Quantized Minimum Error Entropy Criterion

Badong Chen; Lei Xing; Nanning Zheng; Jose C. Principe

doi:10.1109/TNNLS.2018.2868812

Quantized Minimum Error Entropy Criterion

Badong Chen
, Lei Xing
, Nanning Zheng
, Jose C. Principe

Xi'an Jiaotong University
University of Florida

科研成果: 期刊稿件 › 文章 › 同行评审

51 引用（Scopus）

摘要

Comparing with traditional learning criteria, such as mean square error, the minimum error entropy (MEE) criterion is superior in nonlinear and non-Gaussian signal processing and machine learning. The argument of the logarithm in Renyi's entropy estimator, called information potential (IP), is a popular MEE cost in information theoretic learning. The computational complexity of IP is, however, quadratic in terms of sample number due to double summation. This creates the computational bottlenecks, especially for large-scale data sets. To address this problem, in this paper, we propose an efficient quantization approach to reduce the computational burden of IP, which decreases the complexity from ON2 to O({MN}) with M ll N. The new learning criterion is called the quantized MEE (QMEE). Some basic properties of QMEE are presented. Illustrative examples with linear-in-parameter models are provided to verify the excellent performance of QMEE.

源语言	英语
文章编号	08474935
页（从-至）	1370-1380
页数	11
期刊	IEEE Transactions on Neural Networks and Learning Systems
卷	30
期	5
DOI	https://doi.org/10.1109/TNNLS.2018.2868812
出版状态	已出版 - 5月 2019

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10.1109/TNNLS.2018.2868812

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title = "Quantized Minimum Error Entropy Criterion",

abstract = "Comparing with traditional learning criteria, such as mean square error, the minimum error entropy (MEE) criterion is superior in nonlinear and non-Gaussian signal processing and machine learning. The argument of the logarithm in Renyi's entropy estimator, called information potential (IP), is a popular MEE cost in information theoretic learning. The computational complexity of IP is, however, quadratic in terms of sample number due to double summation. This creates the computational bottlenecks, especially for large-scale data sets. To address this problem, in this paper, we propose an efficient quantization approach to reduce the computational burden of IP, which decreases the complexity from ON2 to O(\{MN\}) with M ll N. The new learning criterion is called the quantized MEE (QMEE). Some basic properties of QMEE are presented. Illustrative examples with linear-in-parameter models are provided to verify the excellent performance of QMEE.",

keywords = "Computational complexity, information theoretic learning (ITL), minimum error entropy (MEE), quantization",

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doi = "10.1109/TNNLS.2018.2868812",

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AU - Chen, Badong

AU - Xing, Lei

AU - Zheng, Nanning

AU - Principe, Jose C.

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N2 - Comparing with traditional learning criteria, such as mean square error, the minimum error entropy (MEE) criterion is superior in nonlinear and non-Gaussian signal processing and machine learning. The argument of the logarithm in Renyi's entropy estimator, called information potential (IP), is a popular MEE cost in information theoretic learning. The computational complexity of IP is, however, quadratic in terms of sample number due to double summation. This creates the computational bottlenecks, especially for large-scale data sets. To address this problem, in this paper, we propose an efficient quantization approach to reduce the computational burden of IP, which decreases the complexity from ON2 to O({MN}) with M ll N. The new learning criterion is called the quantized MEE (QMEE). Some basic properties of QMEE are presented. Illustrative examples with linear-in-parameter models are provided to verify the excellent performance of QMEE.

AB - Comparing with traditional learning criteria, such as mean square error, the minimum error entropy (MEE) criterion is superior in nonlinear and non-Gaussian signal processing and machine learning. The argument of the logarithm in Renyi's entropy estimator, called information potential (IP), is a popular MEE cost in information theoretic learning. The computational complexity of IP is, however, quadratic in terms of sample number due to double summation. This creates the computational bottlenecks, especially for large-scale data sets. To address this problem, in this paper, we propose an efficient quantization approach to reduce the computational burden of IP, which decreases the complexity from ON2 to O({MN}) with M ll N. The new learning criterion is called the quantized MEE (QMEE). Some basic properties of QMEE are presented. Illustrative examples with linear-in-parameter models are provided to verify the excellent performance of QMEE.

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Quantized Minimum Error Entropy Criterion

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