AFC控制中离散有限增益谐振器的设计

Marcos Orellana, R. Griñó
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引用次数: 0

摘要

基于无限增益谐振器的控制技术也被称为自适应前馈抵消(AFC),已经应用了几年,主要是在连续时间。本文分析了离散时间有限增益谐振器,并从动力学行为和计算实现的角度讨论了其在实际应用中的优点。现有的优化系统鲁棒性的设计规则推广到任何类型的谐振器,无论是无限增益还是有限增益。如今,由于大多数实际实现都是通过数字系统(如数字信号处理器(dsp))来实现的,因此直接在离散时间内工作是合理的,避免了当谐振控制器通过连续时间近似离散时可能出现的任何问题。
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Design of discrete-time finite-gain resonators in AFC control
The control technique based on infinite-gain resonators also called Adaptive Feedforward Cancellation (AFC) has been used for some years, mainly in continuous time. In this article, finite-gain resonators in discrete time are analyzed and the advantages for their use in practical applications are discussed, from the perspectives of dynamical behavior and computational implementation. The existing design rules for optimizing system robustness are generalized to any kind of resonator, whether of infinite or finite gain. Nowadays, because most practical implementations are carried out by means of digital systems, such as Digital Signal Processors (DSPs), working directly in discrete time is justified, avoiding any problems that may appear when the resonant controllers are discretized by means of approximations from continuous time.
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