Hostname: page-component-78c5997874-fbnjt Total loading time: 0 Render date: 2024-11-10T12:55:05.722Z Has data issue: false hasContentIssue false

Simulating Surveillance Options for the Canadian North

Published online by Cambridge University Press:  04 April 2016

Anna-Liesa S. Lapinski*
Affiliation:
(Defence R&D Canada – Atlantic, Dartmouth, Nova Scotia, Canada)
Anthony W. Isenor
Affiliation:
(Defence R&D Canada – Atlantic, Dartmouth, Nova Scotia, Canada)
Sean Webb
Affiliation:
(Defence R&D Canada – Atlantic, Dartmouth, Nova Scotia, Canada)

Abstract

As part of the overarching research goal to assess current and potential maritime information sources for use in maritime defence and security in the Canadian north, we examine whether wide-area surveillance data, as represented by Space-based Automatic Identification System (S-AIS) data, offers sufficient information for surveillance requirements in the Canadian north. If S-AIS data are not sufficient, we address how the additional information provided by Long-Range Identification and Tracking (LRIT) can be used to meet the surveillance requirements. A Systems Tool Kit (STK) simulation scenario is constructed that includes five exactEarth satellites collecting AIS data. Simulated AIS transmitters are positioned at 20 northern Canada ground locations. The results indicate that for each location, two thirds of the eight-day simulation is spent without a satellite within range, when using the five satellites. As the number of satellites decreases, intervals in the range of 80 to 105 minutes, during which there are no AIS messages received, increase in frequency. If the end-user requires vessel location information more often than S-AIS consistently provides, augmenting the S-AIS information with LRIT polling should achieve the desired vessel traffic awareness.

Type
Research Article
Copyright
Copyright © The Royal Institute of Navigation 2016 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Analytical Graphics Inc (2013). STK Systems Tool Kit®. http://www.agi.com/products/stk/modules/default.aspx/id/stk-free, Last Accessed: November 8 2013.Google Scholar
Balduzzi, M., Pasta, A. and Wilhoit, K. (2014). A security evaluation of AIS automated identification system. Proceedings of the Proceedings of the 30th Annual Computer Security Applications Conference, New Orleans, Louisiana, USA.Google Scholar
Cairns, W. R. (2005). AIS and Long Range Identification & Tracking. The Journal of Navigation, 58, 181189.Google Scholar
Carson-Jackson, J. (2012). Satellite AIS – Developing Technology or Existing Capability? The Journal of Navigation, 65, 303321.Google Scholar
Cervera, M. A. and Ginesi, A. (2008). On the performance analysis of a satellite-based AIS system. Proceedings of the Signal Processing for Space Communications, 2008. SPSC 2008. 10th International Workshop on.Google Scholar
Cervera, M. A., Ginesi, A. and Eckstein, K. (2011). Satellite-based vessel Automatic Identification System: A feasibility and performance analysis. International Journal of Satellite Communications and Networking, 29, 117142.Google Scholar
Dekker, R., Bouma, H., Breejen, E. d., Broek, B. v. d., Hanckmann, P., Hogervorst, M., Mohamoud, A., Schoemaker, R., Sijs, J., Tan, R., Toet, A. and Smith, A. (2013). Maritime Situation Awareness Capabilities from Satellite and Terrestrial Sensor Systems. Proceedings of the Maritime Systems and Technology conference and exhibition, MAST Europe 2013, Gdansk, Poland.Google Scholar
Dembovskis, A. (2012). Testbed for performance evaluation of SAT-AIS receivers. Proceedings of the Advanced Satellite Multimedia Systems Conference (ASMS) and 12th Signal Processing for Space Communications Workshop (SPSC), 2012 6th.Google Scholar
Eriksen, T., Skauen, A. N., Narheim, B., Helleren, O., Olsen, O. and Olsen, R. B. (2010). Tracking ship traffic with Space-Based AIS: Experience gained in first months of operations. Proceedings of the Waterside Security Conference (WSS), 2010 International.Google Scholar
exactEarth (2013). personal communication. October 13, 2013, email addressed to S. Webb, DRDC Atlantic.Google Scholar
Greidanus, H., Alvarez, M., Eriksen, T., Argentieri, P., Çokacar, T., Pesaresi, A., Falchetti, S., Nappo, D., Mazzarella, F. and Alessandrini, A. (2013). Basin-Wide Maritime Awareness From Multi-Source Ship Reporting Data. TransNav, the International Journal on Marine Navigation and Safety of Sea Transportation, 7, 185192.Google Scholar
International Maritime Organization. (2002, 1974). SOLAS Chapter V.Google Scholar
International Maritime Organization. (2015a). AIS transponders. http://www.imo.org/ourwork/safety/navigation/pages/ais.aspx, Last Accessed: 2015-04-08.Google Scholar
International Maritime Organization. (2015b). Long-range identification and tracking (LRIT). http://www.imo.org/OurWork/Safety/Navigation/Pages/LRIT.aspx, Last Accessed: 2015-04-08.Google Scholar
International Maritime Organization: Maritime Safety Committee. (2006). Annex 2: Resolution MSC.202(81). International Maritime Organization.Google Scholar
International Maritime Organization: Maritime Safety Committee. (2008). Annex 9: Resolution MSC.263(84). International Maritime Organization.Google Scholar
International Telecommunications Union. (2014). Recommendation ITU-R M.1371-5. Technical characteristics for an automatic identification system using time-division multiple access in the VHF maritime mobile band. ITU.Google Scholar
International Telecommunications Union (2015). Recommendation ITU-R M.585-7. Assignment and use of identities in the maritime mobile service. ITU.Google Scholar
Isenor, A. W., Cross, R., Webb, S. and Lapinski, A.-L. S. (2013). Utilizing wide area Maritime Domain Awareness (MDA) data to cue a remote surveillance system. Proceedings of the SPIE 8899 (Security + Defence 2013), Emerging Technologies in Security and Defence; and Quantum Security II; and Unmanned Sensor Systems X, Desden, Germany.Google Scholar
Lapinski, A.-L. S. (2014). LRIT and AIS: An analysis of October 2010 data (DRDC Atlantic TM 2012-234). Defence Research and Development Canada.Google Scholar
Lapinski, A.-L. S. and Isenor, A. W. (2011). Estimating Reception Coverage Characteristics of AIS. The Journal of Navigation, 64, 609623.Google Scholar
Larsen, J. A., Nielsen, J. D., Mortensen, H. P., Rasmussen, U. W., Laursen, T. and Ledet-Pedersen, J. (2012). Evaluation of AIS reception in Arctic regions from space by using a stratospheric balloon flight. Polar Record, 48, 3947.Google Scholar
Mazzarella, F., Alessandrini, A., Greidanus, H., Alvarez, M., Argentieri, P., Nappo, D. and Ziemba, L. (2013). Data Fusion for Wide-Area Maritime Surveillance. Proceedings of the COST MOVE Workshop on Moving Objects at Sea, Brest, France.Google Scholar
McIntyre, M., Genik, L., Mason, P. and Hammond, T. (2007). Towards an Understanding of Security, Privacy and Safety in Maritime Self-Reporting Systems. Proceedings of the of IFIPTM 2007: Joint iTrust and PST Conferences on Privacy, Trust Management and Security, New Brunswick, Canada.Google Scholar
Re, E., Boissinot, V., Ginesi, A. and Tobehn, C. (2012). A simple high precision method for extrapolating Sat-AIS system performance. Proceedings of the Advanced Satellite Multimedia Systems Conference (ASMS) and 12th Signal Processing for Space Communications Workshop (SPSC), 2012 6th.Google Scholar
United States Government Accountability Office. (2009). Maritime Security; Vessel Tracking Systems Provide Key Information, but the Need for Duplicate Data Should Be Reviewed (GAO-09-337).Google Scholar
Vachon, P. W., Kabatoff, C. and Quinn, R. (2014). Operational ship detection in Canada using RADARSAT. Proceedings of the Geoscience and Remote Sensing Symposium (IGARSS), 2014 IEEE International.CrossRefGoogle Scholar
Vesecky, J. F., Laws, K. E. and Paduan, J. D. (2009). Using HF surface wave radar and the ship Automatic Identification System (AIS) to monitor coastal vessels. Proceedings of the Geoscience and Remote Sensing Symposium, 2009 IEEE International, IGARSS 2009.CrossRefGoogle Scholar