Least-squares support vector machines modelization for time-resolved spectroscopy

Fabien Chauchard; Sylvie Roussel; Jean Michel Roger; Véronique Bellon-Maurel; Christoffer Abrahamsson; Tomas Svensson; Stefan Andersson-Engels; Sune Svanberg

doi:10.1364/AO.44.007091

Least-squares support vector machines modelization for time-resolved spectroscopy

Fabien Chauchard
, Sylvie Roussel
, Jean Michel Roger
, Véronique Bellon-Maurel
, Christoffer Abrahamsson
, Tomas Svensson
, Stefan Andersson-Engels
, Sune Svanberg

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

Abstract

By use of time-resolved spectroscopy it is possible to separate light scattering effects from chemical absorption effects in samples. In the study of propagation of short light pulses in turbid samples the reduced scattering coefficient and the absorption coefficient are usually obtained by fitting diffusion or Monte Carlo models to the measured data by use of numerical optimization techniques. In this study we propose a prediction model obtained with a semiparametric modeling technique: the least-squares support vector machines. The main advantage of this technique is that it uses theoretical time dispersion curves during the calibration step. Predictions can then be performed by use of data measured on different kinds of sample, such as apples.

Original language	English
Pages (from-to)	7091-7097
Number of pages	7
Journal	Applied Optics
Volume	44
Issue number	33
DOIs	https://doi.org/10.1364/AO.44.007091
Publication status	Published - 20 Nov 2005
Externally published	Yes

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10.1364/AO.44.007091

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title = "Least-squares support vector machines modelization for time-resolved spectroscopy",

abstract = "By use of time-resolved spectroscopy it is possible to separate light scattering effects from chemical absorption effects in samples. In the study of propagation of short light pulses in turbid samples the reduced scattering coefficient and the absorption coefficient are usually obtained by fitting diffusion or Monte Carlo models to the measured data by use of numerical optimization techniques. In this study we propose a prediction model obtained with a semiparametric modeling technique: the least-squares support vector machines. The main advantage of this technique is that it uses theoretical time dispersion curves during the calibration step. Predictions can then be performed by use of data measured on different kinds of sample, such as apples.",

author = "Fabien Chauchard and Sylvie Roussel and Roger, \{Jean Michel\} and V{\'e}ronique Bellon-Maurel and Christoffer Abrahamsson and Tomas Svensson and Stefan Andersson-Engels and Sune Svanberg",

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AU - Chauchard, Fabien

AU - Roussel, Sylvie

AU - Roger, Jean Michel

AU - Bellon-Maurel, Véronique

AU - Abrahamsson, Christoffer

AU - Svensson, Tomas

AU - Andersson-Engels, Stefan

AU - Svanberg, Sune

PY - 2005/11/20

Y1 - 2005/11/20

N2 - By use of time-resolved spectroscopy it is possible to separate light scattering effects from chemical absorption effects in samples. In the study of propagation of short light pulses in turbid samples the reduced scattering coefficient and the absorption coefficient are usually obtained by fitting diffusion or Monte Carlo models to the measured data by use of numerical optimization techniques. In this study we propose a prediction model obtained with a semiparametric modeling technique: the least-squares support vector machines. The main advantage of this technique is that it uses theoretical time dispersion curves during the calibration step. Predictions can then be performed by use of data measured on different kinds of sample, such as apples.

AB - By use of time-resolved spectroscopy it is possible to separate light scattering effects from chemical absorption effects in samples. In the study of propagation of short light pulses in turbid samples the reduced scattering coefficient and the absorption coefficient are usually obtained by fitting diffusion or Monte Carlo models to the measured data by use of numerical optimization techniques. In this study we propose a prediction model obtained with a semiparametric modeling technique: the least-squares support vector machines. The main advantage of this technique is that it uses theoretical time dispersion curves during the calibration step. Predictions can then be performed by use of data measured on different kinds of sample, such as apples.

UR - https://www.scopus.com/pages/publications/29144434987

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SN - 1559-128X

VL - 44

SP - 7091

EP - 7097

JO - Applied Optics

JF - Applied Optics

IS - 33

ER -

Least-squares support vector machines modelization for time-resolved spectroscopy

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