Imbalanced High-Current Multi-Phase Buck Converters for High-Performance CPUs

2019 IEEE 62nd International Midwest Symposium on Circuits and Systems (MWSCAS) Pub Date : 2019-08-01 DOI:10.1109/MWSCAS.2019.8885141

Manmeet Singh, A. Fayed

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引用次数: 5

Abstract

High-performance CPUs require buck converters with high-current ratings (4-12 A), fast dynamic response, and high efficiency across a wide load range. The most common approach for realizing such buck converters is the conventional multi-phase topology with phase-shedding, where all the active phases are identical in terms of the inductor, the switching frequency, and the share of the total load current, i.e. balanced phases. Instead, this paper proposes using a different inductor, switching frequency, and share of the total load current for each individual phase, i.e. imbalanced phases. This approach provides additional degrees of freedom by the independent choice of the inductor and the switching frequency of each phase, which enables higher maximum load current rating and higher efficiency across the entire load current range compared to conventional balanced multi-phase designs. To demonstrate the viability and the advantages of imbalanced multi-phase buck converters in high-current application, a 12-A 4-phase design in 0.13-µm CMOS for high-performance CPUs is presented and compared to three conventional balanced reference designs in the same process technology.

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用于高性能cpu的不平衡大电流多相降压转换器

高性能cpu需要具有高额定电流(4-12 A)、快速动态响应和宽负载范围内高效率的降压转换器。实现这种降压变换器的最常见方法是具有减相的传统多相拓扑结构，其中所有的有源相在电感、开关频率和总负载电流的份额(即平衡相位)方面是相同的。相反，本文建议使用不同的电感、开关频率和每个单独相位(即不平衡相位)的总负载电流份额。这种方法通过独立选择电感器和每个相位的开关频率提供了额外的自由度，与传统的平衡多相设计相比，在整个负载电流范围内实现更高的最大负载电流额定值和更高的效率。为了证明非平衡多相降压变换器在大电流应用中的可行性和优势，提出了一种用于高性能cpu的0.13µm CMOS 12-A 4相设计，并与相同工艺技术下的三种传统平衡参考设计进行了比较。

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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2019 IEEE 62nd International Midwest Symposium on Circuits and Systems (MWSCAS)

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