Inverse Kinematics on Guiding Vector Fields for Robot Path Following

TL;DR

This paper extends inverse kinematics to guiding vector fields for robot path following, enabling precise control of mobile robots and drones along complex paths with improved transient behavior.

Contribution

It introduces a novel application of inverse kinematics to guiding vector fields for path following, including solutions for unicycle robots and validation with drone flights.

Findings

Successful implementation on fixed-wing drones

Enhanced transient control of robot paths

Theoretical validation and practical experiments

Abstract

Inverse kinematics is a fundamental technique for motion and positioning control in robotics, typically applied to end-effectors. In this paper, we extend the concept of inverse kinematics to guiding vector fields for path following in autonomous mobile robots. The desired path is defined by its implicit equation, i.e., by a collection of points belonging to one or more zero-level sets. These level sets serve as a reference to construct an error signal that drives the guiding vector field toward the desired path, enabling the robot to converge and travel along the path by following such a vector field. We start with the formal exposition on how inverse kinematics can be applied to guiding vector fields for single-integrator robots in an m-dimensional Euclidean space. Then, we leverage inverse kinematics to ensure that the level-set error signal behaves as a linear system, facilitating control over the robot's transient motion toward the desired path and allowing for the injection of feed-forward signals to induce precise motion behavior along the path. We then propose solutions to the theoretical and practical challenges of applying this technique to unicycles with constant speeds to follow 2D paths with precise transient control. We finish by validating the predicted theoretical results through real flights with fixed-wing drones.