Efficient variable-length hanging tether parameterization for marsupial robot planning in 3D environments
Abstract
This paper presents a novel approach to efficiently parameterize and estimate the state of a hanging tether for path and trajectory planning of a UGV tied to a UAV in a marsupial configuration. Most implementations in the state of the art assume a taut tether or make use of the catenary curve to model the shape of the hanging tether. The catenary model is complex to compute and must be instantiated thousands of times during the planning process, becoming a time-consuming task, while the taut tether assumption simplifies the problem, but might overly restrict the movement of the platforms. In order to accelerate the planning process, this paper proposes defining an analytical model to efficiently compute the hanging tether state, and a method to get a tether state parameterization free of collisions. We exploit the existing similarity between the catenary and parabola curves to derive analytical expressions of the tether state.
Cite
@article{arxiv.2502.04467,
title = {Efficient variable-length hanging tether parameterization for marsupial robot planning in 3D environments},
author = {S. Martínez-Rozas and D. Alejo and F. Caballero and L. Merino and M. A. Pérez-Cutiño and F. Rodriguez and V. Sánchez-Canales and I. Ventura and J. M. Díaz-Bañez},
journal= {arXiv preprint arXiv:2502.04467},
year = {2025}
}
Comments
Submitted in T-RO