Indoor Navigation System using Asynchronous Pseudolites

Changdon Kee; Haeyoung Jun; Doohee Yun

doi:10.1017/S0373463303002467

Abstract

The Global Positioning System (GPS) is now attracting worldwide attention as a navigation sensor. One of the advantages of GPS is that people can find their position using a GPS receiver wherever they are except in obstructed environments. Existing GPS receivers do not work in an obstructed environment despite there being many potential applications. This paper shows the possibility of navigation using GPS technologies indoors in a blocked environment. The paper describes the pseudolite-based indoor navigation system that was developed and implemented at Seoul National University (SNU). The system, which uses GPS technologies, has some different characteristics to normal outdoor GPS systems. The differences cause some practical problems, such as near/far, time-tag, multipath and unknown transmission position problems, which need to be solved to implement the indoor navigation system. The paper introduces various methods for solving such problems. The paper then shows the experimental results and the system accuracy. The satisfactory experimental results show that the RMS static error is 1 mm(1σ) horizontally and 2 mm(1σ) vertically and the RMS dynamic error is 5·6 mm(1σ) horizontally and 15 mm(1σ) vertically. The paper also shows the result of a field application test in the ocean engineering basin of the Korea Research Institute of Ships & Ocean Engineering (KRISO).

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Br&Scaron;cic, Drazen Sasaki, Takeshi and Hashimoto, Hideki 2008. Tracking of Humans and Robots Using Laser Range Finders. SICE Journal of Control, Measurement, and System Integration, Vol. 1, Issue. 5, p. 383.

Yi, Soo-Yeong 2008. Global ultrasonic system with selective activation for autonomous navigation of an indoor mobile robot. Robotica, Vol. 26, Issue. 3, p. 277.

So, Hyoungmin Kim, Ghangho Lee, Taikjin Jeon, Sanghoon and Kee, Changdon 2009. Modified High-Resolution Correlator Technique for Short-Delayed Multipath Mitigation. Journal of Navigation, Vol. 62, Issue. 3, p. 523.

Kemppi, P. Rautiainen, T. Ranki, V. Belloni, F. and Pajunen, J. 2010. Hybrid positioning system combining angle-based localization, pedestrian dead reckoning and map filtering. p. 1.

Samama, Nel and Fluerasu, Anca 2012. Pseudolites/repeaters infrastructure autopositioning approach—mathematics and first simulation-based results. annals of telecommunications - annales des télécommunications, Vol. 67, Issue. 9-10, p. 485.

Selmi, Ikhlas Samama, Nel and Vervisch-Picois, Alexandre 2013. A new approach for decimeter accurate GNSS indoor positioning using Carrier Phase Measurements. p. 1.

So, Hyoungmin Park, Junpyo and Song, Kiwon 2013. Performance Analysis of Pseudolite Tropospheric Delay Models Using Radiosonde Meteorological Data. Journal of Positioning, Navigation, and Timing, Vol. 2, Issue. 1, p. 49.

Seo, Seungwoo Park, Junpyo Suk, Jin-Young and Song, Kiwon 2014. A Design of Dual Frequency Bands Time Synchronization System for Synchronized-Pseudolite Navigation System. Journal of Positioning, Navigation, and Timing, Vol. 3, Issue. 2, p. 71.

Park, Jun-Pyo and Suk, Jinyoung 2014. A Study on Navigation Performance Analysis Technique of Pseudolite Navigation Systems. Journal of the Korean Society for Aeronautical & Space Sciences, Vol. 42, Issue. 11, p. 947.

Park, Jun-Pyo and Suk, Jinyoung 2014. A Study on the Effects and the Countermeasure of Sea Surface Reflection Waves in Pseudolite Navigation Systems. Journal of the Korean Society for Aeronautical & Space Sciences, Vol. 42, Issue. 6, p. 505.

Jang, Jaegyu Ahn, Woo-Guen Seo, Seungwoo Lee, Jang and Park, Jun-Pyo 2015. Flight Test Result for the Ground-Based Radio Navigation System Sensor with an Unmanned Air Vehicle. Sensors, Vol. 15, Issue. 11, p. 28472.

Ma, Chao Yang, Jun and Chen, Jianyun 2018. Satellite-ground Joint Positioning System Based on Pseudolite. p. 1.

Liu, Kai Yang, Jun Guo, Xiye Zhou, Yongbin and Liu, Changshui 2018. Correction of fractional cycle bias of pseudolite system for user integer ambiguity resolution. GPS Solutions, Vol. 22, Issue. 4,

Ma, Chao Yang, Jun Chen, Jianyun and Tang, Yinyin 2018. Indoor and outdoor positioning system based on navigation signal simulator and pseudolites. Advances in Space Research, Vol. 62, Issue. 9, p. 2509.

Wang, Tengfei Yao, Zheng and Lu, Mingquan 2019. Combined difference square observation-based ambiguity determination for ground-based positioning system. Journal of Geodesy, Vol. 93, Issue. 10, p. 1867.

2019. Indoor Positioning. p. 191.

Wang, Tengfei Yao, Zheng and Lu, Mingquan 2019. On-the-fly ambiguity resolution involving only carrier phase measurements for stand-alone ground-based positioning systems. GPS Solutions, Vol. 23, Issue. 2,

Uzun, Abdulkadir Ghani, Firas Abdul Ahmadi Najafabadi, Amir Mohsen Yenigün, Hüsnü and Tekin, İbrahim 2021. Indoor Positioning System Based on Global Positioning System Signals with Down- and Up-Converters in 433 MHz ISM Band. Sensors, Vol. 21, Issue. 13, p. 4338.

Park, Minhuck Han, Jin‐Hee Kim, O‐Jong Kim, Jungbeom and Kee, Changdon 2021. One‐way deep indoor positioning system for conventional GNSS receiver using paired transmitters. NAVIGATION, Vol. 68, Issue. 3, p. 601.

Kim, Woohyun and Seo, Jiwon 2023. Low-Cost GNSS Simulators With Wireless Clock Synchronization for Indoor Positioning. IEEE Access, Vol. 11, Issue. , p. 55861.

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Indoor Navigation System using Asynchronous Pseudolites

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Indoor Navigation System using Asynchronous Pseudolites

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