Scaled Graph Bounding Techniques for Reset Systems

T. de Groot; W.P.M.H. Heemels; T.A.E. Oomen; S.J.A.M. van den Eijnden

Scaled Graph Bounding Techniques for Reset Systems

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Abstract

Reset systems can overcome fundamental limitations of linear time-invariant control. The recently introduced notion of scaled (relative) graphs provides a promising framework for developing graphical analysis and design tools for reset systems, in line with widely adopted loopshaping methods for linear systems. The aim of this paper is to derive techniques for over-bounding the scaled graph of reset systems, and obtain insights in their accuracy. We exploit connections between quadratic dissipativity and scaled graphs to recast the over-bounding problem as the search for piecewise quadratic storage functions. Using specific sampling techniques, we reveal a fundamental limitation of general scaled graph approximation methods that are based on quadratic dissipativity.

Original language	English
Number of pages	6
Journal	IFAC-PapersOnLine
Volume	XX
Publication status	Accepted/In press - 2026

Funding

The research leading to these results has partially received funding from the European Research Council under the Advanced ERC Grant Agreement PROACTHIS, no. 101055384.

Keywords

Scaled Graphs
Reset Systems
linear matrix inequalities

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Cite this

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title = "Scaled Graph Bounding Techniques for Reset Systems",

abstract = "Reset systems can overcome fundamental limitations of linear time-invariant control. The recently introduced notion of scaled (relative) graphs provides a promising framework for developing graphical analysis and design tools for reset systems, in line with widely adopted loopshaping methods for linear systems. The aim of this paper is to derive techniques for over-bounding the scaled graph of reset systems, and obtain insights in their accuracy. We exploit connections between quadratic dissipativity and scaled graphs to recast the over-bounding problem as the search for piecewise quadratic storage functions. Using specific sampling techniques, we reveal a fundamental limitation of general scaled graph approximation methods that are based on quadratic dissipativity. ",

keywords = "Scaled Graphs, Reset Systems, linear matrix inequalities",

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year = "2026",

language = "English",

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T1 - Scaled Graph Bounding Techniques for Reset Systems

AU - de Groot, T.

AU - Heemels, W.P.M.H.

AU - Oomen, T.A.E.

AU - van den Eijnden, S.J.A.M.

PY - 2026

Y1 - 2026

N2 - Reset systems can overcome fundamental limitations of linear time-invariant control. The recently introduced notion of scaled (relative) graphs provides a promising framework for developing graphical analysis and design tools for reset systems, in line with widely adopted loopshaping methods for linear systems. The aim of this paper is to derive techniques for over-bounding the scaled graph of reset systems, and obtain insights in their accuracy. We exploit connections between quadratic dissipativity and scaled graphs to recast the over-bounding problem as the search for piecewise quadratic storage functions. Using specific sampling techniques, we reveal a fundamental limitation of general scaled graph approximation methods that are based on quadratic dissipativity.

AB - Reset systems can overcome fundamental limitations of linear time-invariant control. The recently introduced notion of scaled (relative) graphs provides a promising framework for developing graphical analysis and design tools for reset systems, in line with widely adopted loopshaping methods for linear systems. The aim of this paper is to derive techniques for over-bounding the scaled graph of reset systems, and obtain insights in their accuracy. We exploit connections between quadratic dissipativity and scaled graphs to recast the over-bounding problem as the search for piecewise quadratic storage functions. Using specific sampling techniques, we reveal a fundamental limitation of general scaled graph approximation methods that are based on quadratic dissipativity.

KW - Scaled Graphs

KW - Reset Systems

KW - linear matrix inequalities

M3 - Conference article

SN - 2405-8963

VL - XX

JO - IFAC-PapersOnLine

JF - IFAC-PapersOnLine

ER -

Scaled Graph Bounding Techniques for Reset Systems

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Keywords

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