基于Butterworth模式的纳米定位系统同步阻尼和跟踪控制器设计

Douglas Russell, A. San-Millán, V. F. Batlle, S. S. Aphale
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引用次数: 2

摘要

已知巴特沃斯滤波器具有最大的平坦响应。顺便提一下,精确定位系统也需要同样的响应。本文提出了一种利用积分共振控制(IRC)、正位置反馈(PPF)和正速度位置反馈(PVPF)等常用的定位控制方案获得闭环巴特沃斯滤波器的方法。仿真结果表明,与传统的设计方法相比,带宽有了显著的提高,并验证了所期望的极点位置的实现。实验采用两轴串联运动学纳米定位平台进行。结果表明,带宽和定位精度显著提高,特别是在转弯点。这允许在高扫描速度下使用更大的扫描部分并提高定位精度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Butterworth pattern based simultaneous damping and tracking controller designs for nanopositioning systems
The Butterworth filter is known to have maximally flat response. Incidentally, the same response is desired in precise positioning systems. This paper presents a method for obtaining a closed-loop Butterworth filter pattern using common control schemes for positioning applications, i.e. Integral Resonant Control (IRC), Positive Position Feedback (PPF), and Positive Velocity and Position Feedback (PVPF). Simulations show a significant increase in bandwidth over traditional design methods and verify the desired pole placement is achieved. Experiments are performed using a two-axis serial kinematic nanopositioning stage. The results show a significant improvement in bandwidth and increased positioning accuracy, specifically at the turn-around point. This allows a greater portion of the scan to be used and improved positioning accuracy at high scanning speeds.
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