An all-digital coherent AFSK demodulator for CubeSat applications

IF 2.9 3区工程技术 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

Digital Signal Processing Pub Date : 2025-03-14 DOI:10.1016/j.dsp.2025.105147

Rubem Vasconcelos Pacelli , Rodrigo de Lima Florindo , Felix Antreich , Antônio Macilio Pareira de Lucena

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引用次数: 0

Abstract

Audio frequency-shift keying (AFSK) is a widely adopted modulation scheme for CubeSat systems due to its favorable bandwidth efficiency and implementation simplicity. However, coherent detection usually is avoided because synchronization impairments, caused by intense line-of-sight (LOS) dynamics inherent in low Earth orbit (LEO), may significantly degrade the bit error rate (BER). This paper presents a new all-digital coherent AFSK demodulator based on a Kalman filter (KF) for carrier phase and timing delay synchronization and the Viterbi algorithm for bit detection. The Viterbi algorithm is employed for maximum likelihood sequence detection, and the detected bit statistics are fed back to the KF to estimate phase shift, Doppler frequency shift, and Doppler drift induced by the LOS dynamics. Original mathematical analyses are derived to provide a theoretical foundation for the proposed demodulator's operation, specifically addressing its synchronization accuracy in dynamic LEO environments. The proposed demodulator is evaluated considering an additive white Gaussian noise channel with real CubeSat orbits. The performance results obtained through computer simulations demonstrate that the proposed model can withstand such scenarios with a gain of 5 dB in terms of BER compared to the conventional noncoherent AFSK demodulator. The KF performance is assessed using a moving root-mean-square error (MRMSE) statistic and the trace of its state error covariance matrix estimate.

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用于立方体卫星的全数字相干AFSK解调器

音频移频键控（AFSK）由于其良好的带宽效率和实现的简单性而被广泛应用于立方体卫星系统。然而，相干检测通常是避免的，因为低地球轨道（LEO）固有的强烈视距（LOS）动力学引起的同步损伤可能会显著降低误码率（BER）。本文提出了一种新的全数字相干AFSK解调器，该解调器采用卡尔曼滤波器（KF）实现载波相位和时延同步，采用维特比算法实现位检测。采用Viterbi算法进行最大似然序列检测，将检测到的比特统计信息反馈到KF中，用于估计由LOS动态引起的相移、多普勒频移和多普勒漂移。推导了原始的数学分析，为所提出的解调器的工作提供了理论基础，特别是解决了动态LEO环境下的同步精度问题。利用实际立方体卫星轨道的加性高斯白噪声信道对所提解调器进行了评价。通过计算机仿真得到的性能结果表明，与传统的非相干AFSK解调器相比，所提出的模型可以承受这种情况，并且可以获得5 dB的误码率增益。使用移动均方根误差（MRMSE）统计量及其状态误差协方差矩阵估计的跟踪来评估KF性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Digital Signal Processing 工程技术-工程：电子与电气

CiteScore

5.30

自引率

17.20%

发文量

435

审稿时长

66 days

期刊介绍： Digital Signal Processing: A Review Journal is one of the oldest and most established journals in the field of signal processing yet it aims to be the most innovative. The Journal invites top quality research articles at the frontiers of research in all aspects of signal processing. Our objective is to provide a platform for the publication of ground-breaking research in signal processing with both academic and industrial appeal. The journal has a special emphasis on statistical signal processing methodology such as Bayesian signal processing, and encourages articles on emerging applications of signal processing such as: • big data• machine learning• internet of things• information security• systems biology and computational biology,• financial time series analysis,• autonomous vehicles,• quantum computing,• neuromorphic engineering,• human-computer interaction and intelligent user interfaces,• environmental signal processing,• geophysical signal processing including seismic signal processing,• chemioinformatics and bioinformatics,• audio, visual and performance arts,• disaster management and prevention,• renewable energy,