考虑运算放大器带宽限制包络线跟踪电源的前馈控制策略

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摘要为提高3G通信中功率放大器供电电源的效率, 本文提出多电平开关切换结构与线性电源串联构成ET电源的方案。该方案可以使电路中选通开关的开关频率等于参考信号的频率。与其他现有方法相比, 其可以用同样的开关频率获得更高的跟踪带宽。针对包络线跟踪电源基本控制策略中闭环无法有效抑制扰动电压影响的问题, 本文提出了阶梯波电压前馈的控制策略。为克服运算放大器线性放大能力受其带宽限制的影响, 本文提出级联运算放大器的频率补偿方法以扩展等效级联带宽, 保证前馈控制策略相对低频部分的实现；提出输出电压高频尖峰抑制方法以匹配阶梯波电压到输出电压间两条通路的传递函数, 消除阶梯波电压中高频分量对输出电压的影响。本文以一台跟踪信号为300kHz正弦波, 输出电压为10～32V, 峰值功率为50W的原理样机进行实验验证。实验结果表明了本文所提方法的有效性。

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	郗焕
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关键词 ： 3G通信, 功率放大器, 包络线跟踪, 高带宽, 频率补偿

Abstract：In order to improve the power supply efficiency to power amplifier in 3G communication system, an envelope tracking power supply, consists of a multilevel converter in series connected with a linear power supply, is proposed. This scheme can operate the switches in same frequency with the reference signal, so as to gain better tracking bandwidth compared to existing general schemes. In basic control method for envelop tracking power supply, the closed loop can not suppress the disturbance effectively. To address the problem, the feed-forwarding the step-wave voltage control strategy is proposed. For practical implementation, the thesis proposes the frequency compensation scheme of cascaded operational amplifiers to extend the equivalent bandwidth; and the high-frequency spike suppression scheme to match the transfer functions of the two branches between step-wave voltage and output port, so as to eliminate the disturbance effect to the output voltage. A prototype for 300kHz sine wave tracking, with 10～32V output voltage and 50W peak output power is built. The experimental results validate the schemes proposed.

Key words： 3G communication power amplifier envelope tracking high bandwidth frequency compensation

收稿日期: 2012-08-23 出版日期: 2014-06-27

PACS:

TM46

作者简介: 郗焕, 男, 1982年生, 博士研究生, 研究方向为包络线跟踪电源, 高频模块化电源; 金茜, 女, 1988年生, 博士研究生, 研究方向为包络线跟踪电源, 高频模块化电源。

引用本文:

郗焕, 金茜, 阮新波. 考虑运算放大器带宽限制包络线跟踪电源的前馈控制策略[J]. 电工技术学报, 2014, 29(4): 142-151. Xi Huan, Jin Qian, Ruan Xinbo. Feed-Forward Control Strategy for Envelope Tracking Power Supply Considering Bandwidth Limitation of Operational Amplifiers. Transactions of China Electrotechnical Society, 2014, 29(4): 142-151.

链接本文:

http://dgjsxb.ces-transaction.com/CN/Y2014/V29/I4/142

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