Journal
SENSORS
Volume 23, Issue 2, Pages -Publisher
MDPI
DOI: 10.3390/s23020567
Keywords
pneumatic; soft robotics; tactile sensors; variable stiffness; medical palpation
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This paper introduces a novel soft tactile sensor that can dynamically adjust its stiffness to enhance sensitivity to a wide range of applied forces. The sensor is inspired by the Eustachian tube in the mammalian ear and uses adjustable pneumatic back pressure to control the effective stiffness of its elastomer interface. It can detect forces as small as 0.012 N and differentiate between forces with a difference of 0.006 N in the range of 35 to 40 N. The sensor has the ability to detect tactile cues on sub-millimeter scale objects and can adapt its compliance to distinguish between stimuli with similar stiffnesses.
Optimising the sensitivity of a tactile sensor to a specific range of stimuli magnitude usually compromises the sensor's widespread usage. This paper presents a novel soft tactile sensor capable of dynamically tuning its stiffness for enhanced sensitivity across a range of applied forces, taking inspiration from the Eustachian tube in the mammalian ear. The sensor exploits an adjustable pneumatic back pressure to control the effective stiffness of its 20 mm diameter elastomer interface. An internally translocated fluid is coupled to the membrane and optically tracked to measure physical interactions at the interface. The sensor can be actuated by pneumatic pressure to dynamically adjust its stiffness. It is demonstrated to detect forces as small as 0.012 N, and to be sensitive to a difference of 0.006 N in the force range of 35 to 40 N. The sensor is demonstrated to be capable of detecting tactile cues on the surface of objects in the sub-millimetre scale. It is able to adapt its compliance to increase its ability for distinguishing between stimuli with similar stiffnesses (0.181 N/mm difference) over a large range (0.1 to 1.1 N/mm) from only a 0.6 mm deep palpation. The sensor is intended to interact comfortably with skin, and the feasibility of its use in palpating tissue in search of hard inclusions is demonstrated by locating and estimating the size of a synthetic hard node embedded 20 mm deep in a soft silicone sample. The results suggest that the sensor is a good candidate for tactile tasks involving unpredictable or unknown stimuli.
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