To address the bottlenecks in fusion analysis and decision support caused by strongly coupled dynamics, significant non-stationary disturbances, and cross-condition distribution shifts under high-frequency sampling conditions of multi-source flight parameters in flight test experiments, this paper proposes a structural perception fusion representation learning framework based on a dynamic flight parameter hypergraph. The method employs dual-stream gated multi-scale encoding in the temporal dimension to achieve scale decoupling and adaptive fusion, which respectively characterize transient mutations and low-frequency trends while suppressing noise-induced spurious correlations, thereby generating robust channel-level representations. In the structural dimension, flight parameter channels are modeled as nodes, enabling end-to-end learning of hypergraph associations that vary with window contents, and achieving cross-channel collaborative fusion through high-order message passing and normalized propagation across nodes, hyperedges, and nodes. A structural fingerprint is also constructed to support traceable analysis of key channel groups and collaborative mechanisms. At the geometric representation level, supervised contrastive learning constraints are introduced to compress intra-class variance and enlarge inter-class separation, enhancing metric consistency and cross-domain robustness of the embedding space, allowing the same representation to simultaneously adapt to state recognition, similar segment retrieval, and retrieval-enhanced prediction. Evaluated on complex engineering benchmarks and multiple random seeds, the proposed method outperforms sequence baselines such as LSTM and TCN in metrics such as F1 and PR-AUC. Ablation experiments further validate the critical contributions of dynamic hypergraph structural modeling and multi-scale encoding; changes in gated statistics and hyperedge allocation entropy reveal structural reconstruction patterns triggered by collaborative events. Results indicate that this framework provides a stable, reusable, and interpretable foundation for fusion representations in flight state assessment.
Liu et al. (Tue,) studied this question.
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