TWO-STAGE VOLTAGE REGULATOR FED VOLTAGE CONTROL USING PIC MICRO CONTROLLER

2022 International Virtual Conference on Power Engineering Computing and Control: Developments in Electric Vehicles and Energy Sector for Sustainable Future (PECCON) Pub Date : 2022-05-05 DOI:10.1109/PECCON55017.2022.9851075

S. Vijayalakshmi, S. Magibalan, M. Marimuthu, S. Emmanuvel, M. Dinesh, B. Paranthagan, V. Gokul

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Abstract

For today's laptops, computer peripherals, and light load efficiency, improving battery life is a major task. High-end server applications are increasingly focusing on the dual step 48V into 12V into 1.8V VRM (Voltage Regulator Module) configuration. Because it efficiently delivers the isolated 12V output, the Inductor-Inductor-Capacitor (LLC) dc-dc converters are the recommended option of the initial step of conversion. The multi-phase Buck converter next converts it to 1.8V. Because the switching loss is lower, this study offers a high-efficiency half-bridge inverter LC resonant circuit, followed by a full-wave diode rectifier. Because of the LLC's reduced core loss and the multi-phase Buck converter's lower switching loss, as well as the simplified converter architecture's reduced number of switches, total light load efficiency will improve significantly. A step-down transformer is then used to lower the inverter voltage. Experiments on the two-stage VRM reveal a fast transient response as well as a light load and an improved efficiency, high compactness 48V into 12V into 1.8V Inductor Inductor Capacitor is built. The outcomes of the experiment reveal the benefits of the approaches proposed.

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采用PIC单片机对两级稳压器进行电压控制

对于今天的笔记本电脑、计算机外围设备和轻负载效率来说，提高电池寿命是一项主要任务。高端服务器应用越来越关注48V到12V到1.8V的双阶VRM(稳压模块)配置。因为它有效地提供隔离的12V输出，电感-电感-电容(LLC) dc-dc转换器是转换初始步骤的推荐选择。多相Buck转换器接下来将其转换为1.8V。由于开关损耗较低，本研究提出了一种高效率的半桥逆变LC谐振电路，然后是全波二极管整流器。由于LLC降低了铁芯损耗，多相Buck变换器降低了开关损耗，简化了变换器架构，减少了开关数量，因此总轻载效率将得到显著提高。然后使用降压变压器降低逆变器电压。在两级VRM上进行的实验表明，该级VRM具有瞬态响应快、负载轻、效率高、结构紧凑的特点，实现了48V转12V转1.8V的电感电容。实验结果显示了所提出方法的好处。

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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2022 International Virtual Conference on Power Engineering Computing and Control: Developments in Electric Vehicles and Energy Sector for Sustainable Future (PECCON)

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