Hyangsun Han and Hoonyol Lee

Slides:

Advertisements

Similar presentations

A thermodynamic model for estimating sea and lake ice thickness with optical satellite data Student presentation for GGS656 Sanmei Li April 17, 2012.

Advertisements

David Prado Oct Antarctic Sea Ice: John N. Rayner and David A. Howarth 1979.

ADVANCED FIRE INFORMATION SYSTEM AFIS I AFIS is the 1 st satellite based, near real time fire information system developed to fulfill the needs of both.

Multiple Criteria for Evaluating Land Cover Classification Algorithms Summary of a paper by R.S. DeFries and Jonathan Cheung-Wai Chan April, 2000 Remote.

Modeling Digital Remote Sensing Presented by Rob Snyder.

Monitoring the Arctic and Antarctic By: Amanda Kamenitz.

Applications of Remote Sensing: The Cryosphere (Snow & Ice) Menglin Jin, San Jose Stte University Outline  Physical principles  International satellite.

Surface Skin Temperatures Observed from IR and Microwave Satellite Measurements Catherine Prigent, CNRS, LERMA, Observatoire de Paris, France Filipe Aires,

1 High Resolution Daily Sea Surface Temperature Analysis Errors Richard W. Reynolds (NOAA, CICS) Dudley B. Chelton (Oregon State University)

A Multi-Sensor, Multi-Parameter Approach to Studying Sea Ice: A Case-Study with EOS Data Walt Meier 2 March 2005IGOS Cryosphere Theme Workshop.

Cooperative Institute for Meteorological Satellite Studies University of Wisconsin - Madison Steve Ackerman Director, Cooperative Institute for Meteorological.

Analysis of High Resolution Infrared Images of Hurricanes from Polar Satellites as a Proxy for GOES-R INTRODUCTION GOES-R will include the Advanced Baseline.

Interannual and Regional Variability of Southern Ocean Snow on Sea Ice Thorsten Markus and Donald J. Cavalieri Goal: To investigate the regional and interannual.

earthobs.nr.no Land cover classification of cloud- and snow-contaminated multi-temporal high-resolution satellite images Arnt-Børre Salberg and.

Experiments with the microwave emissivity model concerning the brightness temperature observation error & SSM/I evaluation Henning Wilker, MIUB Matthias.

SSM/I Sea Ice Concentrations in the Marginal Ice Zone A Comparison of Four Algorithms with AVHRR Imagery submitted to IEEE Trans. Geosci. and Rem. Sensing.

Comparison of SSM/I Sea Ice Concentration with Kompsat-1 EOC Images of the Arctic and Antarctic Hyangsun Han and Hoonyol Lee Department of Geophysics,

Developing a High Spatial Resolution Aerosol Optical Depth Product Using MODIS Data to Evaluate Aerosol During Large Wildfire Events STI-5701 Jennifer.

Workbook DAAC Product Review Passive Microwave Data Sets Walt Meier.

Development and evaluation of Passive Microwave SWE retrieval equations for mountainous area Naoki Mizukami.

Satellite Imagery and Remote Sensing DeeDee Whitaker SW Guilford High EES & Chemistry

DEVELOPING HIGH RESOLUTION AOD IMAGING COMPATIBLE WITH WEATHER FORECAST MODEL OUTPUTS FOR PM2.5 ESTIMATION Daniel Vidal, Lina Cordero, Dr. Barry Gross.

ESTIMATION OF OCEAN CURRENT VELOCITY IN COASTAL AREA USING RADARSAT-1 SAR IMAGES AND HF-RADAR DATA Moon-Kyung Kang 1, Hoonyol Lee 2, Chan-Su Yang 3, Wang-Jung.

1) Canadian Airborne and Microwave Radiometer and Snow Survey campaigns in Support of International Polar Year. 2) New sea ice algorithm Does not use a.

Andrew Heidinger and Michael Pavolonis

14 ARM Science Team Meeting, Albuquerque, NM, March 21-26, 2004 Canada Centre for Remote Sensing - Centre canadien de télédétection Geomatics Canada Natural.

Assessing the Phenological Suitability of Global Landsat Data Sets for Forest Change Analysis The Global Land Cover Facility What does.

Evaluation of Passive Microwave Rainfall Estimates Using TRMM PR and Ground Measurements as References Xin Lin and Arthur Y. Hou NASA Goddard Space Flight.

The Variability of Sea Ice from Aqua’s AMSR-E Instrument: A Quantitative Comparison of the Team and Bootstrap Algorithms By Lorraine M. Beane Dr. Claire.

Ship-Image map derived from a Terra MODIS image from October 20, 2003 (01:35 UT acquisition time), showing the course of the ARISE cruise (red line) between.

Environmental Remote Sensing GEOG 2021 Lecture 8 Observing platforms & systems and revision.

Statistical Atmospheric Correction of Lake Surface Temperature from Landsat Thermal Images Hyangsun Han and Hoonyol Lee Department of Geophysics, Kangwon.

Satellites Storm “Since the early 1960s, virtually all areas of the atmospheric sciences have been revolutionized by the development and application of.

Evaluation of Passive Microwave Sea Ice Concentration in Arctic Summer and Antarctic Spring by Using KOMPSAT-1 EOC Hoonyol Lee and Hyangsun Han

Validation of Satellite-derived Clear-sky Atmospheric Temperature Inversions in the Arctic Yinghui Liu 1, Jeffrey R. Key 2, Axel Schweiger 3, Jennifer.

Microwave Radiation Characteristics of Glacial Ice Observed by AMSR-E Hyangsun Han and Hoonyol Lee Kangwon National University, KOREA.

Global Ice Coverage Claire L. Parkinson NASA Goddard Space Flight Center Presentation to the Earth Ambassador program, meeting at NASA Goddard Space Flight.

Oct 31, 2008C. Grassotti Comparison of MIRS Sea Ice Concentration and Snow Water Equivalent Retrievals with AMSR-E Daily Products C. Grassotti, C. Kongoli,

SeaWiFS Highlights July 2002 SeaWiFS Celebrates 5th Anniversary with the Fourth Global Reprocessing The SeaWiFS Project has just completed the reprocessing.

Center for Satellite Applications and Research (STAR) Review 09 – 11 March 2010 Marine Environmental Responses to the Saemangeum Reclamation Project in.

GHRSST HL_TAG meeting Copenhagen, March 2010 Validation of L2P products in the Arctic Motivation: Consistent inter-satellite validation of L2p SST observations.

Assessment on Phytoplankton Quantity in Coastal Area by Using Remote Sensing Data RI Songgun Marine Environment Monitoring and Forecasting Division State.

There is also inconsistency in ice area (Figure 1, right), but this occurs during where the chart areas are mostly lower than PM; before and.

Satellite Imagery and Remote Sensing DeeDee Whitaker SW Guilford High EES & Chemistry

In order to accurately estimate polar air/sea fluxes, sea ice drift and then ocean circulation, global ocean models should make use of ice edge, sea ice.

Integrating LiDAR Intensity and Elevation Data for Terrain Characterization in a Forested Area Cheng Wang and Nancy F. Glenn IEEE GEOSCIENCE AND REMOTE.

Fig Wilkins Ice Shelf breakup events of (a) MODIS band 1 image 10 days after the end of the first event; (b) Envisat ASARimage during the second.

Motion of David Glacier in East Antarctica Observed by

Temporal Classification and Change Detection

Weather Cloud Detection

Changes in the Melt Season and the Declining Arctic Sea Ice

Report by Japan Meteorological Agency (JMA)

NSIDC’s Passive Microwave Sensor Transition for Polar Data

Tae Young Kim and Myung jin Choi

Yinghui Liu1, Jeff Key2, and Xuanji Wang1

Precipitation Classification and Analysis from AMSU

ASCAT sensors onboard MetOps : application for sea ice

Junsoo Kim, Hyangsun Han and Hoonyol Lee

Passive Microwave Systems & Products

Release plan of the data sets (year)

Kostas Andreadis and Dennis Lettenmaier

C. Prigent and F. Aires (Estellus + Observatoire de Paris )

VIIRS Cloud Mask Validation Exercises

Evaluating Land-Use Classification Methodology Using Landsat Imagery

ISRS2007, Lamada Plaza Hotel, Jeju, Korea, 31 October - 2 November 2007 Radargrammetry of High-Resolution Synthetic Aperture Radar A Theoretical Study.

The 10-cm SSM/I and AMSR ice thickness algorithm: what is its value?

NASA NSIDC DAAC Metrics

Hoonyol Lee Department of Geophysics Kangwon National University

Igor Appel Alexander Kokhanovsky

Andrew Heidinger JPSS Cloud Team Lead

Presentation transcript:

Comparative Study of Sea Ice Concentration by Using DMSP SSM/I, Aqua AMSR-E and KOMPSAT-1 EOC Hyangsun Han and Hoonyol Lee Department of Geophysics, Kangwon National University, Korea imakdong@kangwon.ac.kr, hoonyol@kangwon.ac.kr Introduction SSM/I and AMSR-E have produced the daily sea ice concentration (SIC) products since 1987 and 2002, respectively. Many studies have focused on calibration and evaluation of sea ice algorithms and reported the disagreement of SICs between SSM/I, AMSR-E, and other sensors especially for thin ice areas. Most of them, however, used low-to mid-resolution satellite images such as SAR, Landsat TM/ETM+, Terra/Aqua MODIS, and NOAA AVHRR. Higher resolution sensors would be more favorable to observe various ice types, snow cover, cracks and leads mixed in a relatively small region, but few studies have used them for polar research due to their high cost, low success rate of obtaining cloud-free images, and low sun elevation. In this paper, we report the evaluation results of SSM/I SIC derived from NASA Team Algorithm (NTA) and AMSR-E SIC from NASA Team2 Algorithm (NT2A) by using 6 m resolution optical images of the Antarctic sea ice obtained by EOC (Electro-Optical Camera) onboard Kompsat-1 (Korea Multi-Purpose SATellite-1). We classified various ice types in EOC images, calculated SIC of each ice types, and compared with SSM/I and AMSR-E SIC. Data and Processing Table I. KOMPSAT-1 EOC images used in this study. Orbit Date Total Scenes Cloud-free Scenes 1 2005/09/25 60 14 2 2005/10/05 61 40 3 2005/10/08 5 4 2005/11/04 63 9 Total 245 68 During September to November 2005, we obtained 676 scenes from 11 orbits along the Antarctic continental edges. Among them, only 68 cloud-free scenes from 4 orbits could be used for further analysis (Table 1, Fig. 1a). Fig. 1(b) shows an example of sea ice by EOC taken on 5 October 2005. It was springtime in the Antarctic when sea ice began to melt slowly after peak expansion of ice regime. Sea ice blocks that were thickened during winter were mostly covered with snow. Leads were filled by refrozen thin ice with little snow ice cover while narrow cracks exposed open water. As we have no in situ ice thickness data, we setup new-sea ice classes such as White ice (W), Grey ice (G), Dark-grey ice (D), and Open water (O), according to grey-level of sea ice in EOC images. For the classification of ice types in EOC images, we applied supervised classification (Fig. 1(c)). EOC SIC of each ice types were compared with the results by SSM/I and AMSR-E SICs. We have extracted SSM/I and AMSR-E SICs of the same observation date and location as Kompsat-1 EOC to compare with. We also calculated the Spatio-Temporal STandard Deviation (ST-STD) of SIC in each pixel using 3×3×3 cubic pixel window that comprises the days before and after, and neighboring pixels to see the temporal stability and spatial homogeneity of the SIC. W D 1, 4 G 2, 3 O (a) (b) (c) Effect of Dark-Grey Ice on Passive Microwave Sensors Fig 1. (a) KOMPSAT-1 EOC orbits overlying SSM/I sea ice concentration image of the Antarctic on 25 Sep. 2005 (7600 km×8300 km). (b) An example of EOC scene of the Antarctic sea ice taken on 5 Oct. 2005 (18 km×18 km). (c) Classification example of EOC ice types into W, G, D, and O (2 km×2 km). (b) Comparison of EOC and PM SICs (a) (b) (c) (d) (e) (f) We have compared various combinations of EOC SIC of W+G+D, W, and W+G with SSM/I (Fig. 2(a)-(c)) and AMSR-E SIC (Fig. 2(d)-(f)). Vertical error bar of each data point indicates the ST-STD of SIC from PM sensors. The black points were the SICs with ST-STD less than 2.5% while white dots otherwise. When we compared SSM/I SIC with EOC (W+G; excluding D) SIC, all statistics indicated the best match among Fig. 2(a)-(c). Therefore, we could conclude that SSM/I SIC responds to W and G, but not to D. For all points, AMSR-E SIC seemed to best correlate with EOC SIC of W+G, excluding D (Fig. 2(f)), the closest to one among Fig. 2(d)-(f). However, some black points were spread in a spurious way distorting the regression model for black points in Fig. 2(f). For the comparison of black points only, all ice types of EOC (W+G+D) SIC was better matched with AMSR-E SIC, as shown in Fig. 2(d). As the statistics obtained with the black data points only was considered more reliable than those with the all point case, it is postulated that AMSR-E SIC responds not only to white ice (W) and grey ice (G) but also to dark-grey ice (D). (a) (b) Fig 3. (a) Comparison of SSM/I and AMSR-E SIC used for the comparisons with EOC SIC. AMSR-E SIC shows higher value than SSM/I SIC by approximately 5% due to the detection of ice type C for the Antarctic sea ice in the NT2A in addition to ice type A and B for the SSM/I NTA. (b) Comparison of the difference of AMSR-E SIC and SSM/I SIC with EOC SICs of dark-grey ice. It is indicating that dark-grey ice is the major source of the difference between AMSR-E SIC and SSM/I SIC. W W O O G D G (a) (b) Fig 2. The relationship between EOC SIC and SSM/I SIC (a-c) and EOC SIC and AMSR-E SIC (d-f) in Antarctic springtime, 2005. Black dots are SICs with standard deviation (vertical error bar) less than 2.5%. Fig 4. Examples of EOC scenes (18 km×18 km) with different ice concentrations. (a) EOC image with large portion of dark-grey ice (W: 51.8%, G: 29.0%, D: 13.0%, O: 6.2%) taken on 25 September 2005 (AMSR-E: 89%, SSM/I: 80%). (b) EOC image with little dark-grey ice (W: 97.4%, G: 1.0%, D: 0.5%, O: 1.1%) taken on 5 October 2005 (AMSR-E: 98%, SSM/I: 96%). It supports the finding in Fig. 3(b) that the dark-grey ice concentration positively correlates with the difference of AMSR-E and SSM/I SICs. Conclusion Comparison of EOC with passive microwave sensors showed that SSM/I SIC calculated by NASA Team Algorithm (NTA) responds not only to W but also to G, but not to D, while AMSR-E SIC calculated by NASA Team2 Algorithm (NT2A) can see D as well. Sea ice types can be defined differently from different observation methods one may have used, and could not be homologous to each other. However, this study suggests that SSM/I SIC responds not only to multi-year ice and first-year ice but also to young ice, while AMSR-E SIC includes new ice as well. It is also suggested that new ice is the major source of difference between SSM/I and AMSR-E SIC, and is analogous to the ice type C defined in AMSR-E NT2A.