Cascade principal component least squares neural network learning Algorithm

Waqar Ahmed Khan; Sai Ho Chung; Ching Yuen Chan

doi:10.23919/IConAC.2018.8748964

Cascade principal component least squares neural network learning Algorithm

Waqar Ahmed Khan
, Sai Ho Chung
, Ching Yuen Chan

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

1 Scopus citations

Abstract

Cascading correlation learning (CasCor) is a constructive algorithm which determines its own network size and typology by adding hidden units one at a time based on covariance with output error. Its generalization performance and computational time depends on the cascade architecture and iteratively tuning of the connection weights. CasCor was developed to address the slowness of backpropagation (BP), however, recent studies have concluded that in many applications, CasCor generalization performance does not guarantee to be optimal. Apart from BP, CasCor learning speed can be considered slow because of iterative tuning of connection weights by numerical optimization techniques. Therefore, this paper addresses CasCor bottlenecks and introduces a new algorithm with improved cascade architecture and tuning free learning to achieve the objectives of better generalization performance and fast learning ability. The proposed algorithm determines input connection weights by orthogonally transforming a set of correlated input units into uncorrelated hidden units and output connection weights by considering hidden units and the output units in a linear relationship. This research work is unique in that it does not need a random generation of connection weights. A comparative study on nonlinear classification and regression tasks has proven that the proposed algorithm has better generalization performance and learns many times faster than CasCor.

Original language	English
Title of host publication	ICAC 2018 - 2018 24th IEEE International Conference on Automation and Computing
Subtitle of host publication	Improving Productivity through Automation and Computing
Editors	Xiandong Ma
Publisher	Institute of Electrical and Electronics Engineers Inc.
ISBN (Electronic)	9781862203426
DOIs	https://doi.org/10.23919/IConAC.2018.8748964
State	Published - Sep 2018
Externally published	Yes

Publication series

Name	ICAC 2018 - 2018 24th IEEE International Conference on Automation and Computing: Improving Productivity through Automation and Computing

Bibliographical note

Publisher Copyright:
© 2018 Chinese Automation and Computing Society in the UK - CACSUK.

Keywords

Cascade principal component least squares
Cascading correlation learning
Connection weights
Ordinary least squares
Principal component analysis

ASJC Scopus subject areas

Process Chemistry and Technology
Computer Networks and Communications
Computer Science Applications
Industrial and Manufacturing Engineering
Mechanical Engineering
Safety, Risk, Reliability and Quality
Control and Optimization

Access to Document

10.23919/IConAC.2018.8748964

Cite this

Khan, W. A., Chung, S. H., & Chan, C. Y. (2018). Cascade principal component least squares neural network learning Algorithm. In X. Ma (Ed.), ICAC 2018 - 2018 24th IEEE International Conference on Automation and Computing: Improving Productivity through Automation and Computing Article 8748964 (ICAC 2018 - 2018 24th IEEE International Conference on Automation and Computing: Improving Productivity through Automation and Computing). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.23919/IConAC.2018.8748964

Khan, Waqar Ahmed ; Chung, Sai Ho ; Chan, Ching Yuen. / Cascade principal component least squares neural network learning Algorithm. ICAC 2018 - 2018 24th IEEE International Conference on Automation and Computing: Improving Productivity through Automation and Computing. editor / Xiandong Ma. Institute of Electrical and Electronics Engineers Inc., 2018. (ICAC 2018 - 2018 24th IEEE International Conference on Automation and Computing: Improving Productivity through Automation and Computing).

@inproceedings{bd012fd972af4c98bd217d9bbedbb15b,

title = "Cascade principal component least squares neural network learning Algorithm",

abstract = "Cascading correlation learning (CasCor) is a constructive algorithm which determines its own network size and typology by adding hidden units one at a time based on covariance with output error. Its generalization performance and computational time depends on the cascade architecture and iteratively tuning of the connection weights. CasCor was developed to address the slowness of backpropagation (BP), however, recent studies have concluded that in many applications, CasCor generalization performance does not guarantee to be optimal. Apart from BP, CasCor learning speed can be considered slow because of iterative tuning of connection weights by numerical optimization techniques. Therefore, this paper addresses CasCor bottlenecks and introduces a new algorithm with improved cascade architecture and tuning free learning to achieve the objectives of better generalization performance and fast learning ability. The proposed algorithm determines input connection weights by orthogonally transforming a set of correlated input units into uncorrelated hidden units and output connection weights by considering hidden units and the output units in a linear relationship. This research work is unique in that it does not need a random generation of connection weights. A comparative study on nonlinear classification and regression tasks has proven that the proposed algorithm has better generalization performance and learns many times faster than CasCor.",

keywords = "Cascade principal component least squares, Cascading correlation learning, Connection weights, Ordinary least squares, Principal component analysis",

author = "Khan, \{Waqar Ahmed\} and Chung, \{Sai Ho\} and Chan, \{Ching Yuen\}",

note = "Publisher Copyright: {\textcopyright} 2018 Chinese Automation and Computing Society in the UK - CACSUK.",

year = "2018",

month = sep,

doi = "10.23919/IConAC.2018.8748964",

language = "English",

series = "ICAC 2018 - 2018 24th IEEE International Conference on Automation and Computing: Improving Productivity through Automation and Computing",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

editor = "Xiandong Ma",

booktitle = "ICAC 2018 - 2018 24th IEEE International Conference on Automation and Computing",

address = "United States",

}

Khan, WA, Chung, SH & Chan, CY 2018, Cascade principal component least squares neural network learning Algorithm. in X Ma (ed.), ICAC 2018 - 2018 24th IEEE International Conference on Automation and Computing: Improving Productivity through Automation and Computing., 8748964, ICAC 2018 - 2018 24th IEEE International Conference on Automation and Computing: Improving Productivity through Automation and Computing, Institute of Electrical and Electronics Engineers Inc. https://doi.org/10.23919/IConAC.2018.8748964

Cascade principal component least squares neural network learning Algorithm. / Khan, Waqar Ahmed; Chung, Sai Ho; Chan, Ching Yuen.
ICAC 2018 - 2018 24th IEEE International Conference on Automation and Computing: Improving Productivity through Automation and Computing. ed. / Xiandong Ma. Institute of Electrical and Electronics Engineers Inc., 2018. 8748964 (ICAC 2018 - 2018 24th IEEE International Conference on Automation and Computing: Improving Productivity through Automation and Computing).

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

TY - GEN

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AU - Khan, Waqar Ahmed

AU - Chung, Sai Ho

AU - Chan, Ching Yuen

PY - 2018/9

Y1 - 2018/9

N2 - Cascading correlation learning (CasCor) is a constructive algorithm which determines its own network size and typology by adding hidden units one at a time based on covariance with output error. Its generalization performance and computational time depends on the cascade architecture and iteratively tuning of the connection weights. CasCor was developed to address the slowness of backpropagation (BP), however, recent studies have concluded that in many applications, CasCor generalization performance does not guarantee to be optimal. Apart from BP, CasCor learning speed can be considered slow because of iterative tuning of connection weights by numerical optimization techniques. Therefore, this paper addresses CasCor bottlenecks and introduces a new algorithm with improved cascade architecture and tuning free learning to achieve the objectives of better generalization performance and fast learning ability. The proposed algorithm determines input connection weights by orthogonally transforming a set of correlated input units into uncorrelated hidden units and output connection weights by considering hidden units and the output units in a linear relationship. This research work is unique in that it does not need a random generation of connection weights. A comparative study on nonlinear classification and regression tasks has proven that the proposed algorithm has better generalization performance and learns many times faster than CasCor.

AB - Cascading correlation learning (CasCor) is a constructive algorithm which determines its own network size and typology by adding hidden units one at a time based on covariance with output error. Its generalization performance and computational time depends on the cascade architecture and iteratively tuning of the connection weights. CasCor was developed to address the slowness of backpropagation (BP), however, recent studies have concluded that in many applications, CasCor generalization performance does not guarantee to be optimal. Apart from BP, CasCor learning speed can be considered slow because of iterative tuning of connection weights by numerical optimization techniques. Therefore, this paper addresses CasCor bottlenecks and introduces a new algorithm with improved cascade architecture and tuning free learning to achieve the objectives of better generalization performance and fast learning ability. The proposed algorithm determines input connection weights by orthogonally transforming a set of correlated input units into uncorrelated hidden units and output connection weights by considering hidden units and the output units in a linear relationship. This research work is unique in that it does not need a random generation of connection weights. A comparative study on nonlinear classification and regression tasks has proven that the proposed algorithm has better generalization performance and learns many times faster than CasCor.

KW - Cascade principal component least squares

KW - Cascading correlation learning

KW - Connection weights

KW - Ordinary least squares

KW - Principal component analysis

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DO - 10.23919/IConAC.2018.8748964

M3 - Conference contribution

AN - SCOPUS:85069211525

T3 - ICAC 2018 - 2018 24th IEEE International Conference on Automation and Computing: Improving Productivity through Automation and Computing

BT - ICAC 2018 - 2018 24th IEEE International Conference on Automation and Computing

A2 - Ma, Xiandong

PB - Institute of Electrical and Electronics Engineers Inc.

ER -

Khan WA, Chung SH, Chan CY. Cascade principal component least squares neural network learning Algorithm. In Ma X, editor, ICAC 2018 - 2018 24th IEEE International Conference on Automation and Computing: Improving Productivity through Automation and Computing. Institute of Electrical and Electronics Engineers Inc. 2018. 8748964. (ICAC 2018 - 2018 24th IEEE International Conference on Automation and Computing: Improving Productivity through Automation and Computing). doi: 10.23919/IConAC.2018.8748964

Cascade principal component least squares neural network learning Algorithm

Abstract

Publication series

Bibliographical note

Keywords

ASJC Scopus subject areas

Access to Document

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Cite this