Investigation of Tactile Perception Evoked by Ridged Texture Using ERP and Non-linear Methods

Overview

Journal Front Neurosci

Date 2021 Jul 12

PMID 34248483

Citations 1

Authors

Wei Tang

Meimei Zhang

Guofang Chen

Rui Liu

Yuxing Peng

Si Chen

Yibing Shi

Chunai Hu

Shengjie Bai

Affiliations

Soon will be listed here.

Abstract

The triangular ridged surface can improve the grip reliability of products, but the sharp edge of triangular ridge induces sharp and uncomfortable feeling. To study the effect of edge shape (sharp, round, and flat shape) of triangular ridges on brain activity during touching, electroencephalograph (EEG) signals during tactile perception were evaluated using event-related potentials (ERP) and non-linear analysis methods. The results showed that the early component of P100 and P200, and the late component of P300 were successfully induced during perceiving the ridged texture. The edge shape features affect the electrical activity of brain during the tactile perceptions. The sharp shape feature evoked fast P100 latency and high P100 amplitude. The flat texture with complex (sharp and flat) shape feature evoked fast P200 latency, high P200 amplitude and RQA parameters. Both of the sharp shape and complex shape feature tended to evoke high peak amplitude of P300. The large-scale structures of recurrence plots (RPs) and recurrence quantification analysis (RQA) parameters can visually and quantitatively characterize the evolution regulation of the dynamic behavior of EEG system along with the tactile process. This study proved that RPs and RQA were protential methods for the feature extraction and state recognition of EEG during tactile perception of textured surface. This research contributes to optimize surface tactile characteristics on products, especially effective surface textures design for good grip.

Citing Articles

Study of event-related potentials by withdrawal friction on the fingertip.

Si C, Qin H, Chuanzhuang Y, Wei T, Lin X Skin Res Technol. 2022; 29(1):e13232.

PMID: 36428289 PMC: 9838764. DOI: 10.1111/srt.13232.

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