计算机科学
通信卫星
自动目标识别
人工智能
调制(音乐)
信号处理
噪音(视频)
人工神经网络
实时计算
电信
卫星
频道(广播)
干扰(通信)
特征(语言学)
计算机网络
传输(电信)
钥匙(锁)
语音识别
数据传输
雷达跟踪器
作者
Yong Zhang,Yong Wang,Qingsong Zhao,Shihua Pan,Fei Xie,Sheng Luo,Yadi Zhai,Jiaxiong Yang
标识
DOI:10.1007/s44443-026-00675-w
摘要
Automatic Modulation Recognition (AMR) constitutes a critical enabling technology for satellite cognitive radio systems, enabling receivers to identify modulation schemes without prior channel state information (CSI). However, satellite-to-ground communication links present unique challenges, including dynamic Doppler frequency shifts arising from Low Earth Orbit (LEO) satellite motion and nonlinear amplitude-phase distortions from Traveling Wave Tube Amplifiers (TWTA) operating near saturation regions. Existing deep learning approaches predominantly focus on time-domain signal analysis, thereby underutilizing the interpretable spectral fingerprints that these channel impairments leave in the frequency domain. To address these limitations, this paper proposes a Frequency-aware Cross-scale Attention Network (FCAN) that employs a dual-branch parallel architecture for joint time–frequency feature extraction. The time-domain branch utilizes Cross-Scale Dilated Convolution (CSDC) modules with adaptive Multi-scale Feature Selection (MFS) to capture temporal patterns across varying symbol rates and modulation orders. The frequency-domain branch integrates learned deep spectral representations with four physics-driven statistical descriptors—spectral centroid, spectral flatness, spectral bandwidth, and low-frequency energy ratio—that encode interpretable domain knowledge about satellite channel characteristics. A bounded gating fusion mechanism with constrained modulation coefficients dynamically recalibrates features from both domains while preventing feature extinction under adverse low signal-to-noise ratio (SNR) conditions. Comprehensive experiments on the RML24 satellite benchmark dataset demonstrate that FCAN achieves state-of-the-art performance with 72.78% overall accuracy across 22 modulation classes using only 422 K parameters, outperforming the best baseline method by 1.64% while maintaining computational efficiency suitable for resource-constrained satellite terminals. Systematic ablation studies validate the synergistic contributions of each architectural component, confirming the effectiveness of integrating physical priors with data-driven representations for robust satellite AMR.
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