Dynamic Risk Inference Method for Chemical Industrial Inspection Based on Spatio-Temporal Scene Graphs
Meng Zhou, Liheng Wang, Sai Li, Zhixia DingTo address the challenge of high false alarm rates caused by dynamic viewpoint noise in mobile chemical inspections, this study established a highly robust adaptive dynamic risk inference model. This research proposes an inference framework integrating spatio-temporal semantic constraints. Spatially, this study constructed a heterogeneous dynamic scene graph and introduced a kinematic-aware anisotropic dynamic field. This field transforms geometric hard boundaries into continuous risk gradients that deform dynamically with target intentions to suppress observation ambiguity. Temporally, the work designed an uncertainty-aware adaptive hysteresis filter, whose state machine thresholds adjust dynamically according to real-time sensor noise levels. Comparative tests on a real-world chemical dataset show that the model achieves a peak F1-Score of 93.1%, reduces the false alarm rate to 1.3 times/h, and requires a single-frame processing time of only 24.8 ms. The method theoretically achieves spatio-temporal dynamic noise reduction, significantly mitigates topological mutations and alarm chattering under complex visual noise conditions, meets edge computing deployment requirements, and provides a high-confidence sensing decision hub for industrial process safety monitoring.