3-D Relative Localization for Multi-Robot Systems with Angle and Self-Displacement Measurements

TL;DR

This paper introduces a systematic 3-D relative localization framework for multi-robot systems using angle and self-displacement measurements, addressing measurement noise with advanced optimization techniques.

Contribution

It proposes a linear localization theory with a distributed algorithm and develops a MAP estimator incorporating WTLS, NDE, and marginalization for improved accuracy and efficiency.

Findings

Linear relative localization algorithm accurately determines neighbor positions.

WTLS optimization improves initial estimates for MAP, reducing local optima risk.

The combined approach effectively handles measurement noise and computational cost.

Abstract

Realizing relative localization by leveraging inter-robot local measurements is a challenging problem, especially in the presence of measurement noise. Motivated by this challenge, in this paper we propose a novel and systematic 3-D relative localization framework based on inter-robot interior angle and self-displacement measurements. Initially, we propose a linear relative localization theory comprising a distributed linear relative localization algorithm and sufficient conditions for localizability. According to this theory, robots can determine their neighbors' relative positions and orientations in a purely linear manner. Subsequently, in order to deal with measurement noise, we present an advanced Maximum a Posterior (MAP) estimator by addressing three primary challenges existing in the MAP estimator. Firstly, it is common to formulate the MAP problem as an optimization problem, whose inherent non-convexity can result in local optima. To address this issue, we reformulate the linear computation process of the linear relative localization algorithm as a Weighted Total Least Squares (WTLS) optimization problem on manifolds. The optimal solution of the WTLS problem is more accurate, which can then be used as initial values when solving the optimization problem associated with the MAP problem, thereby reducing the risk of falling into local optima. The second challenge is the lack of knowledge of the prior probability density of the robots' relative positions and orientations at the initial time, which is required as an input for the MAP estimator. To deal with it, we combine the WTLS with a Neural Density Estimator (NDE). Thirdly, to prevent the increasing size of the relative positions and orientations to be estimated as the robots continuously move when solving the MAP problem, a marginalization mechanism is designed, which ensures that the computational cost remains constant.