Title :
A Gaussian Error Model for Triangulation-Based Pose Estimation Using Noisy Landmarks
Author :
Easton, Adam ; Cameron, Stephen
Author_Institution :
Oxford Univ. Comput. Lab.
Abstract :
As multiple robot approaches to localization become more prevalent, existing triangulation methods involving fixed location landmarks are inadequate to accurately determine a robot´s pose. We present an error model for a robot´s pose based on triangulation from three landmarks. The model represents each landmark position as a Gaussian distribution and, consequently, factors landmark positional uncertainty into robot pose error. We demonstrate the performance and accuracy of this model through a series of experiments and use the results to explain some of the inconsistencies in earlier results. We also present four metrics for analyzing the output of any Gaussian-based localization error model, demonstrating the metrics´ particular applicability to multiple robot localization problems
Keywords :
Gaussian distribution; Gaussian processes; mobile robots; multi-robot systems; pose estimation; position control; Gaussian distribution; Gaussian error model; fixed location landmarks; landmark position; landmark positional uncertainty; mobile robots; multiple robot localization problems; noisy landmarks; triangulation methods; triangulation-based pose estimation; Algorithm design and analysis; Gaussian distribution; Gaussian noise; Iterative methods; Laboratories; Machine vision; Mobile robots; Position measurement; Robot sensing systems; Uncertainty; Gaussian Error; Localisation; Mobile Robots; Triangulation;
Conference_Titel :
Robotics, Automation and Mechatronics, 2006 IEEE Conference on
Conference_Location :
Bangkok
Print_ISBN :
1-4244-0024-4
Electronic_ISBN :
1-4244-0025-2
DOI :
10.1109/RAMECH.2006.252663
