@INPROCEEDINGS {10763660,
author = { Xie, Qipeng and Wang, Weizheng and Huang, Yongzhi and Zheng, Mengyao and Shang, Shuai and Jiang, Linshan and Khan, Salabat and Wu, Kaishun },
booktitle = { 2024 IEEE 30th International Conference on Parallel and Distributed Systems (ICPADS) },
title = {{ LiteCrypt: Enhancing IoMT Security with Optimized HE and Lightweight Dual-Authorization }},
year = {2024},
volume = {},
ISSN = {},
pages = {166-175},
abstract = { The integration of 5G/6G networks with intelligent healthcare systems has enabled early disease detection through patient data monitoring. However, the Internet of Medical Things (IoMT) and remote healthcare services introduce significant privacy and security risks. In this paper, we propose LiteCrypt, which addresses these challenges by introducing an optimized Homomorphic Convolutional Neural Networks (HCNN) structure for secure inference and a lightweight Threshold Signature Scheme (TSS) based dual-authorization mechanism. To enhance the practicality of Homomorphic Encryption (HE)-based secure inference in telemedicine applications, LiteCrypt presents an optimized HCNN framework that ensures efficient and adaptable operations across multiple datasets. A high-performance GPU-accelerated HE engine is developed to address the computational demands of HE operations, enabling real-time processing of encrypted patient data. Besides, LiteCrypt introduces a novel TSS-based dual-authorization protocol, requiring consent from both the patient and the hospital to access patient data, thereby mitigating unauthorized access risks. The system adapts to a flexible 2-out-of-3 authorization scheme for emergencies, ensuring timely data retrieval while maintaining security. To overcome the initial challenge of prolonged computation time due to compute-intensive operations, In LiteCrypt, we utilized the lightweight TSS protocol, based on Oblivious Transfer (OT), which is designed for resource-constrained IoMT devices, reducing computation time from 11.9 to 0.11 seconds. Empirical validation demonstrates LiteCrypt’s superior performance, achieving a 233-fold increase in processing speed, a $96 \%$ reduction in encrypted message size, and a 28-fold speed increase using GPUs. },
keywords = {Performance evaluation;Privacy;Protocols;Telemedicine;Memory management;Performance gain;Real-time systems;Cryptography;Homomorphic encryption;Monitoring},
doi = {10.1109/ICPADS63350.2024.00031},
url = {https://doi.ieeecomputersociety.org/10.1109/ICPADS63350.2024.00031},
publisher = {IEEE Computer Society},
address = {Los Alamitos, CA, USA},
month =Oct}