%0 Book Section %1 rajendran2021ultra %A Rajendran, D. %A Ben Atitallah, B. %A Ramalingame, R. %A Quijano Jose, R.B. %A Kanoun, O. %B Advanced Sensors for Biomedical Applications. Smart Sensors, Measurement and Instrumentation %D 2021 %E Kanoun, O. %E Derbel, N. %I Cham: Springer %K a03 crc1410 %P 33-45 %R https://doi.org/10.1007/978-3-030-71225-9_2 %T Ultra Thin Nanocomposite In-Sole Pressure Sensor Matrix for Gait Analysis %V 38 %X Gait analysis plays an important role in various applications such as health care, clinical rehabilitation, sport training and pedestrian navigation. In order to monitor the human gait, an interesting approach is to analyze the foot plantar pressure distribution between the foot and the ground. In recent years, the emergence of flexible, soft and lightweight sensors facilitates the rapid technological advances in in-shoe foot pressure measurements, thereby especially carbon nanotubes-based sensors provide an outstanding solution for the implementation of flexible, soft pressure sensors in foot pressure distribution analysis. This chapter focuses on the design and implementation of multiwalled carbon nanotubes (CNT)/polydimethylsil-oxane (PDMS) based nanocomposite pressure sensors for the analysis of the foot pressure distribution. The sensor is durable, stable and shows sensitivity of 3.3 kΩ Ω /kPa and hysteresis smaller than 3.64% with maximum detectable pressure up to 217 kPa, which is suitable for the measurement of human foot pressure. The proposed sensor has been implemented in a flexible in-sole, which is designed based on normal arch foot anatomy. A total of 12 sensors are distributed in the heel, lateral back foot, midfoot and front foot. The foot pressure distribution for different persons while walking and standing using nanocomposite sensor based in-sole were investigated by measuring the changing in resistance of the pressure sensors, when pressure applied on it. It shows that foot pressure distribution is higher in the fore foot and the heel while person standing in normal position. While walking, initially the foot pressure is in the heel and then transferred to the entire foot and finally it is concentrated on the fore foot.

@inbook{rajendran2021ultra, abstract = {Gait analysis plays an important role in various applications such as health care, clinical rehabilitation, sport training and pedestrian navigation. In order to monitor the human gait, an interesting approach is to analyze the foot plantar pressure distribution between the foot and the ground. In recent years, the emergence of flexible, soft and lightweight sensors facilitates the rapid technological advances in in-shoe foot pressure measurements, thereby especially carbon nanotubes-based sensors provide an outstanding solution for the implementation of flexible, soft pressure sensors in foot pressure distribution analysis. This chapter focuses on the design and implementation of multiwalled carbon nanotubes (CNT)/polydimethylsil-oxane (PDMS) based nanocomposite pressure sensors for the analysis of the foot pressure distribution. The sensor is durable, stable and shows sensitivity of 3.3 kΩ Ω /kPa and hysteresis smaller than 3.64% with maximum detectable pressure up to 217 kPa, which is suitable for the measurement of human foot pressure. The proposed sensor has been implemented in a flexible in-sole, which is designed based on normal arch foot anatomy. A total of 12 sensors are distributed in the heel, lateral back foot, midfoot and front foot. The foot pressure distribution for different persons while walking and standing using nanocomposite sensor based in-sole were investigated by measuring the changing in resistance of the pressure sensors, when pressure applied on it. It shows that foot pressure distribution is higher in the fore foot and the heel while person standing in normal position. While walking, initially the foot pressure is in the heel and then transferred to the entire foot and finally it is concentrated on the fore foot.}, added-at = {2022-05-06T13:57:05.000+0200}, author = {Rajendran, D. and Ben Atitallah, B. and Ramalingame, R. and Quijano Jose, R.B. and Kanoun, O.}, biburl = {https://www.bibsonomy.org/bibtex/23e6c8e8f1a4d1c3c1d22f73be946f7f5/hybridsocieties}, booktitle = {Advanced Sensors for Biomedical Applications. Smart Sensors, Measurement and Instrumentation}, doi = {https://doi.org/10.1007/978-3-030-71225-9_2}, editor = {Kanoun, O. and Derbel, N.}, interhash = {22b33fada685e0882940aed79840551f}, intrahash = {3e6c8e8f1a4d1c3c1d22f73be946f7f5}, keywords = {a03 crc1410}, pages = {33-45}, publisher = {Cham: Springer}, timestamp = {2023-06-25T19:35:22.000+0200}, title = {Ultra Thin Nanocomposite In-Sole Pressure Sensor Matrix for Gait Analysis}, volume = 38, year = 2021 }