Graph Attention Network-Based Fault Detection for UAVs With Multivariant Time Series Flight Data
Kai He, Daojie Yu, Dong Wang, Mengjuan Chai, Shuntian Lei, Changlin Zhou
Abstract
Timely detection and isolation of faults is crucial to the survival of unmanned aerial vehicle (UAV) systems and to avoid threats to humans and the environment. This paper focused on automatically and accurately identifying the faults with data-driven methods as traditional algorithms may rely on the knowledge of underlying system dynamics. The analytical redundancies are provided with the proposed masked spatial GAT with GRU (masked-SGAT-GRU) model. The model extracts pair-wise dependencies between variables from different components of UAVs explicitly, which is of vital importance in improving fault detection (FD) performance. With the finely-optimized model, residuals are generated from measurements and predictions, which are smoothed with the exponential weighted moving average (EWMA) method to generate the proper fault thresholds. Real flight data under two flight modes are collected for model training and fault injection. The robustness and effectiveness of the model are demonstrated in FD with four types of faults compared with the commonly used data-driven methods.