Abstract
In advanced metering infrastructure (AMI) networks, smart meters installed at the consumer side should report fine-grained power consumption readings (every few minutes) to the system operator for billing, real-time load monitoring, and energy management. On the other hand, the AMI networks are vulnerable to cyber-attacks where malicious consumers report false (low) electricity consumption to reduce their bills in an illegal way. Therefore, it is imperative to develop schemes to accurately identify the consumers that steal electricity by reporting false electricity usage. Most of the existing schemes rely on machine learning for electricity theft detection using the consumers’ fine-grained power consumption meter readings. However, this fine-grained data that is used for electricity theft detection, load monitoring, and billing can also be misused to infer sensitive information regarding the consumers such as whether they are on travel, the appliances they use, and so on. In this paper, we propose an efficient and privacy-preserving electricity theft detection scheme for the AMI network and we refer to it as PPETD. Our scheme allows system operators to identify the electricity thefts, monitor the loads, and compute electricity bills efficiently using masked fine-grained meter readings without violating the consumers’ privacy. The PPETD uses secret sharing to allow the consumers to send masked readings to the system operator such that these readings can be aggregated for the purpose of monitoring and billing. In addition, secure two-party protocols using arithmetic and binary circuits are executed by the system operator and each consumer to evaluate a generalized convolutional-neural network model on the reported masked fine-grained power consumption readings for the purpose of electricity theft detection. An extensive analysis of real datasets is performed to evaluate the security and the performance of the PPETD. Our results confirm that our scheme is accurate in detecting fraudulent consumers with privacy preservation and acceptable communication and computation overhead.
Highlights
Electricity theft is a serious problem in the existing power grid, which causes great economic loss
3) OUR convolutional neural networks (CNNs) MODEL CONSTRUCTION In this subsection, we present the detailed construction of privacy-preserving CNN-based electricity theft detection
Since we focus on the privacy of the online theft detection phase, we assume the model is either trained on an anonymized dataset or the training is done using privacy-preservation method such as differential privacy [42]
Summary
Electricity theft is a serious problem in the existing power grid, which causes great economic loss. Most of the existing models need to access the consumers’ fine-grained power consumption data to detect electricity theft, which seriously invades the privacy of the consumers. The scheme aims at efficient detection of electricity thefts using convolutional machine learning model while preserving consumers’ privacy and enabling the SO to monitor the loads and compute electricity bills following a dynamic pricing mechanism. Secure two-party computation protocols for arithmetic and binary circuits are executed by each consumer’s SM and the SO using a number of consecutive reports, referred to as electricity theft detection interval These protocols use a secure convolutional neural network model that operates on the consumers’ blinded fine-grained reports and can efficiently detect electricity thefts.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
