An Air-Filled Pad With Elastomeric Pillar Array Designed for a Force-Sensing Insole

Studies on footwear-based wearable devices for gait and motion monitoring have been conducted by many researchers, and the force measurement of a foot is one of the most important topics among them. In this paper, we present the design of a soft force-sensing pad for in-shoe force measurement. A for...

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Bibliographic Details
Published inIEEE sensors journal Vol. 18; no. 10; pp. 3968 - 3976
Main Authors Kim, Kanghyun, Shin, Sungwon, Kong, Kyoungchul
Format Journal Article
LanguageEnglish
Published New York IEEE 15.05.2018
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Accuracy
Compression tests
Detection
Elastomers
Error analysis
Error detection
Foot
Footwear
Force
Force measurement
force sensor
Gait
Hysteresis
Pressure measurement
Pressure sensors
Reproducibility
Robot sensing systems
Soft sensor
wearable device
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Summary:Studies on footwear-based wearable devices for gait and motion monitoring have been conducted by many researchers, and the force measurement of a foot is one of the most important topics among them. In this paper, we present the design of a soft force-sensing pad for in-shoe force measurement. A force-sensing method based on an air pressure sensor is utilized to robustly measure the force caused by compression in a shoe. To withstand the human weight, an air-filled structure with an elastomeric pillar array is designed. The force is measured by the increase in air pressure caused by pillar compression. Due to the simple sensing structure, it has the advantage that it can be made into various forms such as an insole pad. To verify the sensing performance, experiments are performed to compare its accuracy, hysteresis, and repeatability with an off-the-shelf load cell. The measured results show an accuracy error of 0.249 kgf, a hysteresis error of 1.071 kgf, and a repeatability error of 0.202 kgf. To verify the robustness of the proposed sensing pad, accuracy and precision change under nine different compression conditions is calculated, and the results show an accuracy error of 0.672 kgf. Moreover, error variation of the proposed sensing pad is about four times smaller than the widely used force-sensing resistor sensor.
ISSN:1530-437X
1558-1748
DOI:10.1109/JSEN.2018.2822685