System identification through online sparse Gaussian process regression with input noise

Hildo Bijl; T.B. Schön; Jan-Willem van Wingerden; Michel Verhaegen

doi:10.1016/j.ifacsc.2017.09.001

System identification through online sparse Gaussian process regression with input noise

Hildo Bijl, T.B. Schön, Jan-Willem van Wingerden, Michel Verhaegen

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

Abstract

There has been a growing interest in using non-parametric regression methods like Gaussian Process (GP) regression for system identification. GP regression does traditionally have three important downsides: (1) it is computationally intensive, (2) it cannot efficiently implement newly obtained measurements online, and (3) it cannot deal with stochastic (noisy) input points. In this paper we present an algorithm tackling all these three issues simultaneously. The resulting Sparse Online Noisy Input GP (SONIG) regression algorithm can incorporate new noisy measurements in constant runtime. A comparison has shown that it is more accurate than similar existing regression algorithms. When applied to nonlinear black-box system modeling, its performance is competitive with existing nonlinear ARX models.

Original language	English
Number of pages	11
Journal	IFAC Journal of Systems and Control
Volume	2
DOIs	https://doi.org/10.1016/j.ifacsc.2017.09.001
Publication status	Published - 2017

Keywords

Nonlinear system identification
Gaussian processes
Regression
Machine learning
Sparse methods

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10.1016/j.ifacsc.2017.09.001

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title = "System identification through online sparse Gaussian process regression with input noise",

abstract = "There has been a growing interest in using non-parametric regression methods like Gaussian Process (GP) regression for system identification. GP regression does traditionally have three important downsides: (1) it is computationally intensive, (2) it cannot efficiently implement newly obtained measurements online, and (3) it cannot deal with stochastic (noisy) input points. In this paper we present an algorithm tackling all these three issues simultaneously. The resulting Sparse Online Noisy Input GP (SONIG) regression algorithm can incorporate new noisy measurements in constant runtime. A comparison has shown that it is more accurate than similar existing regression algorithms. When applied to nonlinear black-box system modeling, its performance is competitive with existing nonlinear ARX models.",

keywords = "Nonlinear system identification, Gaussian processes, Regression, Machine learning, Sparse methods",

author = "Hildo Bijl and T.B. Sch{\"o}n and {van Wingerden}, Jan-Willem and Michel Verhaegen",

year = "2017",

doi = "10.1016/j.ifacsc.2017.09.001",

language = "English",

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journal = "IFAC Journal of Systems and Control",

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T1 - System identification through online sparse Gaussian process regression with input noise

AU - Bijl, Hildo

AU - Schön, T.B.

AU - van Wingerden, Jan-Willem

AU - Verhaegen, Michel

PY - 2017

Y1 - 2017

N2 - There has been a growing interest in using non-parametric regression methods like Gaussian Process (GP) regression for system identification. GP regression does traditionally have three important downsides: (1) it is computationally intensive, (2) it cannot efficiently implement newly obtained measurements online, and (3) it cannot deal with stochastic (noisy) input points. In this paper we present an algorithm tackling all these three issues simultaneously. The resulting Sparse Online Noisy Input GP (SONIG) regression algorithm can incorporate new noisy measurements in constant runtime. A comparison has shown that it is more accurate than similar existing regression algorithms. When applied to nonlinear black-box system modeling, its performance is competitive with existing nonlinear ARX models.

AB - There has been a growing interest in using non-parametric regression methods like Gaussian Process (GP) regression for system identification. GP regression does traditionally have three important downsides: (1) it is computationally intensive, (2) it cannot efficiently implement newly obtained measurements online, and (3) it cannot deal with stochastic (noisy) input points. In this paper we present an algorithm tackling all these three issues simultaneously. The resulting Sparse Online Noisy Input GP (SONIG) regression algorithm can incorporate new noisy measurements in constant runtime. A comparison has shown that it is more accurate than similar existing regression algorithms. When applied to nonlinear black-box system modeling, its performance is competitive with existing nonlinear ARX models.

KW - Nonlinear system identification

KW - Gaussian processes

KW - Regression

KW - Machine learning

KW - Sparse methods

U2 - 10.1016/j.ifacsc.2017.09.001

DO - 10.1016/j.ifacsc.2017.09.001

M3 - Article

SN - 2468-6018

VL - 2

JO - IFAC Journal of Systems and Control

JF - IFAC Journal of Systems and Control

ER -

System identification through online sparse Gaussian process regression with input noise

Abstract

Keywords

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