Utilizing the Landsat spectral-temporal domain for improved mapping and monitoring of ecosystem state and dynamics

Just as the carbon dioxide observations that form the Keeling curve revolutionized the study of the global carbon cycle, free and open access to all available Landsat imagery is fundamentally changing how the Landsat record is being used to study ecosystems and ecological dynamics. This dissertation...

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Main Author: Pasquarella, Valerie
Language:en_US
Published: 2016
Subjects:
Online Access:https://hdl.handle.net/2144/19755
id ndltd-bu.edu-oai-open.bu.edu-2144-19755
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spelling ndltd-bu.edu-oai-open.bu.edu-2144-197552019-01-08T15:40:46Z Utilizing the Landsat spectral-temporal domain for improved mapping and monitoring of ecosystem state and dynamics Pasquarella, Valerie Remote sensing Landsat Beaver activity monitoring Ecosystem dynamics Forest type classification Time series Just as the carbon dioxide observations that form the Keeling curve revolutionized the study of the global carbon cycle, free and open access to all available Landsat imagery is fundamentally changing how the Landsat record is being used to study ecosystems and ecological dynamics. This dissertation advances the use of Landsat time series for visualization, classification, and detection of changes in terrestrial ecological processes. More specifically, it includes new examples of how complex ecological patterns manifest in time series of Landsat observations, as well as novel approaches for detecting and quantifying these patterns. Exploration of the complexity of spectral-temporal patterns in the Landsat record reveals both seasonal variability and longer-term trajectories difficult to characterize using conventional bi-temporal or even annual observations. These examples provide empirical evidence of hypothetical ecosystem response functions proposed by Kennedy et al. (2014). Quantifying observed seasonal and phenological differences in the spectral reflectance of Massachusetts’ forest communities by combining existing harmonic curve fitting and phenology detection algorithms produces stable feature sets that consistently out-performed more traditional approaches for detailed forest type classification. This study addresses the current lack of species-level forest data at Landsat resolutions, demonstrating the advantages of spectral-temporal features as classification inputs. Development of a targeted change detection method using transformations of time series data improves spatial and temporal information on the occurrence of flood events in landscapes actively modified by recovering North American beaver (Castor canadensis) populations. These results indicate the utility of the Landsat record for the study of species-habitat relationships, even in complex wetland environments. Overall, this dissertation confirms the value of the Landsat archive as a continuous record of terrestrial ecosystem state and dynamics. Given the global coverage of remote sensing datasets, the time series visualization and analysis approaches presented here can be extended to other areas. These approaches will also be improved by more frequent collection of moderate resolution imagery, as planned by the Landsat and Sentinel-2 programs. In the modern era of global environmental change, use of the Landsat spectral-temporal domain presents new and exciting opportunities for the long-term large-scale study of ecosystem extent, composition, condition, and change. 2016-12-21T18:29:06Z 2016-12-21T18:29:06Z 2016 2016-12-07T02:08:31Z Thesis/Dissertation https://hdl.handle.net/2144/19755 en_US Attribution 4.0 International http://creativecommons.org/licenses/by/4.0/
collection NDLTD
language en_US
sources NDLTD
topic Remote sensing
Landsat
Beaver activity monitoring
Ecosystem dynamics
Forest type classification
Time series
spellingShingle Remote sensing
Landsat
Beaver activity monitoring
Ecosystem dynamics
Forest type classification
Time series
Pasquarella, Valerie
Utilizing the Landsat spectral-temporal domain for improved mapping and monitoring of ecosystem state and dynamics
description Just as the carbon dioxide observations that form the Keeling curve revolutionized the study of the global carbon cycle, free and open access to all available Landsat imagery is fundamentally changing how the Landsat record is being used to study ecosystems and ecological dynamics. This dissertation advances the use of Landsat time series for visualization, classification, and detection of changes in terrestrial ecological processes. More specifically, it includes new examples of how complex ecological patterns manifest in time series of Landsat observations, as well as novel approaches for detecting and quantifying these patterns. Exploration of the complexity of spectral-temporal patterns in the Landsat record reveals both seasonal variability and longer-term trajectories difficult to characterize using conventional bi-temporal or even annual observations. These examples provide empirical evidence of hypothetical ecosystem response functions proposed by Kennedy et al. (2014). Quantifying observed seasonal and phenological differences in the spectral reflectance of Massachusetts’ forest communities by combining existing harmonic curve fitting and phenology detection algorithms produces stable feature sets that consistently out-performed more traditional approaches for detailed forest type classification. This study addresses the current lack of species-level forest data at Landsat resolutions, demonstrating the advantages of spectral-temporal features as classification inputs. Development of a targeted change detection method using transformations of time series data improves spatial and temporal information on the occurrence of flood events in landscapes actively modified by recovering North American beaver (Castor canadensis) populations. These results indicate the utility of the Landsat record for the study of species-habitat relationships, even in complex wetland environments. Overall, this dissertation confirms the value of the Landsat archive as a continuous record of terrestrial ecosystem state and dynamics. Given the global coverage of remote sensing datasets, the time series visualization and analysis approaches presented here can be extended to other areas. These approaches will also be improved by more frequent collection of moderate resolution imagery, as planned by the Landsat and Sentinel-2 programs. In the modern era of global environmental change, use of the Landsat spectral-temporal domain presents new and exciting opportunities for the long-term large-scale study of ecosystem extent, composition, condition, and change.
author Pasquarella, Valerie
author_facet Pasquarella, Valerie
author_sort Pasquarella, Valerie
title Utilizing the Landsat spectral-temporal domain for improved mapping and monitoring of ecosystem state and dynamics
title_short Utilizing the Landsat spectral-temporal domain for improved mapping and monitoring of ecosystem state and dynamics
title_full Utilizing the Landsat spectral-temporal domain for improved mapping and monitoring of ecosystem state and dynamics
title_fullStr Utilizing the Landsat spectral-temporal domain for improved mapping and monitoring of ecosystem state and dynamics
title_full_unstemmed Utilizing the Landsat spectral-temporal domain for improved mapping and monitoring of ecosystem state and dynamics
title_sort utilizing the landsat spectral-temporal domain for improved mapping and monitoring of ecosystem state and dynamics
publishDate 2016
url https://hdl.handle.net/2144/19755
work_keys_str_mv AT pasquarellavalerie utilizingthelandsatspectraltemporaldomainforimprovedmappingandmonitoringofecosystemstateanddynamics
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