ATTRIBUTION AND CHARACTERISATION OF SCLEROPHYLL FORESTED LANDSCAPES OVER LARGE AREAS

This paper presents a methodology for the attribution and characterisation of Sclerophyll forested landscapes over large areas. First we define a set of woody vegetation data primitives (e.g. canopy cover, leaf area index (LAI), bole density, canopy height), which are then scaled-up using multiple r...

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Main Authors: S. Jones, M. Soto-Berelov, L. Suarez, P. Wilkes, W. Woodgate, A. Haywood
Format: Article
Language:English
Published: Copernicus Publications 2016-06-01
Series:The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences
Online Access:https://www.int-arch-photogramm-remote-sens-spatial-inf-sci.net/XLI-B8/673/2016/isprs-archives-XLI-B8-673-2016.pdf
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author S. Jones
S. Jones
M. Soto-Berelov
M. Soto-Berelov
L. Suarez
L. Suarez
P. Wilkes
P. Wilkes
W. Woodgate
W. Woodgate
A. Haywood
A. Haywood
A. Haywood
spellingShingle S. Jones
S. Jones
M. Soto-Berelov
M. Soto-Berelov
L. Suarez
L. Suarez
P. Wilkes
P. Wilkes
W. Woodgate
W. Woodgate
A. Haywood
A. Haywood
A. Haywood
ATTRIBUTION AND CHARACTERISATION OF SCLEROPHYLL FORESTED LANDSCAPES OVER LARGE AREAS
The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences
author_facet S. Jones
S. Jones
M. Soto-Berelov
M. Soto-Berelov
L. Suarez
L. Suarez
P. Wilkes
P. Wilkes
W. Woodgate
W. Woodgate
A. Haywood
A. Haywood
A. Haywood
author_sort S. Jones
title ATTRIBUTION AND CHARACTERISATION OF SCLEROPHYLL FORESTED LANDSCAPES OVER LARGE AREAS
title_short ATTRIBUTION AND CHARACTERISATION OF SCLEROPHYLL FORESTED LANDSCAPES OVER LARGE AREAS
title_full ATTRIBUTION AND CHARACTERISATION OF SCLEROPHYLL FORESTED LANDSCAPES OVER LARGE AREAS
title_fullStr ATTRIBUTION AND CHARACTERISATION OF SCLEROPHYLL FORESTED LANDSCAPES OVER LARGE AREAS
title_full_unstemmed ATTRIBUTION AND CHARACTERISATION OF SCLEROPHYLL FORESTED LANDSCAPES OVER LARGE AREAS
title_sort attribution and characterisation of sclerophyll forested landscapes over large areas
publisher Copernicus Publications
series The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences
issn 1682-1750
2194-9034
publishDate 2016-06-01
description This paper presents a methodology for the attribution and characterisation of Sclerophyll forested landscapes over large areas. First we define a set of woody vegetation data primitives (e.g. canopy cover, leaf area index (LAI), bole density, canopy height), which are then scaled-up using multiple remote sensing data sources to characterise and extract landscape woody vegetation features. The advantage of this approach is that vegetation landscape features can be described from composites of these data primitives. The proposed data primitives act as building blocks for the re-creation of past woody characterisation schemes as well as allowing for re-compilation to support present and future policy and management and decision making needs. <br><br> Three main research sites were attributed; representative of different sclerophyll woody vegetated systems (Box Iron-bark forest; Mountain Ash forest; Mixed Species foothills forest). High resolution hyperspectral and full waveform LiDAR data was acquired over the three research sites. At the same time, land management agencies (Victorian Department of Environment, Land Water and Planning) and researchers (RMIT, CRC for Spatial Information and CSIRO) conducted fieldwork to collect structural and functional measurements of vegetation, using traditional forest mensuration transects and plots, terrestrial lidar scanning and high temporal resolution in-situ autonomous laser (VegNet) scanners. <br><br> Results are presented of: 1) inter-comparisons of LAI estimations made using ground based hemispherical photography, LAI 2200 PCA, CI-110 and terrestrial and airborne laser scanners; 2) canopy height and vertical canopy complexity derived from airborne LiDAR validated using ground observations; and, 3) time-series characterisation of land cover features. <br><br> 1. Accuracy targets for remotely sensed LAI products to match within ground based estimates are ± 0.5 LAI or a 20% maximum (CEOS/GCOS) with new aspirational targets of 5%). In this research we conducted a total of 67 ground-based method-to-method pairwise comparisons across 11 plots in five sites, incorporating the previously mentioned LAI methods. Out of the 67 comparisons, 29 had an RMSE ≥ 0.5 LAIe. This has important implications for the validation of remotely sensed products since ground based techniques themselves exhibit LAI variations greater than internationally recommended guidelines for satellite product accuracies. <br><br> 2. Two methods of canopy height derivation are proposed and tested over a large area (4 Million Ha). 99th percentile maximum height achieved a RMSE of 6.6%, whilst 95th percentile dominant height a RMSE = 10.3%. Vertical canopy complexity (i.e. the number of forest layers of strata) was calculated as the local maxima of vegetation density within the LiDAR canopy profile and determined using a cubic spline smoothing of Pgap. This was then validated against in-situ and LiDAR observations of canopy strata with an RMSE 0.39 canopy layers. <br><br> 3. Preliminary results are presented of landcover characterisation using LandTrendr analysis of Landsat LEDAPS data. kNN is then used to link these features to a dense network of 800 field plots sites.
url https://www.int-arch-photogramm-remote-sens-spatial-inf-sci.net/XLI-B8/673/2016/isprs-archives-XLI-B8-673-2016.pdf
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spelling doaj-84f2b51947f14097bb0cfd25e1f6784d2020-11-25T00:06:34ZengCopernicus PublicationsThe International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences1682-17502194-90342016-06-01XLI-B867367610.5194/isprs-archives-XLI-B8-673-2016ATTRIBUTION AND CHARACTERISATION OF SCLEROPHYLL FORESTED LANDSCAPES OVER LARGE AREASS. Jones0S. Jones1M. Soto-Berelov2M. Soto-Berelov3L. Suarez4L. Suarez5P. Wilkes6P. Wilkes7W. Woodgate8W. Woodgate9A. Haywood10A. Haywood11A. Haywood12Centre for Remote Sensing, School of Mathematical and Geospatial Sciences, RMIT University, Melbourne, AustraliaCoopertive Research Centre for Spatial Information, Carlton, 3053, Victoria, AustraliaCentre for Remote Sensing, School of Mathematical and Geospatial Sciences, RMIT University, Melbourne, AustraliaCoopertive Research Centre for Spatial Information, Carlton, 3053, Victoria, AustraliaCentre for Remote Sensing, School of Mathematical and Geospatial Sciences, RMIT University, Melbourne, AustraliaCoopertive Research Centre for Spatial Information, Carlton, 3053, Victoria, AustraliaCentre for Remote Sensing, School of Mathematical and Geospatial Sciences, RMIT University, Melbourne, AustraliaCoopertive Research Centre for Spatial Information, Carlton, 3053, Victoria, AustraliaCentre for Remote Sensing, School of Mathematical and Geospatial Sciences, RMIT University, Melbourne, AustraliaCoopertive Research Centre for Spatial Information, Carlton, 3053, Victoria, AustraliaDepartment of Environment, Land Water and Planning, East Melbourne, 3002, Victoria, AustraliaCoopertive Research Centre for Spatial Information, Carlton, 3053, Victoria, AustraliaEuropean Forestry Institute, Kuala Lumpur, MalaysiaThis paper presents a methodology for the attribution and characterisation of Sclerophyll forested landscapes over large areas. First we define a set of woody vegetation data primitives (e.g. canopy cover, leaf area index (LAI), bole density, canopy height), which are then scaled-up using multiple remote sensing data sources to characterise and extract landscape woody vegetation features. The advantage of this approach is that vegetation landscape features can be described from composites of these data primitives. The proposed data primitives act as building blocks for the re-creation of past woody characterisation schemes as well as allowing for re-compilation to support present and future policy and management and decision making needs. <br><br> Three main research sites were attributed; representative of different sclerophyll woody vegetated systems (Box Iron-bark forest; Mountain Ash forest; Mixed Species foothills forest). High resolution hyperspectral and full waveform LiDAR data was acquired over the three research sites. At the same time, land management agencies (Victorian Department of Environment, Land Water and Planning) and researchers (RMIT, CRC for Spatial Information and CSIRO) conducted fieldwork to collect structural and functional measurements of vegetation, using traditional forest mensuration transects and plots, terrestrial lidar scanning and high temporal resolution in-situ autonomous laser (VegNet) scanners. <br><br> Results are presented of: 1) inter-comparisons of LAI estimations made using ground based hemispherical photography, LAI 2200 PCA, CI-110 and terrestrial and airborne laser scanners; 2) canopy height and vertical canopy complexity derived from airborne LiDAR validated using ground observations; and, 3) time-series characterisation of land cover features. <br><br> 1. Accuracy targets for remotely sensed LAI products to match within ground based estimates are ± 0.5 LAI or a 20% maximum (CEOS/GCOS) with new aspirational targets of 5%). In this research we conducted a total of 67 ground-based method-to-method pairwise comparisons across 11 plots in five sites, incorporating the previously mentioned LAI methods. Out of the 67 comparisons, 29 had an RMSE ≥ 0.5 LAIe. This has important implications for the validation of remotely sensed products since ground based techniques themselves exhibit LAI variations greater than internationally recommended guidelines for satellite product accuracies. <br><br> 2. Two methods of canopy height derivation are proposed and tested over a large area (4 Million Ha). 99th percentile maximum height achieved a RMSE of 6.6%, whilst 95th percentile dominant height a RMSE = 10.3%. Vertical canopy complexity (i.e. the number of forest layers of strata) was calculated as the local maxima of vegetation density within the LiDAR canopy profile and determined using a cubic spline smoothing of Pgap. This was then validated against in-situ and LiDAR observations of canopy strata with an RMSE 0.39 canopy layers. <br><br> 3. Preliminary results are presented of landcover characterisation using LandTrendr analysis of Landsat LEDAPS data. kNN is then used to link these features to a dense network of 800 field plots sites.https://www.int-arch-photogramm-remote-sens-spatial-inf-sci.net/XLI-B8/673/2016/isprs-archives-XLI-B8-673-2016.pdf