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Shear-Pressure Decoupling and Accurate Perception of Shear Directions in Ionic Sensors by Analyzing the Frequency-Dependent Ionic Behavior

Wonjeong Suh, Kanghyun Ki, Tae Yeong Kim, Hyeong-Seok Choi, Anna Lee, Unyong Jeong

2023ACS Applied Materials & Interfaces15 citationsDOI

Abstract

In artificial tactile sensing, to emulate the human sense of touch, independent perception of shear force and pressure is important. Decoupling the pressure and shear force is a challenging task for ensuring stable grasping manipulation for both soft and brittle objects. This study introduces a deformable ion gel-based tactile sensor that is capable of distinguishing pressure from shear force when pressurized shear force is applied in any direction. Recognition of the decoupled forces and precise shear directions is enabled by acquiring tactile data at only two frequencies (20 Hz and 10 kHz) based on the frequency-dependent ion dynamics. This study demonstrates monitoring the changes in pressure, shear force, and shear directions while performing practical robotic actions, such as pouring a water bottle, opening a water bottle cap, and picking up a book and placing it on a shelf.

Topics & Concepts

Shear (geology)Materials scienceShear forceAcousticsDecoupling (probability)Pressure sensorTactile sensorPerceptionComputer scienceArtificial intelligenceMechanical engineeringComposite materialRobotEngineeringPhysicsControl engineeringNeuroscienceBiologyAdvanced Sensor and Energy Harvesting MaterialsTactile and Sensory InteractionsAnalytical Chemistry and Sensors
Shear-Pressure Decoupling and Accurate Perception of Shear Directions in Ionic Sensors by Analyzing the Frequency-Dependent Ionic Behavior | Litcius