Abstract
Feature extraction is essential for classifying different motor imagery (MI) tasks in a brain-computer interface. To improve classification accuracy, we propose a novel feature extraction method in which the connectivity increment rate (CIR) of the brain function network (BFN) is extracted. First, the BFN is constructed on the basis of the threshold matrix of the Pearson correlation coefficient of the mu rhythm among the channels. In addition, a weighted BFN is constructed and expressed by the sum of the existing edge weights to characterize the cerebral cortex activation degree in different movement patterns. Then, on the basis of the topological structures of seven mental tasks, three regional networks centered on the C3, C4, and Cz channels are constructed, which are consistent with correspondence between limb movement patterns and cerebral cortex in neurophysiology. Furthermore, the CIR of each regional functional network is calculated to form three-dimensional vectors. Finally, we use the support vector machine to learn a classifier for multiclass MI tasks. Experimental results show a significant improvement and demonstrate the success of the extracted feature CIR in dealing with MI classification. Specifically, the average classification performance reaches 88.67% which is higher than other competing methods, indicating that the extracted CIR is effective for MI classification.
Highlights
Motor imagery (MI) refers to a thinking activity in which one can imagine completing a specific movement without the help of limb movements
We proposed connectivity increment rate (CIR) as a novel brain function network (BFN) feature and applied it to multiclass MI classification research
The CIR was proposed for the dynamic changes of BFN connection characteristics under different movement patterns to reflect the changes of network location and connection well
Summary
Motor imagery (MI) refers to a thinking activity in which one can imagine completing a specific movement without the help of limb movements. A weighted BFN is constructed, and the sum of the existing edge weights is used to characterize the cerebral cortex activation degree in different MIs. The main advantage of the framework is that the novel feature connectivity increment rate (CIR) is a regional network feature centered on the functional cortex area, which reflects the changes of network location and connectivity and reduces the loss of network information. (1) The construction of weighted BFNs facilitates the study of cerebral cortex activation degree in different movement patterns (2) The feature CIR can reflect the dynamic changes of the network and provides a new idea for feature extraction (3) The study of multiclass MI is conducive to expanding the instruction set of the BCI. Experimental results are presented in “Results,” followed by the discussion and conclusions in “Discussion and Conclusions”
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
