Error Analysis in Multibeam Hydrographic Survey System

IF 0.3 Q4 REMOTE SENSING

South African Journal of Geomatics Pub Date : 2024-07-10 DOI:10.4314/sajg.v13i2.2

Basil Daniel Devote

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Abstract

Hydrographic surveying involves the integration of a depth-measuring sonar (Sound navigation and ranging) with a positioning system or Global Navigation Satellite System (GNSS); a motion sensor or Inertia Measuring Unit (IMU); and an azimuth sensor (gyroscope). The various sensors acquire data in terms of their respective reference frame and time. The challenge lies in integrating the various sensor frames and time, and in transforming the vessel frame coordinate system into a terrestrial reference frame. The integration of the various sensor frames and time is necessary to minimize systematic errors in the bathymetric data that result from latency, and calibration uncertainty. The focus of this research is to model the systematic bias associated with the integration of the various sensor reference frames. In so doing, the quality of the acquired data is enhanced, and error budgeting and uncertainty prediction can be effectively carried out during the preparation, acquisition, and processing stages of the bathymetric exercise. As such, the required project specification and hydrographic standards, as defined by the International Hydrographic Organization (IHO), are met.

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多波束水文测量系统的误差分析

水文测量包括将测深声纳（声纳导航和测距）与定位系统或全球导航卫星系统（GNSS）、运动传感器或惯性测量单元（IMU）以及方位角传感器（陀螺仪）集成在一起。各种传感器根据各自的参考框架和时间获取数据。难点在于如何整合各种传感器框架和时间，以及如何将船体框架坐标系转换为地面参考框架。要将延迟和校准不确定性造成的测深数据的系统误差降至最低，就必须整合各种传感器框架和时间。这项研究的重点是模拟与整合各种传感器参考框架相关的系统偏差。这样就能提高获取数据的质量，并在测深工作的准备、获取和处理阶段有效地进行误差预算和不确定性预测。这样，就达到了国际水文组织（IHO）规定的项目规格和水文标准。

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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South African Journal of Geomatics REMOTE SENSING-

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