用于太阳能发电机和片上供电的单输入双极输出（SIBO） DC-DC升压变换器：紫苏变换器的建模和实验评估

IF 3.6 3区计算机科学 Q2 COMPUTER SCIENCE, INFORMATION SYSTEMS

IEEE Access Pub Date : 2025-09-02 DOI:10.1109/ACCESS.2025.3605109

Robert Urbina;Carlos Ivan Paez-Rueda;Germán Yamhure;Manuel R. Pérez;José Vuelvas;Manuel Fernando Párraga Meneses;Abdel Karim Hay Harb;Luis Fernando Melchior Ramirez;Gabriel Perilla Galindo;Arturo Fajardo

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引用次数: 0

摘要

混合电源转换器将开关电容级与传统的基于lc的DC/DC开关转换器级联起来，最近成为需要双极直流总线的应用的有前途的解决方案，例如光伏系统和片内OLED驱动器。然而，尽管在效率、紧凑性和实现简单性方面有明显的优势，但由于缺乏准确的建模和实验验证，它们的采用受到限制。传统的建模技术常常不能捕获这些混合拓扑的静态和动态行为。以前的一些工作要么忽略了电容损耗，要么依赖经验等效模型，而没有明确定义的方法。Perilla SIBO（单输入双极输出）升压转换器是这种新型混合转换器的代表性示例，将传统的单电感单输出（SISO）升压级与开关电容逆变器集成在一起。在早期的工作中，使用小纹波近似和电荷平衡原理推导了Perilla Boost转换器的静态模型，假设输出电容匹配和负载条件平衡，但没有考虑效率估计。本文扩展了以前的模型，以考虑负载不平衡和输出电容不匹配，并引入了一种新的分析表达式来估计变流器效率。在实际工况下进行了全面的静态建模和实验评价。该模型使用在3 V至10 V输入电压范围内工作的原型进行验证，输出功率在1 W至20 W之间。该模型的平均绝对百分比误差为5.76%，标准差为5.68%，为稳态性能预测提供了可靠的工具。转换器的动态建模以及系统设计方法的开发超出了本工作的范围。

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A Single-Input Bipolar-Output (SIBO) DC–DC Boost Converter for Solar Generators and On-Chip Power Delivery: Modeling and Experimental Assessment of the So-Called Perilla Converter

Hybrid power converters that cascade switched-capacitor stages with conventional LC-based DC/DC switching converters have recently emerged as promising solutions for applications requiring a bipolar DC bus, such as photovoltaic systems and in-chip OLED drivers. However, despite clear advantages in efficiency, compactness, and implementation simplicity, their adoption has been limited due to the lack of accurate modeling and experimental validation. Traditional modeling techniques often fail to capture the static and dynamic behavior of these hybrid topologies. Some previous works either neglected capacitive losses or relied on empirical equivalent models without a clearly defined methodology. The Perilla SIBO (Single-Input Bipolar-Output) Boost Converter is a representative example of this new class of hybrid converters, integrating a conventional Single-Inductor Single-Output (SISO) boost stage with a switched-capacitor inverter. In earlier work, a static model for the Perilla Boost converter was derived using the small-ripple approximation and charge balance principles, assuming matched output capacitors and balanced load conditions—but without considering efficiency estimation. This paper extends the previous model to account for unbalanced loading and mismatched output capacitances and introduces a novel analytical expression to estimate converter efficiency. A comprehensive static modeling and experimental evaluation is presented under realistic operating conditions. The model is validated using a prototype operating across an input voltage range of 3 V to 10 V and delivering output power between 1 W and 20 W. The proposed model achieves a mean absolute percentage error of 5.76% and a standard deviation of 5.68%, offering a reliable tool for steady-state performance prediction. The dynamic modeling of the converter, as well as the development of a systematic design methodology, are beyond the scope of this work.

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来源期刊

IEEE Access COMPUTER SCIENCE, INFORMATION SYSTEMSENGIN-ENGINEERING, ELECTRICAL & ELECTRONIC

CiteScore

9.80

自引率

7.70%

发文量

6673

审稿时长

6 weeks

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