FPGA based modified multi-repeat distribution matcher for probabilistic amplitude shaping

Nexo Revista Científica Pub Date : 2023-11-30 DOI:10.5377/nexo.v36i05.17298

Ali Shaban Hassooni, Laith Ali Abdul Rahaim

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Abstract

The technique of probabilistic amplitude modulation, based on distribution matching, has garnered considerable attention in recent years as a means to enhance spectral efficiency and diminish the constellation energy of coded modulation. This paper introduces the implementation of Probabilistic Amplitude Modulation (PAS) using a Modified Multi-Repeat Distribution Matcher (MMRDM) on a Field Programmable Gate Array (FPGA). The Modified Multiple Repetition Distribution Matcher (MMRDM) is integrated into a 2×2 Multiple Input Multiple Output Orthogonal Frequency Division Multiplexing (MIMO-OFDM) system, realized through the Xilinx System Generator (XSG). Simple Zero-Forced and Minimum Mean Squared Error (MMSE) equalizers are applied to the receiver for signal detection across the MIMO channel. The system incorporates enhanced security through chaos-based scrambling with 16 and 64 Quadrature Amplitude Modulation (QAM). VHDL code files for this system are generated for the Xilinx Kintex-7 (xc7k325t-3fbg676) for hardware implementation. Performance evaluation includes an assessment of required storage capacity, complexity, and bit error rate (BER). Using Vivado 2017.4, the system is successfully routed with resource utilization, for example, 0.67% Block RAM (BRAM), 68.6% Look-Up Tables (LUT), 83% DSP 48s, and 1.5% registers for 64-QAM uniform modulation. Similarly, for 64-QAM 10 level (shaper output 60 bit) shaped modulation, the resource utilization is 0.67% BRAM, 68.8% LUT, 83% DSP 48s, and 1.6% registers on the specified device. Simulation results demonstrate an improvement in the net shaping gain of approximately (2-4 dB) at 1×10^(-4) for different equalizer cases compared to uniform QAM, along with a notable reduction in required storage capacity and computational complexity.

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基于 FPGA 的改进型多重复分布匹配器，用于概率振幅整形

近年来，基于分布匹配的概率振幅调制技术作为一种提高频谱效率和降低编码调制星座能量的手段，受到了广泛关注。本文介绍了使用现场可编程门阵列（FPGA）上的修正多重复分布匹配器（MMRDM）实现概率振幅调制（PAS）的情况。修改后的多重复分布匹配器（MMRDM）被集成到一个 2×2 多输入多输出正交频分复用（MIMO-OFDM）系统中，通过赛灵思系统发生器（XSG）实现。接收器采用了简单的零强迫和最小均方误差（MMSE）均衡器，以便在 MIMO 信道上进行信号检测。该系统采用基于混沌的扰码技术和 16 和 64 Quadrature Amplitude Modulation (QAM)，增强了安全性。该系统的 VHDL 代码文件是为 Xilinx Kintex-7 (xc7k325t-3fbg676) 生成的，用于硬件实现。性能评估包括对所需存储容量、复杂性和误码率（BER）的评估。使用 Vivado 2017.4，系统在资源利用率方面成功实现了路由，例如，64-QAM 统一调制时，块 RAM (BRAM)为 0.67%，查找表 (LUT)为 68.6%，DSP 48s 为 83%，寄存器为 1.5%。同样，对于 64-QAM 10 级（整形器输出 60 位）整形调制，指定设备上的资源利用率为 0.67% 的 BRAM、68.8% 的 LUT、83% 的 DSP 48s 和 1.6% 的寄存器。仿真结果表明，与均匀 QAM 相比，在 1×10^(-4) 时，不同均衡器情况下的净整形增益提高了约 (2-4 dB)，所需的存储容量和计算复杂度也显著降低。

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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Nexo Revista Científica

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