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Area of Science:

  • Robotics
  • Artificial Intelligence
  • Computer Vision

Background:

  • Quadrotors exhibit high agility for traversing complex environments.
  • Current autonomous quadrotor systems are limited to low speeds due to sequential processing in sensing, mapping, and planning.
  • High-speed navigation in cluttered environments is challenging for traditional methods because of processing latency and error propagation.

Purpose of the Study:

  • To develop an end-to-end autonomous system for high-speed quadrotor flight in complex environments.
  • To enable quadrotors to operate using only onboard sensing and computation.
  • To overcome limitations of traditional methods by reducing processing latency and improving robustness.

Main Methods:

  • Proposed an end-to-end approach directly mapping sensory observations to collision-free trajectories using a receding-horizon method.
  • Utilized a convolutional neural network for sensorimotor mapping, trained in simulation via privileged learning.
  • Incorporated realistic sensor noise simulation for zero-shot transfer to real-world scenarios.

Main Results:

  • Achieved high-speed autonomous flight in complex, previously unseen environments (forests, collapsed buildings).
  • Demonstrated significantly reduced processing latency compared to traditional pipelines.
  • Outperformed conventional obstacle avoidance methods in challenging real-world tests.

Conclusions:

  • End-to-end policies trained in simulation can enable high-speed autonomous quadrotor flight.
  • Direct sensorimotor mapping is a viable strategy for robust and low-latency navigation.
  • The approach shows promise for real-world applications requiring rapid autonomous traversal of cluttered spaces.