Quantification and Analysis of Icebergs in a Tidewater Glacier Fjord Using an Object-Based Approach

• Published in: PloS one Vol. 11; no. 11; p. e0164444
• Main Authors: McNabb, Robert W, Womble, Jamie N, Prakash, Anupma, Gens, Rudiger, Haselwimmer, Christian E
• Format: Journal Article
• Language: English
• Published: United States Public Library of Science 09.11.2016; Public Library of Science (PLoS)
• Subjects: Alaska; Animals; Aquatic habitats; Biology; Birds - physiology; Case studies; Chemical oceanography; Classification; Climate Change; Digital imaging; Earth Sciences; Ecology and Environmental Sciences; Ecosystem; Ecosystem biology; Ecosystems; Engineering and Technology; Environmental protection; Estuaries; Fjords; Floating; Floating ice; Geography; Glacier ice; Glaciers; Habitats; Ice Cover; Icebergs; Image analysis; Image classification; Image processing; Image resolution; Marine; Marine animals; Marine Biology; Marine mammals; Marine organisms; National parks; Oceanography; People and places; Phoca - physiology; Phoca vitulina; Phoca vitulina richardii; Physical oceanography; Remote Sensing Technology - methods; Reproducibility of Results; Research and Analysis Methods; Satellites; Sea ice; Seals; Sediments (Geology); Spatial discrimination; Spatial distribution; Spatial resolution; Tidewater; Unmanned aerial vehicles; Wildlife conservation
• ISSN: 1932-6203; 1932-6203
• DOI: 10.1371/journal.pone.0164444

Tidewater glaciers are glaciers that terminate in, and calve icebergs into, the ocean. In addition to the influence that tidewater glaciers have on physical and chemical oceanography, floating icebergs serve as habitat for marine animals such as harbor seals (Phoca vitulina richardii). The availability and spatial distribution of glacier ice in the fjords is likely a key environmental variable that influences the abundance and distribution of selected marine mammals; however, the amount of ice and the fine-scale characteristics of ice in fjords have not been systematically quantified. Given the predicted changes in glacier habitat, there is a need for the development of methods that could be broadly applied to quantify changes in available ice habitat in tidewater glacier fjords. We present a case study to describe a novel method that uses object-based image analysis (OBIA) to classify floating glacier ice in a tidewater glacier fjord from high-resolution aerial digital imagery. Our objectives were to (i) develop workflows and rule sets to classify high spatial resolution airborne imagery of floating glacier ice; (ii) quantify the amount and fine-scale characteristics of floating glacier ice; (iii) and develop processes for automating the object-based analysis of floating glacier ice for large number of images from a representative survey day during June 2007 in Johns Hopkins Inlet (JHI), a tidewater glacier fjord in Glacier Bay National Park, southeastern Alaska. On 18 June 2007, JHI was comprised of brash ice ([Formula: see text] = 45.2%, SD = 41.5%), water ([Formula: see text] = 52.7%, SD = 42.3%), and icebergs ([Formula: see text] = 2.1%, SD = 1.4%). Average iceberg size per scene was 5.7 m2 (SD = 2.6 m2). We estimate the total area (± uncertainty) of iceberg habitat in the fjord to be 455,400 ± 123,000 m2. The method works well for classifying icebergs across scenes (classification accuracy of 75.6%); the largest classification errors occur in areas with densely-packed ice, low contrast between neighboring ice cover, or dark or sediment-covered ice, where icebergs may be misclassified as brash ice about 20% of the time. OBIA is a powerful image classification tool, and the method we present could be adapted and applied to other ice habitats, such as sea ice, to assess changes in ice characteristics and availability.