Saved in:
Bibliographic Details
Main Authors: Bredenbeck, Anton, Yang, Teaya, Hamaza, Salua, Mueller, Mark W.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2410.14249
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866918179887906816
author Bredenbeck, Anton
Yang, Teaya
Hamaza, Salua
Mueller, Mark W.
author_facet Bredenbeck, Anton
Yang, Teaya
Hamaza, Salua
Mueller, Mark W.
contents Aerial robots are a well-established solution for exploration, monitoring, and inspection, thanks to their superior maneuverability and agility. However, in many environments, they risk crashing and sustaining damage after collisions. Traditional methods focus on avoiding obstacles entirely, but these approaches can be limiting, particularly in cluttered spaces or on weight-and compute-constrained platforms such as drones. This paper presents a novel approach to enhance drone robustness and autonomy by developing a path recovery and adjustment method for a high-speed collision-resilient aerial robot equipped with lightweight, distributed tactile sensors. The proposed system explicitly models collisions using pre-collision velocities, rates and tactile feedback to predict post-collision dynamics, improving state estimation accuracy. Additionally, we introduce a computationally efficient vector-field-based path representation that guarantees convergence to a user-specified path, while naturally avoiding known obstacles. Post-collision, contact point locations are incorporated into the vector field as a repulsive potential, enabling the drone to avoid obstacles while naturally returning to its path. The effectiveness of this method is validated through Monte Carlo simulations and demonstrated on a physical prototype, showing successful path following, collision recovery, and adjustment at speeds up to 3.7 m/s.
format Preprint
id arxiv_https___arxiv_org_abs_2410_14249
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle A Tactile Feedback Approach to Path Recovery after High-Speed Impacts for Collision-Resilient Drones
Bredenbeck, Anton
Yang, Teaya
Hamaza, Salua
Mueller, Mark W.
Robotics
Aerial robots are a well-established solution for exploration, monitoring, and inspection, thanks to their superior maneuverability and agility. However, in many environments, they risk crashing and sustaining damage after collisions. Traditional methods focus on avoiding obstacles entirely, but these approaches can be limiting, particularly in cluttered spaces or on weight-and compute-constrained platforms such as drones. This paper presents a novel approach to enhance drone robustness and autonomy by developing a path recovery and adjustment method for a high-speed collision-resilient aerial robot equipped with lightweight, distributed tactile sensors. The proposed system explicitly models collisions using pre-collision velocities, rates and tactile feedback to predict post-collision dynamics, improving state estimation accuracy. Additionally, we introduce a computationally efficient vector-field-based path representation that guarantees convergence to a user-specified path, while naturally avoiding known obstacles. Post-collision, contact point locations are incorporated into the vector field as a repulsive potential, enabling the drone to avoid obstacles while naturally returning to its path. The effectiveness of this method is validated through Monte Carlo simulations and demonstrated on a physical prototype, showing successful path following, collision recovery, and adjustment at speeds up to 3.7 m/s.
title A Tactile Feedback Approach to Path Recovery after High-Speed Impacts for Collision-Resilient Drones
topic Robotics
url https://arxiv.org/abs/2410.14249