Automatic body flexibility classification using laser doppler flowmeter

I. Chan Lien; Yung Hui Li; Jian Guo Bau

doi:10.1117/12.2199503

Automatic body flexibility classification using laser doppler flowmeter

I. Chan Lien, Yung Hui Li, Jian Guo Bau

Department of Computer Science and Information Engineering

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Body flexibility is an important indicator that can measure whether an individual is healthy or not. Traditionally, we need to prepare a protractor and the subject need to perform a pre-defined set of actions. The measurement takes place at the same time when the subject performs required action, which is clumsy and inconvenient. In this paper, we propose a statistical learning model using the technique of random forest. The proposed system can classify body flexibility based on LDF signals analyzed in the frequency domain. The reasons of using random forest are because of their efficiency (fast in classification), interpretable structures and their ability to filter out irrelevant features. In addition, using random forest can prevent the problem of over-fitting, and the output model will become more robust to noises. In our experiment, we use chirp Z-transform (CZT), to transform a LDF signal into its energy values in five frequency bands. Combining the power of the random forest algorithm and frequency band analysis methods, a maximum recognition rate of 66% is achieved. Compared to traditional flexibility measuring process, the proposed system shortens the long and tedious stages of measurement to a simple, fast and pre-defined activity set. The major contributions of our work include (1) a novel body flexibility classification scheme using non-invasive biomedical sensor; (2) a set of designed protocol which is easy to conduct and practice; (3) a high precision classification scheme which combines the power of spectrum analysis and machine learning algorithms.

Original language	English
Title of host publication	AOPC 2015
Subtitle of host publication	Advanced Display Technology; and Micro/Nano Optical Imaging Technologies and Applications
Editors	Min Gu, Xiaocong Yuan, Daniel Jaque, Yikai Su, Byoungho Lee
Publisher	SPIE
ISBN (Electronic)	9781628418972
DOIs	https://doi.org/10.1117/12.2199503
State	Published - 2015
Event	Applied Optics and Photonics, China: Advanced Display Technology; and Micro/Nano Optical Imaging Technologies and Applications, AOPC 2015 - Beijing, China Duration: 5 May 2015 → 7 May 2015

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	9672
ISSN (Print)	0277-786X
ISSN (Electronic)	1996-756X

Conference

Conference	Applied Optics and Photonics, China: Advanced Display Technology; and Micro/Nano Optical Imaging Technologies and Applications, AOPC 2015
Country/Territory	China
City	Beijing
Period	5/05/15 → 7/05/15

Keywords

Decision tree
Laser doppler flowmeter
Machine learning
Microcirculation
Random forest

Access to Document

10.1117/12.2199503

Cite this

Lien, I. C., Li, Y. H., & Bau, J. G. (2015). Automatic body flexibility classification using laser doppler flowmeter. In M. Gu, X. Yuan, D. Jaque, Y. Su, & B. Lee (Eds.), AOPC 2015: Advanced Display Technology; and Micro/Nano Optical Imaging Technologies and Applications [96720L] (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 9672). SPIE. https://doi.org/10.1117/12.2199503

Lien, I. Chan ; Li, Yung Hui ; Bau, Jian Guo. / Automatic body flexibility classification using laser doppler flowmeter. AOPC 2015: Advanced Display Technology; and Micro/Nano Optical Imaging Technologies and Applications. editor / Min Gu ; Xiaocong Yuan ; Daniel Jaque ; Yikai Su ; Byoungho Lee. SPIE, 2015. (Proceedings of SPIE - The International Society for Optical Engineering).

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abstract = "Body flexibility is an important indicator that can measure whether an individual is healthy or not. Traditionally, we need to prepare a protractor and the subject need to perform a pre-defined set of actions. The measurement takes place at the same time when the subject performs required action, which is clumsy and inconvenient. In this paper, we propose a statistical learning model using the technique of random forest. The proposed system can classify body flexibility based on LDF signals analyzed in the frequency domain. The reasons of using random forest are because of their efficiency (fast in classification), interpretable structures and their ability to filter out irrelevant features. In addition, using random forest can prevent the problem of over-fitting, and the output model will become more robust to noises. In our experiment, we use chirp Z-transform (CZT), to transform a LDF signal into its energy values in five frequency bands. Combining the power of the random forest algorithm and frequency band analysis methods, a maximum recognition rate of 66% is achieved. Compared to traditional flexibility measuring process, the proposed system shortens the long and tedious stages of measurement to a simple, fast and pre-defined activity set. The major contributions of our work include (1) a novel body flexibility classification scheme using non-invasive biomedical sensor; (2) a set of designed protocol which is easy to conduct and practice; (3) a high precision classification scheme which combines the power of spectrum analysis and machine learning algorithms.",

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Lien, IC, Li, YH & Bau, JG 2015, Automatic body flexibility classification using laser doppler flowmeter. in M Gu, X Yuan, D Jaque, Y Su & B Lee (eds), AOPC 2015: Advanced Display Technology; and Micro/Nano Optical Imaging Technologies and Applications., 96720L, Proceedings of SPIE - The International Society for Optical Engineering, vol. 9672, SPIE, Applied Optics and Photonics, China: Advanced Display Technology; and Micro/Nano Optical Imaging Technologies and Applications, AOPC 2015, Beijing, China, 5/05/15. https://doi.org/10.1117/12.2199503

Automatic body flexibility classification using laser doppler flowmeter. / Lien, I. Chan; Li, Yung Hui; Bau, Jian Guo.
AOPC 2015: Advanced Display Technology; and Micro/Nano Optical Imaging Technologies and Applications. ed. / Min Gu; Xiaocong Yuan; Daniel Jaque; Yikai Su; Byoungho Lee. SPIE, 2015. 96720L (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 9672).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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T1 - Automatic body flexibility classification using laser doppler flowmeter

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AU - Li, Yung Hui

AU - Bau, Jian Guo

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PY - 2015

Y1 - 2015

N2 - Body flexibility is an important indicator that can measure whether an individual is healthy or not. Traditionally, we need to prepare a protractor and the subject need to perform a pre-defined set of actions. The measurement takes place at the same time when the subject performs required action, which is clumsy and inconvenient. In this paper, we propose a statistical learning model using the technique of random forest. The proposed system can classify body flexibility based on LDF signals analyzed in the frequency domain. The reasons of using random forest are because of their efficiency (fast in classification), interpretable structures and their ability to filter out irrelevant features. In addition, using random forest can prevent the problem of over-fitting, and the output model will become more robust to noises. In our experiment, we use chirp Z-transform (CZT), to transform a LDF signal into its energy values in five frequency bands. Combining the power of the random forest algorithm and frequency band analysis methods, a maximum recognition rate of 66% is achieved. Compared to traditional flexibility measuring process, the proposed system shortens the long and tedious stages of measurement to a simple, fast and pre-defined activity set. The major contributions of our work include (1) a novel body flexibility classification scheme using non-invasive biomedical sensor; (2) a set of designed protocol which is easy to conduct and practice; (3) a high precision classification scheme which combines the power of spectrum analysis and machine learning algorithms.

AB - Body flexibility is an important indicator that can measure whether an individual is healthy or not. Traditionally, we need to prepare a protractor and the subject need to perform a pre-defined set of actions. The measurement takes place at the same time when the subject performs required action, which is clumsy and inconvenient. In this paper, we propose a statistical learning model using the technique of random forest. The proposed system can classify body flexibility based on LDF signals analyzed in the frequency domain. The reasons of using random forest are because of their efficiency (fast in classification), interpretable structures and their ability to filter out irrelevant features. In addition, using random forest can prevent the problem of over-fitting, and the output model will become more robust to noises. In our experiment, we use chirp Z-transform (CZT), to transform a LDF signal into its energy values in five frequency bands. Combining the power of the random forest algorithm and frequency band analysis methods, a maximum recognition rate of 66% is achieved. Compared to traditional flexibility measuring process, the proposed system shortens the long and tedious stages of measurement to a simple, fast and pre-defined activity set. The major contributions of our work include (1) a novel body flexibility classification scheme using non-invasive biomedical sensor; (2) a set of designed protocol which is easy to conduct and practice; (3) a high precision classification scheme which combines the power of spectrum analysis and machine learning algorithms.

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KW - Laser doppler flowmeter

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M3 - 會議論文篇章

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A2 - Su, Yikai

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Y2 - 5 May 2015 through 7 May 2015

ER -

Automatic body flexibility classification using laser doppler flowmeter

Abstract

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Keywords

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