Evaluation of angle of arrival estimation for localization in multiple indoor environments

2014 Ubiquitous Positioning Indoor Navigation and Location Based Service (UPINLBS) Pub Date : 2014-11-01 DOI:10.1109/UPINLBS.2014.7033708

S. Wielandt, A. V. Nieuwenhuyse, Jean-Pierre Goemaere, B. Nauwelaers, L. D. Strycker

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引用次数: 10

Abstract

The performance of indoor localization systems based on angle of arrival strongly depends on the environment. Consequently, a characterization of localization errors in different environments is necessary to correctly assess the accuracy of these systems. This paper focuses on the localization errors in multiple environments using basic 2.4 GHz linear antenna arrays. First, a theoretical algorithm is elaborated to predict the expected localization error in various environments. Subsequently, this algorithm is tested in practical tests performed in an anechoic room, an empty room and a room with obstacles. In these tests, various techniques for error minimization are evaluated, as well as the Beamscan, ESPRIT and MUSIC angle of arrival algorithms. It is shown that the accuracy in an anechoic room can also be obtained in an empty room for certain configurations. This is not the case for a room with obstacles preventing line-of-sight connections. For this case, a new type of localization system is proposed.

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多室内环境下定位的到达角估计评估

基于到达角的室内定位系统的性能很大程度上取决于环境。因此，有必要对不同环境下的定位误差进行表征，以正确评估这些系统的准确性。本文主要研究了2.4 GHz基本线性天线阵列在多种环境下的定位误差。首先，阐述了一种理论算法来预测各种环境下的预期定位误差。随后，在无回声房间、空房间和有障碍物的房间进行了实际测试。在这些测试中，评估了各种最小化误差的技术，以及波束扫描、ESPRIT和MUSIC到达角算法。结果表明，对于某些配置，在无回声房间中也可以获得在空房间中的精度。但如果房间里有阻碍视线连接的障碍物，情况就不一样了。针对这种情况，提出了一种新型的定位系统。

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

2014 Ubiquitous Positioning Indoor Navigation and Location Based Service (UPINLBS)

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