Detection and location of surfaces in a 3D environment through a single transducer and ultrasonic spherical caps

Fabio T. Moreno-Ortiz; Eduardo Castillo-Castañeda; Antonio Hernández-Zavala

doi:10.15446/ing.investig.v37n3.59508

Detection and location of surfaces in a 3D environment through a single transducer and ultrasonic spherical caps

Translated title of the contribution: Detection and location of surfaces in a 3D environment through a single transducer and ultrasonic spherical caps

Fabio T. Moreno-Ortiz, Eduardo Castillo-Castañeda, Antonio Hernández-Zavala

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

In this paper, an ultrasonic arc map method for flat mapping is extended to three-dimensional space replacing the circumference arcs by spherical caps. An enclosed environment is scanned by employing a single ultrasonic device. The range, position, and orientation of the transducer are used to digitize the uncertainty caps and place them in a three-dimensional map. Through the spatial voting method, the generated voxels are elected in order to distinguish those which mark the true position of an obstacle and discard those that are produced by cross talk, noise, fake ranges, and angular resolution. The results show that it is possible to obtain sufficient information to build a three-dimensional map for navigation by employing inexpensive sensors and a low power data processing.

Translated title of the contribution	Detection and location of surfaces in a 3D environment through a single transducer and ultrasonic spherical caps
Original language	English
Pages (from-to)	37-44
Number of pages	8
Journal	Ingenieria e Investigacion
Volume	37
Issue number	3
DOIs	https://doi.org/10.15446/ing.investig.v37n3.59508
State	Published - Dec 2017
Externally published	Yes

Keywords

Beam pattern
Bresenham algorithm
SLAM
Sonar resolution
Spatial voting
Ultrasonic arc map
Voxelized spherical cap

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10.15446/ing.investig.v37n3.59508

Cite this

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title = "Detection and location of surfaces in a 3D environment through a single transducer and ultrasonic spherical caps",

abstract = "In this paper, an ultrasonic arc map method for flat mapping is extended to three-dimensional space replacing the circumference arcs by spherical caps. An enclosed environment is scanned by employing a single ultrasonic device. The range, position, and orientation of the transducer are used to digitize the uncertainty caps and place them in a three-dimensional map. Through the spatial voting method, the generated voxels are elected in order to distinguish those which mark the true position of an obstacle and discard those that are produced by cross talk, noise, fake ranges, and angular resolution. The results show that it is possible to obtain sufficient information to build a three-dimensional map for navigation by employing inexpensive sensors and a low power data processing.",

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AB - In this paper, an ultrasonic arc map method for flat mapping is extended to three-dimensional space replacing the circumference arcs by spherical caps. An enclosed environment is scanned by employing a single ultrasonic device. The range, position, and orientation of the transducer are used to digitize the uncertainty caps and place them in a three-dimensional map. Through the spatial voting method, the generated voxels are elected in order to distinguish those which mark the true position of an obstacle and discard those that are produced by cross talk, noise, fake ranges, and angular resolution. The results show that it is possible to obtain sufficient information to build a three-dimensional map for navigation by employing inexpensive sensors and a low power data processing.

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Detection and location of surfaces in a 3D environment through a single transducer and ultrasonic spherical caps

Abstract

Keywords

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