A Closed-Form Solution to Estimate Spatially Varying Parameters in Heat and Mass Transport

Ricky J.R. van Kampen; Amritam Das; Siep Weiland; Matthijs van Berkel

doi:10.1109/LCSYS.2020.3042933

A Closed-Form Solution to Estimate Spatially Varying Parameters in Heat and Mass Transport

Ricky J.R. van Kampen (Corresponding author), Amritam Das, Siep Weiland, Matthijs van Berkel

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

Abstract

This letter presents a closed-form solution to estimate space-dependent transport parameters of a linear one dimensional diffusion-transport-reaction equation. The infinite dimensional problem is approximated by a finite dimensional model by 1) taking a frequency domain approach, 2) linear parameterization of the unknown parameters, and 3) using a semi-discretization. Assuming full state knowledge, the commonly used output error criterion is rewritten as the equation error criterion such that the problem results in linear least squares. The optimum is then given by a closed-form solution, avoiding computational expensive optimization methods. Functioning of the proposed method is illustrated by means of simulation.

Original language	English
Article number	9284622
Pages (from-to)	1681-1686
Number of pages	6
Journal	IEEE Control Systems Letters
Volume	5
Issue number	5
DOIs	https://doi.org/10.1109/LCSYS.2020.3042933
Publication status	Published - Nov 2021

Keywords

distributed parameter systems
Grey-box modeling
identification
inverse problems

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10.1109/LCSYS.2020.3042933

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abstract = "This letter presents a closed-form solution to estimate space-dependent transport parameters of a linear one dimensional diffusion-transport-reaction equation. The infinite dimensional problem is approximated by a finite dimensional model by 1) taking a frequency domain approach, 2) linear parameterization of the unknown parameters, and 3) using a semi-discretization. Assuming full state knowledge, the commonly used output error criterion is rewritten as the equation error criterion such that the problem results in linear least squares. The optimum is then given by a closed-form solution, avoiding computational expensive optimization methods. Functioning of the proposed method is illustrated by means of simulation.",

keywords = "distributed parameter systems, Grey-box modeling, identification, inverse problems",

author = "{van Kampen}, {Ricky J.R.} and Amritam Das and Siep Weiland and {van Berkel}, Matthijs",

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AU - Das, Amritam

AU - Weiland, Siep

AU - van Berkel, Matthijs

PY - 2021/11

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AB - This letter presents a closed-form solution to estimate space-dependent transport parameters of a linear one dimensional diffusion-transport-reaction equation. The infinite dimensional problem is approximated by a finite dimensional model by 1) taking a frequency domain approach, 2) linear parameterization of the unknown parameters, and 3) using a semi-discretization. Assuming full state knowledge, the commonly used output error criterion is rewritten as the equation error criterion such that the problem results in linear least squares. The optimum is then given by a closed-form solution, avoiding computational expensive optimization methods. Functioning of the proposed method is illustrated by means of simulation.

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KW - Grey-box modeling

KW - identification

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ER -

A Closed-Form Solution to Estimate Spatially Varying Parameters in Heat and Mass Transport

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Keywords

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