Determining Glacier Drift Ages Using Multispectral Remote Sensing Data

Determining the ages of glacier drifts in Antarctica can help paleoclimatologists determine the changes Earth’s climate has gone through and thereby inform models for future climate change prediction. However, many of these drifts are difficult to reach for sample collection necessary to determine t...

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Main Author: Crock, Paula
Format: Text
Language:unknown
Published: UND Scholarly Commons 2017
Subjects:
Ong Valley
Transantarctic Mountains
Antarc*
Antarctica
Online Access:https://commons.und.edu/theses/2106
https://commons.und.edu/cgi/viewcontent.cgi?article=3107&context=theses
id ftunivndakota:oai:commons.und.edu:theses-3107
record_format openpolar
spelling ftunivndakota:oai:commons.und.edu:theses-3107 2023-05-15T13:35:07+02:00 Determining Glacier Drift Ages Using Multispectral Remote Sensing Data Crock, Paula 2017-01-01T08:00:00Z application/pdf https://commons.und.edu/theses/2106 https://commons.und.edu/cgi/viewcontent.cgi?article=3107&context=theses unknown UND Scholarly Commons https://commons.und.edu/theses/2106 https://commons.und.edu/cgi/viewcontent.cgi?article=3107&context=theses Theses and Dissertations text 2017 ftunivndakota 2022-09-14T06:11:22Z Determining the ages of glacier drifts in Antarctica can help paleoclimatologists determine the changes Earth’s climate has gone through and thereby inform models for future climate change prediction. However, many of these drifts are difficult to reach for sample collection necessary to determine their ages. This research attempts to use multispectral remote sensing data to expand the mapping of drift ages from known point measurements regionally. This research is based on existing drift ages from Ong Valley, Transantarctic Mountains. Two methods were used to determine a combination of the image band data that would sufficiently distinguish the three age-distinct drift regions: Principal Component Analysis (PCA) and an empirical analysis based on observed trends in the data. The PCA results showed that virtually all bands contribute equally to the differences in the image data from the three drift regions, precluding the use of a small number of bands in an index to classify the regions. An index was developed from the empirical analysis but this index was unable to sufficiently overcome the count variations in the data sets to successfully classify the regions. Although neither method provided a conclusive means to distinguish the drift regions from the remote sensing data used in this analysis other remote sensing data, e.g. – data at different or more extensive bands ranges, or other analysis techniques, e.g. – more preprocessing of the data or machine learning algorithms applied to the image data, may yet yield successful results. Text Antarc* Antarctica UND Scholarly Commons (University of North Dakota) Ong Valley ENVELOPE(157.617,157.617,-83.233,-83.233) Transantarctic Mountains
institution Open Polar
collection UND Scholarly Commons (University of North Dakota)
op_collection_id ftunivndakota
language unknown
description Determining the ages of glacier drifts in Antarctica can help paleoclimatologists determine the changes Earth’s climate has gone through and thereby inform models for future climate change prediction. However, many of these drifts are difficult to reach for sample collection necessary to determine their ages. This research attempts to use multispectral remote sensing data to expand the mapping of drift ages from known point measurements regionally. This research is based on existing drift ages from Ong Valley, Transantarctic Mountains. Two methods were used to determine a combination of the image band data that would sufficiently distinguish the three age-distinct drift regions: Principal Component Analysis (PCA) and an empirical analysis based on observed trends in the data. The PCA results showed that virtually all bands contribute equally to the differences in the image data from the three drift regions, precluding the use of a small number of bands in an index to classify the regions. An index was developed from the empirical analysis but this index was unable to sufficiently overcome the count variations in the data sets to successfully classify the regions. Although neither method provided a conclusive means to distinguish the drift regions from the remote sensing data used in this analysis other remote sensing data, e.g. – data at different or more extensive bands ranges, or other analysis techniques, e.g. – more preprocessing of the data or machine learning algorithms applied to the image data, may yet yield successful results.
format Text
author Crock, Paula
spellingShingle Crock, Paula
Determining Glacier Drift Ages Using Multispectral Remote Sensing Data
author_facet Crock, Paula
author_sort Crock, Paula
title Determining Glacier Drift Ages Using Multispectral Remote Sensing Data
title_short Determining Glacier Drift Ages Using Multispectral Remote Sensing Data
title_full Determining Glacier Drift Ages Using Multispectral Remote Sensing Data
title_fullStr Determining Glacier Drift Ages Using Multispectral Remote Sensing Data
title_full_unstemmed Determining Glacier Drift Ages Using Multispectral Remote Sensing Data
title_sort determining glacier drift ages using multispectral remote sensing data
publisher UND Scholarly Commons
publishDate 2017
url https://commons.und.edu/theses/2106
https://commons.und.edu/cgi/viewcontent.cgi?article=3107&context=theses
long_lat ENVELOPE(157.617,157.617,-83.233,-83.233)
geographic Ong Valley
Transantarctic Mountains
geographic_facet Ong Valley
Transantarctic Mountains
genre Antarc*
Antarctica
genre_facet Antarc*
Antarctica
op_source Theses and Dissertations
op_relation https://commons.und.edu/theses/2106
https://commons.und.edu/cgi/viewcontent.cgi?article=3107&context=theses
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