Efficient and Privacy-Preserving Decision Tree Classification for Health Monitoring Systems

Due to the increasing healthcare costs and the advance of wireless technology, health monitoring systems have been widely adopted recently. In health monitoring systems, a hospital outsources a clinical decision model to a cloud service provider, which receives biomedical data from remote clients and produces clinical decisions based on the outsourced model. Due to critical privacy concerns, both the clinical decision model and biomedical data should be protected. In this article, we propose an efficient and privacy-preserving decision tree (PPDT) classification scheme for health monitoring systems. Specifically, we first transform a decision tree classifier (i.e., the clinical decision model) into the Boolean vectors. Then, we leverage symmetric key encryption to encrypt the Boolean vectors as encrypted indices. The PPDT classification is achieved by searching the encrypted indices with encrypted tokens. We formulate a leakage function and provide the security definition and simulation-based proof for PPDT. The performance analyses demonstrate that PPDT is very efficient in terms of computation, communication, and storage. Experimental evaluations show that PPDT only requires microsecond-level execution time, kilobyte-level communication costs, and kilobyte-level storage costs on the test data set.

Automated summary

This article proposes an efficient and privacy-preserving decision tree (PPDT) classification scheme for health monitoring systems. The scheme involves converting a decision tree classifier into Boolean vectors and encrypting them with symmetric key encryption to achieve PPDT classification. Experimental evaluations demonstrate the high efficiency of PPDT in terms of execution time, communication costs, and storage costs on the test data set.