A new data fusion model for high spatial- and temporal-resolution mapping of forest disturbance based on Landsat and MODIS
A new data fusion model for high spatial- and temporal-resolution mapping of forest disturbance based on Landsat and MODIS
Investigating the temporal and spatial pattern of landscape disturbances is an important requirement for modeling ecosystem characteristics, including understanding changes in the terrestrial carbon cycle or mapping the quality and abundance of wildlife habitats. Data from the Landsat series of satellites have been successfully applied to map a range of biophysical vegetation parameters at a 30Â m spatial resolution; the Landsat 16Â day revisit cycle, however, which is often extended due to cloud cover, can be a major obstacle for monitoring short term disturbances and changes in vegetation characteristics through time. The development of data fusion techniques has helped to improve the temporal resolution of fine spatial resolution data by blending observations from sensors with differing spatial and temporal characteristics. This study introduces a new data fusion model for producing synthetic imagery and the detection of changes termed Spatial Temporal Adaptive Algorithm for mapping Reflectance Change (STAARCH). The algorithm is designed to detect changes in reflectance, denoting disturbance, using Tasseled Cap transformations of both Landsat TM/ETM and MODIS reflectance data. The algorithm has been tested over a 185Ã?185Â km study area in west-central Alberta, Canada. Results show that STAARCH was able to identify spatial and temporal changes in the landscape with a high level of detail. The spatial accuracy of the disturbed area was 93{\%} when compared to the validation data set, while temporal changes in the landscape were correctly estimated for 87{\%} to 89{\%} of instances for the total disturbed area. The change sequence derived from STAARCH was also used to produce synthetic Landsat images for the study period for each available date of MODIS imagery. Comparison to existing Landsat observations showed that the change sequence derived from STAARCH helped to improve the prediction results when compared to previously published data fusion techniques.
change detection, data blending, disturbance, eosd, landsat, modis, staarch, starfm, synthetic imagery
1613-1627
Hilker, Thomas
c7fb75b8-320d-49df-84ba-96c9ee523d40
Wulder, Michael A.
13414360-db3d-4d88-a76d-ccffd69d0084
Coops, Nicholas C.
5511e778-fec2-4f54-8708-de65ba5a0992
Linke, Julia
af5caa3d-41c3-492c-b1aa-492e53fca194
McDermid, Greg
7d3bf34b-12c5-453a-ab33-4ef6a9d14dd2
Masek, Jeffrey G.
612a1421-99af-49d8-b171-7fe2dd9f8617
Gao, Feng
b70fc7ee-1c00-4b32-aa1a-272e603a3add
White, Joanne C.
d577fc32-2e72-4619-b84f-8efe7ee7f3e0
August 2009
Hilker, Thomas
c7fb75b8-320d-49df-84ba-96c9ee523d40
Wulder, Michael A.
13414360-db3d-4d88-a76d-ccffd69d0084
Coops, Nicholas C.
5511e778-fec2-4f54-8708-de65ba5a0992
Linke, Julia
af5caa3d-41c3-492c-b1aa-492e53fca194
McDermid, Greg
7d3bf34b-12c5-453a-ab33-4ef6a9d14dd2
Masek, Jeffrey G.
612a1421-99af-49d8-b171-7fe2dd9f8617
Gao, Feng
b70fc7ee-1c00-4b32-aa1a-272e603a3add
White, Joanne C.
d577fc32-2e72-4619-b84f-8efe7ee7f3e0
Hilker, Thomas, Wulder, Michael A., Coops, Nicholas C., Linke, Julia, McDermid, Greg, Masek, Jeffrey G., Gao, Feng and White, Joanne C.
(2009)
A new data fusion model for high spatial- and temporal-resolution mapping of forest disturbance based on Landsat and MODIS.
Remote Sensing of Environment, 113 (8), .
(doi:10.1016/j.rse.2009.03.007).
Abstract
Investigating the temporal and spatial pattern of landscape disturbances is an important requirement for modeling ecosystem characteristics, including understanding changes in the terrestrial carbon cycle or mapping the quality and abundance of wildlife habitats. Data from the Landsat series of satellites have been successfully applied to map a range of biophysical vegetation parameters at a 30Â m spatial resolution; the Landsat 16Â day revisit cycle, however, which is often extended due to cloud cover, can be a major obstacle for monitoring short term disturbances and changes in vegetation characteristics through time. The development of data fusion techniques has helped to improve the temporal resolution of fine spatial resolution data by blending observations from sensors with differing spatial and temporal characteristics. This study introduces a new data fusion model for producing synthetic imagery and the detection of changes termed Spatial Temporal Adaptive Algorithm for mapping Reflectance Change (STAARCH). The algorithm is designed to detect changes in reflectance, denoting disturbance, using Tasseled Cap transformations of both Landsat TM/ETM and MODIS reflectance data. The algorithm has been tested over a 185Ã?185Â km study area in west-central Alberta, Canada. Results show that STAARCH was able to identify spatial and temporal changes in the landscape with a high level of detail. The spatial accuracy of the disturbed area was 93{\%} when compared to the validation data set, while temporal changes in the landscape were correctly estimated for 87{\%} to 89{\%} of instances for the total disturbed area. The change sequence derived from STAARCH was also used to produce synthetic Landsat images for the study period for each available date of MODIS imagery. Comparison to existing Landsat observations showed that the change sequence derived from STAARCH helped to improve the prediction results when compared to previously published data fusion techniques.
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More information
Accepted/In Press date: 14 March 2009
e-pub ahead of print date: 14 April 2009
Published date: August 2009
Keywords:
change detection, data blending, disturbance, eosd, landsat, modis, staarch, starfm, synthetic imagery
Organisations:
Earth Surface Dynamics
Identifiers
Local EPrints ID: 384696
URI: http://eprints.soton.ac.uk/id/eprint/384696
ISSN: 0034-4257
PURE UUID: 2d431c06-8684-47ae-af26-e301743f9e7a
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Date deposited: 15 Apr 2016 15:46
Last modified: 14 Mar 2024 22:02
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Contributors
Author:
Thomas Hilker
Author:
Michael A. Wulder
Author:
Nicholas C. Coops
Author:
Julia Linke
Author:
Greg McDermid
Author:
Jeffrey G. Masek
Author:
Feng Gao
Author:
Joanne C. White
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