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Vision-Based Indoor Corridor Localization via Smartphone Using Relative Distance Perception and Deviation Compensation

Published: 27 February 2024 Publication History

Abstract

Nowadays, the determination of the indoor position has become a hot issue in industry and academia as it is fundamental for many applications and services. Thanks to the pervasive availability of smartphones, a plethora of indoor navigation systems has been developed based on different techniques, such as radio-frequency-based technologies, sensor-based technologies, and vision-based technologies; however, there are certain limitations for general use, such as high cost of adding extra hardware, more labor input, violent fluctuation, low accuracy result, etc. To improve the robustness and accuracy of traditional means, this paper proposes a new solution to accurate indoor positioning for narrow corridors. The proposed method consists of coarse positioning from Wi-Fi matching and image-level positioning and verification from holistic and local visual feature matching. A rough position area called subarea is first predicted using Wi-Fi information and a geometric relationship derived in this paper is used to calculate user’s coordinates in higher precision. A feed-forward neural network is also trained for error mitigation. The experiments conducted in this paper have proved that our method owns an above-average precision (positioning error results fewer than 0.3 m on average) in related field which can be used to locate users in corridors or channels accurately while still keeping humble in labors.

References

[1]
Yang T, Cabani A, and Chafouk H A survey of recent indoor localization scenarios and methodologies Sensors 2021 21 8086
[2]
Wang Z, Chen R, Xu S, Liu Z, Guo G, and Chen L A novel method locating pedestrian with smartphone indoors using acoustic fingerprints IEEE Sens J 2021 21 24 27887-27896
[3]
Chen R and Chen L Smartphone-based indoor positioning technologies 2021 Singapore Springer Singapore 467-490
[4]
IEEE standard for information technology–telecommunications and information exchange between systems—local and metropolitan area networks-specific requirements—part 11: Wireless LAN medium access control (MAC) and physical layer (phy) specifications—corrigendum 1—correct IEEE 802.11ay assignment of protected announce support bit, IEEE Std 802.11-2020/Cor 1-2022 (Corrigendum to IEEE Std 802.11-2020 as amended by IEEE Std 802.11ax-2021, IEEE Std 802.11ay-2021, and IEEE Std 802.11ba-2021). 2022:1–8.
[5]
Bellavista-Parent V, Torres-Sospedra J, Perez-Navarro A. New trends in indoor positioning based on wifi and machine learning: a systematic review. In: 2021 International Conference on Indoor Positioning and Indoor Navigation (IPIN), 2021, p. 1–8.
[6]
Naser RS, Lam MC, Qamar F, Zaidan BB. Smartphone-based indoor localization systems: a systematic literature review. Electronics. 2023;12(8). [Online]. Available: https://www.mdpi.com/2079-9292/12/8/1814.
[7]
Li W, Chen R, Yu Y, Wu Y, and Zhou H Pedestrian dead reckoning with novel heading estimation under magnetic interference and multiple smartphone postures Measurement 2021 182
[8]
Ouyang G, Abed-Meraim K, Ouyang Z. Magnetic-field-based indoor positioning using temporal convolutional networks. Sensors. 2023;23(3). [Online]. Available: https://www.mdpi.com/1424-8220/23/3/1514.
[9]
Jia S, Ma L, Wei S, Fu Y. Location drift detection method for monocular vision based indoor positioning. In: 2022 IEEE 95th Vehicular Technology Conference: (VTC2022-Spring), 2022, p. 1–5.
[10]
Liu X, Huang H, and Hu B Indoor visual positioning method based on image features Sens Mater 2022 34 1 337-348
[11]
Yang S, Ma L, Jia S, and Qin D An improved vision-based indoor positioning method IEEE Access 2020 8 26941-26949
[12]
Peng P, Yu C, Xia Q, Zheng Z, Zhao K, Chen W. An indoor positioning method based on uwb and visual fusion. Sensors. 2022;22(4). [Online]. Available: https://www.mdpi.com/1424-8220/22/4/1394.
[13]
Kong X, Wu C, You Y, Lv Z, Zhao Z. Hybrid indoor positioning method of BLE and monocular VINS based smartphone. IEEE Trans Instrum Meas. 2023;72.
[14]
Lu P, Zhang J, Lin X, Qi J, Chen Y, Yang K. Research on indoor target positioning system based on image feature extraction and recognition. In: 2023 IEEE 2nd International Conference on Electrical Engineering, Big Data and Algorithms (EEBDA), 2023, p. 547–50.
[15]
Deng S, Zhang W, Xu L, and Yang J RRIFLoc: radio robust image fingerprint indoor localization algorithm based on deep residual networks IEEE Sens J 2023 23 3 3233-3242
[16]
Mekruksavanich S, Jantawong P, Jitpattanakul A. Deep learning-based action recognition for pedestrian indoor localization using smartphone inertial sensors. In: 2022 Joint International Conference on Digital Arts, Media and Technology with ECTI Northern Section Conference on Electrical, Electronics, Computer and Telecommunications Engineering (ECTI DAMT & NCON), 2022, p. 346–9.
[17]
Sung S, Kim H, and Jung J-I Accurate indoor positioning for UWB-based personal devices using deep learning IEEE Access 2023 11 20095-20113
[18]
Bansal M, Kumar M, and Kumar M 2D object recognition: a comparative analysis of SIFT, SURF and ORB feature descriptors Multimed Tools Appl 2021 80 18839-18857
[19]
Rublee E, Rabaud V, Konolige K, Bradski G. ORB: an efficient alternative to sift or surf. In: 2021 International Conference on Computer Vision. IEEE; 2011. p. 2564–71.
[20]
Bay H, Ess A, Tuytelaars T, and Van Gool L Speeded-up robust features (SURF) Comput Vis Image Underst 2008 110 3 346-359
[21]
Alcantarilla PF, Nuevo J, Bartoli A. Fast explicit diffusion for accelerated features in nonlinear scale spaces. 2013.
[22]
Huang G, Hu Z, Wu J, Xiao H, and Zhang F WiFi and vision-integrated fingerprint for smartphone-based self-localization in public indoor scenes IEEE Internet Things J 2020 7 8 6748-6761
[23]
Guan K, Ma L, Tan X, Guo S. Vision-based indoor localization approach based on surf and landmark. In: 2016 International Wireless Communications and Mobile Computing Conference (IWCMC). IEEE; 2016. p. 655–9.

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Published In

cover image SN Computer Science
SN Computer Science  Volume 5, Issue 3
Mar 2024
750 pages

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Springer-Verlag

Berlin, Heidelberg

Publication History

Published: 27 February 2024
Accepted: 28 December 2023
Received: 17 November 2022

Author Tags

  1. Indoor positioning
  2. Wi-Fi matching
  3. Smartphone vision
  4. Image processing
  5. Relative distance perception
  6. Deviation compensation

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