Weighted multiple multiscale entropy and its application in electroencephalography analysis of autism assessment.
10.7507/1001-5515.201806047
- Author:
Xin LI
1
,
2
;
Zhanzhou AN
1
,
3
;
Qiuyue LI
1
,
3
;
Chunyan SHI
1
,
3
;
Jie ZHANG
1
,
3
;
Jiannan KANG
4
Author Information
1. Institute of Biomedical Engineering, Yanshan University, Qinhuangdao 066004, P.R.China
2. Measurement Technology and Instrumentation Key Lab of Hebei Province, Qinhuangdao 066004, P.R.China.yddylixin@ysu.edu.cn.
3. Measurement Technology and Instrumentation Key Lab of Hebei Province, Qinhuangdao 066004, P.R.China.
4. Institute of Biomedical Engineering, Heibei University, Baoding 071028, P.R.China.
- Publication Type:Journal Article
- Keywords:
autism;
electroencephalography;
sample entropy;
weighted multiple multiscale entropy
- From:
Journal of Biomedical Engineering
2019;36(1):33-39
- CountryChina
- Language:Chinese
-
Abstract:
In this paper, a feature extraction algorithm of weighted multiple multiscale entropy is proposed to solve the problem of information loss which is caused in the multiscale process of traditional multiscale entropy. Algorithm constructs the multiple data sequences from large to small on each scale. Then, considering the different contribution degrees of multiple data sequences to the entropy of the scale, the proportion of each sequence in the scale sequence is calculated by combining the correlation between the data sequences, so as to reconstruct the sample entropy of each scale. Compared with the traditional multiscale entropy the feature extraction algorithm based on weighted multiple multiscale entropy not only overcomes the problem of information loss, but also fully considers the correlation of sequences and the contribution to total entropy. It reduces the fluctuation between scales, and digs out the details of electroencephalography (EEG). Based on this algorithm, the EEG characteristics of autism spectrum disorder (ASD) children are analyzed, and the classification accuracy of the algorithm is increased by 23.0%, 10.4% and 6.4% as compared with the EEG extraction algorithm of sample entropy, traditional multiscale entropy and multiple multiscale entropy based on the delay value method, respectively. Based on this algorithm, the 19 channel EEG signals of ASD children and healthy children were analyzed. The results showed that the entropy of healthy children was slightly higher than that of the ASD children except the FP2 channel, and the numerical differences of F3, F7, F8, C3 and P3 channels were statistically significant ( <0.05). By classifying the weighted multiple multiscale entropy of each brain region, we found that the accuracy of the anterior temporal lobe (F7, F8) was the highest. It indicated that the anterior temporal lobe can be used as a sensitive brain area for assessing the brain function of ASD children.
