Abstract
The recognition of non-line-of-sight (NLOS) state is a prerequisite for alleviating NLOS errors and is crucial to ensure the accuracy of positioning. Recent studies only identify the line-of-sight (LOS) state and the NLOS state, but ignore the contribution of occlusion categories to spatial information perception. This paper proposes a bidirectional search algorithm based on maximum correlation, minimum redundancy, and minimum computational cost (BS-mRMRMC). The optimal channel impulse response (CIR) feature set, which can identify NLOS and LOS states well, as well as the blocking categories, are determined by setting the constraint thresholds of both the maximum evaluation index, and the computational cost. The identification of blocking categories provides more effective information for the indoor space perception of ultra-wide band (UWB). Based on the vector projection method, the hierarchical structure of decision tree support vector machine (DT-SVM) is designed to verify the recognition accuracy of each category. Experiments show that the proposed algorithm has an average recognition accuracy of 96.7% for each occlusion category, which is better than those of the other three algorithms based on the same number of CIR signal characteristics of UWB.
Highlights
Due to the complexity of the indoor environment, there are often barriers between fixed base station (FS) and mobile base station (MS), namely non-line-of-sight propagation (NLOS) conditions, which will lead to the blocking of the signal propagation path between FS and MS and introduce positive deviation [2]
This paper provides a new research method for ultra-wide band (UWB) subsequent indoor positioning, indoor information perception construction and target tracking
A large amount of channel impulse response (CIR) data of a UWB device with five different blocking materials at LOS and NLOS are obtained in a large experimental center, and eight features are extracted from CIR
Summary
Among the existing indoor-positioning systems, ultra-wide band (UWB) technology has become one of the most promising methods due to its high precision, good time-delay resolution, low power consumption, and high robustness in complex indoor environments. It has significant advantages over other indoor positioning technologies in terms of accuracy [1]. Due to the complexity of the indoor environment, there are often barriers between fixed base station (FS) and mobile base station (MS), namely non-line-of-sight propagation (NLOS) conditions, which will lead to the blocking of the signal propagation path between FS and MS and introduce positive deviation [2]. The status recognition of Sensors 2020, 20, 4178; doi:10.3390/s20154178 www.mdpi.com/journal/sensors
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