English

Specific Multi-emitter Identification: Theoretical Limits and Low-complexity Design

Signal Processing 2025-12-23 v1

Abstract

Specific emitter identification (SEI) distinguishes emitters by utilizing hardware-induced signal imperfections. However, conventional SEI techniques are primarily designed for single-emitter scenarios. This poses a fundamental limitation in distributed wireless networks, where simultaneous transmissions from multiple emitters result in overlapping signals that conventional single-emitter identification methods cannot effectively handle. To overcome this limitation, we present a specific multi-emitter identification (SMEI) framework via multi-label learning, treating identification as a problem of directly decoding emitter states from overlapping signals. Theoretically, we establish performance bounds using Fano's inequality. Methodologically, the multi-label formulation reduces output dimensionality from exponential to linear scale, thereby substantially decreasing computational complexity. Additionally, we propose an improved SMEI (I-SMEI), which incorporates multi-head attention to effectively capture features in correlated signal combinations. Experimental results demonstrate that SMEI achieves high identification accuracy with a linear computational complexity. Furthermore, the proposed I-SMEI scheme significantly improves identification accuracy across various overlapping scenarios compared to the proposed SMEI and other advanced methods.

Keywords

Cite

@article{arxiv.2512.19127,
  title  = {Specific Multi-emitter Identification: Theoretical Limits and Low-complexity Design},
  author = {Yuhao Chen and Boxiang He and Junshan Luo and Shilian Wang and Lei Yao and Jing Lei},
  journal= {arXiv preprint arXiv:2512.19127},
  year   = {2025}
}
R2 v1 2026-07-01T08:36:24.413Z