While contact tracing is of paramount importance in preventing the spreading of infectious diseases, manual contact tracing is inefficient and time consuming as those in close contact with infected individuals are informed hours, if not days, later. This article proposes a smart contact tracing (SCT) system utilizing the smartphone's Bluetooth low energy signals and machine learning classifiers to automatically detect those possible contacts to infectious individuals. SCT's contribution is two-fold: a) classification of the user's contact as high/low-risk using precise proximity sensing, and b) user anonymity using a privacy-preserving communication protocol. To protect the user's privacy, both broadcasted and observed signatures are stored in the user's smartphone locally and only disseminate the stored signatures through a secure database when a user is confirmed by public health authorities to be infected. Using received signal strength each smartphone estimates its distance from other user's phones and issues real-time alerts when social distancing rules are violated. Extensive experimentation utilizing real-life smartphone positions and a comparative evaluation of five machine learning classifiers indicate that a decision tree classifier outperforms other state-of-the-art classification methods with an accuracy of about 90% when two users carry their smartphone in a similar manner. Finally, to facilitate research in this area while contributing to the timely development, the dataset of six experiments with about 123 000 data points is made publicly available.
The meeting of pervasive screens and smart devices has witnessed the birth of screen-smart device interaction (SSI), a key enabler to many novel interactive use cases. Most current surveys focus on direct human-screen interaction, and to the best of our knowledge, none have studied state-of-the-art SSI. This survey identifies three core elements of SSI and delivers a timely discussion on SSI oriented around the screen, the smart device, and the interaction modality. Two evaluation metrics (i.e., interaction latency and accuracy) have been adopted and refined to match the evaluation criterion of SSI. The bottlenecks that hinder the further advancement of the current SSI in connection with this metrics are studied. Last, future research challenges and opportunities are highlighted in the hope of inspiring continuous research efforts to realize the next generation of SSI.
While many industries are preparing to resume their operations for the post-pandemic world, essential preventive measures must be imposed to protect their employees and customers from the second outbreak. This paper presents a contact tracing solution based on wearable devices that can be adopted by industry to track the epidemic exposure of their people. Our proximity-based privacy-preserving contact tracing (P 3 CT) integrates 1) the Bluetooth Low Energy (BLE) technology for reliable proximity sensing, 2) a machine learning approach to classify the exposure risk of a user, and 3) an ambient signature protocol for preserving the user's identity. Proximity sensing exploits the signals emitted from a smartwatch to estimate users' interaction, in terms of distance and duration. Supervised learning is then used to train classification models to identify the exposure risk of a user with respect to a patient diagnosed with an infectious disease. Finally, our proposed P 3 CT protocol uses ambient signatures to anonymize the infected patient's identity. Extensive experiments demonstrate the feasibility of our proposed solution for real-world contact tracing problems. Besides performance evaluations, the deliverables of this work also include a large-scale dataset consisting of the signal information collected from the smartwatch and four well-trained classifiers that can be implemented directly for contact tracing applications.
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