TY - JOUR
T1 - Granger Causality Analysis Based on Quantized Minimum Error Entropy Criterion
AU - Chen, Badong
AU - Ma, Rongjin
AU - Yu, Siyu
AU - Du, Shaoyi
AU - Qin, Jing
N1 - Funding Information:
Manuscript received November 4, 2018; revised December 21, 2018; accepted December 31, 2018. Date of publication January 4, 2019; date of current version January 16, 2019. This work was supported in part by 973 Program 2015CB351703 and in part by National NSF of China under Grants 91648208 and U1613219. The associate editor coordinating the review of this manuscript and approving it for publication was M. Huemer. (Corresponding author: Badong Chen.) B. Chen, R. Ma, S. Yu, and S. Du are with the Institute of Artificial Intelligence and Robotics, School of Electronic and Information Engineering, Xi’an Jiaotong University, Xi’an 710049, China (e-mail:, [email protected]; [email protected]; [email protected]; [email protected]).
Publisher Copyright:
© 1994-2012 IEEE.
PY - 2019/2
Y1 - 2019/2
N2 - Linear regression model (LRM) based on mean square error (MSE) criterion is widely used in Granger causality analysis (GCA), which is the most commonly used method to detect the causality between a pair of time series. However, when signals are seriously contaminated by non-Gaussian noises, the LRM coefficients will be inaccurately identified. This may cause the GCA to detect a wrong causal relationship. Minimum error entropy (MEE) criterion can be used to replace the MSE criterion to deal with the non-Gaussian noises. But its calculation requires a double summation operation, which brings computational bottlenecks to GCA especially when sizes of the signals are large. To address the aforementioned problems, in this letter, we propose a new method called GCA based on the quantized MEE (QMEE) criterion (GCA-QMEE), in which the QMEE criterion is applied to identify the LRM coefficients and the quantized error entropy is used to calculate the causality indexes. Compared with the traditional GCA, the proposed GCA-QMEE not only makes the results more discriminative, but also more robust. Its computational complexity is also not high because of the quantization operation. Illustrative examples on synthetic and EEG datasets are provided to verify the desirable performance and the availability of the GCA-QMEE.
AB - Linear regression model (LRM) based on mean square error (MSE) criterion is widely used in Granger causality analysis (GCA), which is the most commonly used method to detect the causality between a pair of time series. However, when signals are seriously contaminated by non-Gaussian noises, the LRM coefficients will be inaccurately identified. This may cause the GCA to detect a wrong causal relationship. Minimum error entropy (MEE) criterion can be used to replace the MSE criterion to deal with the non-Gaussian noises. But its calculation requires a double summation operation, which brings computational bottlenecks to GCA especially when sizes of the signals are large. To address the aforementioned problems, in this letter, we propose a new method called GCA based on the quantized MEE (QMEE) criterion (GCA-QMEE), in which the QMEE criterion is applied to identify the LRM coefficients and the quantized error entropy is used to calculate the causality indexes. Compared with the traditional GCA, the proposed GCA-QMEE not only makes the results more discriminative, but also more robust. Its computational complexity is also not high because of the quantization operation. Illustrative examples on synthetic and EEG datasets are provided to verify the desirable performance and the availability of the GCA-QMEE.
KW - Granger causality analysis
KW - linear regression model
KW - mean square error criterion
KW - minimum error entropy criterion
KW - quantized minimum error entropy criterion
UR - http://www.scopus.com/inward/record.url?scp=85060581701&partnerID=8YFLogxK
U2 - 10.1109/LSP.2019.2890973
DO - 10.1109/LSP.2019.2890973
M3 - Journal article
AN - SCOPUS:85060581701
SN - 1070-9908
VL - 26
SP - 347
EP - 351
JO - IEEE Signal Processing Letters
JF - IEEE Signal Processing Letters
IS - 2
M1 - 8601314
ER -