%0 Journal Article %J IEEE Trans Neural Syst Rehabil Eng %D 2014 %T Adaptive spatio-temporal filtering for movement related potentials in EEG-based brain-computer interfaces. %A Lu, Jun %A Xie, Kan %A Dennis J. McFarland %K Algorithms %K Artificial Intelligence %K brain-computer interfaces %K Data Interpretation, Statistical %K Electroencephalography %K Evoked Potentials, Motor %K Humans %K Imagination %K Motor Cortex %K Movement %K Pattern Recognition, Automated %K Reproducibility of Results %K Sensitivity and Specificity %K Signal Processing, Computer-Assisted %K Spatio-Temporal Analysis %X Movement related potentials (MRPs) are used as features in many brain-computer interfaces (BCIs) based on electroencephalogram (EEG). MRP feature extraction is challenging since EEG is noisy and varies between subjects. Previous studies used spatial and spatio-temporal filtering methods to deal with these problems. However, they did not optimize temporal information or may have been susceptible to overfitting when training data are limited and the feature space is of high dimension. Furthermore, most of these studies manually select data windows and low-pass frequencies. We propose an adaptive spatio-temporal (AST) filtering method to model MRPs more accurately in lower dimensional space. AST automatically optimizes all parameters by employing a Gaussian kernel to construct a low-pass time-frequency filter and a linear ridge regression (LRR) algorithm to compute a spatial filter. Optimal parameters are simultaneously sought by minimizing leave-one-out cross-validation error through gradient descent. Using four BCI datasets from 12 individuals, we compare the performances of AST filter to two popular methods: the discriminant spatial pattern filter and regularized spatio-temporal filter. The results demonstrate that our AST filter can make more accurate predictions and is computationally feasible. %B IEEE Trans Neural Syst Rehabil Eng %V 22 %P 847-57 %8 07/2014 %G eng %U http://www.ncbi.nlm.nih.gov/pubmed/24723632 %N 4 %R 10.1109/TNSRE.2014.2315717 %0 Journal Article %J Journal of neural engineering %D 2013 %T Adaptive Laplacian filtering for sensorimotor rhythm-based brain-computer interfaces. %A Lu, Jun %A Dennis J. McFarland %A Jonathan Wolpaw %K assistive communication %K brain computer interface (BCI) %K brain-machine interface (BMI) %K electroencephalogram (EEG) %K leave-one-out (LOO) cross-validation %K spatial filter %X OBJECTIVE: Sensorimotor rhythms (SMRs) are 8-30 Hz oscillations in the electroencephalogram (EEG) recorded from the scalp over sensorimotor cortex that change with movement and/or movement imagery. Many brain-computer interface (BCI) studies have shown that people can learn to control SMR amplitudes and can use that control to move cursors and other objects in one, two or three dimensions. At the same time, if SMR-based BCIs are to be useful for people with neuromuscular disabilities, their accuracy and reliability must be improved substantially. These BCIs often use spatial filtering methods such as common average reference (CAR), Laplacian (LAP) filter or common spatial pattern (CSP) filter to enhance the signal-to-noise ratio of EEG. Here, we test the hypothesis that a new filter design, called an 'adaptive Laplacian (ALAP) filter', can provide better performance for SMR-based BCIs. APPROACH: An ALAP filter employs a Gaussian kernel to construct a smooth spatial gradient of channel weights and then simultaneously seeks the optimal kernel radius of this spatial filter and the regularization parameter of linear ridge regression. This optimization is based on minimizing the leave-one-out cross-validation error through a gradient descent method and is computationally feasible. MAIN RESULTS: Using a variety of kinds of BCI data from a total of 22 individuals, we compare the performances of ALAP filter to CAR, small LAP, large LAP and CSP filters. With a large number of channels and limited data, ALAP performs significantly better than CSP, CAR, small LAP and large LAP both in classification accuracy and in mean-squared error. Using fewer channels restricted to motor areas, ALAP is still superior to CAR, small LAP and large LAP, but equally matched to CSP. SIGNIFICANCE: Thus, ALAP may help to improve the accuracy and robustness of SMR-based BCIs. %B Journal of neural engineering %V 10 %P 016002 %8 02/2013 %G eng %U http://www.ncbi.nlm.nih.gov/pubmed/23220879 %R 10.1088/1741-2560/10/1/016002