Mechanics and energetics of walking and running up and downhill: A joint-level perspective to guide design of lower-limb exoskeletons
Richard W. Nuckols, Kota Z. Takahashi, Dominic J. Farris, Sarai Mizrachi, Raziel Riemer, Gregory S. Sawicki
- 发表年份
- 2020
- 引用次数
- 7
- 访问权限
- 开放获取
摘要
Abstract Lower-limb wearable robotic devices can provide effective assistance to both clinical and healthy populations; however, how assistance should be applied in different gait conditions and environments is still unclear. We suggest a biologically-inspired approach derived from knowledge of human locomotion mechanics and energetics to establish a ‘roadmap’ for wearable robot design. In this study, we characterize the changes in joint mechanics during both walking and running across a range of incline/decline grades and then provide an analysis that informs the development of lower-limb exoskeletons capable of operating across a range of mechanical demands. Eight subjects (6M,2F) completed five walking (1.25 m -1 ) trials at −15%, −10%, 0%, 10%, and 15% grade and five running (2.25 m s -1 ) trials at −10%, −5%, 0%, 5%, and 10% grade on a treadmill. We calculated time-varying joint moment and power output for the ankle, knee, and hip. For each gait, we examined how individual limb-joints contributed to total limb positive, negative and net power across grades. For both walking and running, changes in grade caused a redistribution of joint mechanical power generation and absorption. From level to incline walking, the ankle’s contribution to limb positive power decreased from 44% on the level to 28% at 15% uphill grade ( p < 0.0001) while the hip’s contribution increased from 27% to 52% ( p < 0.0001). In running, regardless of the surface gradient, the ankle was consistently the dominant source of lower-limb positive mechanical power (47-55%). In the context of our results, we outline three distinct use-modes that could be emphasized in future lower-limb exoskeleton designs 1) Energy injection: adding positive work into the gait cycle, 2) Energy extraction: removing negative work from the gait cycle, and 3) Energy transfer: extracting energy in one gait phase and then injecting it in another phase ( i . e ., regenerative braking).
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