基于遗传算法的波形学习及其在信号完整性改进中的应用

2017 IEEE 4th International Conference on Soft Computing & Machine Intelligence (ISCMI) Pub Date : 2017-11-01 DOI:10.1109/ISCMI.2017.8279615

M. Yasunaga, I. Yoshihara

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引用次数: 1

摘要

提出了一种新型的波形发生器及其设计方法。在这个想法中，没有复杂的电路，只使用印刷电路板上的一条走线作为发生器:走线被分成多个不同宽度和长度的段。任何期望的输出波形可以通过调整每个段的宽度和长度来产生，因为多个反射波出现在轨迹中，并且它们叠加到输入波形上。调整，或宽度-长度设计，但涉及到一个组合爆炸问题。为了克服设计困难，我们使用遗传算法(GA)，将分段划分的传输线映射到遗传算法中的染色体上，并使它们学习所需的输出波形。我们将所提出的波形发生器应用于高速互连中的信号完整性改善，并使用原型板验证了其显著的效率。

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Waveform learning based on a genetic algorithm and its application to signal integrity improvement

A novel waveform generator and its design methodology are proposed in this paper. In the idea, no complicated circuits but only a trace in a printed circuit board is used as the generator: the trace is divided into multiple segments of different widths and lengths. Any desired output waveforms can be generated by adjusting each segment's width and length because the multiple reflection waves occur in the trace and they are superposed onto the input waveform. The adjusting, or the width-length design however comes to a combinatorial explosion problem. In order to overcome the design difficulty we use a genetic algorithm (GA) by mapping the segmentally divided transmission lines onto chromosomes in the GA, and make them learn the desired output waveform. We apply the proposed waveform generator to signal integrity improvement in high-speed interconnections, and demonstrate its remarkable efficiency using a prototype board.

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2017 IEEE 4th International Conference on Soft Computing & Machine Intelligence (ISCMI)

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