Application of neural fuzzy network to pulse compression with binary phase code

Fun-Bin Duh, Chia-Feng Juang, Chin-Teng Lin
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Abstract

To solve the existing dilemma between making good range resolution and maintaining the low average transmitted power, it is necessary for the pulse compression processing to give low range sidelobes in the modern high-resolution radar systems. The traditional pulse compression algorithms based on 13-element Barker code such as direct autocorrelation filter (ACF), least squares (LS) inverse filter, and linear programming (LP) filter have been developed, and the neural network algorithms were issued recently. However, the traditional algorithms cannot achieve the requirement of high signal-to-sidelobe ratio, and the normal neural network such as backpropagation (BP) network usually produces the extra problems of low convergence speed and sensitive to the Doppler frequency shift. To overcome these defects, a new approach using a neural fuzzy network with binary phase code to deal with pulse compression in a radar system is presented in this paper. The 13-element Barker code used as the binary phase signal code is carried out by six-layer self-constructing neural fuzzy network (SONFIN) with supervised learning algorithm. Simulation results show that this neural fuzzy network pulse compression (NFNPC) algorithm has the significant advantages in noise rejection performance, range resolution ability and Doppler tolerance, which are superior to the traditional and BP algorithms, and has faster convergence speed than BP algorithm.
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神经模糊网络在二相码脉冲压缩中的应用
为了解决当前高分辨率雷达系统中存在的既要获得良好的距离分辨率又要保持较低的平均发射功率的难题,需要在脉冲压缩处理中给予较低的距离旁瓣。传统的基于13元巴克码的脉冲压缩算法如直接自相关滤波(ACF)、最小二乘反滤波(LS)和线性规划滤波(LP)等已经得到了发展,近年来又出现了神经网络算法。然而,传统的算法无法达到高信旁比的要求,而传统的神经网络如BP网络往往会产生收敛速度慢、对多普勒频移敏感等额外问题。为了克服这些缺陷,本文提出了一种利用二元相位编码的神经模糊网络处理雷达系统脉冲压缩的新方法。将13元巴克码作为二相信号码,采用六层自构造神经模糊网络(SONFIN)结合监督学习算法进行编码。仿真结果表明,该神经模糊网络脉冲压缩(NFNPC)算法在噪声抑制性能、距离分辨能力和多普勒容忍度等方面都优于传统的BP算法,收敛速度也比BP算法快。
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