Woods Hole Oceanographic Institution Ryan Eustice Front Page  |  Curriculum Vitae (external file)  |  Projects  |  Publications  |  Photo Gallery Publications » Exactly sparse extended information filters for feature-based SLAM » Experimental Results in Synchronous-clock One-Way-Travel-time Acoustic Navigation for Autonomous Underwater Vehicles » Visually augmented navigation for autonomous underwater vehicles » Underwater Vehicle Navigation: Recent Advances and New Challenges » Visually Mapping the RMS Titanic: Convervative Covariance Estimates for SLAM Information Filters » Recent Advances in Synchronous-Clock One-Way-Travel-Time Acoustic Navigation » Characterizing the deep insular shelf coral reef habitat of the Hind Bank marine conservation district (US Virgin Islands) using the Seabed autonomous underwater vehicle » Visually Augmented Navigation for Autonomous Underwater Vehicles » Towards High-Resolution Imaging from Underwater Vehicles » Exactly Sparse Delayed-State Filters for View-Based SLAM » Photogrammetric Models for Marine Archaeology » A provably consistent method for imposing sparsity in feature-based SLAM information filters » Exactly Sparse Delayed-State Filters » Sparse Extended Information Filters: Insights into Sparsification » Visually Navigating the RMS Titanic with SLAM Information Filters » Large-Area Visually Augmented Navigation for Autonomous Underwater Vehicles » Towards Bathymetry-Optimized Doppler Re-navigation for AUVs » Advances in high-resolution imaging from underwater vehicles » A Provably Consistent Method for Imposing Sparsity in Feature-Based SLAM Information Filters » Advances in High-Resolution Imaging from Underwater Vehicles » Large Area 3D Reconstructions from Underwater Surveys » Imaging Coral I: Imaging Coral Habitats with The SeaBED AUV » SeaBED AUV Offers New Platform for High-Resolution Imaging » Visually Augmented Navigation in an Unstructured Environment Using a Delayed State History » Relative Pose Estimation for Instrumented, Calibrated Imaging Platforms » The Seabed AUV - A Platform for High Resolution Imaging » Sensor Fusion of Structure-from-Motion, Bathymetric 3D, and Beacon-Based Navigation Modalities » UWIT: Underwater Image Toolbox for Optical Image Processing and Mosaicking in MATLAB » A New Autonomous Underwater Vehicle for Imaging Research » Image Registration Underwater for Fluid Flow Measurements and Mosaicking M. Walter, R. Eustice, and J. Leonard, A provably consistent method for imposing sparsity in feature-based SLAM information filters, Intl. Symp. on Robotics Research, October 2005 Abstract An open problem in Simultaneous Localization and Mapping (SLAM) is the development of algorithms which scale with the size of the environment. A few promising methods exploit the key insight that representing the posterior in the canonical form parameterized by a sparse information matrix provides significant advantages regarding computational efficiency and storage requirements. Because the information matrix is naturally dense in the case of feature-based SLAM, additional steps are necessary to achieve sparsity. The delicate issue then becomes one of performing this sparsification in a manner which is consistent with the original distribution. In this paper, we present a SLAM algorithm based in the information form in which sparseness is preserved while maintaining consistency. We describe an intuitive approach to controlling the population of the information matrix by essentially ignoring a small fraction of proprioceptive measurements whereby we track a modified version of the posterior. In this manner, the Exactly Sparse Extended Information Filter (ESEIF) performs exact inference, employing a model which is conservative relative to the standard distribution. We demonstrate our algorithm both in simulation as well as on two nonlinear datasets, comparing it against the standard EKF as well as the Sparse Extended Information Filter (SEIF) by Thrun et al. The results convincingly show that our method yields conservative estimates for the robot pose and map which are nearly identical to those of the EKF in comparison to the SEIF formulation which results in overconfident error bounds. @INPROCEEDINGS{mwalter-2005a, author = {Walter, M. and Eustice, R. and Leonard, J.}, title = {A provably consistent method for imposing sparsity in feature-based {SLAM} information filters}, booktitle = {Intl. Symp. Robotics Research}, year = {2005}, address = {San Francisco, CA}, month = oct, note = {{In Press.}}, keywords = {SLAM, information filters, sparsity, sparsification}, } FILE » mwalter-2005a.pdf

© Woods Hole Oceanographic Institution All rights reserved