Abstract
Brain-computer interaction (BCI) and physiological computing are terms that refer to using processed neural or physiological signals to influence human interaction with computers, environment, and each other. A major challenge in developing these systems arises from the large individual differences typically seen in the neural/physiological responses. As a result, many researchers use individually-trained recognition algorithms to process this data. In order to minimize time, cost, and barriers to use, there is a need to minimize the amount of individual training data required, or equivalently, to increase the recognition accuracy without increasing the number of user-specific training samples. One promising method for achieving this is collaborative filtering, which combines training data from the individual subject with additional training data from other, similar subjects. This paper describes a successful application of a collaborative filtering approach intended for a BCI system. This approach is based on transfer learning (TL), active class selection (ACS), and a mean squared difference user-similarity heuristic. The resulting BCI system uses neural and physiological signals for automatic task difficulty recognition. TL improves the learning performance by combining a small number of user-specific training samples with a large number of auxiliary training samples from other similar subjects. ACS optimally selects the classes to generate user-specific training samples. Experimental results on 18 subjects, using both nearest neighbors and support vector machine classifiers, demonstrate that the proposed approach can significantly reduce the number of user-specific training data samples. This collaborative filtering approach will also be generalizable to handling individual differences in many other applications that involve human neural or physiological data, such as affective computing.
Highlights
Future technologies that allow computer systems to adapt to individual users – or even to the current cognitive/affective state of the user – have many potential applications including entertainment, training, communication, and medicine
An example of this may be found in our earlier work [5], in which we used a support vector machine (SVM) to classify three task difficulty levels from neural and physiological signals while a user was immersed in a virtual reality based Stroop task [6], which has been shown to have high individual differences in neural and physiological response as the task difficulty varies [7]
In our previous research we have shown that Transfer Learning (TL) can improve classification performance compared with a baseline that uses only the user-specific training samples [30], and Active Class Selection (ACS) can improve classification performance compared with a baseline that selects the classes uniformly [31]
Summary
Future technologies that allow computer systems to adapt to individual users – or even to the current cognitive/affective state of the user – have many potential applications including entertainment, training, communication, and medicine. While it is possible to train a generic model with group or normative data, in practice this tends to result in significantly lower performance than calibrating with individual data [4] An example of this may be found in our earlier work [5], in which we used a support vector machine (SVM) to classify three task difficulty levels from neural and physiological signals while a user was immersed in a virtual reality based Stroop task [6], which has been shown to have high individual differences in neural and physiological response as the task difficulty varies [7]. This paper presents theory and experimental results on a collaborative filtering approach which combine TL and ACS for learning an optimal classifier from a minimum amount of user-specific training data samples. We propose an optimized procedure to generate the user-specific training data online
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
