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Control of high-speed jumps: the rotation and energetics of the locust (Schistocerca gregaria).

Chloe K GoodeGregory P Sutton
Published in: Journal of comparative physiology. B, Biochemical, systemic, and environmental physiology (2023)
Locusts (Schistocerca gregaria) jump using a latch mediated spring actuated system in the femur-tibia joint of their metathoracic legs. These jumps are exceptionally fast and display angular rotation immediately after take-off. In this study, we focus on the angular velocity, at take-off, of locusts ranging between 0.049 and 1.50 g to determine if and how rotation-rate scales with size. From 263 jumps recorded from 44 individuals, we found that angular velocity scales with mass -0.33 , consistent with a hypothesis of locusts having a constant rotational kinetic energy density. Within the data from each locust, angular velocity increased proportionally with linear velocity, suggesting the two cannot be independently controlled and thus a fixed energy budget is formed at take-off. On average, the energy budget of a jump is distributed 98.7% to translational kinetic energy and gravitational potential energy, and 1.3% to rotational kinetic energy. The percentage of energy devoted to rotation was constant across all sizes of locusts and represents a very small proportion of the energy budget. This analysis suggests that smaller locusts find it harder to jump without body rotation.
Keyphrases
  • high speed
  • blood flow
  • mass spectrometry
  • body composition
  • bone mineral density
  • deep learning
  • artificial intelligence
  • atomic force microscopy