Abstract
An ultra-wideband (UWB) localization system is an alternative in a GPS-denied environment. However, a distance measurement with UWB modules using a two-way communication protocol induces an orientation-dependent error. Previous research studied this error by looking at parameters such as the received power and the channel response signal. In this paper, the neural network (NN) method for correcting the orientation-induced distance error without the need to calculate the signal strength, obtain the channel response or know any parameters of the antenna and the UWB modules is presented. The NN method utilizes only the measured distance and the tag orientation, and implements an NN model obtained by machine learning, using measurements at different distances and orientations of the two UWB modules. The verification of the experimental setup with 12 anchors and a tag shows that with the proposed NN method, 5 cm better root mean square error values (RMSEs) are obtained for the measured distance between the anchors and the tag compared to the calibration method that did not include orientation information. With the least-square estimator, 14 cm RMSE in 3D is obtained with the NN model corrected distances, with a 9 cm improvement compared to when raw distances are used. The method produces better results without the need to obtain the UWB module’s diagnostics parameters that are required to calculate the received signal strength or channel response, and in this way maintain the minimum packet size for the ranging protocol.
Highlights
Indoor localization using ultra-wideband (UWB) radio is a popular research topic [1,2,3,4,5,6] and an off-the-shelf real-time localization system [7]
14 cm root mean square error values (RMSEs) in 3D is obtained with the neural network (NN) model corrected distances, with a 9 cm improvement compared to when raw distances are used
The NN model results for the elevation/azimuth data that were not used in the NN model training and the data from the real-time localization systems (RTLSs) experimental setup are presented
Summary
Indoor localization using ultra-wideband (UWB) radio is a popular research topic [1,2,3,4,5,6] and an off-the-shelf real-time localization system [7]. In real-time localization systems (RTLSs), the tags (agents, mobile units) are localized by measuring the distances from the tag to the anchors (ground station, static units) with known positions. The accuracy of the measured distances depends on the accuracy of the tag’s position [10]. An orientation-dependent error is present in UWB-radio distance measurements [11,12,13,14,15]. A non-empirical model that would contain a large set of distance and orientation variations could be relevant for effective error mitigation
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