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基于聚类和加权最小二乘法的 GNSS 伪距与 UWB 距离融合。

Fusion of GNSS Pseudoranges with UWB Ranges Based on Clustering and Weighted Least Squares.

机构信息

Department of Geodesy and Geoinformation, TU Wien-Vienna University of Technology, 1040 Vienna, Austria.

出版信息

Sensors (Basel). 2023 Mar 21;23(6):3303. doi: 10.3390/s23063303.

DOI:10.3390/s23063303
PMID:36992013
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10051160/
Abstract

Global navigation satellite systems (GNSSs) and ultra-wideband (UWB) ranging are two central research topics in the field of positioning and navigation. In this study, a GNSS/UWB fusion method is investigated in GNSS-challenged environments or for the transition between outdoor and indoor environments. UWB augments the GNSS positioning solution in these environments. GNSS stop-and-go measurements were carried out simultaneously to UWB range observations within the network of grid points used for testing. The influence of UWB range measurements on the GNSS solution is examined with three weighted least squares (WLS) approaches. The first WLS variant relies solely on the UWB range measurements. The second approach includes a measurement model that utilizes GNSS only. The third model fuses both approaches into a single multi-sensor model. As part of the raw data evaluation, static GNSS observations processed with precise ephemerides were used to define the ground truth. In order to extract the grid test points from the collected raw data in the measured network, clustering methods were applied. A self-developed clustering approach extending density-based spatial clustering of applications with noise (DBSCAN) was employed for this purpose. The results of the GNSS/UWB fusion approach show an improvement in positioning performance compared to the UWB-only approach, in the range of a few centimeters to the decimeter level when grid points were placed within the area enclosed by the UWB anchor points. However, grid points outside this area indicated a decrease in accuracy in the range of about 90 cm. The precision generally remained within 5 cm for points located within the anchor points.

摘要

全球导航卫星系统 (GNSS) 和超宽带 (UWB) 测距是定位和导航领域的两个核心研究课题。在这项研究中,研究了 GNSS 挑战环境或室外到室内环境过渡中的 GNSS/UWB 融合方法。在这些环境中,UWB 增强了 GNSS 定位解决方案。在用于测试的网格点网络内,同时进行了 GNSS 停走测量和 UWB 测距观测。使用三种加权最小二乘 (WLS) 方法检查了 UWB 测距观测对 GNSS 解的影响。第一种 WLS 变体仅依赖于 UWB 测距观测。第二种方法包括仅利用 GNSS 的测量模型。第三种模型将这两种方法融合到一个多传感器模型中。作为原始数据评估的一部分,使用精确星历处理的静态 GNSS 观测值用于定义地面真值。为了从所收集的测量网络中的原始数据中提取网格测试点,应用了聚类方法。为此,使用了一种扩展了基于密度的空间聚类应用噪声 (DBSCAN) 的自开发聚类方法。与仅使用 UWB 的方法相比,GNSS/UWB 融合方法的结果表明,在网格点位于 UWB 锚点包围的区域内时,定位性能有所提高,在几厘米到分米的范围内。然而,在该区域之外的网格点的精度下降了约 90 厘米。对于位于锚点内的点,精度通常保持在 5 厘米以内。

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