CONTAIN: Privacy-oriented Contact Tracing Protocols for Epidemics

Pandemic and epidemic diseases such as CoVID-19, SARS-CoV2, and Ebola have spread to multiple countries and infected thousands of people. Such diseases spread mainly through person-to-person contacts. Health care authorities recommend contact tracing procedures to prevent the spread to a vast population. Although several mobile applications have been developed to trace contacts, they typically require collection of privacy-intrusive information such as GPS locations, and the logging of privacy-sensitive data on a third party server, or require additional infrastructure such as WiFi APs with known locations. In this paper, we introduce CONTAIN, a privacy-oriented mobile contact tracing application that does not rely on GPS or any other form of infrastructure-based location sensing, nor the continuous logging of any other personally identifiable information on a server. The goal of CONTAIN is to allow users to determine with complete privacy if they have been within a short distance, specifically, Bluetooth wireless range, of someone that is infected, and potentially also when. We identify and prove the privacy guarantees provided by our approach. Our simulation study utilizing an empirical trace dataset (Asturies) involving 100 mobile devices and around 60000 records shows that users can maximize their possibility of identifying if they were near an infected user by turning on the app during active times.

[1]  Erik C. Rye,et al.  A Study of MAC Address Randomization in Mobile Devices and When it Fails , 2017, Proc. Priv. Enhancing Technol..

[2]  Fredson Kuti-George,et al.  Contact Tracing during an Outbreak of Ebola Virus Disease in the Western Area Districts of Sierra Leone: Lessons for Future Ebola Outbreak Response , 2016, Front. Public Health.

[3]  Xiaohui Liang,et al.  EPIC: Efficient Privacy-Preserving Contact Tracing for Infection Detection , 2018, 2018 IEEE International Conference on Communications (ICC).

[4]  Ming Li,et al.  Privacy-preserving inference of social relationships from location data: a vision paper , 2015, SIGSPATIAL/GIS.

[5]  R. Emonet,et al.  Epidemic Contact Tracing via Communication Traces , 2014, PloS one.

[6]  Eric Horvitz,et al.  PACT: Privacy-Sensitive Protocols And Mechanisms for Mobile Contact Tracing , 2020, IEEE Data Eng. Bull..

[7]  David Kotz,et al.  ENACT: Encounter-based Architecture for Contact Tracing , 2017, WPA@MobiSys.

[8]  Rohitash Chandra,et al.  Mobile Application for Dengue Fever Monitoring and Tracking via GPS: Case Study for Fiji , 2015, ArXiv.

[9]  Ozan K. Tonguz,et al.  Bluetooth 5: A Concrete Step Forward toward the IoT , 2017, IEEE Communications Magazine.

[10]  Jon Crowcroft,et al.  EpiMap: Towards quantifying contact networks for understanding epidemiology in developing countries , 2014, Ad Hoc Networks.

[11]  Helen A. Weiss,et al.  Use of a mobile application for Ebola contact tracing and monitoring in northern Sierra Leone: a proof-of-concept study , 2019, BMC Infectious Diseases.

[12]  Jason Bay,et al.  BlueTrace: A privacy-preserving protocol for community-driven contact tracing across borders , 2020 .

[13]  David Melendi,et al.  CRAWDAD dataset oviedo/asturies-er (v.2016-08-08) , 2016 .

[14]  Carmela Troncoso,et al.  Decentralized Privacy-Preserving Proximity Tracing , 2020, IEEE Data Eng. Bull..

[15]  Ahmed Helmy,et al.  Infection tracing in smart hospitals , 2016, 2016 IEEE 12th International Conference on Wireless and Mobile Computing, Networking and Communications (WiMob).