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Auteurs principaux: Li, Yude, Zhou, Zhexuan, Li, Huizhe, Gong, Youmin, Mei, Jie
Format: Preprint
Publié: 2025
Sujets:
Accès en ligne:https://arxiv.org/abs/2509.13816
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author Li, Yude
Zhou, Zhexuan
Li, Huizhe
Gong, Youmin
Mei, Jie
author_facet Li, Yude
Zhou, Zhexuan
Li, Huizhe
Gong, Youmin
Mei, Jie
contents Robust autonomous navigation for Autonomous Aerial Vehicles (AAVs) in complex environments is a critical capability. However, modern end-to-end navigation faces a key challenge: the high-frequency control loop needed for agile flight conflicts with low-frequency perception streams, which are limited by sensor update rates and significant computational cost. This mismatch forces conventional synchronous models into undesirably low control rates. To resolve this, we propose an asynchronous reinforcement learning framework that decouples perception and control, enabling a high-frequency policy to act on the latest IMU state for immediate reactivity, while incorporating perception features asynchronously. To manage the resulting data staleness, we introduce a theoretically-grounded Temporal Encoding Module (TEM) that explicitly conditions the policy on perception delays, a strategy complemented by a two-stage curriculum to ensure stable and efficient training. Validated in extensive simulations, our method was successfully deployed in zero-shot sim-to-real transfer on an onboard NUC, where it sustains a 100~Hz control rate and demonstrates robust, agile navigation in cluttered real-world environments. Our source code will be released for community reference.
format Preprint
id arxiv_https___arxiv_org_abs_2509_13816
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Agile in the Face of Delay: Asynchronous End-to-End Learning for Real-World Aerial Navigation
Li, Yude
Zhou, Zhexuan
Li, Huizhe
Gong, Youmin
Mei, Jie
Robotics
Robust autonomous navigation for Autonomous Aerial Vehicles (AAVs) in complex environments is a critical capability. However, modern end-to-end navigation faces a key challenge: the high-frequency control loop needed for agile flight conflicts with low-frequency perception streams, which are limited by sensor update rates and significant computational cost. This mismatch forces conventional synchronous models into undesirably low control rates. To resolve this, we propose an asynchronous reinforcement learning framework that decouples perception and control, enabling a high-frequency policy to act on the latest IMU state for immediate reactivity, while incorporating perception features asynchronously. To manage the resulting data staleness, we introduce a theoretically-grounded Temporal Encoding Module (TEM) that explicitly conditions the policy on perception delays, a strategy complemented by a two-stage curriculum to ensure stable and efficient training. Validated in extensive simulations, our method was successfully deployed in zero-shot sim-to-real transfer on an onboard NUC, where it sustains a 100~Hz control rate and demonstrates robust, agile navigation in cluttered real-world environments. Our source code will be released for community reference.
title Agile in the Face of Delay: Asynchronous End-to-End Learning for Real-World Aerial Navigation
topic Robotics
url https://arxiv.org/abs/2509.13816