A LEARNING APPROACH TO IDENTIFICATION OF NONLINEAR PHYSIOLOGICAL SYSTEMS USING WIENER MODELS

Xingjian Jing; Natalia Angarita-Jaimes; David Simpson; Robert Allen; Philip Newland

doi:10.5220/0003163704720476

A LEARNING APPROACH TO IDENTIFICATION OF NONLINEAR PHYSIOLOGICAL SYSTEMS USING WIENER MODELS

Xingjian Jing
, Natalia Angarita-Jaimes
, David Simpson
, Robert Allen
, Philip Newland

Research output: Chapters, Conference Papers, Creative and Literary Works › RGC 32 - Refereed conference paper (with host publication) › peer-review

Abstract

The Wiener model is a natural description of many physiological systems. Although there have been a number of algorithms proposed for the identification of Wiener models, most of the existing approaches were developed under some restrictive assumptions of the system such as a white noise input, part or full invertibility of the nonlinearity, or known nonlinearity. In this study a new recursive algorithm based on Lyapunov stability theory is presented for the identification of Wiener systems with unknown and noninvertible nonlinearity and noisy data. The new algorithm can guarantee global convergence of the estimation error to a small region around zero and is as easy to implement as the well-known back propagation algorithm. Theoretical analysis and example studies show the effectiveness and advantages of the proposed method compared with the earlier approaches.

Original language	English
Title of host publication	BIOSIGNALS 2011 - Proceedings of the International Conference on Bio-Inspired Systems and Signal Processing
Editors	Fabio Babiloni, Ana Fred, Joaquim Filipe, Hugo Gamboa
Publisher	SciTePress
Pages	472-476
ISBN (Print)	978-989-8425-35-5
DOIs	https://doi.org/10.5220/0003163704720476
Publication status	Published - 2011
Externally published	Yes
Event	International Conference on Bio-Inspired Systems and Signal Processing, BIOSIGNALS 2011 - Rome, Italy Duration: 26 Jan 2011 → 29 Jan 2011

Publication series

Name	BIOSIGNALS - Proceedings of the International Conference on Bio-Inspired Systems and Signal Processing

Conference

Conference	International Conference on Bio-Inspired Systems and Signal Processing, BIOSIGNALS 2011
Place	Italy
City	Rome
Period	26/01/11 → 29/01/11

Research Keywords

Wiener models
Neuronal modelling
Noninvertible nonlinearity
Noisy data
Lyapunov stability

Access Output

10.5220/0003163704720476

Other Access Options

Check CityUHK Library

Permanent Link

Right click to copy link

Cite this

Jing, X., Angarita-Jaimes, N., Simpson, D., Allen, R., & Newland, P. (2011). A LEARNING APPROACH TO IDENTIFICATION OF NONLINEAR PHYSIOLOGICAL SYSTEMS USING WIENER MODELS. In F. Babiloni, A. Fred, J. Filipe, & H. Gamboa (Eds.), BIOSIGNALS 2011 - Proceedings of the International Conference on Bio-Inspired Systems and Signal Processing (pp. 472-476). (BIOSIGNALS - Proceedings of the International Conference on Bio-Inspired Systems and Signal Processing). SciTePress. https://doi.org/10.5220/0003163704720476

Jing, Xingjian ; Angarita-Jaimes, Natalia ; Simpson, David et al. / A LEARNING APPROACH TO IDENTIFICATION OF NONLINEAR PHYSIOLOGICAL SYSTEMS USING WIENER MODELS. BIOSIGNALS 2011 - Proceedings of the International Conference on Bio-Inspired Systems and Signal Processing. editor / Fabio Babiloni ; Ana Fred ; Joaquim Filipe ; Hugo Gamboa. SciTePress, 2011. pp. 472-476 (BIOSIGNALS - Proceedings of the International Conference on Bio-Inspired Systems and Signal Processing).

@inproceedings{f284ba81b9c640deba49c3109bfb8685,

title = "A LEARNING APPROACH TO IDENTIFICATION OF NONLINEAR PHYSIOLOGICAL SYSTEMS USING WIENER MODELS",

abstract = "The Wiener model is a natural description of many physiological systems. Although there have been a number of algorithms proposed for the identification of Wiener models, most of the existing approaches were developed under some restrictive assumptions of the system such as a white noise input, part or full invertibility of the nonlinearity, or known nonlinearity. In this study a new recursive algorithm based on Lyapunov stability theory is presented for the identification of Wiener systems with unknown and noninvertible nonlinearity and noisy data. The new algorithm can guarantee global convergence of the estimation error to a small region around zero and is as easy to implement as the well-known back propagation algorithm. Theoretical analysis and example studies show the effectiveness and advantages of the proposed method compared with the earlier approaches.",

keywords = "Wiener models, Neuronal modelling, Noninvertible nonlinearity, Noisy data, Lyapunov stability",

author = "Xingjian Jing and Natalia Angarita-Jaimes and David Simpson and Robert Allen and Philip Newland",

year = "2011",

doi = "10.5220/0003163704720476",

language = "English",

isbn = "978-989-8425-35-5",

series = "BIOSIGNALS - Proceedings of the International Conference on Bio-Inspired Systems and Signal Processing",

publisher = "SciTePress",

pages = "472--476",

editor = "Fabio Babiloni and Ana Fred and Joaquim Filipe and Hugo Gamboa",

booktitle = "BIOSIGNALS 2011 - Proceedings of the International Conference on Bio-Inspired Systems and Signal Processing",

note = "International Conference on Bio-Inspired Systems and Signal Processing, BIOSIGNALS 2011 ; Conference date: 26-01-2011 Through 29-01-2011",

}

Jing, X, Angarita-Jaimes, N, Simpson, D, Allen, R & Newland, P 2011, A LEARNING APPROACH TO IDENTIFICATION OF NONLINEAR PHYSIOLOGICAL SYSTEMS USING WIENER MODELS. in F Babiloni, A Fred, J Filipe & H Gamboa (eds), BIOSIGNALS 2011 - Proceedings of the International Conference on Bio-Inspired Systems and Signal Processing. BIOSIGNALS - Proceedings of the International Conference on Bio-Inspired Systems and Signal Processing, SciTePress, pp. 472-476, International Conference on Bio-Inspired Systems and Signal Processing, BIOSIGNALS 2011, Rome, Italy, 26/01/11. https://doi.org/10.5220/0003163704720476

A LEARNING APPROACH TO IDENTIFICATION OF NONLINEAR PHYSIOLOGICAL SYSTEMS USING WIENER MODELS. / Jing, Xingjian; Angarita-Jaimes, Natalia; Simpson, David et al.
BIOSIGNALS 2011 - Proceedings of the International Conference on Bio-Inspired Systems and Signal Processing. ed. / Fabio Babiloni; Ana Fred; Joaquim Filipe; Hugo Gamboa. SciTePress, 2011. p. 472-476 (BIOSIGNALS - Proceedings of the International Conference on Bio-Inspired Systems and Signal Processing).

Research output: Chapters, Conference Papers, Creative and Literary Works › RGC 32 - Refereed conference paper (with host publication) › peer-review

TY - GEN

T1 - A LEARNING APPROACH TO IDENTIFICATION OF NONLINEAR PHYSIOLOGICAL SYSTEMS USING WIENER MODELS

AU - Jing, Xingjian

AU - Angarita-Jaimes, Natalia

AU - Simpson, David

AU - Allen, Robert

AU - Newland, Philip

PY - 2011

Y1 - 2011

N2 - The Wiener model is a natural description of many physiological systems. Although there have been a number of algorithms proposed for the identification of Wiener models, most of the existing approaches were developed under some restrictive assumptions of the system such as a white noise input, part or full invertibility of the nonlinearity, or known nonlinearity. In this study a new recursive algorithm based on Lyapunov stability theory is presented for the identification of Wiener systems with unknown and noninvertible nonlinearity and noisy data. The new algorithm can guarantee global convergence of the estimation error to a small region around zero and is as easy to implement as the well-known back propagation algorithm. Theoretical analysis and example studies show the effectiveness and advantages of the proposed method compared with the earlier approaches.

AB - The Wiener model is a natural description of many physiological systems. Although there have been a number of algorithms proposed for the identification of Wiener models, most of the existing approaches were developed under some restrictive assumptions of the system such as a white noise input, part or full invertibility of the nonlinearity, or known nonlinearity. In this study a new recursive algorithm based on Lyapunov stability theory is presented for the identification of Wiener systems with unknown and noninvertible nonlinearity and noisy data. The new algorithm can guarantee global convergence of the estimation error to a small region around zero and is as easy to implement as the well-known back propagation algorithm. Theoretical analysis and example studies show the effectiveness and advantages of the proposed method compared with the earlier approaches.

KW - Wiener models

KW - Neuronal modelling

KW - Noninvertible nonlinearity

KW - Noisy data

KW - Lyapunov stability

UR - https://www.scopus.com/pages/publications/79960202079

UR - https://www.scopus.com/record/pubmetrics.uri?eid=2-s2.0-79960202079&origin=recordpage

U2 - 10.5220/0003163704720476

DO - 10.5220/0003163704720476

M3 - RGC 32 - Refereed conference paper (with host publication)

SN - 978-989-8425-35-5

T3 - BIOSIGNALS - Proceedings of the International Conference on Bio-Inspired Systems and Signal Processing

SP - 472

EP - 476

BT - BIOSIGNALS 2011 - Proceedings of the International Conference on Bio-Inspired Systems and Signal Processing

A2 - Babiloni, Fabio

A2 - Fred, Ana

A2 - Filipe, Joaquim

A2 - Gamboa, Hugo

PB - SciTePress

T2 - International Conference on Bio-Inspired Systems and Signal Processing, BIOSIGNALS 2011

Y2 - 26 January 2011 through 29 January 2011

ER -

Jing X, Angarita-Jaimes N, Simpson D, Allen R, Newland P. A LEARNING APPROACH TO IDENTIFICATION OF NONLINEAR PHYSIOLOGICAL SYSTEMS USING WIENER MODELS. In Babiloni F, Fred A, Filipe J, Gamboa H, editors, BIOSIGNALS 2011 - Proceedings of the International Conference on Bio-Inspired Systems and Signal Processing. SciTePress. 2011. p. 472-476. (BIOSIGNALS - Proceedings of the International Conference on Bio-Inspired Systems and Signal Processing). doi: 10.5220/0003163704720476

A LEARNING APPROACH TO IDENTIFICATION OF NONLINEAR PHYSIOLOGICAL SYSTEMS USING WIENER MODELS

Abstract

Publication series

Conference

Research Keywords

Access Output

Other Access Options

Permanent Link

Other Files and Links

Fingerprint

Cite this