Structured μ-Synthesis for Nanopositioners under Payload-Induced Uncertainties: Minimising Conservatism for Robust Performance

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Structured μ-Synthesis for Nanopositioners under Payload-Induced Uncertainties: Minimising Conservatism for Robust Performance

Preprint (2026)

Author(s)

Manavi Araga (TU Delft - Mechanical Engineering)

Aditya Natu (TU Delft - Mechanical Engineering)

S. Hassan HosseinNia (TU Delft - Mechanical Engineering)

Research Group

Mechatronic Systems Design

Systems and Control

DOI related publication

https://doi.org/10.48550/ARXIV.2601.11962 Final published version

To reference this document use

https://resolver.tudelft.nl/uuid:7b156e8b-dd2c-4099-8f3c-85b9320f0953

More Info

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Publication Year

2026

Language

English

Research Group

Mechatronic Systems Design

Publisher

ArXiv

Downloads counter

15

Abstract

Most systems exhibit significant variability in their dynamics, including variations in system parameters and large high-frequency dynamic uncertainties. Traditional uncertainty modelling techniques consolidate all such variations into a single uncertainty block, often yielding overly conservative representations of the true plant behaviour. This paper introduces an uncertainty modelling framework that employs multiple structured and unstructured uncertainty blocks to reduce this conservatism. The methodology is evaluated for an industrial piezoelectric nanopositioner subject to payload-induced variations, using uncertainty models of differing complexity. A bandpass controller is synthesised via structured mixed-μ synthesis, and the resulting designs are compared in terms of conservatism of the uncertainty model, robust performance, and computational effort.