Interval-based simulation of Zélus IVPs using DynIbex

Jason Brown; François Pessaux

doi:10.14232/actacyb.285246

Interval-based simulation of Zélus IVPs using DynIbex

Research output: Contribution to journal › Article › peer-review

Abstract

Modeling continuous-time dynamical systems is a complex task. Fortunately some dedicated programming languages exist to ease this work. Zélus is one such language that generates a simulation executable which can be used to study the behavior of the modeled system. However, such simulations cannot handle uncertainties on some parameters of the system. This makes it necessary to run multiple simulations to check that the system fulfills particular requirements (safety for instance) for all the values in the uncertainty ranges. Interval-based guaranteed integration methods provide a solution to this problem. The DynIbex library provides such methods but it requires a manual encoding of the system in a general purpose programming language (C++). This article presents an extension of the Zélus compiler to generate interval-based guaranteed simulations of IVPs using DynIbex. This extension is conservative since it does not break the existing compilation workflow.

Original language	English
Journal	Acta Cybernetica
Issue number	2
DOIs	https://doi.org/10.14232/actacyb.285246
Publication status	Published - 19 Aug 2020
Externally published	Yes

Keywords

Compilation
DynIbex
Guaranteed integration
Hybrid system
Interval
Simulation
Zélus

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10.14232/actacyb.285246

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@article{32009567ea714b8bb55c62f6802c7389,

title = "Interval-based simulation of Z{\'e}lus IVPs using DynIbex",

abstract = "Modeling continuous-time dynamical systems is a complex task. Fortunately some dedicated programming languages exist to ease this work. Z{\'e}lus is one such language that generates a simulation executable which can be used to study the behavior of the modeled system. However, such simulations cannot handle uncertainties on some parameters of the system. This makes it necessary to run multiple simulations to check that the system fulfills particular requirements (safety for instance) for all the values in the uncertainty ranges. Interval-based guaranteed integration methods provide a solution to this problem. The DynIbex library provides such methods but it requires a manual encoding of the system in a general purpose programming language (C++). This article presents an extension of the Z{\'e}lus compiler to generate interval-based guaranteed simulations of IVPs using DynIbex. This extension is conservative since it does not break the existing compilation workflow.",

keywords = "Compilation, DynIbex, Guaranteed integration, Hybrid system, Interval, Simulation, Z{\'e}lus",

author = "Jason Brown and Fran{\c c}ois Pessaux",

year = "2020",

month = aug,

day = "19",

doi = "10.14232/actacyb.285246",

language = "English",

journal = "Acta Cybernetica",

issn = "0324-721X",

number = "2",

}

TY - JOUR

T1 - Interval-based simulation of Zélus IVPs using DynIbex

AU - Brown, Jason

AU - Pessaux, François

PY - 2020/8/19

Y1 - 2020/8/19

N2 - Modeling continuous-time dynamical systems is a complex task. Fortunately some dedicated programming languages exist to ease this work. Zélus is one such language that generates a simulation executable which can be used to study the behavior of the modeled system. However, such simulations cannot handle uncertainties on some parameters of the system. This makes it necessary to run multiple simulations to check that the system fulfills particular requirements (safety for instance) for all the values in the uncertainty ranges. Interval-based guaranteed integration methods provide a solution to this problem. The DynIbex library provides such methods but it requires a manual encoding of the system in a general purpose programming language (C++). This article presents an extension of the Zélus compiler to generate interval-based guaranteed simulations of IVPs using DynIbex. This extension is conservative since it does not break the existing compilation workflow.

AB - Modeling continuous-time dynamical systems is a complex task. Fortunately some dedicated programming languages exist to ease this work. Zélus is one such language that generates a simulation executable which can be used to study the behavior of the modeled system. However, such simulations cannot handle uncertainties on some parameters of the system. This makes it necessary to run multiple simulations to check that the system fulfills particular requirements (safety for instance) for all the values in the uncertainty ranges. Interval-based guaranteed integration methods provide a solution to this problem. The DynIbex library provides such methods but it requires a manual encoding of the system in a general purpose programming language (C++). This article presents an extension of the Zélus compiler to generate interval-based guaranteed simulations of IVPs using DynIbex. This extension is conservative since it does not break the existing compilation workflow.

KW - Compilation

KW - DynIbex

KW - Guaranteed integration

KW - Hybrid system

KW - Interval

KW - Simulation

KW - Zélus

U2 - 10.14232/actacyb.285246

DO - 10.14232/actacyb.285246

M3 - Article

AN - SCOPUS:85105458566

SN - 0324-721X

JO - Acta Cybernetica

JF - Acta Cybernetica

IS - 2

ER -

Interval-based simulation of Zélus IVPs using DynIbex

Abstract

Keywords

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