Abstract
Indoor location-based services have been widely investigated to take advantage of semantic trajectories for providing user oriented services in indoor environments. Although indoor semantic trajectories can provide seamless understanding to users regarding the provided location-based services, studies on the application of deep learning approaches for robust and valid semantic indoor localization are lacking. In this study, we combined a stacked denoising autoencoder and long short term memory technique with a rule-based refinement method applying a rule-based hidden Markov model (HMM) to perform robust and valid semantic trajectory extraction. In particular, our rule-based HMM approach incorporates a direct set of rules into HMM to resolve invalid movements of the extracted semantic trajectories and is extensible to various deep learning techniques. We compared the performance of our proposed approach with that of other cutting-edge deep learning approaches on two different real-world data sets. The experimental results demonstrate the feasibility of our proposed approach to produce more robust and valid semantic trajectories.
Highlights
Location based services (LBSs) provide various services to consumers based on their locations
We introduced the combined stacked denoising autoencoder with a rule-based refinement method that applies direct rule-based hidden Markov model (HMM) to ensure movement occurs from one location only to its possible adjacent locations based on floor-map representations
We implement our approach in Python 3.6 using Tensorflow-GPU 1.10.1 and Keras 2.2.2 performed with the CUDA Toolkit 9.0.176 and cuDNN 7.0
Summary
Location based services (LBSs) provide various services to consumers based on their locations. The increasing indoor-based services have attracted the attention of researchers to study indoor localization approaches. Because Global Positioning System (GPS) signals cannot be accessed well in indoor environments, various other signals such as radio frequency identification (RFID) [1], magnetic and light sensors [2], [3], Wi-Fi [4], [5] or Bluetooth low energy (BLE) beacons [6]–[10] have been employed for this purpose. Most studies [7]–[12] have focused on the received signal strength indicator (RSSI) obtained from BLE beacons because of the low cost and compatibility for simultaneous scans.
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