Modeling and Analysis of Sea-Surface Vehicle System for Underwater Mapping Using Single-Beam Echosounder

Kartal, Seda Karadeniz; Hacıoğlu, Rıfat; Gormus, K. S.; Kutoğlu, Şenol Hakan; Leblebi̇ci̇oğlu, Kemal

doi:10.3390/jmse10101349

Cited by 4 publications

(4 citation statements)

References 41 publications

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“…Previous work is indicative of similar motivations and methodology when compared with this study. Device and computational inabilities experienced in past works may no longer be applicable now, e.g., Kartal et al [9] in their work explored the possibility of collecting bathymetric data from seabeds sloped in two axes using one single-beam SONAR. Simulations, powerful computing, and the ease of conducting real-life experiments makes it possible to conduct such studies.…”

Section: A Single-beam Sonars For Navigationmentioning

confidence: 99%

Low-cost Underwater Localisation Using Single-Beam Echosounders and Inertial Measurement Units

Azam,

Jie Kong,

et al. 2023

OCEANS 2023 - Limerick

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Underwater robot localisation is challenging as it cannot rely on sensors such as the GPS due to electromagnetic wave attenuation or optical cameras due to water turbidity. SONARs are immune to these issues, hence they are used as alternatives for underwater navigation despite lower spatial and temporal resolution. Single-beam SONARs are sensors whose main output is distance. When combined with a filtering algorithm like the Kalman filter, these distance readings can correct localisation data obtained by inertial measurement units. Compared to multi-beam imaging SONARs, the single-beam SONARs are inexpensive to integrate into underwater robots. Therefore, this study aims to develop a low-cost localisation solution utilizing single-beam SONARs and pressure-based depth sensors to correct dead-reckoning linear localisation data using Kalman filters. From experiments, a single-beam SONAR per degree of freedom was able to correct localisation data, without the need of complicated data fusion methods.

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Section: A Single-beam Sonars For Navigationmentioning

confidence: 99%

Low-cost Underwater Localisation Using Single-Beam Echosounders and Inertial Measurement Units

Azam,

Jie Kong,

et al. 2023

OCEANS 2023 - Limerick

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“…= − − − + − (Kartal et al, 2022), where SL is the "source level", a measurement of a sound source's power emitted, more specifically it is a measurement of its far-field radiant intensity; TL is the "transmission loss", the difference between the signal level received at the sonar and the SL, which is the inverse of the transfer function from source to receiver; NL is "noise level", the degree of undesired noise or non-acoustic noise interfering with the sonar signal; DI is the "directivity index", as a rough estimate of the array gain; BS is the "bottom backscattering strength", used for assessing an accurate mapping and categorization of the seafloor; and DT is the "detection threshold" as the space-time processor (Ainslie & Leighton, 2016;Solikin et al, 2018;Yang et al, 2018). However, there will be several sites where the SBES has not assessed the depth.…”

Section: Ee Sl Tl Nd DI Bs Dtmentioning

confidence: 99%

A Comparison of Different Gis-Based Interpolation Methods for Bathymetric Data: Case Study of Bawean Island, East Java

Pratomo,

Safira,

Stefani

2023

Geodesy and Cartography

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The bottom surface’s portrayal is crucial in many different practices. Therefore, accurate bathymetry data is required. The interpolation method is one element that influences the accuracy of a Single Beam Echosounder’s depth data. IDW, Kriging, and TIN are three standard interpolation techniques. This study compares these three methods with two scenarios utilizing the spatial analysis to establish the most effective technique for producing the digital elevation model of the seafloor beneath Bawean Island. The IDW exhibits the strongest R-squared (0.9998779 in Scenario-1 and 0.9999875 in Scenario-2) and correlation (0.9998796 in Scenario-1 and 0.9999595 in Scenario-2). It indicates that IDW and bathymetric data have the closest relationships. IDW has the lowest error, as measured by the MAE value (0.02 in Scenario-1 and 0.009 in Scenario-2), followed in both cases by Kriging and TIN. Additionally, the RMSE for IDW shows the same outcome (0.045 in Scenario 1 and 0.016 in Scenario 2). In the meantime, comparing the first and second scenarios reveals that the second, which has fewer data, is preferable to the first. Since the MAE and RMSE in the first scenario are greater than those in the second, we may infer that more data leads to more significant errors.

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“…There are several survey systems for acquiring the water depth data, while their operating principle, operating environment, and delivered measurement accuracy significantly differ [ 18 ]. Currently, the most widely used measurement system is a multibeam system, which functions on the principles of aquatic acoustics [ 19 , 20 , 21 ] due to the significant limitations of electromagnetic wave propagation in the water medium [ 22 , 23 , 24 ]. The basic device of the multibeam system is a multibeam echosounder (MBES), which allows for the measurement of the depth distribution of a body of water.…”

Section: Introductionmentioning

confidence: 99%

Testing the Effect of Bathymetric Data Reduction on the Shape of the Digital Bottom Model

Mujta,

Wlodarczyk-Sielicka,

Stateczny

2023

Sensors

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Depth data and the digital bottom model created from it are very important in the inland and coastal water zones studies and research. The paper undertakes the subject of bathymetric data processing using reduction methods and examines the impact of data reduction according to the resulting representations of the bottom surface in the form of numerical bottom models. Data reduction is an approach that is meant to reduce the size of the input dataset to make it easier and more efficient for analysis, transmission, storage and similar. For the purposes of this article, test datasets were created by discretizing a selected polynomial function. The real dataset, which was used to verify the analyzes, was acquired using an interferometric echosounder mounted on a HydroDron-1 autonomous survey vessel. The data were collected in the ribbon of Lake Klodno, Zawory. Data reduction was conducted in two commercial programs. Three equal reduction parameters were adopted for each algorithm. The research part of the paper presents the results of the conducted analyzes of the reduced bathymetric datasets based on the visual comparison of numerical bottom models, isobaths, and statistical parameters. The article contains tabular results with statistics, as well as the spatial visualization of the studied fragments of numerical bottom models and isobaths. This research is being used in the course of work on an innovative project that aims to develop a prototype of a multi-dimensional and multi-temporal coastal zone monitoring system using autonomous, unmanned floating platforms at a single survey pass.

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Modeling and Analysis of Sea-Surface Vehicle System for Underwater Mapping Using Single-Beam Echosounder

Cited by 4 publications

References 41 publications

Low-cost Underwater Localisation Using Single-Beam Echosounders and Inertial Measurement Units

Low-cost Underwater Localisation Using Single-Beam Echosounders and Inertial Measurement Units

A Comparison of Different Gis-Based Interpolation Methods for Bathymetric Data: Case Study of Bawean Island, East Java

Testing the Effect of Bathymetric Data Reduction on the Shape of the Digital Bottom Model

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