Detecting temperature of small object using hybrid tactile sensor array and multi-parameter extraction analysis

Detecting temperature of small object using hybrid tactile sensor array and multi-parameter extraction analysis

An artificial hybrid tactile sensor and a signal process which can detect precisely temperature and pressure were demonstrated. Although a resistive temperature sensor has been used widely due to the easy fabrication process for tactile sensors, it was hard to detect an exact temperature value and t...

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Veröffentlicht in:Sensors and actuators. A. Physical. 2022-06, Vol.340, p.113541, Article 113541
Hauptverfasser: Kang, Min Soo, Jang, Hyun Woo, Sim, Min Kyung, Shin, Kwonsik, Kim, Dong Su, Kang, Hongki, Kwon, Hyuk-Jun, Jang, Jae Eun
Format: Artikel
Sprache:eng
Schlagworte:
Fast response time
Heat conductivity
Hybrid systems
Hybrid tactile sensor
Mathematical analysis
Object recognition
Piezoelectric pressure sensor
Piezoelectricity
Resistance factors
Resistance thermometers
Resistive temperature sensor
Response time
Sensitivity enhancement
Sensor arrays
Signal processing
Tactile sensors (robotics)
Temperature
Temperature of a small object
Temperature sensors
Thermal conductivity
Thermal resistance
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container_end_page
container_issue
container_start_page 113541
container_title Sensors and actuators. A. Physical.
container_volume 340
creator Kang, Min Soo
Jang, Hyun Woo
Sim, Min Kyung
Shin, Kwonsik
Kim, Dong Su
Kang, Hongki
Kwon, Hyuk-Jun
Jang, Jae Eun
description An artificial hybrid tactile sensor and a signal process which can detect precisely temperature and pressure were demonstrated. Although a resistive temperature sensor has been used widely due to the easy fabrication process for tactile sensors, it was hard to detect an exact temperature value and the sensor showed the slow response when an object smaller than the dimensions of the sensor structure touched the sensor. To measure the exact temperature for a small object, we conducted a signal process using two major factors, the change of resistance provided by the thermal sensor and the information on the contact dimensions acquired from piezoelectric multi-array sensors. The design of the temperature sensor was simplified by utilizing a single resistor placed on the top layer of the hybrid sensor structure to enhance the sensitivity of thermal detection. Furthermore, using the gradient of resistance change instead of a saturation value can provide more reliable data due to the minimization of thermal conductivity change among various contact situations on sensors and fast detection time. The hybrid sensor system provided area information by which the gradient values were modified, and then the actual temperature value was calculated using the two variables, slope and contact size. As a result, the hybrid sensor successfully classified temperature levels on objects up to 30 times smaller than the resistive sensor dimensions with a very fast response time of below 10 msec. [Display omitted] •We introduce a hybrid tactile sensor which employing piezoelectricity and a resistive mechanism.•Resistance change and contact dimension of hybrid sensor were processed to measure exact temperature of a small object.•We used the gradient of resistance change, which provided more reliable data compare to the saturation value.•The temperature of object 30 times smaller than a resistive sensor dimension was measured with response time below 10 msec.
doi_str_mv 10.1016/j.sna.2022.113541
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Although a resistive temperature sensor has been used widely due to the easy fabrication process for tactile sensors, it was hard to detect an exact temperature value and the sensor showed the slow response when an object smaller than the dimensions of the sensor structure touched the sensor. To measure the exact temperature for a small object, we conducted a signal process using two major factors, the change of resistance provided by the thermal sensor and the information on the contact dimensions acquired from piezoelectric multi-array sensors. The design of the temperature sensor was simplified by utilizing a single resistor placed on the top layer of the hybrid sensor structure to enhance the sensitivity of thermal detection. Furthermore, using the gradient of resistance change instead of a saturation value can provide more reliable data due to the minimization of thermal conductivity change among various contact situations on sensors and fast detection time. 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subjects Fast response time
Heat conductivity
Hybrid systems
Hybrid tactile sensor
Mathematical analysis
Object recognition
Piezoelectric pressure sensor
Piezoelectricity
Resistance factors
Resistance thermometers
Resistive temperature sensor
Response time
Sensitivity enhancement
Sensor arrays
Signal processing
Tactile sensors (robotics)
Temperature
Temperature of a small object
Temperature sensors
Thermal conductivity
Thermal resistance
title Detecting temperature of small object using hybrid tactile sensor array and multi-parameter extraction analysis
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