Computational Models of Trajectory Investigation of Marine Geophysical Fields and Its Implementation for Solving Problems of Map-Aided Navigation

Q3 Engineering

Advances in Systems Science and Applications Pub Date : 2020-01-01 DOI:10.25728/ASSA.2020.20.4.972

L. Kiselev, V. Kostousov, A. Medvedev, A. E. Tarkhanov, K. V. Dunaevskaya

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引用次数: 5

Abstract

Comprehensive investigations of geophysical fields (GPF) of the ocean are among the top priority problems in underwater robotics. Problems reside in developing automated systems capable of real-time operation for gathering, accumulating, and processing diverse geophysical information. The data’s total volume is applied for long-term or real-time monitoring of marine areas, environment or objects surveillance, mapping certain regions, or anomalies in geographical coordinates. One of the main elements of such systems is the computational models sensitive to properties of geophysical fields, features of search routes of underwater vehicles, and particular aspects of missions performed during trajectory measurements and features of navigational support tasks. The work considers computational models of comprehensive interpretation of the results of trajectory measurements of geophysical fields using an autonomous underwater vehicle (AUV), and estimation of accuracy of map-aided navigation on the reconstructed map of geophysical fields. Algorithms and software consider distinctive features of representation of bathymetry, magnetometry, and gravimetry data visualized in 2D and 3D. Algorithm of map-aided navigation by the reconstructed fields is discussed. The final assessments of the considered models’ accuracy consider averaged errors of measurements, mapping, and inertial navigation. Obtained assessments are based on theoretical investigations, results of model experiments, and experimental trials of AUV’s systems under actual operating conditions.

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海洋地球物理场轨迹调查计算模型及其在地图辅助导航中的实现

海洋地球物理场的综合探测是水下机器人研究的首要问题之一。问题在于开发能够实时操作的自动化系统来收集、积累和处理各种地球物理信息。数据总量用于海洋区域的长期或实时监测、环境或物体监测、特定区域的测绘或地理坐标的异常。这种系统的一个主要要素是计算模型对地球物理场的特性、水下航行器搜索路线的特征、在轨迹测量期间执行的任务的特定方面和导航支持任务的特征敏感。该工作考虑了使用自主水下航行器(AUV)对地球物理场轨迹测量结果进行综合解释的计算模型，以及在地球物理场重建地图上估计地图辅助导航的精度。算法和软件考虑了在2D和3D中可视化的测深、磁测和重力数据的独特特征。讨论了利用重构场进行地图辅助导航的算法。对所考虑的模型精度的最终评估考虑了测量、测绘和惯性导航的平均误差。获得的评估是基于理论研究、模型实验结果和AUV系统在实际操作条件下的实验试验。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Advances in Systems Science and Applications Engineering-Engineering (all)

CiteScore

1.20

自引率

0.00%

发文量

期刊介绍： Advances in Systems Science and Applications (ASSA) is an international peer-reviewed open-source online academic journal. Its scope covers all major aspects of systems (and processes) analysis, modeling, simulation, and control, ranging from theoretical and methodological developments to a large variety of application areas. Survey articles and innovative results are also welcome. ASSA is aimed at the audience of scientists, engineers and researchers working in the framework of these problems. ASSA should be a platform on which researchers will be able to communicate and discuss both their specialized issues and interdisciplinary problems of systems analysis and its applications in science and industry, including data science, artificial intelligence, material science, manufacturing, transportation, power and energy, ecology, corporate management, public governance, finance, and many others.