Deep learning based wireless localization for indoor navigation

Ayyalasomayajula, Roshan; Arun, Aditya; Wu, Chih‐Fu; Sharma, Sanatan; Sethi, Abhishek; Vasisht, Deepak; Bharadia, Dinesh

doi:10.1145/3372224.3380894

Cited by 122 publications

(54 citation statements)

References 51 publications

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“…When the sound source is from angle θ and distance d, then Pns(θ, d) have a high value. If we have U and V grid points for θ and d, then we will obtain a likelihood surface with dimension U × V which can indicate the likelihood of the signal in the given θ and d. For reverberation and noise free data, the localization is simply identifying the θ and d that correspond to the maximum likelihood [21]. Due to the reverberation, much of the sound received by the microphones is a result of multipath, which is a complicated function of the different microphone locations relative to the source.…”

Section: Features Extractionmentioning

confidence: 99%

“…Now that we have the inputs and targets for performing single point identification, we utilize the network architecture as shown in Fig. 2 and based on encoder-decoder architecture with one encoder and two parallel decoders inspired from [21]. The input to the encoder is the likelihood surface without range compensation indicated as (2).…”

Section: Sslide Architecturementioning

confidence: 99%

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SSLIDE: Sound Source Localization for Indoors Based on Deep Learning

Ayyalasomayajula

Bianco

et al. 2021

ICASSP 2021 - 2021 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP)

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This paper presents SSLIDE, Sound Source Localization for Indoors using DEep learning, which applies deep neural networks (DNNs) with encoder-decoder structure to localize sound sources with random positions in a continuous space. The spatial features of sound signals received by each microphone are extracted and represented as likelihood surfaces for the sound source locations in each point. Our DNN consists of an encoder network followed by two decoders. The encoder obtains a compressed representation of the input likelihoods. One decoder resolves the multipath caused by reverberation, and the other decoder estimates the source location. Experiments based on both the simulated and experimental data show that our method can not only outperform multiple signal classification (MU-SIC), steered response power with phase transform (SRP-PHAT), sparse Bayesian learning (SBL), and a competing convolutional neural network (CNN) approach in the reverberant environment but also achieve a good generalization performance.

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Section: Features Extractionmentioning

confidence: 99%

Section: Sslide Architecturementioning

confidence: 99%

SSLIDE: Sound Source Localization for Indoors Based on Deep Learning

Ayyalasomayajula

Bianco

et al. 2021

ICASSP 2021 - 2021 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP)

Self Cite

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“…Like other fingerprinting schemes, AngLoc also needs to collect offline angle data for its database construction. The authors in [21] presented a deep-learning based indoor navigation framework (called DLoc) by an environment mapping approach. DLoc uses a CSI-based AoA and ToF combined method to localize a target.…”

Section: Related Workmentioning

confidence: 99%

“…From a practical point of view, this mapping function needs to be evaluated by a specific experiment device used for our PFIPS. Based on (21), given an RSSI value, we can obtain a distance by…”

Section: B Rssi Measurement and Mappingmentioning

confidence: 99%

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Particle Filtering-Based Indoor Positioning System for Beacon Tag Tracking

2020

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DRVAT: Exploring RSSI series representation and attention model for indoor positioning

Sun

Tao

et al. 2021

Int J of Intelligent Sys

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Although Bluetooth Low Energy (BLE) fingerprinting localization has become a hot research topic with encouraging results, it is difficult to predict the location depending on a short duration received signal strength indication (RSSI) sequence in realistic scenarios due to the severe fluctuation of RSSI. We introduce a new perspective to view the indoor positioning problem by radio map fingerprint. We argue that even though beacons may be independently deployed, the RSSI series bear certain spatial relation because of their copresence in the same physical space. The latent relation implicitly conveyed by the coexistence of their signals at various indoor locations. Unlike existing approaches that try to find a direct mapping between sensed signals and the corresponding location, we explore the spatial relation of beacons from the input data to estimate location. We propose a deep learning localization system, termed DRVAT, which is based on the distributed representation vector (DRV) and selfattention (AT) among the pairs of MAC-RSSI. First, we obtain DRVs which represent dense features in low dimensionality through pre-training on all MAC-RSSIs. Then we exploit self-attention mechanism to learn the latent spatial relation of beacons. Finally, MAC-RSSIs labeled with locations are used to fine-tune the model for estimating location. Localization accuracy results

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Deep learning based wireless localization for indoor navigation

Cited by 122 publications

References 51 publications

SSLIDE: Sound Source Localization for Indoors Based on Deep Learning

SSLIDE: Sound Source Localization for Indoors Based on Deep Learning

Particle Filtering-Based Indoor Positioning System for Beacon Tag Tracking

DRVAT: Exploring RSSI series representation and attention model for indoor positioning

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