Antoni Burguera scite author profile

This paper presents a novel approach to mobile robot localization using sonar sensors. This approach is based on the use of particle filters. Each particle is augmented with local environment information which is updated during the mission execution. An experimental characterization of the sonar sensors used is provided in the paper. A probabilistic measurement model that takes into account the sonar uncertainties is defined according to the experimental characterization. The experimental results quantitatively evaluate the presented approach and provide a comparison with other localization strategies based on both the sonar and the laser. Some qualitative results are also provided for visual inspection.

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A Probabilistic Framework for Sonar Scan Matching Localization

Burguera

González

Oliver

2008

Advanced Robotics

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Visual Discrimination and Large Area Mapping of Posidonia Oceanica Using a Lightweight AUV

2017

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Robust scan matching localization using ultrasonic range finders

Burguera

Oliver

Tardós³

2005

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Abstract-The work presented in this paper deals with scan matching localization using ultrasonic range sensors. Our contribution resides in the extension of ICP based algorithms to be used with ultrasonic sensor data. This extension consists of a pre-process step, where ultrasonic sensor readings are grouped to overcome their sparseness, and a post-process step, where the whole robot trajectory involved in the grouping process is corrected. Thanks to that a great improvement with respect to odometry is obtained. Experimental results show that even huge odometric errors are corrected with the presented method.

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High-Resolution Underwater Mapping Using Side-Scan Sonar

Burguera

Oliver

2016

PLoS ONE

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The goal of this study is to generate high-resolution sea floor maps using a Side-Scan Sonar(SSS). This is achieved by explicitly taking into account the SSS operation as follows. First, the raw sensor data is corrected by means of a physics-based SSS model. Second, the data is projected to the sea-floor. The errors involved in this projection are thoroughfully analysed. Third, a probabilistic SSS model is defined and used to estimate the probability of each sea-floor region to be observed. This probabilistic information is then used to weight the contribution of each SSS measurement to the map. Because of these models, arbitrary map resolutions can be achieved, even beyond the sensor resolution. Finally, a geometric map building method is presented and combined with the probabilistic approach. The resulting map is composed of two layers. The echo intensity layer holds the most likely echo intensities at each point in the sea-floor. The probabilistic layer contains information about how confident can the user or the higher control layers be about the echo intensity layer data. Experimental results have been conducted in a large subsea region.

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Antoni Burguera

Sonar Sensor Models and Their Application to Mobile Robot Localization

A Probabilistic Framework for Sonar Scan Matching Localization

Visual Discrimination and Large Area Mapping of Posidonia Oceanica Using a Lightweight AUV

Robust scan matching localization using ultrasonic range finders

High-Resolution Underwater Mapping Using Side-Scan Sonar

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