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contributor authorLall, Pradeep
contributor authorThomas, Tony
contributor authorYadav, Vikas
contributor authorNarangaparambil, Jinesh
contributor authorLiu, Wei
date accessioned2022-02-04T21:57:11Z
date available2022-02-04T21:57:11Z
date copyright7/10/2020 12:00:00 AM
date issued2020
identifier issn1043-7398
identifier otherep_142_04_041112.pdf
identifier urihttp://yetl.yabesh.ir/yetl1/handle/yetl/4274592
description abstractThe use of flexible electronics wearable applications has prompted the need to understand the stresses imposed during human motion for a range of activities. Wearable applications may involve situations in which the electronics may be flexed-to-install, stretched or subjected to thousands cycles of dynamic flexing. In order to develop meaningful test-levels, a better understanding is needed of the use-cases, variance, and the acceleration factors. In this study, the human body motion data for walking, jumping, squats, lunges, and bicep curls were measured using a set of ten Vicon cameras to measure the position, velocity, and accelerations of a standard full-body sensor location of the human body. In addition, reliability data has been gathered on test vehicles subjected to dynamic flexing. Continuous resistance data have been gathered on circuits subjected to dynamic flexing till failure for some of the commonly used trace geometries in electronic circuits. Experimental measurements during the accelerated tests of the boards were combined with the human body motion data to model the acceleration factor for different human activities based on the flexing angles. Human motion for multiple subjects and multiple joints has been correlated to the test levels for the development of acceleration factors. Statistical analysis on the variation of the joint angles with hypothesis testing has been conducted for different subjects and for different human body actions. Acceleration factors models have been developed for walking, jumping, squats, lunges, and bicep curls.
publisherThe American Society of Mechanical Engineers (ASME)
titleAcceleration Factor Modeling of Flexible Electronic Substrates From Actual Human Body Measurements
typeJournal Paper
journal volume142
journal issue4
journal titleJournal of Electronic Packaging
identifier doi10.1115/1.4047579
journal fristpage041113-1
journal lastpage041113-10
page10
treeJournal of Electronic Packaging:;2020:;volume( 142 ):;issue: 004
contenttypeFulltext


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