Discrete Current Controller Design using Ragazzini Method for Active Damper

R. G. Iturra, P. Thiemann
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Abstract

The capability of an active damper to suppress resonances in a wide range of harmonics frequencies and its stability depends heavily on the tracking performance of its inner current controller. Even though nowadays most of the current controllers are implemented digitally in a microcontroller or DSP, the conventional current controller design is still done in the continuous frequency domain. Later on, the current controller discretization is carried out using transformation techniques (e.g. Tustin transformation, forward rule, etc). The disadvantage of such methodology it that the current controller bandwidth is restricted to be ten times smaller than the PWM sampling frequency. This fact affects negatively the performance of the active damper and its stability especially at small values of the emulated resistance. In this paper, we present a current controller design that is carried out directly in the discrete domain using the Ragazzini method. The result is a current closed loop with a bandwidth three times higher than the bandwidth achieved by current controllers designed with traditional methods. The achieved higher bandwidth boosts the effectiveness of the active damper and pushes its stability limit forward.
基于Ragazzini方法的有源阻尼器离散电流控制器设计
主动阻尼器抑制大范围谐振频率的能力及其稳定性在很大程度上取决于其内部电流控制器的跟踪性能。尽管目前大多数电流控制器都是在微控制器或DSP中实现数字化的,但传统的电流控制器设计仍然是在连续频域中完成的。然后利用变换技术(如Tustin变换、正演规则等)对电流控制器进行离散化。这种方法的缺点是当前控制器带宽被限制为比PWM采样频率小十倍。这一事实对主动阻尼器的性能及其稳定性产生了负面影响,特别是在模拟阻力较小的情况下。在本文中,我们提出了一种电流控制器设计,该设计使用Ragazzini方法直接在离散域中进行。其结果是一个电流闭环,其带宽比用传统方法设计的电流控制器的带宽高三倍。所获得的更高带宽提高了主动阻尼器的有效性,并将其稳定性极限向前推进。
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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