Abstract
Nowadays, wireless sensor network technology is being increasingly popular which is applied to a wide range of Internet of Things. Especially, Power Internet of Things is an important and rapidly growing section in Internet of Thing systems, which benefited from the application of wireless sensor networks to achieve fine-grained information collection. Meanwhile, the privacy risk is gradually exposed, which is the widespread concern for electricity power consumers. Non-intrusive load monitoring, in particular, is a technique to recover state of appliances from only the energy consumption data, which enables adversary inferring the behavior privacy of residents. There can be no doubt that applying local differential privacy to achieve privacy preserving in the local setting is more trustworthy than centralized approach for electricity customers. Although it is hard to control the risk and achieve the trade-off between privacy and utility by traditional local differential privacy obfuscation mechanisms, some existing obfuscation mechanisms based on artificial intelligence, called advanced obfuscation mechanisms, can achieve it. However, the large computing resource consumption to train the machine learning model is not affordable for most Power Internet of Thing terminal. In this article, to solve this problem, IFed was proposed—a novel federated learning framework that let electric provider who normally is adequate in computing resources to help Power Internet of Thing users. First, the optimized framework was proposed in which the trade-off between local differential privacy, data utility, and resource consumption was incorporated. Concurrently, the following problem of privacy preserving on the machine learning model transport between electricity provider and customers was noted and resolved. Last, users were categorized based on different levels of privacy requirements, and stronger privacy guarantee was provided for sensitive users. The formal local differential privacy analysis and the experiments demonstrated that IFed can fulfill the privacy requirements for Power Internet of Thing users.
Highlights
Recent years have witnessed the great growth of Internet of Things (IoTs), which have developed significantly in various fields,[1,2,3] especially in Power IoTs
As a smart electric power system that realizes the interconnection of all things in the grid, human–computer interaction, and comprehensive state perception, the Power IoTs are applied to modern information, such as mobile internet and artificial intelligence, around all aspects of the power system
We find that some mechanisms proposed recently are no longer completely randomly obfuscated but transformed first based on the state of the target before applying Local differential privacy (LDP) rather than the traditional method; this kind of mechanism is more efficient to achieve the trade-off between utility and privacy in IoTs
Summary
Recent years have witnessed the great growth of Internet of Things (IoTs), which have developed significantly in various fields,[1,2,3] especially in Power IoTs. Detailed goals are as follows: First, achieve the trade-off between behavior privacy against NILM, data utility–supported electricity bill, and low computing resource consumption in naive Power IoT terminal; Second, all models transport between users and electricity provider subjected to LDP, which will not be a new privacy risk; Note that the proposed federated learning for IoTs does not intend to replace the existing advanced obfuscation mechanisms but aims to solve the problem that power consumption data and trained model safely interact between individuals and grid side. The regular smart meter downloads the global model from electric power provider and overwrites local parameters He runs one epoch of SGD training on his local dataset when using obfuscation mechanism based on neural network. 15 end if send wtk Obfuscating and send consumption data each 15min: Predict the state of the appliance: Y pre d ic t X localmodel
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
