GEOG2021 Environmental Remote Sensing Lecture 3 Spectral Information in Remote Sensing

Aim Mechanisms variations in reflectance - optical/microwave Visualisation/analysis Enhancements/transforms

Mechanisms

Reflectance Reflectance = output / input (radiance) measurement of land complicated by atmosphere input solar radiation for passive optical input from spacecraft for active systems RADAR Strictly NOT reflectance - use related term backscatter

Mechanisms

Optical Mechanisms

Reflectance causes of spectral variation in reflectance (bio)chemical & structural properties chlorophyll concentration soil - minerals/ water/ organic matter

Optical Mechanisms vegetation

Optical Mechanisms soil

Optical Mechanisms soil

RADAR Mechanisms See: http://southport.jpl.nasa.gov/education.html

RADAR Mechanisms

RADAR Mechanisms

RADAR Mechanisms

Vegetation amount consider change in canopy cover over time varying proportions of soil / vegetation (canopy cover)

Vegetation amount Bare soil Full cover Senescence

Vegetation amount 1975 Rondonia See: e.g. http://earth.jsc.nasa.gov/lores.cgi?PHOTO=STS046-078-026 http://www.yale.edu/ceo/DataArchive/brazil.html

Vegetation amount 1986 Rondonia

Vegetation amount 1992 Rondonia

Uses of (spectral) information consider properties as continuous e.g. mapping leaf area index or canopy cover or discrete variable e.g. spectrum representative of cover type (classification)

Leaf Area Index See: http://edcdaac.usgs.gov/modis/dataprod.html

See: http://www.bsrsi.msu.edu/rfrc/stats/seasia7385.html Forest cover 1973

Forest cover 1985

visualisation/analysis spectral curves spectral features, e.g., 'red edge’ scatter plot two (/three) channels of information colour composites three channels of information principal components analysis enhancements e.g. NDVI

visualisation/analysis spectral curves reflectance (absorptance) features information on type and concentration of absorbing materials (minerals, pigments) e.g., 'red edge': increase Chlorophyll concentration leads to increase in spectral location of 'feature' e.g., tracking of red edge through model fitting or differentiation

visualisation/analysis

visualisation/analysis

http://envdiag.ceh.ac.uk/iufro_poster2.shtm

point of inflexion on red edge Red Edge Position point of inflexion on red edge REP moves to shorter wavelengths as chlorophyll decreases

Measure REP e.g. by 1st order derivative REP correlates with ‘stress’, but no information on type/cause See also: Dawson, T. P. and Curran, P. J., "A new technique for interpolating the reflectance of red edge position." Int. J. Remote Sensing, 19, (1998), 2133-2139.

Consider red / NIR ‘feature space’ vegetation Soil line

visualisation/analysis Colour Composites choose three channels of information not limited to RGB use standard composites (e.g., FCC) learn interpretation

visualisation/analysis Std FCC - Rondonia visualisation/analysis

visualisation/analysis Std FCC - Swanley TM data - TM 4,3,2 visualisation/analysis

visualisation/analysis Principal Components Analysis PCA (PCT - transform) may have many channels of information wish to display (distinguish) wish to summarise information Typically large amount of (statistical) redundancy in data

visualisation/analysis Principal Components Analysis red NIR See: http://rst.gsfc.nasa.gov/AppC/C1.html

Scatter Plot reveals relationship between information in two bands red NIR Scatter Plot reveals relationship between information in two bands here: correlation coefficient = 0.137

visualisation/analysis Principal Components Analysis show correlation between all bands TM data, Swanley: correlation coefficients : 1.000 0.927 0.874 0.069 0.593 0.426 0.736 0.927 1.000 0.954 0.172 0.691 0.446 0.800 0.874 0.954 1.000 0.137 0.740 0.433 0.812 0.069 0.172 0.137 1.000 0.369 -0.084 0.119 0.593 0.691 0.740 0.369 1.000 0.534 0.891 0.426 0.446 0.433 -0.084 0.534 1.000 0.671 0.736 0.800 0.812 0.119 0.891 0.671 1.000

visualisation/analysis Principal Components Analysis particularly strong between visible bands indicates (statistical) redundancy TM data, Swanley: correlation coefficients : 1.000 0.927 0.874 0.069 0.593 0.426 0.736 0.927 1.000 0.954 0.172 0.691 0.446 0.800 0.874 0.954 1.000 0.137 0.740 0.433 0.812 0.069 0.172 0.137 1.000 0.369 -0.084 0.119 0.593 0.691 0.740 0.369 1.000 0.534 0.891 0.426 0.446 0.433 -0.084 0.534 1.000 0.671 0.736 0.800 0.812 0.119 0.891 0.671 1.000

visualisation/analysis Principal Components Analysis PCT is a linear transformation Essentially rotates axes along orthogonal axes of decreasing variance red NIR PC1 PC2

visualisation/analysis Principal Components Analysis explore dimensionality of data % pc variance : PC1 PC2 PC3 PC4 PC5 PC6 PC7 79.0 11.9 5.2 2.3 1.0 0.5 0.1 96.1% of the total data variance contained within the first 3 PCs

visualisation/analysis Principal Components Analysis e.g. cut-off at 2% variance Swanley TM data 4-dimensional first 4 PCs = 98.4% great deal of redundancy TM bands 1, 2 & 3 correlation coefficients : 1.000 0.927 0.874 0.927 1.000 0.954 0.874 0.954 1.000

visualisation/analysis Principal Components Analysis display PC 1,2,3 - 96.1% of all data variance Dull - histogram equalise ...

visualisation/analysis Principal Components Analysis PC1 (79% of variance) Essentially ‘average brightness’

visualisation/analysis Principal Components Analysis stretched sorted eigenvectors PC1 +0.14 +0.13 +0.28 +0.13 +0.82 +0.12 +0.43 PC2 -0.44 -0.27 -0.60 +2.23 +0.47 -0.49 -0.77 PC3 +1.68 +1.35 +2.45 +1.34 -1.49 -0.67 +0.05 PC4 +0.29 +0.10 -1.22 +1.90 -1.83 +4.49 +2.30 PC5 +0.03 -0.39 -2.81 +0.70 -1.78 -5.12 +6.52 PC6 10.42 +1.10 -6.35 -0.70 +1.64 -0.23 -2.39 PC7 -8.77 28.50 -8.37 -1.43 +1.04 -0.40 -1.75

visualisation/analysis Principal Components Analysis shows contribution of each band to the different PCs. For example, PC1 (the top line) almost equal (positive) contributions (‘mean’) PC1 +0.14 +0.13 +0.28 +0.13 +0.82 +0.12 +0.43 PC 2 principally, the difference between band 4 and rest of the bands (NIR minus rest) PC2 -0.44 -0.27 -0.60 +2.23 +0.47 -0.49 -0.77

visualisation/analysis Principal Components Analysis Display of PC 2,3,4 Here, shows ‘spectral differences’ (rather than ‘brightness’ differences in PC1)

Enhancements Vegetation Indices reexamine red/nir space features

Enhancements Vegetation Indices define function of the two channels to enhance response to vegetation & minimise response to extraneous factors (soil) maintain (linear?) relationship with desrired quantity (e.g., canopy coverage, LAI)

Enhancements Vegetation Indices function known as ‘vegetation index’ Main categories: ratio indices (angular measure) perpendicular indices (parallel lines)

RATIO INDICES Enhancements Vegetation Indices

Enhancements Vegetation Indices Ratio Vegetation Index RVI Normalised Difference Vegetation Index NDVI

RATIO INDICES Enhancements Vegetation Indices NDVI

RATIO INDICES Enhancements Vegetation Indices NDVI

RATIO INDICES NDVI over Africa (AVHRR-derived) Tucker et al. - A: April; B: July; C: Sept; D: Dec 1982

PERPENDICULAR INDICES Enhancements Vegetation Indices

Enhancements Vegetation Indices Perpendicular Vegetation Index PVI Soil Adjusted Vegetation Index SAVI

PERPENDICULAR INDICES And others ...

Summary Scattering/reflectance mechanisms monitoring vegetation amount visualisation/analysis spectral plots, scatter plots, PCA enhancement VIs