Abstract
Implanted medical devices are expected to be wireless in near future. Wireless nature of sensing, controlling and transmission brings along different security threats. In this work, an analysis of eavesdropping risk is performed for an unencrypted data transmissions from an implanted medical device such as cardiac leadless pacemaker. This work utilizes statistical attenuation model along with measures of capacity, information rate and outage probability. Results show that eavesdropping risk depends on pathloss with shadow fading, distance and information rate (R). In addition, probability of successful eavesdropping increases if legitimate nodes transmits at lower rate. Thus, a proper tradeoff between information rate (R) and eavesdropping risk should be made. Numerical results show that at an information rate of 650 kbps, an IMD has a 5% risk of successful eavesdropping at a distance of 500 mm. This work also consider different transmission parameters like heart rate, blood pressure, ECG and EMG with their information rates and find probability of successful eavesdropping at different distances. This study provide basis for designing secure implantable cardiac leadless pacemaker with associated risks involved due to wireless nature of transmission.
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Acknowledgements
This work was supported by the Marie Curie Research Grants Scheme under EU Horizon 2020 research and innovation network program, with project grant no 675353 WIBEC ITN (Wireless In-Body Environment).
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Awan, M.F., Kansanen, K. (2019). Estimating Eavesdropping Risk for Next Generation Implants. In: Fortino, G., Wang, Z. (eds) Advances in Body Area Networks I. Internet of Things. Springer, Cham. https://doi.org/10.1007/978-3-030-02819-0_29
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DOI: https://doi.org/10.1007/978-3-030-02819-0_29
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