We describe a privacy-preserving system where a server can classify an electrocardiogram (ECG) signal without learning any information about the ECG signal and the client is prevented from gaining knowledge about the classification algorithm used by the server. The system relies on the concept of linear branching programs (LBP) and a recently proposed cryptographic protocol for secure evaluation of private LBPs. We study the trade-off between signal representation accuracy and system complexity both from practical and theoretical perspective. As a result, the inputs to the system are represented with the minimum number of bits ensuring the same classification accuracy of a plain implementation. We show how the overall system complexity can be strongly reduced by modifying the original ECG classification algorithm. Two alternatives of the underlying cryptographic protocol are implemented and their corresponding complexities are analyzed to show suitability of our system in real-life applications for current and future security levels.
Efficient Privacy-Preserving Classification of ECG Signals / 'Barni, M; Failla, P; Koleshnikov, V; Lazzeretti, Riccardo; Paus, A; Sadeghi, A; Schneider, T.. - (2009), pp. 91-95. (Intervento presentato al convegno 1st IEEE International Workshop on Information Forensics and Security, WIFS 2009 tenutosi a London; United Kingdom) [10.1109/WIFS.2009.5386475].
Efficient Privacy-Preserving Classification of ECG Signals
LAZZERETTI, RICCARDO
;
2009
Abstract
We describe a privacy-preserving system where a server can classify an electrocardiogram (ECG) signal without learning any information about the ECG signal and the client is prevented from gaining knowledge about the classification algorithm used by the server. The system relies on the concept of linear branching programs (LBP) and a recently proposed cryptographic protocol for secure evaluation of private LBPs. We study the trade-off between signal representation accuracy and system complexity both from practical and theoretical perspective. As a result, the inputs to the system are represented with the minimum number of bits ensuring the same classification accuracy of a plain implementation. We show how the overall system complexity can be strongly reduced by modifying the original ECG classification algorithm. Two alternatives of the underlying cryptographic protocol are implemented and their corresponding complexities are analyzed to show suitability of our system in real-life applications for current and future security levels.| File | Dimensione | Formato | |
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VE_2009_11573-967138.pdf
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