TY - GEN
T1 - Complexity-Driven and Path-Selective Decoding for DPRNN-based Signal Separation
AU - Zhang, Dan
AU - Yang, Ziyi
AU - Pan, Gaofeng
AU - Wang, Shuai
AU - An, Jianping
N1 - Publisher Copyright:
©2025 IEEE.
PY - 2025
Y1 - 2025
N2 - In complex communication environments, the deep learning-based signal separation method Dual-path RNN(DPRNN) encounters significant challenges due to the inherent difficulty of separating complex mixed signals and the pronounced performance bottlenecks in its decoder architecture. To overcome these limitations, this paper introduces a complexity-driven and path-selective decoding framework, incorporating an adaptive decoder that dynamically adjusts to signal complexity. The proposed decoder employs a complexity estimator to dynamically assess signal complexity in real time, enabling adaptive path selection. Furthermore, it integrates a feature reconstruction and balancing module to establish a feature enhancement path, thereby improving the representation of complex signals. Experimental results demonstrate that under ideal channel conditions, the proposed decoder reduces the error rate (ER) by an average of 63.9% compared to the baseline DPRNN model across mixed-signal separation tasks, while preserving signal fidelity. Ablation studies validate the effectiveness of the complexity-driven mechanism and feature enhancement path, underscoring the necessity of the complexity estimator for improving model generalization. This research offers novel insights and methodologies for designing efficient, high-performance signal decoder tailored to complex communication environments.
AB - In complex communication environments, the deep learning-based signal separation method Dual-path RNN(DPRNN) encounters significant challenges due to the inherent difficulty of separating complex mixed signals and the pronounced performance bottlenecks in its decoder architecture. To overcome these limitations, this paper introduces a complexity-driven and path-selective decoding framework, incorporating an adaptive decoder that dynamically adjusts to signal complexity. The proposed decoder employs a complexity estimator to dynamically assess signal complexity in real time, enabling adaptive path selection. Furthermore, it integrates a feature reconstruction and balancing module to establish a feature enhancement path, thereby improving the representation of complex signals. Experimental results demonstrate that under ideal channel conditions, the proposed decoder reduces the error rate (ER) by an average of 63.9% compared to the baseline DPRNN model across mixed-signal separation tasks, while preserving signal fidelity. Ablation studies validate the effectiveness of the complexity-driven mechanism and feature enhancement path, underscoring the necessity of the complexity estimator for improving model generalization. This research offers novel insights and methodologies for designing efficient, high-performance signal decoder tailored to complex communication environments.
KW - Dynamic decoding
KW - Feature enhancement
KW - Signal separation
UR - http://www.scopus.com/pages/publications/105013622787
U2 - 10.1109/ECIS65594.2025.11086655
DO - 10.1109/ECIS65594.2025.11086655
M3 - Conference contribution
AN - SCOPUS:105013622787
T3 - 2025 IEEE 2nd International Conference on Electronics, Communications and Intelligent Science, ECIS 2025 - Proceeding
BT - 2025 IEEE 2nd International Conference on Electronics, Communications and Intelligent Science, ECIS 2025 - Proceeding
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2nd IEEE International Conference on Electronics, Communications and Intelligent Science, ECIS 2025
Y2 - 23 May 2025 through 25 May 2025
ER -