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Main Authors: Li, Boyang, Jin, Zhongpeng, Zhao, Shuai, Liao, Jiahui, Liu, Tian, Liu, Han, Zhang, Yuanhai, Huang, Kai
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.14046
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author Li, Boyang
Jin, Zhongpeng
Zhao, Shuai
Liao, Jiahui
Liu, Tian
Liu, Han
Zhang, Yuanhai
Huang, Kai
author_facet Li, Boyang
Jin, Zhongpeng
Zhao, Shuai
Liao, Jiahui
Liu, Tian
Liu, Han
Zhang, Yuanhai
Huang, Kai
contents The ability to adapt to changing environments is crucial for the autonomous navigation systems of Unmanned Aerial Vehicles (UAVs). However, existing navigation systems adopt fixed execution configurations without considering environmental dynamics based on available computing resources, e.g., with a high execution frequency and task workload. This static approach causes rigid flight strategies and excessive computations, ultimately degrading flight performance or even leading to failures in UAVs. Despite the necessity for an adaptive system, dynamically adjusting workloads remains challenging, due to difficulties in quantifying environmental complexity and modeling the relationship between environment and system configuration. Aiming at adapting to dynamic environments, this paper proposes E-Navi, an environmental-adaptive navigation system for UAVs that dynamically adjusts task executions on the CPUs in response to environmental changes based on available computational resources. Specifically, the perception-planning pipeline of UAVs navigation system is redesigned through dynamic adaptation of mapping resolution and execution frequency, driven by the quantitative environmental complexity evaluations. In addition, E-Navi supports flexible deployment across hardware platforms with varying levels of computing capability. Extensive Hardware-In-the-Loop and real-world experiments demonstrate that the proposed system significantly outperforms the baseline method across various hardware platforms, achieving up to 53.9% navigation task workload reduction, up to 63.8% flight time savings, and delivering more stable velocity control.
format Preprint
id arxiv_https___arxiv_org_abs_2512_14046
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle E-Navi: Environmental Adaptive Navigation for UAVs on Resource Constrained Platforms
Li, Boyang
Jin, Zhongpeng
Zhao, Shuai
Liao, Jiahui
Liu, Tian
Liu, Han
Zhang, Yuanhai
Huang, Kai
Robotics
The ability to adapt to changing environments is crucial for the autonomous navigation systems of Unmanned Aerial Vehicles (UAVs). However, existing navigation systems adopt fixed execution configurations without considering environmental dynamics based on available computing resources, e.g., with a high execution frequency and task workload. This static approach causes rigid flight strategies and excessive computations, ultimately degrading flight performance or even leading to failures in UAVs. Despite the necessity for an adaptive system, dynamically adjusting workloads remains challenging, due to difficulties in quantifying environmental complexity and modeling the relationship between environment and system configuration. Aiming at adapting to dynamic environments, this paper proposes E-Navi, an environmental-adaptive navigation system for UAVs that dynamically adjusts task executions on the CPUs in response to environmental changes based on available computational resources. Specifically, the perception-planning pipeline of UAVs navigation system is redesigned through dynamic adaptation of mapping resolution and execution frequency, driven by the quantitative environmental complexity evaluations. In addition, E-Navi supports flexible deployment across hardware platforms with varying levels of computing capability. Extensive Hardware-In-the-Loop and real-world experiments demonstrate that the proposed system significantly outperforms the baseline method across various hardware platforms, achieving up to 53.9% navigation task workload reduction, up to 63.8% flight time savings, and delivering more stable velocity control.
title E-Navi: Environmental Adaptive Navigation for UAVs on Resource Constrained Platforms
topic Robotics
url https://arxiv.org/abs/2512.14046