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Auteurs principaux: Sartori, Mattia, Singhal, Chetna, Roy, Neelabhro, Brunelli, Davide, Gross, James
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2505.04972
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author Sartori, Mattia
Singhal, Chetna
Roy, Neelabhro
Brunelli, Davide
Gross, James
author_facet Sartori, Mattia
Singhal, Chetna
Roy, Neelabhro
Brunelli, Davide
Gross, James
contents The miniaturisation of sensors and processors, the advancements in connected edge intelligence, and the exponential interest in Artificial Intelligence are boosting the affirmation of autonomous nano-size drones in the Internet of Robotic Things ecosystem. However, achieving safe autonomous navigation and high-level tasks such as exploration and surveillance with these tiny platforms is extremely challenging due to their limited resources. This work focuses on enabling the safe and autonomous flight of a pocket-size, 30-gram platform called Crazyflie 2.1 in a partially known environment. We propose a novel AI-aided, vision-based reactive planning method for obstacle avoidance under the ambit of Integrated Sensing, Computing and Communication paradigm. We deal with the constraints of the nano-drone by splitting the navigation task into two parts: a deep learning-based object detector runs on the edge (external hardware) while the planning algorithm is executed onboard. The results show the ability to command the drone at $\sim8$ frames-per-second and a model performance reaching a COCO mean-average-precision of $60.8$. Field experiments demonstrate the feasibility of the solution with the drone flying at a top speed of $1$ m/s while steering away from an obstacle placed in an unknown position and reaching the target destination. The outcome highlights the compatibility of the communication delay and the model performance with the requirements of the real-time navigation task. We provide a feasible alternative to a fully onboard implementation that can be extended to autonomous exploration with nano-drones.
format Preprint
id arxiv_https___arxiv_org_abs_2505_04972
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle AI and Vision based Autonomous Navigation of Nano-Drones in Partially-Known Environments
Sartori, Mattia
Singhal, Chetna
Roy, Neelabhro
Brunelli, Davide
Gross, James
Robotics
Artificial Intelligence
Computer Vision and Pattern Recognition
Machine Learning
Networking and Internet Architecture
The miniaturisation of sensors and processors, the advancements in connected edge intelligence, and the exponential interest in Artificial Intelligence are boosting the affirmation of autonomous nano-size drones in the Internet of Robotic Things ecosystem. However, achieving safe autonomous navigation and high-level tasks such as exploration and surveillance with these tiny platforms is extremely challenging due to their limited resources. This work focuses on enabling the safe and autonomous flight of a pocket-size, 30-gram platform called Crazyflie 2.1 in a partially known environment. We propose a novel AI-aided, vision-based reactive planning method for obstacle avoidance under the ambit of Integrated Sensing, Computing and Communication paradigm. We deal with the constraints of the nano-drone by splitting the navigation task into two parts: a deep learning-based object detector runs on the edge (external hardware) while the planning algorithm is executed onboard. The results show the ability to command the drone at $\sim8$ frames-per-second and a model performance reaching a COCO mean-average-precision of $60.8$. Field experiments demonstrate the feasibility of the solution with the drone flying at a top speed of $1$ m/s while steering away from an obstacle placed in an unknown position and reaching the target destination. The outcome highlights the compatibility of the communication delay and the model performance with the requirements of the real-time navigation task. We provide a feasible alternative to a fully onboard implementation that can be extended to autonomous exploration with nano-drones.
title AI and Vision based Autonomous Navigation of Nano-Drones in Partially-Known Environments
topic Robotics
Artificial Intelligence
Computer Vision and Pattern Recognition
Machine Learning
Networking and Internet Architecture
url https://arxiv.org/abs/2505.04972