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Autores principales: Yamamoto, Seiichi, Ishizuka, Hiroki, Kawasetsu, Takumi, Hosoda, Koh, Kameoka, Takayuki, Yanagida, Kango, Horii, Takato, Ikeda, Sei, Oshiro, Osamu
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2511.06311
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author Yamamoto, Seiichi
Ishizuka, Hiroki
Kawasetsu, Takumi
Hosoda, Koh
Kameoka, Takayuki
Yanagida, Kango
Horii, Takato
Ikeda, Sei
Oshiro, Osamu
author_facet Yamamoto, Seiichi
Ishizuka, Hiroki
Kawasetsu, Takumi
Hosoda, Koh
Kameoka, Takayuki
Yanagida, Kango
Horii, Takato
Ikeda, Sei
Oshiro, Osamu
contents We present a tactile sensing method enabled by the mechanical compliance of soft robots; an externally attachable photoreflective module reads surface deformation of silicone skin to estimate contact force without embedding tactile transducers. Locating the sensor off the contact interface reduces damage risk, preserves softness, and simplifies fabrication and maintenance. We first characterize the optical sensing element and the compliant skin, thendetermine the design of a prototype tactile sensor. Compression experiments validate the approach, exhibiting a monotonic force output relationship consistent with theory, low hysteresis, high repeatability over repeated cycles, and small response indentation speeds. We further demonstrate integration on a soft robotic gripper, where the module reliably detects grasp events. Compared with liquid filled or wireembedded tactile skins, the proposed modular add on architecture enhances durability, reduces wiring complexity, and supports straightforward deployment across diverse robot geometries. Because the sensing principle reads skin strain patterns, it also suggests extensions to other somatosensory cues such as joint angle or actuator state estimation from surface deformation. Overall, leveraging surface compliance with an external optical module provides a practical and robust route to equip soft robots with force perception while preserving structural flexibility and manufacturability, paving the way for robotic applications and safe human robot collaboration.
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id arxiv_https___arxiv_org_abs_2511_06311
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle External Photoreflective Tactile Sensing Based on Surface Deformation Measurement
Yamamoto, Seiichi
Ishizuka, Hiroki
Kawasetsu, Takumi
Hosoda, Koh
Kameoka, Takayuki
Yanagida, Kango
Horii, Takato
Ikeda, Sei
Oshiro, Osamu
Robotics
We present a tactile sensing method enabled by the mechanical compliance of soft robots; an externally attachable photoreflective module reads surface deformation of silicone skin to estimate contact force without embedding tactile transducers. Locating the sensor off the contact interface reduces damage risk, preserves softness, and simplifies fabrication and maintenance. We first characterize the optical sensing element and the compliant skin, thendetermine the design of a prototype tactile sensor. Compression experiments validate the approach, exhibiting a monotonic force output relationship consistent with theory, low hysteresis, high repeatability over repeated cycles, and small response indentation speeds. We further demonstrate integration on a soft robotic gripper, where the module reliably detects grasp events. Compared with liquid filled or wireembedded tactile skins, the proposed modular add on architecture enhances durability, reduces wiring complexity, and supports straightforward deployment across diverse robot geometries. Because the sensing principle reads skin strain patterns, it also suggests extensions to other somatosensory cues such as joint angle or actuator state estimation from surface deformation. Overall, leveraging surface compliance with an external optical module provides a practical and robust route to equip soft robots with force perception while preserving structural flexibility and manufacturability, paving the way for robotic applications and safe human robot collaboration.
title External Photoreflective Tactile Sensing Based on Surface Deformation Measurement
topic Robotics
url https://arxiv.org/abs/2511.06311