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Main Authors: Dutta, Shiladitya, Gupta, Aayush, Saran, Varun, Zakhor, Avideh
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.24449
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author Dutta, Shiladitya
Gupta, Aayush
Saran, Varun
Zakhor, Avideh
author_facet Dutta, Shiladitya
Gupta, Aayush
Saran, Varun
Zakhor, Avideh
contents Although quadcopters boast impressive traversal capabilities enabled by their omnidirectional maneuverability, the need for continuous pilot control in complex environments impedes their application in GNSS and telemetry-denied scenarios. To this end, we propose a novel sensorimotor policy that uses stereo-vision depth and visual-inertial odometry (VIO) to autonomously navigate through obstacles in an unknown environment to reach a goal point. The policy is comprised of a pre-trained autoencoder as the perception head followed by a planning and control LSTM network which outputs velocity commands that can be followed by an off-the-shelf commercial drone. We leverage reinforcement and privileged learning paradigms to train the policy in simulation through a two-stage process: 1) initial training with optimal trajectories generated by a global motion planner acting as a supervisory backbone, 2) further fine-tuning in a curriculum environment. To bridge the sim-to-real gap, we employ domain randomization and reward shaping to create a policy that is both robust to noise and domain shift. In outdoor experiments, our approach achieves successful zero-shot transfer to both obstacle environments and a drone platform that were never encountered during training.
format Preprint
id arxiv_https___arxiv_org_abs_2605_24449
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Vision-Guided Outdoor Flight and Obstacle Evasion via Reinforcement Learning
Dutta, Shiladitya
Gupta, Aayush
Saran, Varun
Zakhor, Avideh
Robotics
Machine Learning
Although quadcopters boast impressive traversal capabilities enabled by their omnidirectional maneuverability, the need for continuous pilot control in complex environments impedes their application in GNSS and telemetry-denied scenarios. To this end, we propose a novel sensorimotor policy that uses stereo-vision depth and visual-inertial odometry (VIO) to autonomously navigate through obstacles in an unknown environment to reach a goal point. The policy is comprised of a pre-trained autoencoder as the perception head followed by a planning and control LSTM network which outputs velocity commands that can be followed by an off-the-shelf commercial drone. We leverage reinforcement and privileged learning paradigms to train the policy in simulation through a two-stage process: 1) initial training with optimal trajectories generated by a global motion planner acting as a supervisory backbone, 2) further fine-tuning in a curriculum environment. To bridge the sim-to-real gap, we employ domain randomization and reward shaping to create a policy that is both robust to noise and domain shift. In outdoor experiments, our approach achieves successful zero-shot transfer to both obstacle environments and a drone platform that were never encountered during training.
title Vision-Guided Outdoor Flight and Obstacle Evasion via Reinforcement Learning
topic Robotics
Machine Learning
url https://arxiv.org/abs/2605.24449