National approaches for citizen data management in response to COVID-19: An overview and implications of contact tracing apps in 21 countries

5.1.1Case #1 – China: Health Code mini-program

First released on Feb 9th 2020, China’s Health Code is a mandatory digital contact tracing tool that uses telecommunication technology and Q.R. code scanning as its sensor technology to collect citizens’ personal information, including their name, I.D. number, phone number, home address, and their travel history (Akinbi et al., 2020; Chowdhury et al., 2020; Utz et al., 2020). While the official did not reveal the protocol of the mini-program, we know that the mini-program uses a centralized framework that stored the data in a central server managed by the government (i.e., the State Information Center and the National Health Commission of China) and technology companies (i.e., Alibaba and Tencent) (Zhu & Wu, 2020). Specifically, it is integrated as a mini-program into Alibaba’s Alipay app and Tencent’s Wechat app, the two most-used apps in China, to guarantee the widespread and coverage of the Health Code – by Feb 2021, the contact tracing mini-program has reached around 65% coverage of the whole population in China and complete coverage of travelers (China Internet Network Information Center 2021; Li & Guo, 2020; Yang et al., 2021; Zhu & Wu, 2020). Based on the data, the app evaluates the health status of the individual and generates a health color: green refers to healthy (unrestricted movement), yellow refers to observation required (suggestion of self-isolation), and red refers to dangerous (mandatory self-quarantine) (Chowdhury et al., 2020; Yang et al., 2021). As the first mandatory digital contact tracing tool worldwide, China used the Health Code efficiently and effectively to prevent the further expansion of the pandemic. However, it meets some critics and doubts on the privacy issue – researchers argue that the central government and the Communist Party overly collected personal information from citizens, and this information might be used for surveillance by the government post-COVID-19 (Chowdhury et al., 2020; Kluth, 2020).

5.1.2Case #2 – India: Aarogya setu app

Developed by the National Informatics Centre (NIC) under the Indian government, the Aarogya Setu app was launched in April 2020 and in more than 12 Indian languages (Gupta et al., 2020). The app is designed to include four sections, which are 1) health status, 2) self-assessment, 3) COVID-19 news update, and 4) E-Pass. Among these four sections, the “health status” section plays the most part for contact tracing, in which the app uses both Bluetooth and GPS as sensor technology to track and collect citizens’ contact and location data (Ahmed et al., 2020; Basu, 2021). The app uses GPS and Bluetooth because it can use the GPS data to identify and predict hotspots for the possible virus infection areas. The app uses a centralized framework – after individual’s contact and location data is collected, his/her data will be stored both in his/her mobile phone and the central server. Once the individual is infected, the app will receive real-time infection information from the Indian Council of Medical Research database, and the app will then request the infected individual to share contact data. After getting approval from the infected, the app will upload the data stored in the central server to the government (Basu, 2021; Gupta et al., 2020). Interestingly, the Indian government initially refused to open their code for this app for the sake of national security issues. But their lack of transparency met critics, and later the government agreed to openly share their code. The app is mandatory by the Indian government for people who work in public and private sectors and those who live in the containment zones (Ahmed et al., 2020; Chowdhury et al., 2020). By Jan 2021, the app’s adoption rate has reached 12.05% nationwide (MIT Tracker, 2021).

5.1.3Case #3 – Indonesia: PeduiLindungi app

Developed by the Indonesian government (i.e., the Communications and Information Ministry and the State-Owned Enterprises Ministry) and launched on Apr 10th 2020, the PeduiLindungi app uses both Bluetooth and GPS as sensor technologies to notify citizens of the high-risk zone and track their contact and travel history (Amann et al., 2021; Fachriansyah & Syakriah, 2020). The app requests permission to access to users’ location and camera, as well as users’ complete names during the app registration (Shepherdson & Boxall, 2020). By knowing users’ location and real names, the app is able to notify users when they are close to the red zone, the area where infected cases are reported (Lin et al., 2020; Indrapati et al., 2020). In addition to the notification function, new features “digital diary” and face recognition were added to the app to record the citizens’ locations (by scanning Q.R. code) and check if the citizen has worn a mask before entering public areas (Lin et al., 2020). According to Communication and Information Technology Minister Johnny G. Plate, “the data will be archived and converted into Q.R. codes that will be sent to the Health Ministry,” and the app uses a centralized framework in data storage (Marchelin, 2020).

5.1.4Case #4 – Israel: HaMagen app

First launched in Mar 2020, Israel’s HaMagen app, which used GPS for data collection, was criticized for the inaccuracy of false positive. After that, the Health Ministry of Israel revamped the HaMagen app by using both Bluetooth and GPS to guarantee the accuracy and efficiency of the contact tracing app, and it is re-launched on Jul 27th 2020 (Sokol & Staff, 2020). The app collects location-based personal data, which is identifiable information for the infected. Therefore, even if the app uses a decentralized framework for data collection (which means that the data will only be stored on the individual’s mobile device rather than any central server and will be shared with the government only after the individual is confirmed infection and agrees to share), citizen privacy is still at risk when compared to other decentralized apps (Sönmez & Celik, 2020; Sun et al., 2021). Despite the privacy concerns, the app enjoys an adoption rate of around 25% (MIT Tracker, 2021) due to its mandatory compliance policy. It is noteworthy that the contact tracing app is developed by Shin Bet, Israel’s internal security service. The successful development of the HaMagen app means that Shin Bet gains more power over people’s individual data (Sönmez & Celik, 2020).

5.1.5Case #5 – Malaysia: MyTrace app

Malaysian government developed three main applications to manage COVID-19 at the state level, which are 1) MyTrace for contact tracing, 2) Gerak Malaysia for monitoring interstate travel, and 3) MySejahtera for self-assessment of health status and latest information about the pandemic (Bunyan, 2020; Yatid, 2020). To supplement the MySejahtera app, MyTrace app tracks and records citizens’ contact history via Bluetooth and is released after the release of MySejahtera (“COVID-19: ‘MyTrace’ app”, 2020). According to Shepherdson and Boxall (2020), little information has been revealed on how citizens’ data is processed within the app. According to MIT Tracker (2021), the voluntary MyTrace app uses Bluetooth as sensor technology, and decentralized data storage as framework.

5.1.6Case #6 – Philippines: StaySafe.ph app

Released on Sep 3rd 2021, the Philippines’ national contact tracing app StaySafe.ph is developed by a Manila-based private company Multisys Technologies Corp and is funded by the central government (Department of the Interior and Local Government (DILG), Republican of The Philippines, 2021). Upon its launch, the app received support from big private companies in the Philippines, such as S.M. Supermalls, McDonald’s, and Jollibee Foods Corporation (Moaje, 2020). Despite its financial support towards the app development, the Philippines government still tried to develop its own national contact tracing app in Oct 2020, one month after the launch of StaySafe.ph, because the government has security concerns over this private-company-developed app (Salaverria, 2020). But soon, in November 2020, the national government announced that 1) the use of StaySafe.ph app is mandatory for staffs in national and local government agencies, and 2) the respective contact tracing apps used by local governments need to integrate into the national contact tracing app StaySafe.ph (Salaverria, 2020; Aguilar, 2021). It is because the national government already set safeguards to guarantee data protection from the private developer company, and the app uses a centralized framework that individuals’ data is stored in a central server that is managed by the government. Philippine’s StaySafe app uses Bluetooth as its sensor technology for data collection and is voluntary for citizens (Shahroz et al., 2021).

5.1.7Case #7 – Singapore: TraceTogether app

Launched by the government on Mar 20th 2020, Singapore’s TraceTogether app is one of the pioneers of the contact tracing apps worldwide. It uses Bluetooth and Q.R. code scanning as its sensor technology to collect citizen data, and uses the app protocol of BlueTrace – it gives citizens random time-varying tokens as their TempID to protect the infected’s personal information from snoopers; once the citizen is confirmed infection, the notification will be given to the close contacts of that individual from the government without sharing identifiable information of the infected to protect them from the contacts (Ahmed et al., 2020; Cho et al., 2020; Chowdhury et al., 2020). Despite the protection of the infected from other citizens, TraceTogether app did not protect the personal information of the infected from the government because the app uses a centralized framework and all citizens’ information (including the identifiable personal data and their close contacts’ phone number data) is stored in a central server managed by the government, and will be uploaded to the government once the infected are confirmed and agree to share their data with the government (Cho et al., 2020). Originally when the app was first launched, citizens’ adoption of the TraceTogether app was voluntary, leading to a low download rate of 25% two months after its release (Bahaudin & Wong, 2020). The government merged the TraceTogether app with the SafeEntry system, a digital check-in system for public areas to boost its download rate. By doing so, the so-called “voluntary” TraceTogether app is de facto mandatory in terms of public adoption. The Singapore government announced officially on Oct 20th 2020 that the TraceTogether will become mandatory by December 2020 and did the pilot in cinemas from Oct 19th (Wong, 2020). With this de facto mandatory policy, TraceTogether app and its token enjoy a public adoption rate of 80% by Jan 2021, which is the highest among all countries worldwide (Tham, 2021).

5.1.8Case #8 – South Korea: Corona 100m app

While it is the government who developed the digital contact tracing tool in most countries, South Korea’s Corona 100m app is developed by the private sector, of which the representative developer is Bae Won-Seok (Kluth, 2020; Watson & Jeong, 2020). Launched as early as Feb 11th, 2020 (only two days later than China’s launch of the Health Code mini-program), the Corona 100m app is one of the first contact tracing apps worldwide and is famous for its discounted privacy issue and trade-off with collective safety (Cho et al., 2020; Chowdhury et al., 2020; Kluth, 2020). More specifically, the app not only uses GPS to track individuals’ locations but also uses the data released in the public database of the government, such as footage from Closed Circuit Television (CCTV) cameras and credit card transaction records, to track individuals’ travel histories (Chowdhury et al., 2020; Kluth, 2020; Law & Choon, 2020; Mora et al., 2021). The app gains its name of “Corona 100m” because it will alert people with the possible infection if the app finds that they are passing by a place once visited by the infected within 100 meters (Wray, 2020). With the GPS and public databased as data collection method and the centralized data storage, the app can easily identify the personal information such as name, gender, and close contacts of the infected, but the download of the app is voluntary (Cho et al., 2020; Kim, 2020). While the biggest concern for this app is the privacy issue, Korean citizens seem to be fine with this invasion of personal information, for the sake of collective good. Kluth (2020) explained it in the cultural perspective and stated that this way of contact tracing would not fly in western countries; Akinbi et al. (2020) analyzed in the perspective of law and argued that laws that approve the government to collect and publish citizens’ personal data of the infected passes after the breakout of MERS in 2015.

5.1.9Case #9 – Thailand: Mor Chana app

The Thailand government co-developed with private sectors and released their version of contact tracing app – Mor Chana app (which means “doctors win” in Thai), on April 10th 2021, using both GPS and Bluetooth as its sensor technologies in the data collection (Shahroz et al., 2021; “Taweesilp clarifies ‘Mor Chana’ confusion”, 2021). Thai government’s attitude toward the compliance policy of citizens’ use of the app experienced a U-turn: despite the initial “recommend” attitude, the Centre for COVID-19 Situation Administration (CCSA) spokesman Dr. Taweesilp announced a few days later that people would get punishment (e.g., an up-to-40,000 baht-fine or 2-year imprisonment) if they do not use the app. He later apologized via his Facebook page that it is not mandatory and there will be no punishment if people do not use it, after receiving public criticism (Bangprapa & Wipatayotin, 2021). The Mor Chana app received critics because it failed in protecting citizen data – it uploads citizens’ individual data automatically to the central server and collects citizens’ location data via GPS (CTN News, 2021; “Taweesilp clarifies ‘Mor Chana’ confusion”, 2021). Despite the voluntary compliance policy, the app reached a download rate of more than 50% by Jan 2021 (MIT Tracker).

5.1.10Case #10 – Vietnam: BlueZone app

Launched on Apr 18th 2020, the BlueZone app is developed by the Ministry of Information and Communications in Vietnam (Shahroz et al., 2021). According to Li and Guo (2020), the BlueZone app uses Bluetooth as its sensor technology for data collection and decentralized framework for data storage. It reached 20% adoption rate in 2021 (MIT Tracker 2021). Nevertheless, not much information about Vietnam’s BlueZone app has been exposed on media till now.

5.2.1Case #11 – Austria: Stopp corona

As one of the first countries to launch the contact tracing app, Austria launched its national contact tracing app Stopp Corona on Mar 25th 2020 (Amann et al., 2021). This voluntary app’s birth signals a perfect partnership between the Austrian government and the Austrian Red Cross (Accenture, 2020). In particular, the Austrian Red Cross was delegated by the government, and asked Accenture, an American-Irish company, to develop the contact tracing app for the country (Li & Guo, 2020). The app adopts a decentralized framework that individuals’ data is stored in a cloud server hosted by the Red Cross rather than the government – the Red Cross as a mediator controls whether the individuals’ data will be uploaded to the government or not (Bock et al., 2020; Fritz & Klimpfinger, 2020).

5.2.2Case #12 – Finland: Koronavilkku app

Released on Aug 31st, 2020, the Koronavilkku app was jointly developed by the private companies Solita and SoteDigi, as well as the government agencies Kela (i.e., The Social Insurance Institution), Ministry of Social Affairs and Health, and the Institute for Health and Welfare (THL) (Ministry of Social Affairs and Health, Finnish Government, 2020). While strongly recommended by THL, the download and use of the app are voluntary. In addition, governments’ control over citizen data is minimal – based on the THL official website,33 the Finnish government uses the app protocol of Apple-Google API exposure and the decentralized app framework to store citizen data, and uses Bluetooth alone as its sensor technology to collect data. THL announced on Jan 7th 2021 that Finland’s Koronavilkku app was able to interoperable with national contact tracing apps from other E.U. countries, including Germany, Italy, Ireland, Spain, Denmark, the Netherlands, and Poland.

5.2.3Case #13 – France: TousAntiCovid app

The TousAntiCovid app, where “Tous Anti Covid” refers to “everyone against COVID-19”, is a relaunched app after the failed launch of StopCovid, the first version of the contact tracing app (Sun et al., 2021). The first version StopCovid is launched on Jun 2nd 2020, while the rebranded TousAntiCovid app is launched on Oct 21st. The government relaunched the app to have more functions besides contact tracing (Dillet, 2020a). France’s contact tracing app is a rebellious one among its European counterparts. For example, firstly, it develops its own app protocol rather than uses the Apple-Google API or other protocols such as BlueTrace (which is used by Singapore and Australia). France’s self-developed protocol ROBust and privacy-presERving proximity Tracing (ROBERT) is developed by research institutes INRIA in France and Fraunhofer in Germany and several private companies (Ahmed et al., 2020; Dillet, 2020b). Secondly, France uses a centralized app framework for their data storage, different from most European countries that use decentralized frameworks. Based on Ministry of Solidarity and Health in France (2020), the government hesitated between the two frameworks and finally chose a centralized one because it could offer more data security than the decentralized one – the centralized framework prevented the list of contact information from leaking because the data will not store on citizens’ individual mobile devices.

5.2.4Case #14 – Germany: Corona-Warn-App

Launched on Jun 16th 2020, Germany’s Corona-Warn app is developed by the Robert Koch Institute (RKI) (Ahmed et al., 2020). The Corona-Warn app uses the protocol of the Apple-Google API, and uses Bluetooth as its sensor technology to collect non-identifiable information of the citizens (Utz et al., 2020). Eigen and Gasser (2020a) explained in detail the app’s working mechanism: the mobile devices generate and exchange randomized I.D. with the app users nearby, and once the citizen is diagnosed and agrees to share his data with the government, the unidentifiable information will be shared with the government. Meanwhile, the app will send notifications to the close contacts a warning message, together with their risk level according to the distance and duration between them and the infected citizen. The app uses the decentralized app framework. Due to historical reasons, transparency and decentralized data collection is an important and sensitive topic to Germans (Eigen & Gasser, 2020a; Kluth, 2020). After experiencing the centralized data collection method used by the Nazi Gestapo, Germans select the decentralized app framework and openly share the app’s code on Github (Eigen & Gasser, 2020a; Kluth, 2020). The Corona-Warn app has been downloaded 22.8 million times until Nov 19th 2020, among the 83.78 million populations in Germany, which means it already covered around 30% of Germany’s whole population (Beierle et al., 2020).

5.2.5Case #15 – Italy: Immuno app

The Italian Ministry of Health and the Minister of Technological Innovation developed their national contact tracing app Immuni and released it on Jun 1st 2020 (Italian Government Tourist Board, 2021). According to the Immuno official website,44 the Italian government emphasizes the citizen data protection of this contact tracing app by using Bluetooth alone as its sensor technology, and guaranteed that the app will not collect location data (no GPS), or any other personal information, such as name, date of birth, or telephone number during registration. The app uses a decentralized framework that the citizen data is stored on citizens’ individual mobile phones rather than a central server, and the download of the app is voluntary. It is noteworthy that Italy is the first country following China that has been in the emergency situation dealing with COVID-19 infection. This partially pushes Italy to become one of the first batches to launch the contact tracing app, especially among European countries.

5.2.6Case #16 – Switzerland: SwissCovid app

The Switzerland government launched the SwissCovid app on Jun 25th 2020 with the protocol DP-3T self-developed by the Swiss Federal Institute of Technology Lausanne (EPFL) and Swiss Federal Institute of Technology in Zurich (ETH) (Eigen & Gasser, 2020b). With the similar philosophy of data management, the government fine-tuned the DP-3T protocol after the announcement of the Apple-Google API protocol to make sure the app is compatible with iOS and Android systems (Leprince-Ringuet, 2020). Like most contact tracing apps in Europe, the voluntary SwissCovid app uses Bluetooth alone as its sensor technology in data collection and stores data in the decentralized framework based on Apple-Google API protocol (Ahmed et al., 2020; Eigen & Gasser, 2020b).

5.2.7Case #17 – U.K.: NHS COVID-19 app

The development and design of the digital contact tracing app in the U.K. experienced a major U-turn: England’s National Health Service (NHS) launched the centralized contact tracing app in May 2020, and changed it into decentralized framework after the failure in trial implementation (Kent, 2020). The second version of NHS COVID-18 app is launched on Sep 24th 2020 (Burgess, 2020). In particular, the first version app which used the centralized framework confronted failure in its two-week pilot launch trial in Isle of Wight in May 2020 – since the app used its own protocol rather than Apple-Google API protocol, the app could only recognize 4% of the iPhone users via Bluetooth and the app in iPhone would go to sleep when it is not used and could not be activated by Bluetooth, according to experts who experienced the trial launch (Hern & Sabbagh, 2020; Jacob & Lawarée, 2020; Sabbagh & Hern, 2020). After the failure of the trial, the U.K. government launched its second version of the NHS COVID-19 app. This voluntary app uses Bluetooth technology alone to record very few necessary contact information of the citizens and uses the Apple-Google API to store the information in citizens’ own mobile devices without any identifiable information during the registration process, such as name, phone number, address, etc. (Burgess, 2020; Lomas, 2020). After changing into decentralized framework, the public adoption rate increased to almost 30%, even if the download of the app is voluntary (MIT Tracker, 2021).

5.3.1Case #18 – Canada: COVID Alert app

The Canadian government released its national contact tracing app – COVID Alert, on Jul 31st 2020. Like the majority of western countries, Canada’s COVID Alert app is a voluntary, and uses Bluetooth alone for data collection, together with the decentralized framework and the Apple-Google API protocol for data storage. In this way, the Canadian government is able to protect citizen privacy to the greatest extent, according to the government website.55 However, both Global News (2021) and CTV News (Anderson, 2021) pointed out that the low download rate of the app makes this app almost “useless.” According to Global News, despite being launched for almost one year and implemented in ten provinces in Canada, about 80% of smartphone users have not downloaded the app, and less than 4% of people used the app to notify others of the potential COVID-19 exposure.

5.3.2Case #19 – U.S.: Different apps for different states

MIT Tracker (2021) summarized the contact tracing apps across the states in the U.S., and provided information about the app of each state, such as the app names, developers, sensor technologies, and protocols used. Based on the Tracker, more than half of the U.S. states (27/50) have their local contact tracing app developed by different organizations, including LLCs (such as ProudCrowd and NearForm) and NPOs (such as PathCheck). Most of the apps use Bluetooth alone as the sensor technology and a decentralized app framework based on the Apple-Google API protocol. Only a few of them use GPS to track and record citizens’ location information.

5.4.1Case #20 – Australia: COVIDSafe app

Developed based on Singapore’s open code of the TraceTogether app, Australia launched on Apr 26th 2020 its own version of the digital contact tracing app – the voluntary COVIDSafe app (Abbas & Michael, 2020). The two apps have many things in common, such as the same protocol of BlueTrace, the same sensor technology of Bluetooth, and the same centralized app framework in data storage. Meanwhile, the two apps have differences, such as compliance policy of the apps – Singapore makes the download and use of the app mandatory, while Australia remains the adoption of the app voluntary. Despite the low download rate of the app in the beginning, the public adoption of the app increased gradually among Australian citizens. Until Jan 8th 2021, the voluntary COVIDSafe app has been downloaded more than 7.3 million times, covering around 30% of the population in Australia (Bonyhady, 2020).

5.4.2Case #21 – New Zealand: NZ COVID Tracer app

Launched on May 20th 2020, New Zealand’s COVID Tracer app uses the Q.R. code scanning as their sensor technology to collect citizens’ contact data – every citizen has to scan the Q.R. code to check in before entering into any public venues (Walls, 2020). However, different from other contact tracing apps that use Q.R. code scanning technology (such as China’s Health Code app and Singapore’s TraceTogether app), the COVID Tracer app is voluntary that citizens can still enter the public venues without scanning the Q.R. code (Yang et al., 2021).

Updated on Dec 10th 2020, the COVID Tracer app added Bluetooth tracing (which is developed based on the Apple-Google API protocol) to its data collection sensor technology to improve the efficiency of contact tracing (Barbaschow, 2020). According to the Ministry of Health in New Zealand, while Q.R. code scanning can record where the citizens have been (which functions as a digital diary), the Bluetooth can record the close contacts of the citizens. However, the primary method for contact tracing is still Q.R. code scanning, and the Bluetooth functions only as an additional tool (Barbaschow, 2020). According to Hon Chris Hipkins, the Minister for COVID-19 Response, the NZ COVID Tracer app uses a decentralized framework for citizen data storage.