Improved Delta-Sigma Modulator for Direct Switch Control of a DC-DC Converter

2023 IEEE Applied Power Electronics Conference and Exposition (APEC) Pub Date : 2023-03-19 DOI:10.1109/APEC43580.2023.10131231

B. Bokmans, B. Vermulst, J. Schellekens

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Abstract

Digital Delta-Sigma modulators can be an interesting alternative to Pulse Width Modulation for generating switching signals of a power converter. Their noise-shaping behavior results in low output distortion for output frequencies well below the modulation frequency. To directly generate the switch control signals of a traditional DC-DC converter, a first-order modulator with a two-level quantizer is preferred as they are inherently stable for the entire output range. However, the noise attenuation of a first-order modulator is limited to 20dB per decade for frequencies below the modulation frequency. Additionally, they suffer from limit cycles due to the low modulator order and 2-level quantizer resolution. To overcome this problem, a fast feedback loop is proposed that acts on disturbances introduced by the quantizer and compensates low frequency noise. As a result, an improved Delta-Sigma modulator is obtained that remains stable for almost the entire output range but also provides improved noise attenuation like that of a second-order modulator. Moreover, the output noise signature is whitened resulting in less power being present at the limit cycle frequencies.

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用于DC-DC变换器直接开关控制的改进Delta-Sigma调制器

数字德尔塔-西格玛调制器可以是一个有趣的替代脉冲宽度调制产生电源转换器的开关信号。它们的噪声整形行为导致输出频率远低于调制频率的低输出失真。为了直接产生传统的DC-DC变换器的开关控制信号，首选具有两电平量化器的一阶调制器，因为它们在整个输出范围内固有稳定。然而，对于低于调制频率的频率，一阶调制器的噪声衰减被限制为每十年20dB。此外，由于低调制器阶数和2级量化器分辨率，它们受到极限环的影响。为了克服这一问题，提出了一种快速反馈回路，对量化器引入的干扰进行补偿，并对低频噪声进行补偿。结果，得到了一个改进的Delta-Sigma调制器，它在几乎整个输出范围内保持稳定，而且还提供了像二阶调制器那样的改进的噪声衰减。此外，输出噪声特征被白化，导致在极限环频率处存在更少的功率。

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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2023 IEEE Applied Power Electronics Conference and Exposition (APEC)

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