Automatic Detection of the Ice Edge in SAR Imagery Using Curvelet Transform and Active Contour

Liu, Jiange; Scott, K. Andrea; Gawish, Ahmed; Fieguth, Paul

doi:10.3390/rs8060480

Cited by 22 publications

(8 citation statements)

References 40 publications

(45 reference statements)

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“…Many of these studies use 'engineered' or hand-crafted features, which are features designed and selected to carry out a specific task. Examples include, the HH autocorrelation, normalized polarization difference and cross-polarization ratio all of which have been used in ice concentration estimation [3,4], grey level co-occurrence matrix features, Gabor filters and Markov random fields, which have been used to classify imagery into ice type and ice/water [5][6][7][8], and curvelet features used to locate the ice edge [9]. One of the challenges with using a set of engineered features to automatically extract information from SAR imagery is the difficulty of developing a set of robust features that can be applied to different geographic regions and seasons and for different imaging geometries.…”

Section: Introductionmentioning

confidence: 99%

Sea Ice Concentration Estimation during Freeze-Up from SAR Imagery Using a Convolutional Neural Network

2017

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Abstract:In this study, a convolutional neural network (CNN) is used to estimate sea ice concentration using synthetic aperture radar (SAR) scenes acquired during freeze-up in the Gulf of St. Lawrence on the east coast of Canada. The ice concentration estimates from the CNN are compared to those from a neural network (multi-layer perceptron or MLP) that uses hand-crafted features as input and a single layer of hidden nodes. The CNN is found to be less sensitive to pixel level details than the MLP and produces ice concentration that is less noisy and in closer agreement with that from image analysis charts. This is due to the multi-layer (deep) structure of the CNN, which enables abstract image features to be learned. The CNN ice concentration is also compared with ice concentration estimated from passive microwave brightness temperature data using the ARTIST sea ice (ASI) algorithm. The bias and RMS of the difference between the ice concentration from the CNN and that from image analysis charts is reduced as compared to that from either the MLP or ASI algorithm. Additional results demonstrate the impact of varying the input patch size, varying the number of CNN layers, and including the incidence angle as an additional input.

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Section: Introductionmentioning

confidence: 99%

Sea Ice Concentration Estimation during Freeze-Up from SAR Imagery Using a Convolutional Neural Network

2017

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“…TerraSAR-X (VV)/texture~8 3% for three ice classes and OW; estimated using test datasets from 3 scenes Ressel et al, 2015 [52] TerraSAR-X (HH, VV)/co-pol ratio, polarimetric features~9 5% for three ice classes and OW; estimated using test datasets from 3 scenes Ressel et al, 2016 [45] ALOS-2 and S1(HH, HV)/co-and cross-pol ratios, incidence angle, autocorrelation (texture) S1: 87.23% and 89.33%; ALOS-2: 84.17% and 85.2% for three classes compared with manual ice charts and the AMSR2 data; estimated using independent 12 S1 and 13 ALOS-2 scenes respectively Hong and Yang 2018 [95] Numerous attempts have been made to develop an automatic algorithm for ice/ocean discrimination using SAR data [28,31,48,90,96]. Based on the early studies in [80,86], a novel method of automatic detection of the ice edge in dual-polarized RS-2 SAR images was proposed to employ the curvelet transform and active contour method [97]. Comparison of the ice edge with that from manually analyzed SAR images demonstrates the effective detection of the ice edge in SAR images by the proposed method.…”

Section: Sar Data-based Methods For Ice Classificationmentioning

confidence: 99%

Satellite SAR Data-based Sea Ice Classification: An Overview

2019

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A review of the main approaches developed for sea ice classification using satellite imagery is presented. Satellite data are the main and very often only information source for sea ice classification and charting in the remote arctic regions. The main techniques used for ice classification and ice charting in several national ice services are considered. Advantages and disadvantages of various SAR data-based methods for ice classification are analyzed. It is shown that an increase of SAR technical abilities contributes to the enhancement of sea ice classification reliability. The possible further development of satellite data-based methods for ice classification is discussed.

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“…Therefore, the proposed approach might not be optimal for other operational applications such as ice edge detection. Perhaps, other algorithms based on curvelet transform [20] or image classification [9] might be more efficient to accurately locate the ice edge. Also, use of other verification metrics such as one described in [21] might be more suitable for marginal ice zones.…”

Section: Examples Of Ice and Water Retrievalmentioning

confidence: 99%

Improved Retrieval of Ice and Open Water From Sequential RADARSAT-2 Images

Komarov

Buehner

2019

IEEE Trans. Geosci. Remote Sensing

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In this paper, we present a new technique for automated detection of ice and open water from sequential RADARSAT-2 ScanSAR dual-polarization HH-HV images. The technique is based on combining a previously developed approach to ice and water detection applied to single synthetic aperture radar (SAR) images with the ice motion information derived from sequential SAR images. To evaluate the new approach, it was applied to 736 SAR image pairs acquired in 2013. Compared with the previous approach, the new approach produced an increase in the fraction of correctly classified water samples from 57.7% to 72.6% while the fraction of correctly classified ice samples did not change appreciably. The overall accuracy stayed at a high level exceeding 99.8%, when compared against the Canadian Ice Service Image Analysis pure ice and water samples. Verification results for different regions and months showed that the detection accuracy exceeds 99.5% for the most regions and months. The proposed approach can also assign enhanced quality to ice and water retrievals found in the reference image. The results are particularly relevant in light of the upcoming Canadian RADARSAT Constellation Mission which will significantly increase the amount and frequency of SAR observations over the Arctic region.

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Automatic Detection of the Ice Edge in SAR Imagery Using Curvelet Transform and Active Contour

Cited by 22 publications

References 40 publications

Sea Ice Concentration Estimation during Freeze-Up from SAR Imagery Using a Convolutional Neural Network

Sea Ice Concentration Estimation during Freeze-Up from SAR Imagery Using a Convolutional Neural Network

Satellite SAR Data-based Sea Ice Classification: An Overview

Improved Retrieval of Ice and Open Water From Sequential RADARSAT-2 Images

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