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Advanced Indoor Zone Detection with Bluetooth and Ultrasound of Smartphone
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 Title & Authors
Advanced Indoor Zone Detection with Bluetooth and Ultrasound of Smartphone
Kwon, Jin-Se; Lee, Je-Min; Kim, Hyung-Shin;
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 Abstract
Indoor zone-based services have continuously become popular by increased prevalence of smartphones. Bluetooth and ultrasound can be used for zone detection. However, bluetooth does not guarantee precise zone detection if the signal degrades due to the obstacles. Ultrasound can be easily forged by recording sound on the smartphone. For that reason, zone detection based on ultrasound has a security hole. To remedy each limitation, we propose an advanced zone detection method, that combines bluetooth and ultrasound. An authentication server issues a one-time password to the user over bluetooth. The user generates an ultrasound signal that encodes the password. In this manner, the proposed method ensures secure and accurate zone detection.
 Keywords
Indoor zone detection;Zone-based authentication;Ultrasound and bluetooth beacon;
 Language
Korean
 Cited by
 References
1.
https://yap.net/ko/service#beacon

2.
https://www.ruckuswireless.com/products/smart-wireless-services/location-services

3.
R. Friedman, A. Kogan, Y. Krivolapov, "On Power and Throughput Tradeoffs of Wifi and Bluetooth in Smartphones," IEEE Transactions on Mobile Computing, Vol. 12, No. 7, pp. 1363-1376, 2013. crossref(new window)

4.
http://readme.skplanet.com/?p=9850

5.
http://www.syrup.co.kr/index.do#about_syrup

6.
http://www.i-popcorn.co.kr/

7.
D.J. Na, K.H. Choi, "Step Trajectory/Indoor Map Feature-based Smartphone Indoor Positioning System without Using Wi-Fi Signals," IEMEK J. Embed. Sys. Appl., Vol. 9, No. 6, pp. 323-334, 2014 (in Korean). crossref(new window)

8.
N. B. Priyantha, A. Chakraborty, H. Balakrishnan, "The Cricket location-support system," Proceeding of the annual International Conference on Mobile computing and networking, pp.32-43, 2000.

9.
P. Lazik, A. Rowe, "Indoor pseudo-ranging of mobile devices using ultrasonic chirps," Proceeding of the ACM Conference on Embedded Network Sensor Systems, pp. 99-112, 2012.

10.
P. Lazik, N. Rajagopal, B. Sinopoli, A. Rowe, "Ultrasonic time synchronization and ranging on smartphones," Real-Time and Embedded Technology and Applications Symposium, pp. 108-118, 2015.

11.
T.W. Hnat, E. Griffiths, R. Dawson, K. Whitehouse, "Doorjamb: unobtrusive room-level tracking of people in homes using doorway sensors," Proceeding of the ACM Conference on Embedded Network Sensor Systems, pp. 309-322, 2012.

12.
http://www.istarbucks.co.kr/util/website_tip_view.do?seq=2397&status=app

13.
J.S. Kwon, J.M. Lee, H.S. Kim, "Indoor Zone Detection with Bluetooth and Ultrasound of Smartphone," Proceedings of Institute of Embedded Engineering of Korea, pp. 40-43, 2015 (in Korean).

14.
http://www.knowles.com/eng/Products/Receivers-and-speakers

15.
A. Farina, "Simultaneous Measurement of Impulse Response and Distortion with a Swept-Sine Technique," Proceeding of Audio Engineering Society Conventions and Conferences, 2000.

16.
H.W. Lee, T.H. Kim, J.W. Choi, S.H. Choi, "Chirp Signal-Based Aerial Acoustic Communication for Smart Devices," Proceeding of IEEE Conference on Computer Communications, pp. 2407-2415, 2015.