A Disturbance-Free Built-In Self-Test and Diagnosis Technique for DC-DC Converters

ACM Trans. Design Autom. Electr. Syst. Pub Date : 2017-12-21 DOI:10.1145/3152157

Maryam Shafiee, Navankur Beohar, Priyanka Bakliwal, Sidhanto Roy, Debashis Mandal, B. Bakkaloglu, S. Ozev

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引用次数: 5

Abstract

Complex electronic systems include multiple power domains and drastically varying dynamic power consumption patterns, requiring the use of multiple power conversion and regulation units. High-frequency switching converters have been gaining prominence in the DC-DC converter market due to their high efficiency and smaller form factor. Unfortunately, they are also subject to higher process variations, and faster in-field degradation, jeopardizing stable operation of the power supply. This article presents a technique to track changes in the dynamic loop characteristics of DC-DC converters without disturbing the normal mode of operation using a white noise–based excitation and correlation. Using multiple points for injection and analysis, we show that the degraded part can be diagnosed to take remedial action. White noise excitation is generated via a pseudo-random disturbance at reference, load current, and pulse-width modulation (PWM) nodes of the converter with the test signal energy being spread over a wide bandwidth, without significantly affecting the converter noise and ripple floor. The impulse response is extracted by correlating the random input sequence with the disturbed output generated. Test signal analysis is achieved by correlating the pseudo-random input sequence with the output response and thereby accumulating the desired behavior over time and pulling it above the noise floor of the measurement set-up. An off-the-shelf power converter, LM27402, is used as the device-under-test (DUT) for experimental verification. Experimental results show that the proposed technique can estimate converter natural frequency and quality factor (Q-factor) within ±2.5% and ±0.7% error margin respectively, over changes in load inductance and capacitance. For the diagnosis purpose, a measure of inductor's DC resistance (DCR) value, which is the inductor's series resistance and indicative of the degradation in inductor's Q-factor, is estimated within less than ±1.6% error margin.

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DC-DC变换器的无干扰内置自检诊断技术

复杂的电子系统包括多个功率域和急剧变化的动态功耗模式，需要使用多个功率转换和调节单元。高频开关变换器由于其高效率和更小的外形在DC-DC变换器市场上获得了突出的地位。不幸的是，它们也受到更高的工艺变化和更快的现场退化的影响，危及电源的稳定运行。本文介绍了一种利用基于白噪声的激励和相关技术在不干扰正常工作模式的情况下跟踪DC-DC变换器动态回路特性变化的技术。通过多点注射和分析，我们可以诊断出退化部分并采取补救措施。白噪声激励是通过转换器的参考、负载电流和脉宽调制(PWM)节点上的伪随机扰动产生的，测试信号能量分布在很宽的带宽上，对转换器噪声和纹波底没有明显影响。通过将随机输入序列与扰动输出相关联来提取脉冲响应。测试信号分析是通过将伪随机输入序列与输出响应相关联来实现的，从而随着时间的推移积累所需的行为，并将其拉到测量装置的噪声底之上。使用现成的功率转换器LM27402作为待测器件(DUT)进行实验验证。实验结果表明，该方法可以在负载电感和电容变化范围内，分别在±2.5%和±0.7%的误差范围内估计出变换器的固有频率和品质因子。出于诊断目的，对电感器直流电阻(DCR)值的测量，即电感器的串联电阻，指示电感器q因子的退化，估计误差在±1.6%以内。

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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ACM Trans. Design Autom. Electr. Syst.

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