Comparison of kinematic and kinetic methods for computing the vertical motion of the body center of mass during walking

Gard, Steven A.; Miff, Steve C.; Kuo, Arthur D.

doi:10.1016/j.humov.2003.11.002

Cited by 250 publications

(168 citation statements)

References 17 publications

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“…The horizontal GRF shows the observed change from negative to positive values and the vertical axis, the double peak that distinguishes the walking gait (F x and F y , first row of subplots). Correspondingly, as in animals and humans (Lee & Farley 1998;Gard et al 2004), the COM oscillates around its landing height in the vertical GRF with a smaller increase in height during stance than that of the inverted pendulum motion (Dy, second row). Moreover, closer than the inverted pendulum, the bipedal springmass model describes the out-of-phase changes in the forward kinetic and the gravitational potential energies that occur in walking (DE k,x and DE p , third row).…”

Section: Walking Solutions Reproducing Experimental Datamentioning

confidence: 80%

Compliant leg behaviour explains basic dynamics of walking and running

2006

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The basic mechanics of human locomotion are associated with vaulting over stiff legs in walking and rebounding on compliant legs in running. However, while rebounding legs well explain the stance dynamics of running, stiff legs cannot reproduce that of walking. With a simple bipedal spring-mass model, we show that not stiff but compliant legs are essential to obtain the basic walking mechanics; incorporating the double support as an essential part of the walking motion, the model reproduces the characteristic stance dynamics that result in the observed small vertical oscillation of the body and the observed out-of-phase changes in forward kinetic and gravitational potential energies. Exploring the parameter space of this model, we further show that it not only combines the basic dynamics of walking and running in one mechanical system, but also reveals these gaits to be just two out of the many solutions to legged locomotion offered by compliant leg behaviour and accessed by energy or speed.

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Section: Walking Solutions Reproducing Experimental Datamentioning

confidence: 80%

Compliant leg behaviour explains basic dynamics of walking and running

2006

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“…In this study we used one of the simplest kinematic methods, a single marker placed on the sacrum, to approximate CoM motion. This single marker method has been shown to be an effective, inexpensive, and reasonably accurate estimate in the vertical direction at slower walking speeds (Gard, Miff, & Kuo, 2004;Saini, Kerrigan, Thirunarayan, & Duff-Raffaele, 1998;Thirunarayan, Kerrigan, Rabuffetti, Croce, & Saini, 1996), as well as in the medio-lateral and frontal direction to analyze simple movement activities without trunk flexion or limb bending (Mapelli et al, 2014). For each step sacral root mean squared velocity (ms -1 ) and acceleration (ms -2 ) was calculated over the three axes of movement:…”

Section: Discussionmentioning

confidence: 99%

Level walking in adults with and without Developmental Coordination Disorder: An analysis of movement variability

Wilmut

Barnett

2015

Human Movement Science

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“…We programmed the linear actuator to move up and down through a sinusoidal pattern with a peak-to-peak amplitude of 5 cm. Such a movement trajectory is representative of a person's COM movement while walking at approximately 1.4 m/s [16]. We programmed the linear actuator to move at frequencies of 0, 0.5, 1.0, and 1.5 Hz, while the magnitude of unloading was set to 10, 25, 50, 75, and 100 lb, respectively.…”

Section: Evaluation Of Zerog Unloading Systemmentioning

confidence: 99%

“…In this setting, as the patient moves up and down, they experience a constant amount of vertical support, which can be set as a percentage of the patient's body weight. Dynamic BWS has been shown to produce more natural ground-reaction forces and gait characteristics [11][12][13][14][15][16][17][18] and allows patients to move freely through a wide range of movement profiles (e.g., those needed during gait, sit-to-stand, and getting off the floor). Such activities are not possible with static BWS systems, yet are critical to a patient's ability to practice activities of daily living (ADLs).…”

Section: Introductionmentioning

confidence: 99%

ZeroG: Overground gait and balance training system

Hidler¹,

Brennan²,

Black³

et al. 2011

JRRD

104

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Abstract-A new overground body-weight support system called ZeroG has been developed that allows patients with severe gait impairments to practice gait and balance activities in a safe, controlled manner. The unloading system is capable of providing up to 300 lb of static support and 150 lb of dynamic (or constant force) support using a custom-series elastic actuator. The unloading system is mounted to a driven trolley, which rides along an overhead rail. We evaluated the performance of ZeroG's unloading system, as well as the trolley tracking system, using benchtop and human-subject testing. Average root-mean-square and peak errors in unloading were 2.2 and 7.2 percent, respectively, over the range of forces tested while trolley tracking errors were less than 3 degrees, indicating the system was able to maintain its position above the subject. We believe training with ZeroG will allow patients to practice activities that are critical to achieving functional independence at home and in the community.

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Comparison of kinematic and kinetic methods for computing the vertical motion of the body center of mass during walking

Cited by 250 publications

References 17 publications

Compliant leg behaviour explains basic dynamics of walking and running

Compliant leg behaviour explains basic dynamics of walking and running

Level walking in adults with and without Developmental Coordination Disorder: An analysis of movement variability

ZeroG: Overground gait and balance training system

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