Security, Privacy and Risks Within Smart Cities: Literature Review and Development of a Smart City Interaction Framework

The term ‘smart cities’ generally refers to the use of technology-based solutions to enhance the quality of life for citizens, improve interaction with government and promote sustainable development (Chourabi et al. 2012; Yahia et al. 2019; Yu and Xu 2018). A city can be described as smart where social, environmental and economic development factors are balanced and linked via devolved processes to more efficiently manage key assets, resources and urban flows for real-time processes (Komninos 2013; Yeh 2017). Smart cities are designed around an Information and Communication Technology (ICT) based infrastructure with Internet of Things (IoT) enabled sensor technology to support social and urban interconnectivity through greater citizen interaction and government efficiency (Albino et al. 2015; Alter 2019; Gupta et al. 2019b; Janssen et al. 2019; Lom and Pribyl 2020; Mamonov and Koufaris 2020; Manfreda et al. 2019; Yeh 2017). A number of cities throughout the world have embraced the smart philosophy and have either developed their infrastructure toward this new status or are actively pursuing strategies to adapt their existing assets and networks. These include London, New York, Paris, Amsterdam, Reykjavik, Tokyo, Busan, Dubai, Stockholm and Santander (Forbes 2019; Peris-Ortiz et al. 2016; Simonofski et al. 2019). The Government of India (GoI) has announced plans to develop 100 smart cities throughout the country to drive economic growth via the creation of technological solutions for citizen interaction (Praharaj et al. 2018). The top down, government led approach within China has led to a large number of smart city projects that are viewed as policy based decisions to potentially reshape economic structures, transform economic development, re-educate and enhance the competitiveness of workers and improve government capacity and efficiency in the context of energy management and environmental pollution (Yu and Xu 2018). The technology spending on smart city initiatives worldwide is currently $81 billion and predicted to reach $158 billion (US) by 2022, highlighting the significance attached to these city transformations (Statista 2019).

Smart city designers utilise modern technologies such as mobile cloud computing, electronic objects, networks, sensors and machine learning technologies to enable the different components of smart cities to cooperate and interact with the network architecture (Ismagilova et al. 2019b; Singh et al. 2019). The inherent complexity and new methods of citizen interaction required for the change to existing infrastructure, highlights the significant political, regulatory and technical challenges for governments and regional authorities. One of the key challenges in the development of smart cities is the processing and management of data. This relates to data already present within city databases but also the linking of data with new systems and sensors present within the smart city, that impact security and privacy (Van Zoonen 2016). The threats stemming from information security, data privacy and cyber-related factors where unauthorised access to information can cause undesired consequences, highlights the criticality of addressing these issues early within the design and development stage of smart cities (Chatterjee et al. 2019; Elmaghraby and Losavio 2014).

The literature has developed a number of studies that have presented reviews of the smart city literature (Albino et al. 2015; Anthopoulos 2015; Bibri and Krogstie 2017; Chatterjee and Kar 2015; Ismagiloiva et al. 2019a; Kar et al. 2019; Rana et al. 2019). However, researchers seem to have omitted to offer a meaningful analysis of the significant threats to data security and the inherent complexities surrounding privacy within smart cities. This research aims to bridge this gap in the literature by conducting a comprehensive analysis of the many issues and key complexities relating to privacy, security, and risk issues within smart cities. In alignment with the guidance in Pare et al. (2015), we conduct a theoretical review of current studies and available literature on privacy, security, and risks within smart cities and develop a smart cities security & privacy framework.

The current study aims to address the following questions:

The analysis and findings of this research are presented as offering an informative and timely framework for research on this topic, useful to academics and practitioners alike.

The remaining sections of the paper are organised as follows. Section 2 provides an overview of the methods used to identify relevant studies to be included in this research. Section 3 details the discussion of the emerging themes from the existing research on security and privacy in smart cities. Section 4 discusses many of the key aspects of the research in the context of significant challenges to the further development of smart cities and presents a conceptual framework on security and privacy issues. The study is concluded in Section 5. The limitations and directions for future research are presented in Section 6.

The approach utilised in this study aligns with the recommendations in Moher et al. (2009) and Kitchenham (2004). The study applied the following steps for systematic search of the relevant papers: (1) development of protocol; (2) filtration of research papers by title, keywords and abstract; (3) extraction of data from the selected papers.

Development of protocol. To identify relevant articles from the literature a keyword search was employed. The search was restricted to peer-reviewed research papers. A number of separate keyword searches were utilised, namely “Smart City” OR “Smart Cities” AND “Privacy” OR “Security” OR “Risk” were searched via Scopus database. The Scopus database was selected for this study as it includes a catalogue of more than 50 million records from approximately 20,500 titles and 5,000 publishers (Montoya et al. 2016). As a result, this database can be useful for searching and locating a substantial proportion of the published peer-reviewed research papers in the area of smart cities research. Additionally, by using online databases for conducting a systematic literature the search aligned with the emerging culture narrative, highlighted by a number of information systems researchers (Gupta et al. 2019a; Heidt et al. 2019; Hughes et al. 2019; Papagiannidis and Marikyan 2020; Tamilmani et al. 2020). From the Scopus database, only peer-reviews papers that were published in English were considered. The search resulted in 99 articles returned. This comprehensive search strategy allowed us to minimise source bias and return sufficient articles for a comprehensive review (Dwivedi et al. 2019).

The chronological view by volume of the articles on security and privacy within smart cities is presented in Fig. 1 and depicts the increasing academic interest over recent years.

The wider literature has tended to focus on a number of broad smart cities related key themes namely: the privacy and security of mobile devices and services; smart cities infrastructure and technical architecture; power systems utilised within smart cities; smart healthcare; security and privacy frameworks; algorithms and protocols; operational threats for smart cities; application of blockchain solutions within smart cities; and social media and smart cities.

Figure 2 presents the research themes and the percentage of papers grouped under each theme. The themes and related references are listed in Table 2. The subsections of the article generated discussion around each theme providing insights to research carried under the respective main themes

The advancement of smart cities throughout the world has enabled citizens to communicate with multi-levels of government, gain access to services and enhance the efficiency and effectiveness of system interaction leading to improvements in economic prosperity and quality of life (Nam and Pardo 2011; Yeh 2017). However, significant challenges remain in areas relating to privacy, security and risk from a number of stakeholder perspectives. The literature highlights how these many challenges can impact the benefits to citizens and expose vulnerabilities that could be exploited by third party organisations (Ahmed et al. 2016; Baig et al. 2017). Despite the significant opportunities and merits of IoT enabled smart environments, security and privacy are key factors that expose real threats to the secure operation of smart cities infrastructure (Ahmed et al. 2016).

The evolution of technology and transition towards an integrated digital society is likely to impact many cultural and societal aspects of daily life where the challenges of maintaining human interaction and a sense of belonging and identity, are an integral aspect of being human (Monzon 2015). The literature has presented how these factors can potentially constrain further development and jeopardise the realisation of benefits to citizens and wider stakeholders; where perhaps the interaction and human related factors are omitted (Chauhan et al. 2016; Degbelo et al. 2016). These challenges in the context of the security, privacy and risk within smart cities are outlined below:

This study provides a theoretical review of the smart city literature, focussing on the many threats relating to privacy and security, and how these can impact the operation of smart city processes. A number of emergent themes and significant challenges have been discussed to provide a valuable synthesis of the key factors relating to privacy and security threats within the smart cities literature. We posit this study as a comprehensive and relevant information framework for academics and practitioners analysing the many complexities and issues surrounding smart cities. As a result of the literature review, discussion and developed framework, a number of propositions were developed.

The analysis of the existing literature highlights that generally, studies seem to be lacking quantitative and also qualitative data on the adoption of smart cities. Some studies do include a case element to their research, but the recycling of lessons learned into new smart city initiatives, seems to be a key gap in the literature. The vulnerability of smart city infrastructure to data theft, unauthorised data access, system breaches, virus-based attacks and other threats to operational integrity, are likely to be ongoing as more cities transition to smart capability. The critical factors relating to technical and security governance of smart cities are key factors relating to operational integrity and citizen trust within the smart city infrastructure. Breaches of security that jeopardise data privacy are likely to severely impact citizen engagement and overall trust in smart city systems and services.

The greater focus on sustainability within the smart city infrastructure is likely to impact provision of services, transportation, eating habits and consumerism. The wellbeing and quality of life factors are directly related to these areas as citizens interact with new initiatives and adhere to changes that reduce emissions and reduce our carbon footprint. The links between feelings of safety and security and greater willingness for citizens to transition toward sustainability initiatives, could act as key drivers for smart city authorities to build in these aspects at an early stage.

The ongoing use of technology to provide the infrastructure and interaction that can deliver services to citizens, whilst offering new innovative platforms and systems many of which are available via mobile devices, risks disenfranchising key sectors of the population. The fast pace of technology that can delivery new and exciting ways to interact with healthcare providers, banks insurance companies, utility providers and transport operators, is likely to be a barrier for adoption for older demographics that do not share the same feelings of trust and enthusiasm from younger more technically aware population groups. The challenge for smart city designers and planners as innovations such as blockchain based systems and greater use of AI become integral to system architectures, is to maintain humans in the loop to engender the required levels of trust in security and privacy from citizens.

This study is somewhat limited due to the focus on security and privacy that perhaps may exclude a number of the human-centred factors that may impact the further adoption of smart cities. Further research is recommended to better illustrate the “lived in” experience of smart cities from the citizen perspective to quantify the many interaction and day to day operational complexities to engender greater levels of trust from the population. Furthermore, the current study considered only technological solutions to improve security, privacy, and operational threats. However, city infrastructure also includes legal and institutional dimensions. Future research should consider how the legal system can be used to solve trust challenges within smart cities. Additionally, it is advised that future research should focus on solving identified challenges of smart cities (trust challenges namely trust challenges, operational and transition challenges, technological challenges and sustainability challenges), which will greatly benefit further smart city initiatives.

More research is needed on the use of blockchain in smart cities. It is important that new government and industry regulations are developed with help to avoid disputes among the transacting parties (Krawiec et al. 2016). Additionally, it is important to consider the cost of deploying and operating a blockchain-based system within smart cities. Thus, it is important to perform a targeted pilot in order to test the potential cost of a blockchain-based smart city system (Xie et al. 2019), as well as to evaluate holistic models of societal value co-creation that consider thorough cost-benefit analysis to enable sound decision-making by government.

More research is required on smart cities’ complex institutional and technological environments (Gupta et al. 2020). Future studies could explore the role of leadership and orchestration, which manifested through openness, diffusion, and shared vision in smart city ecosystems (Gupta et al. 2020).

The substantial advances in smart city technological infrastructure have provided for many examples of smart city implementations. However, in order to ensure that benefits can be gained at a local level, as well as at a level that transcends the local community to embrace regional, national, and global dimensions. The current issues around heterogeneity, and lack of communication protocol and standardisation, and the mostly proprietary and close nature of such infrastructure, which currently prevent different ‘smart cities’ to communicate, need to be resolved (Allam and Jones 2020). A globally interconnected, transparent network of smart cities, and democratised access to the infrastructure could be a critical tool in tackling global health issues, such as virus outbreak (as in the case of the COVID-19 pandemic) by greatly enabling real-time and globally coordinated urban health management by access to, and monitoring of, a large number of critical sensory outputs. This line of thinking can also be extended to other global issues such as pollution and environmental monitoring, whereby a communicating network of smart cities would provide a step-change in the predictive ability of environmental models, with evident benefits for city dwellers, proactive policy development at regional, national and international levels (with regulatory, legal, economic and wider research implications that will inevitably accompany them), with the design and adoption of countermeasures at scale. The future research could also explore and learn from the successful adoption of information technology enabled citizen-centric services (e.g. Alryalat et al. 2015; Chatterjee and Kar 2018; Chaudrie and Dwivedi 2005; Dwivedi and Williams 2008; Dwivedi et al. 2007, 2017; Kapoor et al. 2014; Rana and Dwivedi 2015; Rana et al. 2013a2013b2013c2013d2015a2015b2015c2016, 2017; Weerakkody et al. 200720092017) and other IS success/failure projects (e.g. Hughes et al. 20162017a2017b2020) for the proposed smart cities in India.