Multi-level reversible encryption for ECG signals using compressive sensing

TL;DR

This paper introduces a multi-level encryption scheme for ECG signals using compressive sensing, effectively masking sensitive information for semi-authorized users while preserving essential features for heart rate monitoring.

Contribution

It presents a novel compressive sensing-based multi-level encryption method that masks ECG data at multiple levels, balancing privacy and data utility.

Findings

Reduces heartbeat anomaly classification accuracy by up to 50%.

Maintains high R-peak detection accuracy.

Masks data in both time and frequency domains.

Abstract

Privacy concerns in healthcare have gained interest recently via GDPR, with a rising need for privacy-preserving data collection methods that keep personal information hidden in otherwise usable data. Sometimes data needs to be encrypted for several authentication levels, where a semi-authorized user gains access to data stripped of personal or sensitive information, while a fully-authorized user can recover the full signal. In this paper, we propose a compressive sensing based multi-level encryption to ECG signals to mask possible heartbeat anomalies from semi-authorized users, while preserving the beat structure for heart rate monitoring. Masking is performed both in time and frequency domains. Masking effectiveness is validated using 1D convolutional neural networks for heartbeat anomaly classification, while masked signal usefulness is validated comparing heartbeat detection accuracy between masked and recovered signals. The proposed multi-level encryption method can decrease classification accuracy of heartbeat anomalies by up to 50%, while maintaining a fairly high R-peak detection accuracy.