Use of satellite data for detecting icebergs and evaluating the iceberg threats

Te methods of satellite monitoring of dangerous ice formations, namely icebergs in the Arctic seas, representing a threat to the safety of navigation and economic activity on the Arctic shelf are considered. Te main objective of the research is to develop methods for detecting icebergs using satellite radar data and high space resolution images in the visible spectral range. Te developed method of iceberg detection is based on statistical criteria for fnding gradient zones in the analysis of two-dimensional felds of satellite images. Te algorithms of the iceberg detection, the procedure of the false target identifcation, and determination the horizontal dimensions of the icebergs and their location are described. Examples of iceberg detection using satellite information with high space resolution obtained from Sentinel-1 and Landsat-8 satellites are given. To assess the iceberg threat, we propose to use a model of their drif, one of the input parameters of which is the size of the detected objects. Tree possible situations of observation of icebergs are identifed, namely, the «status» state of objects: icebergs on open water; icebergs in drifing ice; and icebergs in the fast ice. At the same time, in each of these situations, the iceberg can be grounded, that prevents its moving. Specifc features of the iceberg monitoring at various «status» states of them are considered. Te «status» state of the iceberg is also taken into account when assessing the degree of danger of the detected object. Te use of iceberg detection techniques based on satellite radar data and visible range images is illustrated by results of monitoring the coastal areas of the Severnaya Zemlya archipelago. Te approaches proposed to detect icebergs from satellite data allow improving the quality and efciency of service for a wide number of users with ensuring the efciency and safety of Arctic navigation and activities on the Arctic shelf.

1. Sputnikovye metody opredeleniya kharakteristik ledyanogo pokrova morey. Satellite methods for determination of sea ice cover characteristics. Ed by V. G. Smirnov. St. Petersburg: AARI Edition, 2011: 239 p. [In Russian].

2. Mironov E.U., Smirnov V.G., Bychkova I.A., Kulakov M.Yu., Demchev D. M. New technologies for detecting icebergs and predicting their drift in the Western sector of the Arctic. Problemy Arktiki i Antarktiki. Problems of Arctic and Antarctic. 2015, 104 (2): 21–32.[In Russian].

3. Smirnov V.G. Satellite monitoring of dangerous ice features in the regions of the offshore oil and gas fields exploration and production. Problemy Arktiki i Antarktiki. Problems of Arctic and Antarctic. 2012, 1: 103–120. [In Russian].

4. https://www .wmo .int/pages/prog/sat/meetings/documents/PSTG-4_Doc_08-04_GlobSatObsReqFloatingIce.pdf. Falkingham J.C. Global satellite observation requirements for floating ice. Focusing on Synthetic Aperture Radar. Contract report for Environment Canada, March 2014: 71 p.

5. Power D., Youden J., Lane K., Randell C., Flett D. Iceberg Detection Capabilities of RADARSAT Synthetic Aperture Radar. Canadian Journ. of Remote Sensing. 2001, 27 (5): 476–486.

6. Howell C., Bobby P., Power D., Randell C., Parsons L. Detecting Icebergs in Sea Ice Using Dual Polarized Satellite Radar Imagery. ICETECH 12. Paper No. ICETECH12-171-RF. 4 p.

7. Hannevik T.N.A. Literature review on ship and ice discrimination / Norwegian Defence Research Establishment (FFI . FFI Rapport 17/16310. 14 November 2017: 35 p.

8. Ressel R., Frost A., Lehner S. Navigation assistance for ice-infested waters through automatic iceberg detection and ice classification based on TerraSAR-X imagery. The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences. 2015. V. XL-7/W3, 36th International Symposium on Remote Sensing of Environment, 11–15 May 2015, Berlin, Germany. P. 1049–1056.

9. Akbari V., Brekke C. Iceberg Detection in Open and IceInfested Waters Using C-Band Polarimetric Synthetic Aperture Radar. IEEE Transactions on Geoscience and Remote Sensing Society. 2018, 56 (1): 407–421.

10. Smirnov V.G., Bychkova I.A., Kulakov M.Yu . Development of experimental hardware and software complex for monitoring icebergs and prediction of their drift in the zone of the Spitsbergen archipelago and in the Western Arctic region of the Russian Federation. Rossiyskie Polyarnye issledovaniya. Russian Polar Research. 2016, 4 (26): 34–35. [In Russian].

11. Obnaruzhenie po sputnikovym dannym opasnykh ledyanykh obrazovaniy vblizi inzhenernykh ob’ektov khozyaystvennoy deyatelnosti na shelfe arkticheskikh morey. Detection of dangerous ice features near the Arctic shelf engineering constructions with the use of satellite imagery: A methodical manual. Ed by V. G. Smirnov. St. Petersburg: AARI Edition, 2017: 76 p. [In Russian].

12. Smith M., Goodchild M., Longley P.Geospatial Analysis. A Comprehensive Guide to Principle, Techniques and Software Tools. 5 ed. 2015: 748 p.

13. Dibner V.D. On the origin of floating ice islands. Priroda. Nature. 1955, 5: 89–92. [In Russian].

14. Koryakin V.S. What happens to the glaciers of Severnaya Zemlya. Priroda. Nature. 2014, 11: 42–49. [In Russian].

15. Willis M., Melkonian A.K., Pritchard M.E. Outlet glacier response to the 2012 collapse of the Matusevich Ice Shelf, Severnaya Zemlya, Russian Arctic. Journ. of Geophys. Research. Earth Surface. 2015, 120 (10): 2040–2055. doi: 10.1002/2015JF003544.

16. Sharov A., Nikolskiy D., Troshko K., Zaprudnova Z. Interferometric control for mapping and quantifying the 2012 breakup of Matusevich Ice Shelf, Severnaya Zemlya. Proc. of the Intern. Workshop «FRINGE 2015». ESA-ESPRIN, 23–27 Mars 2015. Frascati, Italy. ESA SP731, 9 p. doi: 13140/RG.2.1.2444.9121.

17. Zinger E.M., Koryakin V.S. On modern glaciation of Severnaya Zemlya. Izvestiya Vsesouznogo geographicheskogo obshchestva. Proc. of the All-Union Geographical Society. 1964, 6: 471–479. [In Russian].

18. Bolshiyanov D.Yu., Sokolov V.T., Yozhikov I.S., Bulatov R.K., Rachkova A.N., Fedorov G.B., Paramzin A.S. Conditions of the alimentation and the variability of glaciers of the Severnaya Zemlya Archipelago from observations of 2014–2015. Led I Sneg. Ice and Snow. 2016, 56 (3): 358–368.[In Russian]. doi: 10.15356/2076-6734-2016-3-358-368.