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Collaborating Authors
Results
Monitoring Hazardous Sea Ice Features using Satellite Imagery
Zakharov, I. (C-CORE) | Bobby, P. (C-CORE) | Power, D. (C-CORE) | Saunders, K. (C-CORE) | Warren, S. (C-CORE)
Abstract The Canadian Arctic is a highly dynamic environment that has the oldest and thickest sea ice in the world. The ice includes various features hazardous for shipping and offshore operations. The paper describes a technology addressing the problem of satellite based monitoring of hazardous features, which include ice ridges, hummocks and rubble fields. Additional attention was paid to identifying glacier ice (ice islands and icebergs). The technology was demonstrated using images collected over the Canadian Arctic in 2013-2014 and ice features were verified by analyzing high resolution satellite optical images that overlap spatially and temporally with the synthetic aperture radar (SAR) data. Various satellite images and data fusion techniques have been explored for identifying ice features and retrieving their characteristics. Ice parameters being studied include height, size and frequency of ice features.
- Government > Space Agency (0.51)
- Information Technology (0.41)
- Energy > Oil & Gas > Upstream (0.36)
State of the Art in Satellite Surveillance of Icebergs and Sea Ice
Power, D. (C-Core) | Bobby, P. (C-Core) | Howell, C. (C-Core) | Ralph, F. (C-Core) | Randell, C. (C-Core)
Abstract The characterization of the ice environment is a necessary step in the probabilistic design approach of Arctic offshore structures. Without such knowledge, design uncertainty is high with the result being overly conservative designs with higher build costs to deal with the uncertainty associated with sea ice and iceberg loads. In addition to knowledge of the ice environment, the addition of ice management to operations leads to a lower risk of ice impact. When ice management is considered at the design stage, additional design concepts may be considered, which may also lead to lower build costs. A critical component to an effective ice management plan is tactical knowledge of the ice environment. Both tactical and historical knowledge of the ice environment can be achieved cost effectively using satellite monitoring. This paper examines the evolution of satellite SAR-based monitoring of sea ice and icebergs to support Arctic offshore operations, particularly for the oil and gas industry. The presentation will demonstrate, at a high level, how these data might be used by the industry, and how recent advances in satellite mapping technology add value to these services. Background In conducting safe and cost effective operations, ice management and risk mitigation practices are integral to operations. The key and primary element of the ice management plan is the detection and subsequent mapping of ice and iceberg locations, since this provides a fundamental basis for all subsequent ice management decision making such as towing and suspension of operations. Comprehensive explanations of the ice management process and technologies that can be used to facilitate an ice management plan were detailed by Randell et al. (2009). Satellite Synthetic Aperture Radar (SAR) is naturally applicable to map and monitor icebergs and sea ice due to its ability to provide images day or night, through cloud or fog, and various wind conditions. Satellite SAR mapping of ice has been available since the 1970s, although routine SAR monitoring of ice was only made possible in the 1990s with the launch of the European satellite ERS-1 in 1992. This satellite also heralded in an era of large scale data archiving of radar data. In addition to data available through various national ice centres, there is now available an archive of almost 20 years of raw satellite radar data that can be used to create highly detailed historical maps of ice and icebergs to aid in the design process. Many existing and almost all of the new SAR satellites are ‘operational’ in that they provide their data in a near-real-time (NRT) mode, with imagery available via the internet within hours of acquisition. The latest generation of SARs that will be launched within the next few years are specifying imagery delivery times of less than one hour; an investment in a ground station facility can allow data provision in minutes of acquisition. With these capabilities, SAR can be used effectively by the industry to aid in Arctic resource development. The increasing prevalence of SAR, along with lower data costs and more flexible data policies will lead to increased use by the industry into the future.
- North America > Canada (0.68)
- North America > United States > Texas (0.28)
- North America > Canada > Quebec > Arctic Platform (0.98)
- North America > Canada > Nunavut > Arctic Platform (0.98)