Design and characterization of a three-axis hall effect-based soft skin sensor

Tito Pradhono Tomo; Sophon Somlor; Alexander Schmitz; Lorenzo Jamone; Weijie Huang; Harris Kristanto; Shigeki Sugano

doi:10.3390/s16040491

Design and characterization of a three-axis hall effect-based soft skin sensor

Tito Pradhono Tomo^*, Sophon Somlor, Alexander Schmitz, Lorenzo Jamone, Weijie Huang, Harris Kristanto, Shigeki Sugano

^*この研究の対応する著者

研究成果: Article › 査読

86 被引用数 (Scopus)

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This paper presents an easy means to produce a 3-axis Hall effect–based skin sensor for robotic applications. It uses an off-the-shelf chip and is physically small and provides digital output. Furthermore, the sensor has a soft exterior for safe interactions with the environment; in particular it uses soft silicone with about an 8 mm thickness. Tests were performed to evaluate the drift due to temperature changes, and a compensation using the integral temperature sensor was implemented. Furthermore, the hysteresis and the crosstalk between the 3-axis measurements were evaluated. The sensor is able to detect minimal forces of about 1 gf. The sensor was calibrated and results with total forces up to 1450 gf in the normal and tangential directions of the sensor are presented. The test revealed that the sensor is able to measure the different components of the force vector.

本文言語	English
ジャーナル	Sensors (Switzerland)
巻	16
号	4
DOI	https://doi.org/10.3390/s16040491
出版ステータス	Published - 2016 4月 7

ASJC Scopus subject areas

分析化学
情報システム
原子分子物理学および光学
生化学
器械工学
電子工学および電気工学

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title = "Design and characterization of a three-axis hall effect-based soft skin sensor",

abstract = "This paper presents an easy means to produce a 3-axis Hall effect–based skin sensor for robotic applications. It uses an off-the-shelf chip and is physically small and provides digital output. Furthermore, the sensor has a soft exterior for safe interactions with the environment; in particular it uses soft silicone with about an 8 mm thickness. Tests were performed to evaluate the drift due to temperature changes, and a compensation using the integral temperature sensor was implemented. Furthermore, the hysteresis and the crosstalk between the 3-axis measurements were evaluated. The sensor is able to detect minimal forces of about 1 gf. The sensor was calibrated and results with total forces up to 1450 gf in the normal and tangential directions of the sensor are presented. The test revealed that the sensor is able to measure the different components of the force vector.",

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AU - Jamone, Lorenzo

AU - Huang, Weijie

AU - Kristanto, Harris

AU - Sugano, Shigeki

PY - 2016/4/7

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N2 - This paper presents an easy means to produce a 3-axis Hall effect–based skin sensor for robotic applications. It uses an off-the-shelf chip and is physically small and provides digital output. Furthermore, the sensor has a soft exterior for safe interactions with the environment; in particular it uses soft silicone with about an 8 mm thickness. Tests were performed to evaluate the drift due to temperature changes, and a compensation using the integral temperature sensor was implemented. Furthermore, the hysteresis and the crosstalk between the 3-axis measurements were evaluated. The sensor is able to detect minimal forces of about 1 gf. The sensor was calibrated and results with total forces up to 1450 gf in the normal and tangential directions of the sensor are presented. The test revealed that the sensor is able to measure the different components of the force vector.

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Design and characterization of a three-axis hall effect-based soft skin sensor

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