Figure S10. Muscle activation profiles for each belt speed ratio condition for strides generated by minimizing metabolic energy expenditure. </p
Figure S1. Schematic illustration of cost of transport (CoT) and gait speed (v) under normoxia and h...
<p>Activation levels of the superficial muscles (% of MVIC) during the maximal voluntary isometric c...
<p>The average metabolic power consumed over the running gait cycle, normalized by subject mass and ...
Figure S11. Muscle activation profiles for each belt speed ratio condition for strides generated by ...
Figure S9. Total metabolic energy expended per muscle for a full gait cycle, across both muscle exci...
Figure S6. Instantaneous net mechanical power throughout the gait cycle exerted by the legs on the t...
Figure S8. Joint kinematics for both muscle excitation and metabolic energy minimizations for each b...
Figure S8. Positive, negative, and net work rate exerted by the legs on the treadmill belts (top row...
Figure S4. a) Net metabolic rate vs. treadmill belt speed ratio. b) Net metabolic rate vs positive w...
Figure S2. Top row: (A) Fast and slow belt step length, (B) step length asymmetry, and (C) overall s...
Figure S3. Heel distance from body center of mass for both leading and trailing legs at heel-strike ...
Figure S5. Peak horizontal ground reaction force during both heel-strike and push-off vs. the corres...
<p>Each color represents one participant and the shaded regions represent ± one standard deviation a...
<p>Comparison of body postures and muscle activation associated with backpack weights and positions....
<p>Schematic drawing depicting analysis of burst amplitude, duration, inactivity periods and differe...
Figure S1. Schematic illustration of cost of transport (CoT) and gait speed (v) under normoxia and h...
<p>Activation levels of the superficial muscles (% of MVIC) during the maximal voluntary isometric c...
<p>The average metabolic power consumed over the running gait cycle, normalized by subject mass and ...
Figure S11. Muscle activation profiles for each belt speed ratio condition for strides generated by ...
Figure S9. Total metabolic energy expended per muscle for a full gait cycle, across both muscle exci...
Figure S6. Instantaneous net mechanical power throughout the gait cycle exerted by the legs on the t...
Figure S8. Joint kinematics for both muscle excitation and metabolic energy minimizations for each b...
Figure S8. Positive, negative, and net work rate exerted by the legs on the treadmill belts (top row...
Figure S4. a) Net metabolic rate vs. treadmill belt speed ratio. b) Net metabolic rate vs positive w...
Figure S2. Top row: (A) Fast and slow belt step length, (B) step length asymmetry, and (C) overall s...
Figure S3. Heel distance from body center of mass for both leading and trailing legs at heel-strike ...
Figure S5. Peak horizontal ground reaction force during both heel-strike and push-off vs. the corres...
<p>Each color represents one participant and the shaded regions represent ± one standard deviation a...
<p>Comparison of body postures and muscle activation associated with backpack weights and positions....
<p>Schematic drawing depicting analysis of burst amplitude, duration, inactivity periods and differe...
Figure S1. Schematic illustration of cost of transport (CoT) and gait speed (v) under normoxia and h...
<p>Activation levels of the superficial muscles (% of MVIC) during the maximal voluntary isometric c...
<p>The average metabolic power consumed over the running gait cycle, normalized by subject mass and ...
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