Parameter Optimization of Balise Circuit Based on Fusion of BNN and Genetic Algorithm

IF 1.9 4区 工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC
Zhengjiao Li, Zishuo Zhao, Jiang Liu, Zhongqi Zhang, Baigen Cai
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引用次数: 0

Abstract

The optimization of the parameters of the components related to the radio frequency (RF) transmission circuit of the balise can keep the balise working normally under low power consumption and increase the reliability and stability of the high-speed railway vehicle-ground communication. However, the circuit has high complexity, many parameters need to be considered in optimization, and the constraint relationship is complex. Optimizing a single objective is very difficult and time-consuming. Therefore, this paper proposes a ground transponder design and optimization method based on deep learning. Firstly, the functional modules of the balise RF circuit are decomposed, and the influencing factors of circuit start-up conditions and load quality factors are analysed, and the component parameters that need to be optimized are extracted as decision variables. The objective function of the model is established from the perspective of circuit cost and static power consumption, and a multi-objective optimization model is established through its overall circuit scheme. Finally, in order to reduce the time cost, the multi-objective optimization model is processed by the fusion of neural network and genetic algorithm. Among them, the experimental results show that the optimization effect of Bayesian neural network (BNN) is the most significant, and the static power consumption and cost of the circuit can be reduced by 55% and 42%, respectively, with less time overhead.

Abstract Image

基于 BNN 和遗传算法融合的平衡电路参数优化
对平衡器射频(RF)传输电路相关部件的参数进行优化,可以使平衡器在低功耗的情况下正常工作,提高高速铁路车地通信的可靠性和稳定性。然而,电路复杂度高,优化时需要考虑的参数多,约束关系复杂。优化单一目标非常困难且耗时。因此,本文提出了一种基于深度学习的地面转发器设计与优化方法。首先对平衡射频电路的功能模块进行分解,分析电路启动条件的影响因素和负载质量因素,提取需要优化的元件参数作为决策变量。从电路成本和静态功耗的角度建立了模型的目标函数,并通过其整体电路方案建立了多目标优化模型。最后,为了降低时间成本,通过神经网络和遗传算法的融合,对多目标优化模型进行了处理。其中,实验结果表明,贝叶斯神经网络(BNN)的优化效果最为显著,电路的静态功耗和成本可分别降低 55% 和 42%,且时间开销较小。
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来源期刊
CiteScore
5.80
自引率
4.30%
发文量
18
审稿时长
29 weeks
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