Litcius/Paper detail

Compression of dynamic tactile information in the human hand

Yitian Shao, Vincent Hayward, Yon Visell

2020Science Advances49 citationsDOIOpen Access PDF

Abstract

A key problem in the study of the senses is to describe how sense organs extract perceptual information from the physics of the environment. We previously observed that dynamic touch elicits mechanical waves that propagate throughout the hand. Here, we show that these waves produce an efficient encoding of tactile information. The computation of an optimal encoding of thousands of naturally occurring tactile stimuli yielded a compact lexicon of primitive wave patterns that sparsely represented the entire dataset, enabling touch interactions to be classified with an accuracy exceeding 95%. The primitive tactile patterns reflected the interplay of hand anatomy with wave physics. Notably, similar patterns emerged when we applied efficient encoding criteria to spiking data from populations of simulated tactile afferents. This finding suggests that the biomechanics of the hand enables efficient perceptual processing by effecting a preneuronal compression of tactile information.

Topics & Concepts

Tactile sensorEncoding (memory)Tactile perceptionComputer sciencePerceptionComputationCompression (physics)Artificial intelligenceHuman–computer interactionNeurosciencePhysicsBiologyAlgorithmRobotThermodynamicsEEG and Brain-Computer InterfacesNeural dynamics and brain functionTactile and Sensory Interactions