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Unsupervised learning of haptic material properties

Anna Metzger, Matteo Toscani

2021eLife24 citationsDOIOpen Access PDF

Abstract

When touching the surface of an object, its spatial structure translates into a vibration on the skin. The perceptual system evolved to translate this pattern into a representation that allows to distinguish between different materials. Here, we show that perceptual haptic representation of materials emerges from efficient encoding of vibratory patterns elicited by the interaction with materials. We trained a deep neural network with unsupervised learning (Autoencoder) to reconstruct vibratory patterns elicited by human haptic exploration of different materials. The learned compressed representation (i.e., latent space) allows for classification of material categories (i.e., plastic, stone, wood, fabric, leather/wool, paper, and metal). More importantly, classification performance is higher with perceptual category labels as compared to ground truth ones, and distances between categories in the latent space resemble perceptual distances, suggesting a similar coding. Crucially, the classification performance and the similarity between the perceptual and the latent space decrease with decreasing compression level. We could further show that the temporal tuning of the emergent latent dimensions is similar to properties of human tactile receptors.

Topics & Concepts

Haptic technologyArtificial intelligencePerceptionComputer scienceRepresentation (politics)Similarity (geometry)Encoding (memory)Pattern recognition (psychology)Unsupervised learningFeature learningPerceptual systemPerceptual learningSpace (punctuation)Artificial neural networkHaptic perceptionTactile perceptionCompression (physics)Machine learningGround truthComputer visionTactile and Sensory InteractionsMusic Technology and Sound StudiesAdvanced Sensor and Energy Harvesting Materials
Unsupervised learning of haptic material properties | Litcius