Tactile perception of textile fabrics using event-related potentials and nonlinear methods

Abstract

Tactile perception is processed in the somatosensory cortices of the brain. To study the electrical activity of the brain evoked by the tactile perceptions of fabric textures, electroencephalograph signals during tactile perception were evaluated using event-related potentials and recurrence quantification analysis methods. A support vector machine was used to realize the identification of electroencephalograph signals. The results showed that fabric surface with large surface roughness, critical buckling force, and fiber diameter, and low warp-weft density was preferentially perceived, need large attentional resources, and evoke strong nonstationary state of the electroencephalographic system during the tactile perception. The δ rhythm was the main rhythm of event-related potential signals evoked by tactile perception of fabrics and the main energy of the electroencephalograph rhythm was concentrated in the low frequency band. The electroencephalographic system was in a strong nonstationary and fluctuating state during the production stage of P200 and P300 components of the event-related potential wave. The combination of P200, P300, mean diagonal line length L, and trapping time TT can significantly improve the classification accuracy of the electroencephalograph signal of tactile perception to about 72%.