PWM比较器的采样模型及其矩阵描述

摘要/Abstract

摘要：

作为直流变换器中重要的非线性环节,PWM比较器是研究和分析直流变换电路首先需要考虑的问题。将PWM比较器等效为线性比例环节是一种常用的方法,该模型虽然简单,但是只适用于低频段。基于描述函数的方法可以获取准确的理论模型,但其计算量大、物理意义不明确并且结果的描述形式不够简洁。为了建立准确的PWM比较器模型,同时避免描述函数法的各种缺点,本文提出了PWM比较器的采样模型及其矩阵形式的描述。该模型采用采样等效的方法求取PWM比较器输出各频率成分的数值,大大减小了计算量;之后根据线性空间的概念建立了模型的矩阵形式,从而将非线性的PWM比较器转化为由向量和矩阵描述的线性模型。本文所提的模型具有准确、简洁且物理意义明确等优点,仿真和实验结果表明模型的正确性和有效性。

关键词: 分布式供电, DC-DC变换器, PWM比较器建模, 采样理论, 矩阵

Abstract:

When analyzing DC-DC converters, the PWM comparator should be taken into account firstly because it is one of the most importantnonlinear parts. In traditional, PWM comparators are considered as a linear amplifier, which is simple but questionable when approaching half of the switching frequency. The describing function method can obtain accurate model for PWM comparator, however, it takes a large amount of calculations and lacks of physical insight. To make the modeling accurate to describe the PWM comparator and avoid the complexity of describing function method, this paper proposes a sampling-based model and gives its matrix description. The PWM is calculated by an impulse-train sampling equivalent method to reduce the computation and a linear space concept is established to simplify the nonlinear PWM comparator as a linear model described by vectors and matrix. The proposed model has some advantages such as high accuracy, simple formula and definite physical meaning, the simulation and experimental results validate its accuracy and effectiveness.

Key words: Distributed power system, DC-DC converters, PWM comparator, sampling, matrix

中图分类号:

TM46

岳小龙,卓放,杨书豪,陈颖. PWM比较器的采样模型及其矩阵描述[J]. 电气工程学报, 2015, 10(4): 45-52.

Yue Xiaolong,Zhuo Fang,Yang Shuhao,Chen Ying. Sampling Model and Its Matrix Description for PWM Comparators[J]. Journal of Electrical Engineering, 2015, 10(4): 45-52.

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参考文献 20

[1]	Wester G W, Middlebrook R D . Low-frequency characterization of switched DC-DC converters[J]. IEEE Transactions on Aerospace and Electronic Systems, 1973 ( 3):376-385.
[2]	Middlebrook R D, Cuk S. A general unified approach to modelling switching-converter power stages [C]. Power Electronics Specialists Conference, 1976,1:18-34.
[3]	Middlebrook RD . Small-signal modeling of pulse-width modulated switched-mode power converters[J]. Proceedings of the IEEE, 1988,76(4):343-354.
[4]	Vorpérian V . Simplified analysis of PWM converters using model of PWM switch. Part I:Continuous conduction mode[J]. IEEE Transactions on Aerospace and Electronic Systems, 1990,26(3):490-496.
[5]	Xu J, Yu J. An extension of time averaging equivalent circuit analysis for DC-DC converters [C]. IEEE International Symposium on Circuits and Systems, 1989: 2060-2063.
[6]	Czarkowski D, Kazimierczuk M K. A new and systematic method of modeling PWM dc-dc converters [C]. IEEE International Conference on Systems Engineering, 1992: 628-631.
[7]	Verghese G C, Thottuvelil V J. Aliasing effects in PWM power converters [C]. Power Electronics Specialists Conference, 1999: 1043-1049.
[8]	Qiu Y, Xu M, Yao K , et al. The multi-frequency small-signal model for buck and multiphase interleaving Buck converters[J]. IEEE Transactions on Power Electronics, 2006,21(5):1185-1192.
[9]	Qiu Y, Xu M, Sun J , et al. A generic high-frequency model for the nonlinearities in buck converters[J]. IEEE Transactions on Power Electronics, 2007,22(5):1970-1977.
[10]	Jian S, Karimi KJ . Small-signal input impedance modeling of line-frequency rectifiers[J]. IEEE Transactions on Aerospace and Electronic Systems, 2008,44(4):1489-1497.
[11]	Jian S, Zhonghui B, Karimi K J . Input impedance modeling of multipulse rectifiers by harmonic linearization[J]. IEEE Transactions on Power Electronics, 2009,24(12):2812-2820.
[12]	Chen Y K, Wu Y C, Song C C , et al. Design and implementation of energy management system with fuzzy control for DC microgrid systems[J]. IEEE Transactions on Power Electronics, 2013,28(4):1563-1570. doi: 10.1109/TPEL.2012.2210446
[13]	吴卫民, 何远彬, 耿攀 , 等. 直流微网研究中的关键技术[J]. 电工技术学报, 2012,27(1):98-106,113.
	Wu Weimin, He Yuanbin, Geng Pan , et al. Key technologies for DC microgrids[J]. Transactions of China Electrotechnical Society, 2012,27(1):98-106, 113.
[14]	别朝红, 李更丰, 谢海鹏 . 计及负荷与储能装置协调优化的微网可靠性评估[J]. 电工技术学报, 2014,29(2):64-73.
	Bie Zhaohong, Li Gengfeng, Xie Haipeng . Reliability evaluation of microgrids considering coordinative optimization of loads and storage devices[J]. Transactions of China Electrotechnical Society, 2014,29(2):64-73.
[15]	L Jinjun, F Xiaogang , FC Lee, et al. Stability margin monitoring for DC distributed power systems via perturbation approaches[J]. IEEE Transactions on Power Electronics, 2003,18(6):1254-1261.
[16]	F Xiaogang, L Jinjun ,FC Lee. Impedance specifications for stable DC distributed power systems[J]. IEEE Transactions on Power Electronics, 2002,17(2):157-162.
[17]	姚雨迎, 张东来, 徐殿国 . 级联式DC/DC变换器输出阻抗的优化设计与稳定性[J]. 电工技术学报, 2009,24(3):147-152.
	Yao Yuying, Zhang Donglai, Xu Dianguo . Output impedance optimization and stability for cascade DC/DC converter[J]. Transactions of China Electrotechnical Society, 2009,24(3):147-152.
[18]	王建华, 张方华, 龚春英 , 等. 电压控制型Buck DC/DC变换器输出阻抗优化设计[J]. 电工技术学报, 2007,22(8):18-23.
	Wang Jianhua, Zhang Fanghua, Gong Chunying , et al. Study of output impedandce optimization for voltage mode control Buck DC/DC converter[J]. Transactions of China Electrotechnical Society, 2007,22(8):18-23.
[19]	Oppenheim Alan V, Alan S Willsky, Syed Hamid Nawab. 信号与系统[M]. 刘树堂, 译.西安:西安交通大学出版社, 1998.
[20]	魏战线 . 高等数学基础—线性代数与解析几何[M]. 北京: 高等教育出版社, 2004.

频率/kHz	模型计算结果		仿真FFT结果
频率/kHz	幅值	相角	幅值	相角
4	0.05	30°	0.05	30.7°
6	0.05	6°	0.05	6.2°
14	0.05	- 114°	0.05	- 113.7°

频率/kHz	模型计算结果		仿真FFT结果
频率/kHz	幅值	相角	幅值	相角
4	0.078	49.6°	0.079	51.6°
6	0.078	14°	0.080	2.4°
14	0.078	- 94.5°	0.074	- 86.1°