Abstract
With the rapid growth of indoor positioning requirements without equipment and the convenience of channel state information acquisition, the research on indoor fingerprint positioning based on channel state information is increasingly valued. In this article, a multi-level fingerprinting approach is proposed, which is composed of two-level methods: the first layer is achieved by deep learning and the second layer is implemented by the optimal subcarriers filtering method. This method using channel state information is termed multi-level fingerprinting with deep learning. Deep neural networks are applied in the deep learning of the first layer of multi-level fingerprinting with deep learning, which includes two phases: an offline training phase and an online localization phase. In the offline training phase, deep neural networks are used to train the optimal weights. In the online localization phase, the top five closest positions to the location position are obtained through forward propagation. The second layer optimizes the results of the first layer through the optimal subcarriers filtering method. Under the accuracy of 0.6 m, the positioning accuracy of two common environments has reached, respectively, 96% and 93.9%. The evaluation results show that the positioning accuracy of this method is better than the method based on received signal strength, and it is better than the support vector machine method, which is also slightly improved compared with the deep learning method.
Highlights
With the increasing demand for indoor positioning, it has become an increasingly important issue
We propose a multi-level fingerprinting approach, which is composed of two-level methods: the first layer is achieved by deep learning and the second layer is implemented by the optimal subcarriers filtering method
We introduce the experimental results with the comparison of received signal strength (RSS), support vector machine (SVM), and deep learning
Summary
With the increasing demand for indoor positioning, it has become an increasingly important issue. After using the deep learning of the first layer to train each position weight as the fingerprint, we have used the optimal subcarrier filtering method of second layer to distinguish the points of the CSI amplitude information closer. DNN first randomly initializes the weights of each position, and the predictive values are obtained by the forward propagation, and the corresponding classification probability information is output for the second layer. The deep learning method of first layer gives five positions in the order of probability, the Euclidean distance between these positions and the first three optimal subcarriers obtained in the first step is calculated. We use 1 minus those five proportion to get five new probabilities, which is the probability of second layer
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