Real-Time Position, Velocity and Attitude Estimation Using Low-Cost GNSS Only Reduced Navigation System

2022 5th International Conference on Communications, Signal Processing, and their Applications (ICCSPA) Pub Date : 2022-12-27 DOI:10.1109/ICCSPA55860.2022.10019053

Ahmed Radi, J. Fekry, S. Zahran

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Abstract

Integrated navigation systems are essential for position, velocity, and attitude determination for different applications, including military and civilian ones (drones, UAVs, UGVs, self-driving cars, etc.). The advancements in the Micro-Electromechanical Systems (MEMS) technology have allowed the possibilities of having miniature sensors with a whole wide range of accuracies. Most low-cost navigation system are based on the idea of integrating low-cost GNSS receivers with MEMS-based IMUs using sensor fusion algorithms to provide localization and attitude navigational information with acceptable accuracy at relatively low power consumption and reduced computations as well. This paper aims to propose a low-cost Arduino compatible GNSS-only reduced navigation module that provides eight-out of-nine navigation states (represented in 3D positioning, 3D estimated velocity components in LLF, pitch and heading estimated attitude angles) using a proposed real-time estimation algorithm and without incorporating any inertial sensors. Real in-field data were collected under off-road and urban environments to evaluate the fidelity of the proposed GNSS-only module (including real-time estimation algorithm running on the aforementioned Arduino compatible receiver) using two different GNSS antennas. Such an evaluation was performed by comparing the navigation states acquired from the system undertest with an integrated INS/GPS reference system attached on the same platform. The results showed that the proposed reduced navigation system associated with the real-time estimation algorithm is successfully capable of providing 8-out of-9 navigational states with acceptable accuracy using both antennas. Results also demonstrated a better performance for the reduced GNSS-only system connected to one antenna (Taoglas ADFGP.50A) than the other (Taoglas AGGP.35f) in terms of altitude information and speed recovery of the localization information after GNSS outage periods.

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基于低成本GNSS简化导航系统的实时位置、速度和姿态估计

综合导航系统对于不同应用的位置、速度和姿态确定至关重要，包括军用和民用应用(无人机、无人驾驶飞机、ugv、自动驾驶汽车等)。微机电系统(MEMS)技术的进步使具有全范围精度的微型传感器成为可能。大多数低成本导航系统都是基于将低成本GNSS接收器与基于mems的imu集成的想法，使用传感器融合算法在相对较低的功耗和减少的计算量下提供可接受精度的定位和姿态导航信息。本文旨在提出一种低成本的Arduino兼容gnss简化导航模块，该模块使用提出的实时估计算法，在不包含任何惯性传感器的情况下，提供9种导航状态中的8种(以3D定位，LLF中3D估计速度分量，俯仰和航向估计姿态角表示)。采用两种不同的GNSS天线，在越野和城市环境下收集现场真实数据，评估所提出的GNSS-only模块(包括在上述Arduino兼容接收器上运行的实时估计算法)的保真度。通过将从待测系统获得的导航状态与附加在同一平台上的集成INS/GPS参考系统进行比较，进行了这样的评估。结果表明，结合实时估计算法的简化导航系统能够在使用两根天线的情况下提供8 / 9的导航状态，且精度可接受。结果还表明，在GNSS中断期间，仅连接一根天线(Taoglas ADFGP.50A)的简化GNSS系统在高度信息和定位信息的速度恢复方面优于另一根天线(Taoglas AGGP.35f)。

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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2022 5th International Conference on Communications, Signal Processing, and their Applications (ICCSPA)

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