1 of 21 Using CReSIS Radar Data to Determine Ice Thickness and Surface Elevation at Pine Island Glacier Team Members: Nyema Barmore Glenn Michael Koch.

Slides:

Advertisements

Similar presentations

Accumulation Layer Picking Using FMCW CReSIS Radar and North-Central Greenland Ice Core Data Renee’ Butler, David Braaten, Sam Buchanan, Kyle Purdon Center.

Advertisements

Using CReSIS airborne RADAR to constrain ice-volume influx across the lateral margins of the Northeast Greenland Ice Stream.

Our Goal: To develop and implement innovative and relevant research collaboration focused on ice sheet, coastal, ocean, and marine research. NSF: Innovation.

Exploring Beneath an Antarctic Ice Shelf with the Autosub3 AUV Stephen McPhail, Maaten Furlong, Miles Pebody, James Perrett, Peter Stevenson, Andy Webb,

Effect of Climate Cycling and Meltwater Plumbing on Ice-Sheet Grounding-Line Migration Byron R. Parizek 1, Richard B. Alley 1, Todd K. Dupont 2, Ryan T.

SEAT Traverse The Satellite Era Accumulation Traverse (SEAT) collected near-surface firn cores and Ultra High Frequency (UHF) Frequency Modulated.

GEO-BOWL All Grades “We play mind games.” This part of a map tells what the map is about. Title.

Do strain rates determine the spatial density of crevasses on the Greenland Ice Sheet? Brandon Scott Saint Augustine’s College Mentor: Kristin Poinar University.

The University of Kansas Department of Electrical Engineering and Computer Science Ice Thickness Measurements Over Antarctica and Overview of PRISM Pannirselvam.

IPY Satellite Data Legacy Vision: Use the full international constellation of remote sensing satellites to acquire spaceborne ‘snapshots’ of processes.

Chapter 2 Mapping our World.

2015 Water Quality Research Team Jamal Stevenson Jeffrey Wood Mentor Ricky Dixon Steffi Walthall Raveen McKenzie.

California Standards 1h, 9d, 1. * Cartography – The science of map making. * A grid of the imaginary parallel and vertical lines are used to locate points.

Analysis Functionality to enhance MATLAB default interpolation schema using mGstat ABSTRACT The Center for Remote Sensing of Ice Sheets (CReSIS) has a.

The Center for Remote Sensing of Ice Sheets (CReSIS) has been compiling Greenland ice sheet thickness data since The airborne program utilizes a.

Essential Questions What are some of the different types of remote sensing? How are satellites and sonar used to map Earth’s surface and its oceans? What.

Team Member 1 (SCHOOL), Team Member 2 (SCHOOL), Team Member 3 (SCHOOL), Team Member 4 (SCHOOL) Mentor: Dr. Blank Blank (School ) This is the place for.

Sub-Glacial Topography and Ice Discharge of the Greenland Ice Sheet Ms. Amber E. Smith – REU Student Mr. Eunmok Lee – GRA Dr. Kees van der Veen – Advisor.

Why does the spoon appear broken?. Refraction 23 September 2015 Objectives Be able to select and apply Snell’s Law. HSW: AF2 – Understanding the applications.

Maps. Maps are Projections The globe is three-dimensional (3-D) –ex. A ball A map is two-dimensional (2-D) – ex. A piece of paper A projection is a way.

Utilizing Data Sets from the CReSIS Data Archives to Visualize Greenland Echograms Information in Google Earth 2012 Research Experience for Undergraduates.

Validation of the Antarctic Snow Accumulation and Ice Discharge Basal Stress Boundary of the Southeastern Region of the Ross Ice Shelf, Antarctica.

This material is based upon work supported by the National Science Foundation under Grant No. ANT Any opinions, findings, and conclusions or recommendations.

The Center for Remote Sensing of Ice Sheets (CReSIS) at OSU.

Earth Science: 7.1A Glaciers. Glaciers  As recently as 15,000 years ago, up to 30 percent of earth’s land was covered by an glacial ice.  Earth was.

Abstract The Center for Remote Sensing of Ice Sheets (CReSIS) has collected hundreds of terabytes of radar depth sounder data over the Greenland and Antarctic.

Figure 12: An image in ArcMap ® of the 2009 Operation IceBridge flights (represented by the colored lines), the ITASE core sites (represented by the black.

CHAPTER NEW CHAPTER Views of Earth Today the BIG idea

Integration with a Web Application to Create Navigational Instructions for Locations on the Campus of Elizabeth City State University.

Utilizing ArcGIS in Education to Map a Glacier and Its Changes Over Time Erica T. Petersen, Cheri Hamilton, Brandon Gillette, Center for Remote Sensing.

Using a MATLAB/Photoshop Interface to Enhance Image Processing in the Interpretation of Radar Imagery The Center for Remote Sensing of Ice Sheets (CReSIS)

Cloud Evolution and the Sea Breeze Front

Using instrumented aircraft to bridge the observational gap between ICESat and ICESat-2.

Globes: models of the earth; accurate Maps: drawings of flat surfaces that show all or parts of the earth.

CReSIS Data Processing and Analysis Jerome E. Mitchell Indiana University - Bloomington.

Wideband Radar Simulator for Evaluation of Direction-of-Arrival Processing Sean M. Holloway Center for the Remote Sensing of Ice Sheets, University of.

Exploring Learning Algorithms for Layer Identification from Polar Radar Imagery Tori Wilborn (Elizabeth City State University), Omar Owens (Winston Salam.

Mapping Earth Chapter 1 Earth Science. Ch1 L.1 Maps How can a map help determine location? Why are there different map projections for representing Earth’s.

A Comparative Analysis of Localized Command Line Execution, Remote Execution through Command Line, and Torque Submissions of MATLAB® Scripts for the Charting.

Ocean Model Development (and relation to ice shelves) IPCC summarized top two impacts of physical climate change as (a) air temperature, and (b) sea level.

Cartography Mapping the World.

Validation of the basal stress boundary utilizing Satellite Imagery along the George VI Ice Shelf, Antarctica.

Team Members: Nyema Barmore (ECSU), Glenn Michael Koch (ECSU) Mentor: Dr. Sridar Anandakrishnan (PSU), Peter Burkett (PSU ) Using CReSIS Radar Data to.

REU Site: Arctic and Antarctic Project (AaA-REU) with Research Experience for Teachers (RET) Component I would also like to create a poster on the IU/ECSU.

The rise of the planet’s temperature has a very negative impact on the subsurface dynamics of Earth’s Polar Regions. Analyzing the polar subsurface is.

Survey to detect long-term variability in Pine Island Bay Coastal Ice using Archived Landsat Imagery Team Members: Ya’Shonti Bridgers Ryan Lawrence Michael.

The Science of Map Making.  Separates the Earth into 2 halves a) Northern Hemisphere b) Southern Hemisphere.

This material is based upon work supported by the National Science Foundation under Grant No. ANT Any opinions, findings, and conclusions or recommendations.

Dr. Linda Hayden, Box 672 Elizabeth City State University Elizabeth City, NC Cyberinfrastructure for Remote Sensing.

Recent decades of climate and cryospheric change on the Antarctic Peninsula David G. Vaughan British Antarctic Survey.

Mental Map Any visual image in our brain to help us get around in our environment.

Using a MATLAB/Photoshop Interface to Enhance Image Processing in the Interpretation of Radar Imagery.

Chapter 2 – Mapping. Globes The Earth is so large that to study it we need a model The Earth is so large that to study it we need a model A globe is a.

Ice Loss Signs of Change. The Cryosphere  Earth has many frozen features including – sea, lake, and river ice; – snow cover; – glaciers, – ice caps;

A Comparison of Passive Microwave Derive Melt Extent to Melt Intensity Estimated from Combined Optical and Thermal Satellite Signatures Over the Greenland.

World Geography The Basics. What is Geography? A science that deals with the description, distribution, and interaction of the diverse physical, biological,

SADE ANITA Monte Carlo(SAM) Test Results Amir Javaid University of Delaware.

SADE ANITA Monte Carlo(SAM) Test Results Amir Javaid University of Delaware.

Cornelius Holmes, Derek Morris Jr.

Latitude, Longitude, and GIS

The Ocean floor.

Layer Thickness and Map Width

Mapping Our World Cartography What is the equator? Latitude

Project Title Watershed Watch 2007 Elizabeth City State University

Geography vocabulary 2 (21-40)

AMPS DMSP WMC CReSIS IREP Program at Univ. of Tasmania - Dan Steinhoff

Watershed Watch 2007 :: Elizabeth City State University

Undergraduate Research Experience with African Nation Component

Presentation transcript:

1 of 21 Using CReSIS Radar Data to Determine Ice Thickness and Surface Elevation at Pine Island Glacier Team Members: Nyema Barmore Glenn Michael Koch Team Mentors: Dr. Sridhar Anandakrishnan Mr. Peter Burkett

Penn State Team Members 2 of 21 Glenn Michael Koch Elizabeth City State University Nyema Barmore Elizabeth City State University

Team Mentors 3 of 21 Dr. Sridhar Anandakrishnan Penn State University Mr. Peter Burkett Penn State University

Overview Abstract Keywords Methodology Conclusion Future Work 4 of 21

Study Area 5 of 21 Pine Island Bay (100° West Longitude - 112° West Longitude)

Abstract The Pine Island Glacier region of Antarctica is an area under intense scrutiny because of its sensitivity to climate change. Pine Island Glacier is located in Western Antarctica and drains a large portion of the West Antarctic Ice Sheet. It has shown to be particularly vulnerable to glacial ablation [1]. The 2012 Research Experience for Undergraduates (REU), Ocean Marine Polar Science (OMPS), Penn State Team analyzed CReSIS radar data to identify the ice- surface and ice-bottom features. From this, both elevation and ice thickness at Pine Island Glacier were determined. The team utilized MATLAB along with an add-on picker program; The Penn State Environment for Seismic Processing (PSESP), developed at Pennsylvania State University. MATLAB is a programming environment that analyzes data as well as many other technical processing applications. With the picker program the team selected specific, maximum-strength radar peaks on individual radar traces and applied a formula to compute the distance traveled by the signal. The difference between the distance traveled from the surface and bottom features was calculated to produce an ice thickness map. The team results will provide data that will aid in modeling of the Pine Island Glacier. 6 of 21

Keywords Glacier Radar Refractive Index Mass Balance Calving Ice-sheet Topography Echogram Picker Program 7 of 21

Methodology Downloaded radar data files Downloaded PSESP 8 of 21

Initiate_Pick_REU.m 9 of 21

10 of 21 Data Panel

11 of 21 Manual Picked Point

12 of 21 Automatic Program Selected

Flight Path With Single Pass Highlighted 13 of 21

14 of 21 Plotted Data Bottom Surface

CReSIS Echogram Snapshot 15 of 21

16 of 21 Plotted Data Bottom Surface Flipped

Ice Thickness Calculation: [(((Bottom horizon – surface horizon) /10)/2)*170m/uS] 17 of 21 Step 1: Take the picker difference value of time between the bottom and surface. Step 2: Divide by 10. This converts it from "samples" to real time (in micro seconds). Step 3: Divide that time by 2. This converts the "two way" travel time (going from the plane to the bottom of the ice and back to plane) into a one way travel time (from the plane to the bottom of the ice). Step 4: Multiply that number by 170 (which converts time to distance because radar waves travel at 170 meters/uS in ice).

Analysis provided numerical elevation data from CReSIS radar data sets that could be plotted and compared to echogram images Some data sets provide difficulty in human analysis Data plots did correlate to echogram snapshot images Data plots provided a reliable source to perform ice thickness calculations 18 of 21 Conclusion

Plotted Bottom and Surface 19 of 21

Future Works Continued Analysis of Data Sets 3D model PSESP program modification –Possible combining optical character recognition with PSESP –Option to plot image with the ice surface at the top and bedrock at the bottom 20 of 21

21 of 21 Questions?