the need for equity in data processes that prevent what Heeks and Shekhar (Reference Heeks and Shekhar2019), term, “problematic distributive impacts,” where the use of data further marginalizes already disadvantaged communities. As yet, it is not clear how these principles operationalize (Dencik, Reference Dencik and Sanchez-Monedero2022) or whether they actually affect equity of access, representation, and participation (Dodds, Reference Dodds2020).

One approach to increased fairness in data use is that of data autonomy. Data autonomy refers to an individual’s right to decide what happens to their data, as opposed to the right to simply keep it private (Fracassi and Magnusson, Reference Fracassi and Magnusson2021). This includes the willing sharing of data. It is a core tenet of the “freedom and autonomy” human right theme of the proposed UN Habitat Digital Rights Governance Framework for Cities (Lähteenoja et al., Reference Lähteenoja, Dominguez, Facchina, Westerberg, Nkuidje, Goodwin, Shale Sagar, Birchall, Blok, van Eemeren, Ramírez Chico, Pérez Batlle, Boet Serrano, Perrino, Portier and Manso2022). Initiatives such as the MyData principlesFootnote ¹ or the City of Helsinki Data StrategyFootnote ² have begun to acknowledge the human right of citizens to have autonomy over their data. However, assertion of such a right requires a workable framework for its enactment.

2.2. Smart cities

There are myriad definitions of what smart cities are and do (see Karvonen et al., Reference Karvonen, Cugurullo, Caprotti, Karvonen, Cugurullo and Caprotti2018 for a brief overview) and what concepts and activities fall within its purview. At the most implemented end is the ubiquitous “smartcard” such as Oyster in the UK, OV-ChipKaart in the Netherlands or LisboaViva in Portugal. At the most conceptual end of the spectrum lies the (abandoned) Sidewalk Labs and Toronto City “Quayside” project, with autonomous cars, intelligent rubbish collection, smart air quality measurement, and heated streets. The common denominator for a smart city is that it uses information and communications technology (ICT) with data to increase efficiency and improve services for its citizens (Nam and Pardo, Reference Nam and Pardo2011).

Essentially, “smart city technologies are enthusiastically seen as a solution to urban problems” (Borkowska and Osborne, Reference Borkowska and Osborne2018). Smart cities initiatives such as Open and Agile Smart Cities,Footnote ³ have catalyzed investment in infrastructure, enabling the monitoring of many aspects of city life: traffic, air quality, weather, parking, building repair, use of public space, energy consumption and more, creating tremendous amounts of data, which can then be used by private companies to create innovative solutions. Engagement with commercial organizations in this way often takes the form of digital innovation contests where a city or government agency presents an urban challenge and organizations compete to create pilot solutions (Mergei, Reference Mergel2017). In these contests, a municipal authority usually provides some financial and networking support, but the only core requirement of these solutions is access to data, which can be obtained by business in a number of ways. Almirall et al. (Reference Almirall, Lee and Majchrzak2014) note that such contests can sometimes be the venue of conflict between the partnership approach of the municipality, and the competitive approach of the business.

While there are many potential upsides of smart cities, there are conversely many criticisms. Whether smart cities are, in fact, drivers of social change is a matter of debate. Glasmeier and Christopherson (Reference Glasmeier and Christopherson2015) find that smart city technologies are rarely capable of improving quality of life for citizens, addressing problems such as failing schools, or encouraging inclusivity. Hence, the smart city context itself leans toward the inequitable. The processes may lend themselves to numerous potential harms to citizens, including dataveillance, inference, obfuscation, identification, performative consent (Kitchin, Reference Kitchin2016) and treating citizens as sensors (Dooley, Reference Dooley2021). Hollands (Reference Hollands2015) argues that the focus on large corporations working with government institutions for “urban entrepreneurialism” leaves little room for citizens to engage in these processes. Borkowska and Osborne (Reference Borkowska and Osborne2018) find that, in the context of the Glasgow Future City Demonstrator Initiative, funder priorities overruled citizen needs. More benefit for citizens could have accrued if there had been more communication with citizens about the planned smart solutions.

The “smarter” cities become, the more they rely on human involvement for successful implementations. If cities want to become smarter, they have to engage with the people who live in and are affected by their smart solutions (Gascó-Hernandez, Reference Gascó-Hernandez2018; Wachter, Reference Wachter2019). Engaging citizens in the development and improvement of new digital services increases their use, and reduces skepticism. This citizen engagement needs to involve a strong focus on data; but citizens are a notoriously challenging group to engage with data. This is for a number of reasons to do with skills, interest, awareness, incentives, and the sheer amorphous nature of the population (Worthy, Reference Worthy2012; Tinworth, Reference Tinworth2016). Attempts to involve citizens in decisions about smart city implementations have shown that this often involves bringing citizens on board with already existing plans, rather than adapting the plans to citizens’ needs (Breuer and Pierson, Reference Breuer and Pierson2021). Even where bottom-up engagement happens, “smart” solutions are often trialed experimentally and at small scale. This subverts otherwise inclusive participation mechanisms, as only a select few, skilled citizens actually engage in processes where more formal engagement would lead to better representation (Webster and Lelux, Reference Webster and Leleux2018).

2.3. Citizen engagement

Citizen engagement is a traditional way to gain citizens’ approval for projects in local politics. Many councils have established processes by which citizens can influence local development, especially, with regards to building and planning permissions, raise issues such as air pollution, or even distribute finances with participatory budgeting approaches. Citizens’ rights to engagement in policy decisions are enshrined in the Lisbon Treaty of the EU and the Council of Europe, and strongly supported by international bodies such as the UN (European Commission, 2001; Rosenzweigova and Skoric, Reference Rosenzweigova and Skoric2016). Similarly, the co-production of public services between municipal authorities and citizens has been a key international theme for over a decade (Bovaird, Reference Bovaird2007; European Commission, 2018b. Lämmerhirt et al. (Reference Lämmerhirt, Gray, Venturini and Meunier2018) describe how governments can actively involve citizens in campaigns to enable better policy-making.

However, citizen engagement is often found lacking actual engagement with citizens’ views and preferences, or power transfer to citizens. Instead, citizens are often “engaged” in processes that appear to give them influence, while actually manipulating them to rubber-stamp decisions by other stakeholders (Arnstein, Reference Arnstein1969). Arnstein’s ladder of participation is a useful tool to assess the validity of engagement based on the role citizens play, which are classified into the categories of nonparticipation, tokenism, and citizen power. Borkowska and Osborne (Reference Borkowska and Osborne2018) also acknowledge that active citizen engagement is not always possible.

White (Reference White1996) also offers a classification of citizen engagement, based on the intentions of the engaged citizens and those who engage them, distinguishing nominal, instrumental, representative, and transformative engagement. She notes that not all engagement is meant to transfer power, and that there are different ways in which citizens can benefit from engagement, even if they do not make decisions. Thus, while some engagement may appear unjust in terms of direct benefit, there can be other, intangible benefits. If the benefits on both sides are sufficient to justify their respective activities, these can still be valid forms of engagement.

Citizen engagement in innovation can take many forms, such as bottom-up development of new ideas by citizens, citizens participating in market research, crowdsourcing, or co-production between citizens and companies. Involving citizens in innovation processes helps to ensure that those innovations actually meet citizens’ needs, increases diversity and legitimacy, and supports “buy in” from citizens for the results (Simon and Davies, Reference Simon and Davies2013). It can also reduce the cost of innovation (Nesti, Reference Nesti2018).

One form of engagement specifically suited to R&I is citizen science: The involvement of the general public in scientific research activities (European Commission, 2014). However, even in this focused engagement, citizens do not always benefit from projects in which they participate. In their study of the practical application of data justice in citizen science projects, Christine and Thinyane (Reference Christiane and Thinyane2021) found that data processes in some projects were inherently unjust, as the benefits of the data were limited to the hosts of the projects. One such example is the use of citizen labour to create digital data for the UK Met Office’s Old Weather project,Footnote ⁴ which is subsequently used for financial gain, without returning expected benefits to the citizens who generate that data.

3.1. Case study selection

Air pollution is an area of data-driven innovation that is a major area of focus for cities and public innovation funders, including UK R&I, and European R&I funding. The problem of air pollution contributes not only to global warming, but also increases individual health risks, especially among vulnerable groups (European Environment Agency [EEA], 2020). In December 2020, air pollution was for the first time recorded as a cause of death in the UK (Laville, Reference Laville2020).

Data-driven air quality projects make good subjects for the investigation of data justice for citizens. It is almost impossible for citizens to avoid being the subject or object of air quality smart city initiatives. By simply existing, citizens affect air quality. Citizens cannot opt out of data gathering if they live or work in the studied area, and cannot avoid what Couldry and Mejias (Reference Couldry and Mejias2019) call, “the flow of everyday life” being “reconfigured and re-presented in a form that enables its capture as data.” Therefore, they have no natural agency in how they engage with this data and its use for innovation (Taylor, Reference Taylor2017). Further, it is difficult to see how they can opt out of any air quality initiatives implemented as a result of data-driven innovation projects.

Air quality impacts many aspects of life. Primary amongst these is health. Poor air quality is a top cause of non-communicable disease. Improving air quality is a key global health challenge. It can be affected by dimensions such as time, weather, traffic, events, or street layout.

Air quality is also unequal. A study by the UK Department of Fisheries and Rural Affairs (Pye et al., Reference Pye, King and Sturman2006) found correlations between certain pollutant particulates and areas of urban deprivation. Within cities, often the most densely populated, deprived areas also suffer the most air pollution. This makes air quality a politically sensitive issue. Authorities can be reluctant to publish detailed air quality data openly, unless accompanied by a strategy for its improvement.

The projects we have chosen to review are both part of EU funded R&I strategies for smart specialization (RIS3) programmes. Consequently, the projects have clear terms of engagement and are part of a much wider picture of funding and innovation.

While citizen engagement should be active (Arnstein, Reference Arnstein1969), the reality is that it is often passive, and benefits indirect, as described by White (Reference White1996) Therefore, analyzing cases with explicitly high levels of citizen engagement, although vital, is not fairly representative of what actually takes place in many of these programs and projects. By analyzing projects that are not attempting at the outset to attain high levels of citizen engagement, it is easier to assess where the issues of data justice may lie, while more accurately reflecting reality. Further, most projects of this type (in digital innovation contests) are not “successful,” that is, they do not lead to full implementations. Therefore, it is important to look at how citizens may lose out where projects do not lead to the creation of implemented value. While case studies should not be over relied on as being representative of anything but their own situation, this context makes it productive to extrapolate learning and insight.

3.2. Analysis

The analysis was based on 11 relevant documents from both programmes, as well as four interviews with key stakeholders (two of these had more than one participant). A complete list of all documents and interviews, with links to public documents where these are available, is provided in Appendix A. Documents were collected from project files to which the authors had access. They were selected based on relevance to the funding distribution, and the specific cases. The coding was performed inductively, in that the codes arose from our analysis. All documents were thematically coded for the data in question, the objectives set out by the respective stakeholders, the stakeholders considered, and the engagement of citizens. This gave us an overview of the circumstances under which the projects were set up, and the priorities at the outset. We further supplemented this document data with four semi-structured interviews with relevant stakeholders from the projects. All interviews were conducted online or by phone between January and March 2020, and were between 25 and 40 min long. They focused on the project plans and implementation, especially on the role of citizens in them; stakeholders’ views on what engagement was, or should have been, conducted; and where applicable, how and why they fell short of those expectations. All interviews were transcribed and subsequently analyzed in the same framework developed through the document analysis.

In the next section, we present the complete case studies of the two European funded programmes, the air quality challenges, the SME involved, and the activities in the respective programmes.

4.1. Data Pitch

Data Pitch (DP)Footnote ⁵ was a Horizon 2020 programme that ran from 2017 to 2019. It was an open innovation program bringing together corporate and public sector data-holding organizations with start-ups and SMEs, specializing in innovating with data. It aimed specifically to, “create value from sharing data.” (DP GA) From its outset, it aimed to develop the European innovation ecosystem with data-driven business-to-business collaborations. Part of the programme consisted of challenges that offered access to data by large organizations for the purpose of developing new solutions. Across 3 years, DP managed the sharing of data from 13 large organizations to 47 SMEs.

4.2. Smart Cities Innovation Framework Implementation

Smart Cities Innovation Framework Implementation (SCIFI)Footnote ⁶ was an Interreg2Seas funded programme, running from 2018 to 2021. It addressed RIS3, specifically the technological and social innovation program priority objective SO1.1: to improve the framework conditions for the delivery of innovation. The aim of the program was to increase the capacities of cities in the region for technology transfer, stimulate innovative sectors of the regional economy, and increase quality of life in the cities. It also aimed at increasing the capacities of innovative companies to engage in international activities. Like Data Pitch, SCIFI used the challenge format to engage businesses to use city and other data to address public sector problems.

4.3. HOP Ubiquitous

HOP is a Spanish company with around 25 employees specializing in Internet of Things (IoT) technologies, such as sensors and related analysis software. Their main market is environmental monitoring solutions.

4.4. EU research and innovation strategy and the quadruple helix

Research and innovation strategies for smart specialization (RIS3) has been a key concept in EU policy since the nineties. It requires regions across Europe to engage in an entrepreneurial discovery process that supports the implementation of R&I. The EC’s guidance notes for RIS3 recognize the need for a participatory governance of science and technology, and argue the benefits of the quadruple helix approach (Deakin et al., Reference Deakin, Mora and Reid2018). Helices framework theory is a way of conceptualizing the knowledge flows and processes that result in and institutionalize economic growth via innovation and entrepreneurship (Etzkowitz and Zhou, Reference Etzkowitz and Zhou2017). The quadruple helix—where the actors are government, academia, business, and civil society—has been part of the EU’s R&I strategy since 2012 (European Committee of the Regions et al., Reference Volpe, Friedl, Cavallini and Soldi2016).

The programmes that constitute our case studies are explicitly quadruple helix focused. The role of businesses and developers in EU open data policy is to exploit the data for economic value and job creation, via engaging in open innovation with data (Lassinantti, Reference Lassinantti2014). However, the positing of citizens as both users driving innovation and participants in the creative process (Yawson, Reference Yawson2021) opens the door to open innovation that involves a wider group of stakeholders. The idea of co-production or co-creation has been present over the last few decades and now appears in the documentation for Horizon Europe (European Commission, 2018a).

4.5. Cascading funding

EU cascading funding is a technique to redistribute funding to organizations who would be unable to apply for it at its source. Recipients of such grants are commonly start-ups, SMEs or non-governmental organisations (NGOs),completing a specific set of activities, who become subject to the same contractual framework and financial obligations as recipients of the original grant. Cascading funding is part of the implementation of the EU R&I strategy, and the awarding programmes need to ensure that funded projects adhere to those rules, and the wider objectives of the funders and their specific grant. Ideally, cascading funding processes translate the original goals and objectives of the source funders, through the intermediary programmes running the call, to the organizations implementing the innovation project with their grants. The cascading funding process in SCIFI and Data Pitch is outlined in Appendix B.

4.6. The data challenges

The specific data-providing partner relevant to the air quality challenge in DP was the UK’s Met Office (MO), a government trading company and recognized global leader in weather and climate science, technology, and services. The MO challenge was quite wide, and sought solutions and opportunities in using weather data to drive innovative techniques and support communities, for example, in retail (supporting the value chain) or advisory services, for example, When is a good time to cycle based on a route planner? The data provided by the MO were aggregated historical pollen data collected by the MO and not as yet available openly. HOP was successful with an application to work on this data with the intention to improve local governments’ and civil servants’ ability to make decisions about air quality policy and urban planning. Their proposed solution was intended to increase the understanding of these factors, and enable more accurate predictions for mobility and tourism.

The air quality challenge in SCIFI was presented by the Flemish cities of Bruges and Mechelen, who, in addition to general transport and industry pollutants, have built environment issues where pollutants become trapped by air recirculation between narrow buildings (urban canyons). The cities sought data on the causes of pollution, and a way for them to formulate this evidence into impactful policies for improved air quality for citizens. HOP was selected by both Bruges and Mechelen to address their air quality challenge. They were the only SME working in Bruges, although Mechelen also selected another company, Nazka, to address the same challenge. The cities’ goal was to use and publish open data. At the beginning of the project, the only data available was from the EU Copernicus data hub.Footnote ⁷ To collect local and specific data, HOP aimed to place air quality sensors in seven locations in different circumstances, to find differences in concentrations with a lot of traffic, green spaces in the city, and rural areas close to the city. These sensors were intended to track multiple gases, particulate matter, temperature, humidity and noise levels, alongside a weather station, to find correlations with (high) temperature, rainfall or wind. The intention was for those sensors to continuously send data to a platform every minute. The data would then be published as real time open data, and presented in dashboards for consultation by interested city departments and citizens, and also in a machine-readable format.

The DP challenge was completed, although the pilot did not then progress to full implementation, due in part to a change of personnel and goals within the MO. The SCIFI pilot was beset with multiple problems on the ground, including Spanish sensors that did not appreciate Belgian temperatures, and issues regarding compromised locations and poor connectivity. This is not uncommon; “real world messiness” such as dust, wind or even a fingerprint, can interfere with the digital perfection of data (Sambasivan et al., Reference Sambasivan, Kapania, Highfill, Akrong, Paritosh and Aroyo2021). Mechelen now plans to fund citizen scientist-developed low-cost sensors, trading lower accuracy for reduced implementation cost. Bruges has started work with another commercial partner, and is exploring options to work with local citizen scientists in the future.

8.1. Limitations

A case study is by its very nature limited to individual cases. It is illustrative of only the example under exploration. We do not attempt to say every project would be like this, only to show how under certain circumstances, projects can be like this. We still believe that the insight generated from our comparison highlights some inherent weaknesses in data innovation projects, along with recommendations for their mitigation.

8.2. Future work

We plan to test and further investigate the engagement of citizens in program challenges; explore the use of citizen science data for innovation; and develop the idea of data justice plans, by developing a template, and a workable integration into data management best practice. These aspects will be implemented in one of the new Horizon Europe grants: Impetus builds on the cascading funding and innovation acceleration models of DP, SCIFI, and ACTION,Footnote ⁸ to support citizen science project implementations across Europe.Footnote ⁹