Constraining the Body for Better Force-Tracking Analysis
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My work has two goals: to develop a method capable of comfortably isolating a single group of muscles to improve in vivo human muscle testing and to investigate how well humans can track target force profiles.
I designed, built, and tested a system for isolating leg-extensor muscles (muscles that lift the lower leg) and for measuring knee
extension forces during an interactive tracking experiment featuring computer feedback. The chair was designed to isolate the leg-extensor muscle and to eliminate movement by forming rigid connections to the
body. When properly constrained in the chair, the maximum movement observed during "fixed" leg angle experiments was a leg rotation of ~1 degree.
In the first force-tracking experiments, the test subject tracked a periodic target force function at a fixed leg angle. In the second
experiments, the subject attempted to match a constant, ramp, or sine wave force profile as her leg angle was being oscillated from 90 degrees to 120 degrees by a motor. Target wave frequencies for the fixed-angle experiments were 0.10 Hz, 0.25 Hz, 0.50 Hz, 1.00 Hz, and 2.00 Hz; for variable-angle experiments: 0.25 Hz, 0.50 Hz, or 1.00 Hz.
Among fixed-angle tests, the lowest RMS error was 4.12%, and the highest was 23.86%. The best variable angle result, obtained while
tracking a constant force, was 9.06%. Error was considerably lower for fixed-angle experiments than it was for variable-angle
experiments--the lowest measured error in variable-angle tests was similar to the highest error in fixed-angle tests. Results generally improved with increasing target force magnitude and worsened with increasing target and forcing frequency. For fixed-angle tests, conducting additional tests improved accuracy but not precision; the opposite was true for variable-angle tests.
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2008-03-04T16:59:42Z
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mechanical engineering; biomechanics; force-tracking; limb constraints
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bibid: 6397092
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dissertation or thesis