Experience of Satellite Trackers’ Application for Watching Glaciers in the Arctic
S. V. Motyzhev1, ✉, A. P. Tolstosheev1, E. G. Lunev1, A. L. Salman2
1 Marine Hydrophysical Institute, Russian Academy of Sciences, Sevastopol, Russian Federation
2 ES-PAS Ltd, Moscow, Russian Federation
✉ e-mail: smotyzhev@mail.ru
Abstract
The engineering and operational features of the satellite trackers iceST/40-Glacier developed in the Marine Hydrophysical Institute, Russian Academy of Sciences, and produced by Marlin-Yug Ltd are considered. The trackers are developed to monitor the glaciers’ movements. The glaciers’ motion characteristics are calculated using the tracker coordinates measured by the satellite GPS receiver and distributed among the users due to the worldwide location and data collection system Argos-2. The satellite tracker construction is simple enough to place it on a glacier. It represents a specially developed measurement algorithm that permits, first, to apply a standard low-cost GPS receiver and, second, to define location with accuracy not exceeding 1.7 m. The measurements required to determine location are done once a week. The tracker lifetime is not less than 24 months. Statistical analysis of the long-term field experiments carried out on the Arctic archipelagos’ glaciers results in drawing a conclusion that, the iceST/40-Glacier satellite trackers, being used as a basis, make creation of reliable, technological and low-cost network for regular monitoring the glaciers’ movements possible and expedient. The information obtained due to such a network permits to increase navigation safety in the Arctic Ocean marginal seas and can be used for verifying remote sensing data.
Keywords
satellite tracker, determination of position, glacier movement, Arctic observations
Acknowledgements
The work was carried out within the framework of the State Order No. 0827-2014-0011 “The research of regularities of marine environment condition changes on the basis of operational observations and the data of marine area condition nowcast, forecast and reanalysis system” (“Operative oceanography” code) with financial support of PAO OC Rosneft.
Original russian text
Original Russian Text © The Authors, 2018, published in MORSKOY GIDROFIZICHESKIY ZHURNAL, Vol. 34, Iss. 2, pp. 165–174 (2018)
For citation
Motyzhev, S.V., Tolstosheev, A.P., Lunev, E.G. and Salman, A.L., 2018. Experience of Satellite Trackers’ Application for Watching Glaciers in the Arctic. Physical Oceanography, 25(2), pp. 153-161. doi:10.22449/1573-160X-2018-2-153-161
DOI
10.22449/1573-160X-2018-2-153-161
References
- Akimov, V.A., Kozlov, K.A. and Kosorukov, O.A., 2014. Sovremennye Problemy Arkticheskoy Zony Rossiyskoy Federatsii [Contemporary Problems of the Russian Federation Arctic Zone]. Moscow: VNII GOCHS, 308 p. (in Russian).
- Govorushko, S.M., 2006. Ledniki i Ikh Znachenie dlya Chelovecheskoy Deyatel'nosti [Glaciers and their Importance for Human Activity]. Vestnik of the Far East Branch of the Russian Academy of Sciences, (6), pp. 60-70 (in Russian).
- Paul, F., Winsvold, S.H., Kääb, A., Nagler, T. and Schwaizer, G., 2016. Glacier Remote Sensing Using Sentinel-2. Part II: Mapping Glacier Extents and Surface Facies, and Comparison to Landsat-8. Remote Sens., [e-journal] 8(7), 575. doi:10.3390/rs8070575
- Pope, A. and Rees, W.G., 2014. Impact of Spatial, Spectral, and Radiometric Properties of Multispectral Imagers on Glacier Surface Classification. Remote Sens. Environ., [e-journal] 141, pp. 1-13. https://doi.org/10.1016/j.rse.2013.08.028
- Kotlyakov, V.M., Khromova, T.E., Nosenko, G.A., Popova, V.V., Chernova, L.P., Muravev, A.Ya., Rototaeva, O.V., Nikitin, S.A. and Zverkova, N.M., 2015. Sovremennye Izmeneniya Lednikov Gornykh Rayonov Rossii [Recent Glacier Changes in Mountain Regions of Russia]. Moscow: KMK Scientific Press Ltd., 287 p. (in Russian).
- Bolch, T., 2011. Assessment of Cryospheric Variations in Different Climatic Regimes and Their Impacts Using Geomatics: Habilitation. Dresden: Technische Universität Dresden, 268 p. Available at:https://www.researchgate.net/publication/272793711_Assessment_of_cryospheric_variations_in_different_climatic_regimes_and_their_impacts_using_geomatics [Accessed 20 September 2017].
- Karelin, A.V. and Nagovitsyna, N.V., 2014. Bazovye Elementy i Metrologicheskie Aspekty Validatsionnykh Rabot [Basic Elements and Metrological Aspects of Validation Works]. Cosmonautics and Rocket Engineering, (5), pp. 101-107 (in Russian).
- Astashkin, A.A., Komissarova, I.N., Markelova, T.S., Nagovitsyna, N.V., Novikova, N.P., Tverdokhlebova, Ye.M. and Ustinova, M.V., 2015. Informatsionnoe Obespechenie Issledovaniya Arkticheskogo Regiona s Ispol'zovaniem Gidrometeorologicheskoy Kosmicheskoy Sistemy «Arktika-M» [Information Maintenance of Research in the Arctic Region Using the «Arktika-M» Hydrometeorological Space System]. Cosmonautics and Rocket Engineering, (6), pp. 11-19 (in Russian).
- King, M., Watson, C., Coleman, R., Sprent, A., Guichard, A. and Williams, G., 2001. A Low Cost GPS System for Ice Movement Studies. 18 p. Available at: https://www.latitude.aq/publications/pdf/low_cost_gps_system_2001.pdf [Accessed 20 September 2017].
- den Ouden, M.A.G., Reijmer, C.H., Pohjola, V., van de Wal, R.S.W., Oerlemans, J. and Boot, W., 2010. Stand-alone single-frequency GPS ice velocity observations on Nordenskiöldbreen, Svalbard. The Cryosphere, [e-journal] 4, pp. 593-604. doi:10.5194/tc-4-593-2010
- Marlin-Yug, 2017. Available at: http://marlin-yug.com/ru/home [Accessed: 20 September 2017].
- Semenov, S.M., ed., 2012. Metody Otsenki Posledstviy Izmeneniya Klimata dlya Fizicheskikh i Biologicheskikh Sistem [Methods for Assessing the Consequences of Climate Change on Physical and Biological Systems]. Moscow: Planeta, pp. 360-399 (in Russian).
- ARGOS, 2017. Available at: http://www.argos-system.org [Accessed 20 September 2017].
- Zandbergen, P.A., 2008. Positional Accuracy of Spatial Data: Non-Normal Distributions and a Critique of the National Standard for Spatial Data Accuracy. Transactions in GIS, [e-journal] 12(1), pp. 103-130. doi:10.1111/j.1467-9671.2008.01088.x