Abstract
Changes to ice cover on lakes throughout the northern landscape has been established as an indicator of climate change and variability, expected to have implications for both human and environmental systems. Monitoring lake ice cover is also required to enable more reliable weather forecasting across lake-rich northern latitudes. Currently, the Canadian Ice Service (CIS) monitors lakes using synthetic aperture radar (SAR) and optical imagery through visual interpretation, with total lake ice cover reported weekly as a fraction out of ten. An automated method of classification would allow for more detailed records to be delivered operationally. In this research, we present an automatic ice-mapping approach which integrates unsupervised segmentation from the Iterative Region Growing using Semantics (IRGS) algorithm with supervised random forest (RF) labeling. IRGS first locally segments homogeneous regions in an image, then merges similar regions into classes across the entire scene. Recently, these output regions were manually labeled by the user to generate ice maps, or were labeled using a Support Vector Machine (SVM) classifier. Here, three labeling methods (Manual, SVM, and RF) are applied after IRGS segmentation to perform ice-water classification on 36 RADARSAT-2 scenes of Great Bear Lake (Canada). SVM and RF classifiers are also tested without integration with IRGS. An accuracy assessment has been performed on the results, comparing outcomes with author-generated reference data, as well as the reported ice fraction from CIS. The IRGS-RF average classification accuracy for this dataset is 95.8%, demonstrating the potential of this automated method to provide detailed and reliable lake ice cover information operationally.
Highlights
Seasonal ice on lakes represents a significant component of the cryosphere and plays a role in many biologic, ecologic and socio-economic processes [1]
Five classification methods were tested on 36 RADARSAT-2 scenes of Great Bear Lake (GBL) and validated against 400 reference pixels per scene
The Iterative Region Growing using Semantics (IRGS)-random forest (RF) approach had the highest agreement with reference data, resulting in an average accuracy of 95.8%
Summary
Seasonal ice on lakes represents a significant component of the cryosphere and plays a role in many biologic, ecologic and socio-economic processes [1]. A movement towards later freeze-up and earlier break-up dates on northern lakes since the middle of the last century is well documented and predicted to continue [2,3,4]. This alteration to the state of lake ice cover is expected to have implications for both human and environmental systems, making it imperative to monitor in the face of climate change [5]. The advancement and launch of many earth observing synthetic aperture radar (SAR) satellite systems allows detailed lake ice monitoring to take place, especially across large and inaccessible expanses. Despite the proven importance of lake ice phenology in the context of climate change, these detailed records have yet to be created operationally
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