Loop-shaping for reset control systems -- A higher-order sinusoidal-input describing functions approach

TL;DR

This paper extends frequency-domain analysis tools for reset control systems using higher-order sinusoidal-input describing functions, enabling better loop-shaping and performance prediction in precision motion control applications.

Contribution

It introduces HOSIDFs for reset controllers and a novel method linking open-loop and closed-loop frequency responses, improving design and analysis accuracy.

Findings

HOSIDFs provide deeper insight into reset control behaviour.

The proposed method accurately estimates closed-loop sensitivity functions.

Experimental validation confirms the approach's effectiveness.

Abstract

The ever-growing demands on speed and precision from the precision motion industry have pushed control requirements to reach the limitations of linear control theory. Nonlinear controllers like reset provide a viable alternative since they can be easily integrated into the existing linear controller structure and designed using industry-preferred loop-shaping techniques. However, currently, loop-shaping is achieved using the describing function (DF) and performance analysed using linear control sensitivity functions not applicable for reset control systems, resulting in a significant deviation between expected and practical results. We overcome this major bottleneck to the wider adaptation of reset control with two contributions in this paper. First, we present the extension of frequency-domain tools for reset controllers in the form of higher-order sinusoidal-input describing functions (HOSIDFs) providing greater insight into their behaviour. Second, we propose a novel method which uses the DF and HOSIDFs of the open-loop reset control system for the estimation of the closed-loop sensitivity functions, establishing for the first time - the relation between open-loop and closed-loop behaviour of reset control systems in the frequency domain. The accuracy of the proposed solution is verified in both simulation and practice on a precision positioning stage and these results are further analysed to obtain insights into the tuning considerations for reset controllers.