Your search keyword '"sonar resolution"' showing total 3 results

1. Interferometric Measurements with Wideband Signal Processing Techniques

Author

Matt Geen, Jerome Mars, Jitendra Singh Sewada, Cornel Ioana, ITER Systems [Annecy], GIPSA - Signal Images Physique (GIPSA-SIGMAPHY), Département Images et Signal (GIPSA-DIS), Grenoble Images Parole Signal Automatique (GIPSA-lab ), Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Institut Polytechnique de Grenoble - Grenoble Institute of Technology-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019])-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Institut Polytechnique de Grenoble - Grenoble Institute of Technology-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019])-Grenoble Images Parole Signal Automatique (GIPSA-lab ), Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Institut Polytechnique de Grenoble - Grenoble Institute of Technology-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019])-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Institut Polytechnique de Grenoble - Grenoble Institute of Technology-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019]), and Mars, Jerome

Subjects

Matched Filters, Phase Differential Bathymetry Sonar, 02 engineering and technology, 01 natural sciences, Sonar, Wideband signals, Signal-to-noise ratio, 0202 electrical engineering, electronic engineering, information engineering, Bathymetry, 14. Life underwater, Wideband, Sonar resolution, Interferometer, Decorrelation, [SPI.SIGNAL] Engineering Sciences [physics]/Signal and Image processing, Remote sensing, [SPI.ACOU]Engineering Sciences [physics]/Acoustics [physics.class-ph], [SPI.ACOU] Engineering Sciences [physics]/Acoustics [physics.class-ph], Matched filter, 010401 analytical chemistry, 020206 networking & telecommunications, Bathymetric sonar, [SPI.TRON] Engineering Sciences [physics]/Electronics, 0104 chemical sciences, [SPI.TRON]Engineering Sciences [physics]/Electronics, Noise, Pulse compression, Measurement uncertainty, PDBS, Swath bathymetry, Bottom estimation, [SPI.SIGNAL]Engineering Sciences [physics]/Signal and Image processing, Geology

Abstract

International audience; Bathymetric sonar systems are widely used nowadays in seafloor mapping and exploration. The differential phase technique, also known as interferometry, is widely used in these bathymetry measurement sonars, but the assessment of measurement uncertainty and data density are not completely understood and explored. This research paper concerns the description of measurement uncertainties due to different noise sources in interferometric sonars and a wideband signal processing approach to solve them. Interferometers are mostly used in shallow waters, e.g. lakes, inland waterways, rivers, reservoirs and coastal areas, due to having wider swaths compared to conventional multibeam echosounders or beamformers. This paper focuses on getting high-resolution bathymetry with minimum measurement uncertainty. It considers the effect of various acoustic noise sources, and neglects external error sources, e.g. INS, GNSS, sound velocity profiles. Wideband pulses are now used to overcome the range-resolution trade off problem of CW pulses. We have done an assessment of wideband signal processing techniques to reduce the bathymetry uncertainties caused by different noise sources. ITER Systems provided us with a Bathyswath-2 bathymetry system and essential surveying tools. Mathematical noise models are compared with data recorded in the field.

Published

2019

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

Author

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

Subjects

Ultrasonic arc map, voxelized spherical cap, patrón de dispersión, Mapa de arco ultrasónico, votación espacial, resolución del sonar, spatial voting, SLAM, Bresenham algorithm, sonar resolution, casquete esférico voxelizado, beam pattern, algoritmo de Bresenham

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. RESUMEN En este artículo, un método de mapa de arcos ultrasónicos para mapeo plano es extendido al espacio tridimensional, remplazando los arcos de circunferencia por casquetes esféricos. Un ambiente cerrado es explorado empleando solo un dispositivo ultrasónico. La distancia, posición y orientación del transductor son utilizadas para digitalizar casquetes de incertidumbre y colocarlos en un mapa tridimensional. A través del método de votación espacial, los voxeles generados son elegidos con el propósito de distinguir aquellos que marcan la posición real de un obstáculo y descartar aquellos producidos por diafonía, ruido, lecturas falsas y la resolución angular. Los resultados muestran que es posible obtener suficiente información para construir un mapa tridimensional para navegación mediante el empleo de sensores de bajo costo y un procesamiento de datos de baja potencia.

Published

2017

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

Author

Eduardo Castillo-Castaneda, Antonio Hernández-Zavala, and Fabio Tomás Moreno-Ortiz

Subjects

Ultrasonic arc map, 0209 industrial biotechnology, Computer science, Acoustics, Ingeniería, 02 engineering and technology, computer.software_genre, voxelized spherical cap, Mapa de arco ultrasónico, 020901 industrial engineering & automation, Position (vector), Voxel, 0202 electrical engineering, electronic engineering, information engineering, Angular resolution, Data processing, resolución del sonar, Orientation (computer vision), Noise (signal processing), Bresenham algorithm, General Engineering, Building and Construction, beam pattern, algoritmo de Bresenham, patrón de dispersión, Transducer, votación espacial, lcsh:TA1-2040, 62 Ingeniería y operaciones afines / Engineering, spatial voting, SLAM, sonar resolution, 020201 artificial intelligence & image processing, Ultrasonic sensor, casquete esférico voxelizado, lcsh:Engineering (General). Civil engineering (General), computer

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. En este artículo, un método de mapa de arcos ultrasónicos para mapeo plano es extendido al espacio tridimensional, remplazando los arcos de circunferencia por casquetes esféricos. Un ambiente cerrado es explorado empleando solo un dispositivo ultrasónico. La distancia, posición y orientación del transductor son utilizadas para digitalizar casquetes de incertidumbre y colocarlos en un mapa tridimensional. A través del método de votación espacial, los voxeles generados son elegidos con el propósito de distinguir aquellos que marcan la posición real de un obstáculo y descartar aquellos producidos por diafonía, ruido, lecturas falsas y la resolución angular. Los resultados muestran que es posible obtener suficiente información para construir un mapa tridimensional para navegación mediante el empleo de sensores de bajo costo y un procesamiento de datos de baja potencia.

Published

2017