<p>Migratory birds depend on the perception of atmospheric updraft for long-distance flight. To realize more efficient autonomous soaring in an unpowered glider, different strategies for using potential sensorimotor cues to achieve autonomous soaring efficiency were compared and optimized. A simulation framework of autonomous soaring for an unpowered glider was developed based on a reinforcement learning algorithm. The framework was composed of three models: an updraft environment model, the glider’s dynamics and control model, and a reinforcement learning agent, which learns to harvest more energy in flight. Based on the simulation, effects of different combinations of 12 potential sensorimotor cues on soaring efficiency were studied. Firstly, the absence of one particular sensorimotor cue and the use of only a single valid cue in autonomous soaring were analyzed. The results showed that the vertical airflow velocity gradient (<i>a</i><sub>w</sub>) and the wing-tip updraft velocity difference (<i>τ</i>) have advantages over the other cues. Secondly, strategies combining <i>a</i><sub>w</sub> or <i>τ</i> with other cues were analyzed to achieve more effective autonomous soaring, and seven potentially effective combinations of sensorimotor cues were identified. The final results showed that, among the tested combinations, the combination of vertical airflow velocity (<i>V</i><sub>w</sub>) and <i>τ</i>, enables the most efficient autonomous soaring. This study identified a highly effective sensorimotor cue strategy to guide an intelligent glider to achieve long-distance autonomous soaring flight.</p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

Efficient sensorimotor cues for training a glider to soar autonomously

  • Siyuan Zheng,
  • Jiachi Zhao,
  • Lifang Zeng,
  • Zhouhong Wang,
  • Jun Li

摘要

Migratory birds depend on the perception of atmospheric updraft for long-distance flight. To realize more efficient autonomous soaring in an unpowered glider, different strategies for using potential sensorimotor cues to achieve autonomous soaring efficiency were compared and optimized. A simulation framework of autonomous soaring for an unpowered glider was developed based on a reinforcement learning algorithm. The framework was composed of three models: an updraft environment model, the glider’s dynamics and control model, and a reinforcement learning agent, which learns to harvest more energy in flight. Based on the simulation, effects of different combinations of 12 potential sensorimotor cues on soaring efficiency were studied. Firstly, the absence of one particular sensorimotor cue and the use of only a single valid cue in autonomous soaring were analyzed. The results showed that the vertical airflow velocity gradient (aw) and the wing-tip updraft velocity difference (τ) have advantages over the other cues. Secondly, strategies combining aw or τ with other cues were analyzed to achieve more effective autonomous soaring, and seven potentially effective combinations of sensorimotor cues were identified. The final results showed that, among the tested combinations, the combination of vertical airflow velocity (Vw) and τ, enables the most efficient autonomous soaring. This study identified a highly effective sensorimotor cue strategy to guide an intelligent glider to achieve long-distance autonomous soaring flight.