SpinLight: A high accuracy and robust light positioning system for indoor applications

SenSys 2015 - Proceedings of the 13th ACM Conference on Embedded Networked Sensor Systems

Volumn , Issue , 2015, Pages 211-223

  Xie, Bo ^a   Tan, Guang ^a   He, Tian ^b  

^a UNIVERSITY OF CHINESE ACADEMY OF SCIENCES   (China)

^b UNIVERSITY OF MINNESOTA   (United States)

Author keywords

Indoor positioning; Light; Sensing

Indexed keywords

EMBEDDED SYSTEMS; INDOOR POSITIONING SYSTEMS; LIGHT; LIGHT SOURCES; SIGNAL RECEIVERS;

INDOOR APPLICATIONS; INDOOR POSITIONING; LIGHT POSITIONING; OPTIMIZATION SCHEME; PROTOTYPE IMPLEMENTATIONS; RECEIVER DESIGN; SENSING; SIGNAL TRANSMITTERS;

LIGHT EMITTING DIODES;

EID: 84962854187     PISSN: None     EISSN: None     Source Type: Conference Proceeding    
DOI: 10.1145/2809695.2809713     Document Type: Conference Paper

References (47)

1. Analog Devices, Inc. ADXL330: Small, Low Power, 3-Axis ±3g iMEMS Accelerometer (Data Sheet), 2007.
2. ByteLight. http://www.bytelight.com
3. J. Armstrong, Y. A. Sekercioglu, and A. Neild. Visible light positioning: A roadmap for international standardization. IEEE Communications Magazine, 51(12), 2013.
4. P. Bahl and V. N. Padmanabhan. RADAR: An Inbuilding RF-based User Location and Tracking System. In INFOCOM, 2000.
5. J. R. Barry. Wireless infrared communications, Springer, 1994.
6. J. Biswas and M. Veloso. Wifi localization and navigation for autonomous indoor mobile robots. In IEEE International Conference Robotics and Automation (ICRA), 2010.
7. G. Borriello, A. Liu, T. Offer, C. Palistrant, and R. Sharp. WALRUS: wireless acoustic location with roomlevel resolution using ultrasound. In MobiSys, 2005.
8. A. Carroll and G. Heiser. An Analysis of Power Consumption in a Smartphone. USENIX Annual Technical Conference 2010.
9. Y. Chen, D. Lymberopoulos, J. Liu, and B. Priyantha. FM-based indoor localization. In ACM MobiSys, 2012.
10. J. Chung, M. Donahoe, I. Kim, C. Schmandt, P. Razavi, M. Wiseman. Indoor location sensing using geomagnetism. In MobiSys, 2011.
11. Intersil. The ISL29023 Datasheet. July 17, 2012.
12. A. Jovicic, J. Li, and T. Richardson. Visible light communication: Opportunities, challenges and the path to market. IEEE Communications Magazine, 51(12), 2013.
13. Y.-S. Kuo, P. Pannuto, K.-J. Hsiao, and P. Dutta. Luxapose: indoor positioning with mobile phones and visible light. In Mobicom 2014.
14. L. Li, P. Hu, C. Peng, G. Shen, and F. Zhao. Epsilon: A Visible Light Based Positioning System. Proc. NSDI 2014.
15. R. LiKamWa, B. Priyantha, M. Philipose, L. Zhong and P. Bahl. Energy Characterization and Optimization of Image Sensing Toward Continuous Mobile Vision. Proc. of MobiSys 2013.
16. A. T. Mariakakis, S. Sen, J. Lee, K.-H. Kim. SAIL: single access point-based indoor localization. In MobiSys, 2014.
17. L. Ni, Y. Liu, C. Yiu, and A. Patil. LANDMARC: Indoor Location Sensing Using Active RFID. In WINET, 2004.
18. D. Niculescu and B. Nath. Ad hoc positioning system (APS) using AOA. IEEE INFOCOM, 2003.
19. D. Niculescu and B. Nath. Vor base stations for indoor 802.11 positioning. ACM Mobicom, 2004.
20. Nordic semiconductor. nRF8001 Product Specification 1. 2. 2013.
21. Opto-isolator. http://en. wikipedia.org/wiki/Optoisolator.
22. G. B. Prince and T. D. Little. A two phase hybrid RSS/AoA algorithm for indoor device localization using visible light. In IEEE Global Communication Conference (GLOBECOM), 2012.
23. N. Priyantha, A. Chakraborty, and H. Balakrishnan. The Cricket location-support system. In ACM Mobi-Com, 2000.
24. N. Rajagopal, P. Lazik, and A. Wowe. Visual light landmarks for mobile devices. In IPSN, 2014.
25. K. Romer. The Lighthouse Location System for Smart Dust. ACM MobiSys 2003.
26. S. Sen, J. Lee, K.-H. Kim, and P. Congdon. Avoiding Multipath to Revive Inbuilding WiFi Localization. In ACM Mobisys, 2013.
27. G. Sterling and D. Top. Mapping the Indoor Marketing Opportunity. Opus Research Report.
28. STMicroelectronics. STM32 MCU family - 32-bit Flash microcontrollers powered by ARM Cortex™ - M3, May 2008.
29. STMicroelectronics. LIS33DE datasheet, April 2009.
30. R. Stoleru, T. He, J. A. Stankovic, D. Luebke. A High-Accuracy, Low-Cost Localization System for Wireless Sensor Networks. ACM SenSys 2005.
31. S. Tarzia, P. Dinda, R. Dick, G. Memik. Indoor Localization without Infrastructure using the Acoustic Background Spectrum. In ACM MobiSys, 2011.
32. A. Varshavskya, E. D. Lara, J. Hightower, A. LaMarca, V. Otsason. GSM indoor localization. Pervasive and Mobile Computing, 2007.
33. Vexta PK245 technical data sheet. Velmex, Inc.
34. VLC for location, positioning and navigation. http://visiblelightcomm.com/vlc-for-locationpositioning-and-navigation
35. J. Wang, F. Adib, R. Knepper, D. Katabi and D. Rus. RF-Compass: Robot Object Manipulation Using RFIDs. In ACM Mobicom, 2013.
36. J. Wang and D. Katabi. Dude, Where's my card?: Rfid positioning that works with multipath and non-line of sight. In Proc. of ACM SIGCOMM, 2013.
37. R. Want, A. Hopper, V. Falcao, and J. Gibbons. The active badge location system. ACM Trans. on Information Systems, 10(1):91-102, Jan. 1992.
38. A. Ward, A. Jones, and A. Hopper. A new location technique for the active office. IEEE Personal Communications, 4(5):42-47, Oct. 1997.
39. K. Wu., J. Xiao, Y. Yi, M. Gao, and L. M. Ni. FILA: Fine-grained indoor localization. In IEEE INFOCOM, 2012.
40. B. Xie, G. Tan, Y. Liu, M. Lu, K. Chen, T. He. LIPS: A Light Intensity Based Positioning System For Indoor Environments. http://arxiv.org/abs/1403.2331
41. J. Xiong and K. Jamieson. Arraytrack: A fine-grained indoor location system. In Usenix NSDI, 2013.
42. S.-H. Yang, E.-M. Jeong, D.-R. Kim, H.-S. Kim, Y.-H. Son, and S.-K. Han. Indoor three-dimensional location estimation based on LED visible light communication. Electronics Letters, 49(1), January 2013.
43. L. Yang, Y. Chen, X.-Y. Li, C. Xiao, M. Li, and Y. Liu. Tagoram: Real-Time Tracking of Mobile RFID Tags to High Precision Using COTS Devices. In Proc. of Mobicom, 2014.
44. S.-H. Yang, E.-M. Jung, S.-K. Han. Indoor location estimation based on LED visible light communication using multiple optical receivers. IEEE Communications Letters, 17(9), Sept. 2013.
45. M. Yoshino, S. Haruyama, and M. Nakagawa. Highaccuracy positioning system using visible LED lights and image sensor. In IEEE Radio and Wireless Symposium (RWS), 2008.
46. M. Youssef and A. Agrawala. The Horus WLAN Location Determination System. In MobiSys, 2005.
47. Z. Zhou, M. Kavehrad, and P. Deng. Indoor positioning algorithm using light-emitting diode visible light communications. Optical Engineering, 51(8), 2012.