IKONOS: Difference between revisions
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= | = Overview = | ||
IKONOS is a commercial earth observation satellite. Details about the sensor are provided at Digital Globe's [http://www.digitalglobe.com/sites/default/files/DG_IKONOS_DS.pdf IKONOS Data Sheet]. [http://en.wikipedia.org/wiki/Ikonos Wikipedia's article on IKONOS] provides a nice overview as well. | |||
IKONOS is a commercial earth observation satellite. Details about the sensor are provided at Digital Globe's [http://www.digitalglobe.com/sites/default/files/DG_IKONOS_DS.pdf IKONOS Data Sheet] | |||
== Availability (Sample Data) == | == Availability (Sample Data) == | ||
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* ISPRS provides a small [http://www.isprs.org/data/ikonos/ IKONOS data set], fragments from a Panchromatic image as well as from a Stereo product. | * ISPRS provides a small [http://www.isprs.org/data/ikonos/ IKONOS data set], fragments from a Panchromatic image as well as from a Stereo product. | ||
== Pre-Processing Overview == | |||
== Modules overview == | |||
=== Outside of GRASS === | |||
Satellite imagery can be managed and, at some extent, pre-processed with various [http://www.gdal.org/gdal_utilities.html GDAL utilities]. | |||
* [http://www.gdal.org/gdalmanage.html gdalmanage] | |||
* [http://www.gdal.org/gdalinfo.html gdalinfo] | |||
* [http://www.gdal.org/gdal_translate.html gdal_translate] | |||
* [http://www.gdal.org/gdalbuildvrt.html gdalbuildvrt] | |||
* [http://www.gdal.org/gdalwarp.html gdalwarp] | |||
=== Inside GRASS GIS === | |||
GRASS GIS features a complete set of modules and various add-ons enabling pre- and post-processing of IKONOS satellite imagery. The following lists offer an overview of related modules and add-ons. | |||
* {{cmd|r.in.gdal}} | |||
* {{cmd|r.mapcalc}} | |||
* {{cmd|r.colors}} | |||
* {{cmd|i.colors.enhance}} | |||
* {{AddonSrc|imagery|i.fusion.hpf|version=7}} | |||
* {{cmd|i.pansharpen}} | |||
* [https://github.com/NikosAlexandris/i.ikonos.toar i.ikonos.toar] | |||
* {{cmd|i.vi}} | |||
* {{cmd|i.segment}} | |||
== Pre-Processing == | |||
=== Overview === | |||
Typically, multispectral satellite data are converted into physical quantities such as ''Radiance'' or ''Reflectance'' before they are subjected in multispectral analysis techniques (image interpretation, band arithmetic, vegetation indices, matrix transformations, etc.). The latter can be differentiated in ''Top of Atmosphere Reflectance'' (ToAR) which does not account for atmospheric effects (absorption or scattering) and in ''Top of Canopy Reflectance'' (ToCR) which introduces a "correction" for atmospheric effects. | Typically, multispectral satellite data are converted into physical quantities such as ''Radiance'' or ''Reflectance'' before they are subjected in multispectral analysis techniques (image interpretation, band arithmetic, vegetation indices, matrix transformations, etc.). The latter can be differentiated in ''Top of Atmosphere Reflectance'' (ToAR) which does not account for atmospheric effects (absorption or scattering) and in ''Top of Canopy Reflectance'' (ToCR) which introduces a "correction" for atmospheric effects. | ||
In order to derive Reflectance values, likewise as with remotely sensed data acquired by other sensors, IKONOS raw image digital numbers (DNs) need to be converted to ''at-sensor spectral Radiance'' values. At-sensor spectral Radiance values are an important input for the equation to derive Reflectance values. Note, ''Spectal Radiance'' is the measure of the quantity of radiation that hits the sensor and typically expressed in <math>W * sr | In order to derive Reflectance values, likewise as with remotely sensed data acquired by other sensors, IKONOS raw image digital numbers (DNs) need to be converted to ''at-sensor spectral Radiance'' values. At-sensor spectral Radiance values are an important input for the equation to derive Reflectance values. Note, ''Spectal Radiance'' is the measure of the quantity of radiation that hits the sensor and typically expressed in <math>\frac{W}{m^2*sr*nm}</math>, that is ''watts'' per ''unit source area'', per ''unit solid angle'', and per ''unit wavelength''. | ||
Converting DNs to at-sensor Radiance can be done by using the following equation: | <ul> | ||
* Converting DNs to at-sensor Radiance can be done by using the following equation: | |||
<math>L\lambda = \frac{10^4 * DN\lambda}{CalCoef\lambda * Bandwidth\lambda}</math> | <math>L\lambda = \frac{10^4 * DN\lambda}{CalCoef\lambda * Bandwidth\lambda}</math> | ||
Converting to Top of Atmosphere Reflectance, also referred to as Planetary Reflectance, can be done by using the following equation: | * Converting to Top of Atmosphere Reflectance, also referred to as Planetary Reflectance, can be done by using the following equation: | ||
<math>\rho_p = \frac{\pi * L\lambda * d^2}{ESUN\lambda * cos(\Theta_S)}</math> | |||
where: | <br />where: | ||
<ul> | |||
* <math>\rho</math> - Unitless Planetary Reflectance | * <math>\rho</math> - Unitless Planetary Reflectance | ||
* <math>\pi</math> - mathematical constant (3.14159265358) | * <math>\pi</math> - mathematical constant (3.14159265358) | ||
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* <math>d</math> - Earth-Sun distance in astronomical units, interpolated values | * <math>d</math> - Earth-Sun distance in astronomical units, interpolated values | ||
* <math>Esun</math> - Mean solar exoatmospheric irradiance(s) (W/m2/μm), interpolated values | * <math>Esun</math> - Mean solar exoatmospheric irradiance(s) (W/m2/μm), interpolated values | ||
* <math>cos( | * <math>cos(\theta_s)</math> - {{wikipedia||Solar_zenith_angle}} from the image acquisition's metadata | ||
</ul> | |||
</ul> | |||
== | |||
=== Importing data === | |||
==== File Formats & Metadata ==== | |||
''ToAdd'' | ''ToAdd'' | ||
== | ==== Importing ==== | ||
In the following example the publicly available IKONOS acqisition [ftp://ftp.glcf.umd.edu/glcf/China_earthquake_May_2008/IKONOS/po_58204_0000000.20001116.China-Sichuan/ po_58204_0000000.20001116.China-Sichuan] is used. | |||
''ToAdd'' | ''ToAdd'' | ||
<ul> | |||
* Location creation based on georeferenced data | |||
</ul> | |||
Once inside a Location that is defined by the spatial reference system in which the bands of interest are projected, they can be imported with the {{cmd|r.in.gdal}} module. | |||
For example, GeoTIFF files can be imported by looping {{cmd|r.in.gdal}} over all of them | |||
<source lang="bash"> | |||
for TIF in `echo *.tif`; do r.in.gdal in=${TIF} out=${TIF%%.*}; done | |||
</source> | |||
To keep the raw material untouched, we create another Mapset inside the same Location and copy over the bands giving, ''optionally'' at the same time, a new name for each. | |||
<source lang="bash"> | |||
g.mapset -c pre-processing | |||
g.copy rast=po_58204_blu_0000000,Blue_DNs | |||
g.copy rast=po_58204_grn_0000000,Green_DNs | |||
g.copy rast=po_58204_red_0000000,Red_DNs | |||
g.copy rast=po_58204_nir_0000000,NIR_DNs | |||
g.copy rast=po_58204_pan_0000000,Pan_DNs | |||
</source> | |||
=== Deriving Physical Quantities === | |||
Conversions are implemented in a GRASS module available at https://github.com/NikosAlexandris/i.ikonos.toar. | |||
'' | ''Details'' | ||
Converting Digital Numbers to Radiance/Reflectance requires knowledge about the sensor's specific spectral band parameters. Those are, as extracted from the document ''IKONOS Planetary Reflectance and Mean Solar Exoatmospheric Irradiance'', by Martin Taylor (see references): | |||
<source lang=bash> | |||
Pan_CalCoef=161 ; Pan_Width=403 ; Pan_Esun=1375.8 | |||
Blue_CalCoef=728 ; Blue_Width=71.3 ; Blue_Esun=1930.9 | |||
Green_CalCoef=720 ; Green_Width=88.6 ; Green_Esun=1854.8 | |||
Red_CalCoef=949 ; Red_Width=65.8 ; Red_Esun=1556.5 | |||
NIR_CalCoef=843 ; NIR_Width=95.4 ; NIR_Esun=1156.9 | |||
</source> | |||
The following examples exemplify the conversion of raw Blue band digital numbers into Radiance and Reflectance. | |||
=== | ==== Spectral Radiance ==== | ||
Converting a Blue Band (Digital Numbers) in to Spectral at-sensor Radiance in the ''correct'' units to be further used for the conversion in to unitless Reflectance: | Converting a Blue Band (Digital Numbers) in to Spectral at-sensor Radiance in the ''correct'' units to be further used for the conversion in to unitless Reflectance: | ||
<source lang="bash"> | |||
# set the region | |||
g.region rast=Blue_DNs -p | |||
# convert DNs to spectral Radiance values | |||
r.mapcalc "Blue_Radiance = ( (10000 * IKONOS_Blue_DNs) / (728 * 71.3) )" | |||
</source> | |||
==== Planetary Reflectance ==== | |||
The equation to derive Reflectance values incorporates in addition: | |||
<ul> | |||
* The mathematical constant {{wikipedia|Pi}} <source lang="bash" enclose=none>PI=3.14159265358</source>. | |||
* The Earth-Sun distance in astronomical units which depends on the acquisition's day of year (DOY -- also referred to as Julian day, {{wikipedia|Ordinal_date}}) and can be retrieved from the following spreadsheet <http://landsathandbook.gsfc.nasa.gov/excel_docs/d.xls>. | |||
* The mean solar exoatmospheric irradiance in <math>\frac{W}{m^2*\mu m}</math>. See 3rd column of (interplated) values given above. | |||
* The cosine of the ''Solar Zenith Angle'' (SZA) at the time of the acquisition. The SZA can be calculated from its complementary ''Solar Elevation Angle'' (SEA) given in the image acquisition's metadata. | |||
</ul> | |||
In the following example we accept as the acquisition's <source lang="bash" enclose=none>DOY=166</source> and <source lang="bash" enclose=none>SEA=52.78880</source>. Hence, we get the Earth-Sun distance <source lang="bash" enclose=none>ESD=1.0157675</source> and <source lang="bash" enclose=none>SZA = 37.21120 deg</source>. | |||
Converting the in-Blue spectral band at-sensor Radiance in to Planerary Reflectance: | Converting the in-Blue spectral band at-sensor Radiance in to Planerary Reflectance: | ||
{{cmd|r.mapcalc}} <source lang="bash" enclose=none>"Blue_Reflectance = ( ${PI} * Blue_Radiance * ${ESD}^2 ) / ( ${ | <source lang="bash" enclose=none>PI=3.14159265358; ESD=1.0157675; BAND_Esun=1930.9; SZA=37.21120</source> | ||
{{cmd|r.mapcalc}} <source lang="bash" enclose=none>"Blue_Reflectance = ( ${PI} * Blue_Radiance * ${ESD}^2 ) / ( ${BAND_Esun} * cos(${SZA}) )"</source> | |||
==== Automatising Conversions ==== | |||
The conversion process can be scripted to avoid repeating the same steps for each band separately. | |||
===== Python ===== | |||
A custom python script, performing the operations of interest, might be like [https://github.com/NikosAlexandris/i.ikonos.toar i.ikonos.toar (for GRASS 7.x)] | |||
===== Bash ===== | |||
In bash, such a script might be as the following example. '''Note,''' however, in this example script constants, band parameters and acquisition related metadata are hard-coded! | |||
<source lang="bash"> | |||
#!/bin/bash | |||
Pan_CalCoef=161 ; Pan_Width=403 ; Pan_Esun=1375.8 | |||
Blue_CalCoef=728 ; Blue_Width=71.3 ; Blue_Esun=1930.9 | |||
Green_CalCoef=720 ; Green_Width=88.6 ; Green_Esun=1854.8 | |||
Red_CalCoef=949 ; Red_Width=65.8 ; Red_Esun=1556.5 | |||
NIR_CalCoef=843 ; NIR_Width=95.4 ; NIR_Esun=1156.9 | |||
# set constants, band parameters and acquisition related metadata here! | |||
# Pi, first 11 decimals | |||
PI=3.14159265358 | |||
# Acquisition's Day of Year and estimated Earth-Sun Distance | |||
DOY=166; ESD=1.0157675 | |||
# Sun Zenith Angle based on the acquisition's Sun Elevation Angle | |||
SEA=52.78880; SZA=$(echo "90 - ${SEA}" | bc ) | |||
# bands to process | |||
Spectral_Bands="Pan Blue Green Red NIR" | |||
'' | # loop over all bands | ||
for BAND in ${Spectral_Bands}; do | |||
echo "Processing the ${BAND} spectral band" | |||
# set region | |||
g.region rast=${BAND}_DNs | |||
# set band parameters as variables | |||
eval BAND_CalCoef="${BAND}_CalCoef" | |||
eval BAND_Width="${BAND}_Width"; | |||
echo "Band Parameters set to CalCoef=${!BAND_CalCoef}, Bandwidth=${!BAND_Width}" | |||
# conversion to Radiance | |||
r.mapcalc "${BAND}_Radiance = ( ( 10^4 * ${BAND}_DNs ) / ( ${!BAND_CalCoef} * ${!BAND_Width} ) )" | |||
# add info | |||
r.support map=${BAND}_Radiance \ | |||
title="" \ | |||
units="W / m2 / μm / ster" \ | |||
description="At-sensor `echo ${BAND}` band spectral Radiance (W/m2/μm/sr)" \ | |||
source1='"IKONOS Planetary Reflectance and Mean Solar Exoatmospheric Irradiance", by Martin Taylor, Geoeye' | |||
# set Earth-Sun distance | |||
eval BAND_Esun="${BAND}_Esun"; echo "Using Esun=${!BAND_Esun}" | |||
# calculate ToAR | |||
r.mapcalc "${BAND}_ToAR = \ | |||
( ${PI} * ${BAND}_Radiance * ${ESD}^2 ) / ( ${!BAND_Esun} * cos(${SZA}) )" | |||
# add some metadata | |||
r.support map=${BAND}_ToAR \ | |||
title="echo ${BAND} band (Top of Atmosphere Reflectance)" \ | |||
units="Unitless" \ | |||
description="Top of Atmosphere `echo ${BAND}` band spectral Reflectance (unitless)" \ | |||
source1='"IKONOS Planetary Reflectance and Mean Solar Exoatmospheric Irradiance", by Martin Taylor, Geoeye' \ | |||
source2="e.g., the Image Provider!" \ | |||
history="PI=3.14159265358; ESD=1.0157675; BAND_Esun=1930.9; SZA=37.21120" | |||
done | |||
</source> | |||
=== Atmospheric correction === | === Atmospheric correction === | ||
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See [[Atmospheric correction]] | See [[Atmospheric correction]] | ||
=== Color composites === | == Post-Processing == | ||
Having beforehand satellite image data expressed in physical quantities (radiance or reflectance) is preferred to follow-up with digital image analysis techniques. A few common post-processing practices are Contrast-Enhancement, Pan-Sharpening and creating Pseudo- or True-Color Composites. Other well known enhancing manipualtions to support the analyses of satellite imagery, include deriving Vegetation Indices, transforming multi-spectral data based on [[Principal_Components_Analysis | PCA]] and Segmenting images. | |||
=== Contrast Enhancement === | |||
''ToAdd'' | |||
=== Pan-Sharpening === | |||
[http://en.wikipedia.org/wiki/Pansharpened_image Pan-Sharpening] / [http://en.wikipedia.org/wiki/Image_fusion Fusion] is the process of merging high-resolution panchromatic and lower resolution multi-spectral imagery. [http://grass.osgeo.org/grass70/ GRASS 7] holds a dedicated pan-sharpening module, {{cmd|i.pansharpen}} which features three techniques for sharpening, namely the [http://wiki.awf.forst.uni-goettingen.de/wiki/index.php/Brovey_Transformation Brovey transformation], the classical IHS method and one that is based on [[Principal Components Analysis]] (PCA). Another algorithm deriving excellent detail and a realistic representation of original multispectral scene colors, is the High-Pass Filter Addition (HPFA) technique. It is available through the add-on {{AddonSrc|imagery|i.fusion.hpf|version=7}} (for GRASS 6, please refer to a bash shell script https://github.com/NikosAlexandris/i.fusion.hpf.sh which is, however, unmaintained). | |||
One approach inside GRASS-GIS to get an acceptable color-balanced composite image after Pan-sharpening 11-bit IKONOS spectral bands comprises the following steps | |||
<ul> | |||
# rescale the 11-bit IKONOS spectral bands to 8-bit ranging in [0, 255] ({{cmd|r.rescale}}) | |||
# pan-sharpen with any of the featured methods (Brovey, IHS, PCA) ({{cmd|i.pansharpen}}) | |||
# color-balance by using the {{cmd|i.landsat.rgb}} module or manually adjusting the color tables of the bands of interest | |||
# create a composite image by using the {{cmd|r.compose}} module | |||
</ul> | |||
==== Example Instructions for {{cmd|i.pansharpen}} ==== | |||
{{cmd|i.pansharpen}} works fine with 8-bit raster maps as an input. If the data to be processed are out of this range, that is out of <math>[0, 255]</math>, they can be rescaled to fit into this range by using GRASS' {{cmd|r.rescale}} module. | |||
Given an IKONOS set of 11-bit spectral bands (Blue, Green, Red, NIR and Pan) ranging between <math>[0, 2047]</math>, and then querying for example the Blue band | |||
<source lang="bash" enclose=none>r.info Blue_DNs -r</source>, would return | |||
<source lang="bash"> | |||
min=0 | |||
max=2047 | |||
</source> | |||
===== Rescaling single bands ===== | |||
Rescaling the Blue band to range between `[0, 255]` | |||
<source lang="bash"> | |||
r.rescale in=Blue_DNs out=Blue_DNs_255 from=0,2047 to=0,255 | |||
</source> | |||
The same step applies to both the rest of the multi-spectral bands and the Panchromatic band of interest. If working under Bash, To repeat the same command (given, it was the last on used in the GRASS' terminal), one can isntruct | |||
<source lang="bash"> | |||
!!:gs/Blue/Green | |||
</source> | |||
This would substitute everywhere found on the last command the string "Blue" with the string "Green" and re-execute it. The same can be done for the rest of the bands, namely Red, NIR and Pan. Some attention is required to instruct substitution of the ''last'' used string. | |||
===== Rescaling all bands at once ===== | |||
Of course, one can always use a ''for'' loop | |||
<source lang="bash"> | |||
for DN in `g.mlist rast pat=*DNs`; do r.rescale in=${DN} out=${DN}_255 from=0,2047 to=0,255; done | |||
</source> | |||
===== Pan-Sharpening ===== | |||
As usual when working with GRASS, it is required to set the region of interest, i.e. <source lang="bash" enclose=none>g.region rast=Blue_DNs_255</source> to match the extent of the band(s) or else. The resolution itself is taken care in this particular case by the module and the resulting pan-sharpened raster maps will of the same high(er) resolution as the Panchromatic band. | |||
An example command for an IHS-based Pan-Sharpening action might look like | |||
<source lang="bash"> | |||
i.pansharpen pan=Pan_DNs_255 ms1=Blue_DNs_255 ms2=Green_DNs_255 ms3=Red_DNs_255 output=sharptest255 sharpen=ihs | |||
</source> | |||
===== Color Re-Balancnig ===== | |||
After the process completion, the module outputs | |||
<source lang="bash"> | |||
... | |||
The following pan-sharpened output maps have been generated: | |||
sharptest255_red | |||
sharptest255_green | |||
sharptest255_blue | |||
To visualize output, run: g.region -p rast=sharptest255.red | |||
d.rgb r=sharptest255_red g=sharptest255_green b=sharptest255_blue | |||
If desired, combine channels into a single RGB map with 'r.composite'. | |||
</source> | |||
Normally it should be enough to re-balance the colors after the pan-sharpening action by using for example the {{cmd|i.landsat.rgb}} module or manual adjustment of each of the three bands that would compose an RGB image. | |||
<source lang="bash"> | |||
i.landsat.rgb r=sharptest255_red g=sharptest255_green b=sharptest255_blue -p | |||
</source> | |||
===== Automatising Sharpening & RGB Composition ===== | |||
An ''experimental'' bash script to automatise the sharpening/fusion and RGB composition process is demonstrated here. The script uses the Spectral Reflectance values (double precision values), gained from previous steps (see above), and produces Pan-sharpened images by applying all of the three methods that {{addon|i.pansharpen}} offers. In addition, it attempts to produce True-Color composite images, without and with re-balancing the color tables by using the {{cmd|i.landsat.rgb}} module. | |||
Initial tests indicate that at least one of the three sharpening methods, combined with re-balancing, produces very clear and balanced True-Color composites. Note, there is no 100% confidence that it will produce nice looking True-Color composites. Some of the methods might simply work, others might deliver fancy-colored images. As usual, some manual action might be required to get the re-balancing to work as best as possible. | |||
The script can be expanded in terms of using more inputs by utilising bash's positional parameters. However, care has to be taken to alter the instruction that concerns the conversion from double precision values to 8-bit integers. | |||
<source lang="bash"> | |||
#!/bash/sh | |||
# use in G7 only :-) | |||
echo "Rescaling all images to 8-bit" | |||
# convert to 8-bit first :-! | |||
for Method_Input in \ | |||
"Pan ToAR" \ | |||
"Blue ToAR" \ | |||
"Green ToAR" \ | |||
"Red ToAR" \ | |||
"NIR ToAR" | |||
do | |||
# parse "${Method_STR}" and set positional parameters | |||
set -- $Method_Input ; echo -e "\n" #echo $1 $2 | |||
# input BAND is... | |||
eval BAND="${1}_${2}" | |||
# set region | |||
g.region rast=${BAND} | |||
# integerise | |||
r.mapcalc --v \ | |||
"${BAND}_integerised = round( 1000000 * ${BAND} )" # how many decimals? | |||
# integerised BAND is... | |||
eval BAND="${1}_${2}_integerised" | |||
# get ${min} and ${max} | |||
eval `r.info -r ${BAND}` | |||
# | |||
r.rescale in=${1}_${2}_integerised out=${1}_${2}_255 from=${min},${max} to=0,255 | |||
done ######################################################################## | |||
echo "Rescaling done!" | |||
# pan-sharpen High Resolution imagery --------------------------------------- | |||
# needs setting some naming conventions | |||
for Method_Input in \ | |||
"ihs ToAR" \ | |||
"brovey ToAR" \ | |||
"pca ToAR" | |||
do | |||
# parse "${Method_STR}" and set positional parameters | |||
set -- $Method_Input ; echo $1 $2 | |||
# some echo | |||
echo "Pan-Sharpening the <${2}> images based on the <${1}> method" | |||
i.pansharpen \ | |||
sharpen=${1} \ | |||
pan=Pan_${2}_255 \ | |||
ms1=Blue_${2}_255 \ | |||
ms2=Green_${2}_255 \ | |||
ms3=Red_${2}_255 \ | |||
output=sharp_${1}_${2}_255 | |||
done ######################################################################## | |||
# compose BGRs -------------------------------------------------------------- | |||
# loop over Methods and Input Types, compose RGBs | |||
for Method_Input in \ | |||
"ihs ToAR" \ | |||
"brovey ToAR" \ | |||
"pca ToAR" | |||
do | |||
# parse "${Method_STR}" and set positional parameters | |||
set -- $Method_Input ; echo $1 $2 | |||
# region | |||
g.region rast=sharp_"${1}"_"${2}"_255_blue | |||
# compose | |||
r.composite --o \ | |||
r=sharp_"${1}"_"${2}"_255_red \ | |||
g=sharp_"${1}"_"${2}"_255_green \ | |||
b=sharp_"${1}"_"${2}"_255_blue \ | |||
out=rgb_sharpened_"${1}"_"${2}"_255 | |||
done ####################################################################### | |||
# re-balance & re-compose colors -------------------------------------------- | |||
for Method_Input in \ | |||
"ihs ToAR" \ | |||
"brovey ToAR" \ | |||
"pca ToAR" | |||
do | |||
# parse "${Method_STR}" and set positional parameters | |||
set -- $Method_Input ; echo $1 $2 | |||
# re-balance | |||
i.landsat.rgb -p \ | |||
r=sharp_"${1}"_"${2}"_255_red \ | |||
g=sharp_"${1}"_"${2}"_255_green \ | |||
b=sharp_"${1}"_"${2}"_255_blue | |||
# region -- Really necessary, again? | |||
g.region rast=sharp_"${1}"_"${2}"_255_blue | |||
# re-compose | |||
r.composite --o \ | |||
r=sharp_"${1}"_"${2}"_255_red \ | |||
g=sharp_"${1}"_"${2}"_255_green \ | |||
b=sharp_"${1}"_"${2}"_255_blue \ | |||
out=rgb_sharpened_"${1}"_"${2}"_255_rebalanced | |||
done ######################################################################## | |||
</source> | |||
==== Pan-Sharpening based on the HPFA technique ==== | |||
The technique, implemented via the GRASS add-on {{AddonSrc|imagery|i.fusion.hpf|version=7}}, as indicated above, involves a convolution using a High Pass Filter (HPF) on the high resolution data, then combining this with the lower resolution multispectral data. | |||
''Source: "Optimizing the High-Pass Filter Addition Technique for Image Fusion", Ute G. Gangkofner, Pushkar S. Pradhan, and Derrold W. Holcomb (2008)'' | |||
The algorithm's steps are: | |||
# Computing the ratio of the low (Multi-Spectral) to the high (Panchromatic) resolution | |||
# High Pass Filtering the Panchromatic Image | |||
# Resampling the Multi-Spectral image to the higher resolution | |||
# Adding a weighted High-Pass-Filtered image to the upsampled Multi-Spectral image | |||
# Optionally, matching the histogram of the Pan-Sharpened image to the one of the original Multi-Spectral image | |||
=== Color Composites === | |||
''ToAdd'' | ''ToAdd'' | ||
=== | == Vegetation Indices == | ||
''ToAdd'' | |||
== PCA == | |||
''ToAdd'' | ''ToAdd'' | ||
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== References / Sources == | == References / Sources == | ||
* http://www.apollomapping.com/wp-content/user_uploads/2011/09/IKONOS_Esun_Calculations.pdf | * [http://www.apollomapping.com/wp-content/user_uploads/2011/09/IKONOS_Esun_Calculations.pdf IKONOS Planetary Reflectance and Me an Solar Exoatmospheric Irradiance, by Martin Taylor] | ||
* http://web.unicen.edu.ar/crecic/docs/radrefl.pdf | * [http://web.unicen.edu.ar/crecic/docs/radrefl.pdf Ikonos DN Value Conversion to Planetary Reflectance Values, by David Fleming] | ||
* [http://landsathandbook.gsfc.nasa.gov/data_prod/prog_sect11_3.html Landsat7 Science Data Users Handbook, Chapter 11, Section 3] | |||
* [http://igett.delmar.edu/Resources/Remote%20Sensing%20Technology%20Training/Calculation-DN_to_Reflectance_Irish_20June08.pdf Calibrated Landsat Digital Number (DN) to Top of Atmosphere (TOA) Reflectance Conversion, by Richard Irish] | |||
* from [http://landsat.usgs.gov/tools_access_all_faqs.php FAQs about the Landsat Missions] | |||
** [http://landsat.usgs.gov/how_is_radiance_calculated.php How is radiance calculated?] | |||
** [http://landsat.usgs.gov/at_sensor_reflectance_calculated.php How is at-sensor reflectance calculated?] | |||
== See also == | == See also == | ||
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[[Category: FAQ]] | [[Category: FAQ]] | ||
[[Category: IKONOS]] | [[Category: IKONOS]] | ||
[[Category: | [[Category: High Resolution]] | ||
[[Category: Import]] | [[Category: Import]] | ||
[[Category: Digital Numbers]] | [[Category: Digital Numbers]] | ||
[[Category: Radiance]] | [[Category: Radiance]] | ||
[[Category: Reflectance]] | [[Category: Reflectance]] | ||
[[Category: Image processing]] |
Latest revision as of 10:05, 4 December 2018
Overview
IKONOS is a commercial earth observation satellite. Details about the sensor are provided at Digital Globe's IKONOS Data Sheet. Wikipedia's article on IKONOS provides a nice overview as well.
Availability (Sample Data)
- Search for commercial satellite image providers in the internet.
- The Global Land Cover Facility (GLCF) provides four openly available IKONOS scenes of western Sichuan.
- ISPRS provides a small IKONOS data set, fragments from a Panchromatic image as well as from a Stereo product.
Modules overview
Outside of GRASS
Satellite imagery can be managed and, at some extent, pre-processed with various GDAL utilities.
Inside GRASS GIS
GRASS GIS features a complete set of modules and various add-ons enabling pre- and post-processing of IKONOS satellite imagery. The following lists offer an overview of related modules and add-ons.
- r.in.gdal
- r.mapcalc
- r.colors
- i.colors.enhance
- i.fusion.hpf (src)
- i.pansharpen
- i.ikonos.toar
- i.vi
- i.segment
Pre-Processing
Overview
Typically, multispectral satellite data are converted into physical quantities such as Radiance or Reflectance before they are subjected in multispectral analysis techniques (image interpretation, band arithmetic, vegetation indices, matrix transformations, etc.). The latter can be differentiated in Top of Atmosphere Reflectance (ToAR) which does not account for atmospheric effects (absorption or scattering) and in Top of Canopy Reflectance (ToCR) which introduces a "correction" for atmospheric effects.
In order to derive Reflectance values, likewise as with remotely sensed data acquired by other sensors, IKONOS raw image digital numbers (DNs) need to be converted to at-sensor spectral Radiance values. At-sensor spectral Radiance values are an important input for the equation to derive Reflectance values. Note, Spectal Radiance is the measure of the quantity of radiation that hits the sensor and typically expressed in , that is watts per unit source area, per unit solid angle, and per unit wavelength.
- Converting DNs to at-sensor Radiance can be done by using the following equation:
- Converting to Top of Atmosphere Reflectance, also referred to as Planetary Reflectance, can be done by using the following equation:
- - Unitless Planetary Reflectance
- - mathematical constant (3.14159265358)
- spectral Radiance at the sensor's aperture, from equation... ToADD
- - Earth-Sun distance in astronomical units, interpolated values
- - Mean solar exoatmospheric irradiance(s) (W/m2/μm), interpolated values
- - Solar_zenith_angle from the image acquisition's metadata
where:
Importing data
File Formats & Metadata
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Importing
In the following example the publicly available IKONOS acqisition po_58204_0000000.20001116.China-Sichuan is used.
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- Location creation based on georeferenced data
Once inside a Location that is defined by the spatial reference system in which the bands of interest are projected, they can be imported with the r.in.gdal module.
For example, GeoTIFF files can be imported by looping r.in.gdal over all of them
for TIF in `echo *.tif`; do r.in.gdal in=${TIF} out=${TIF%%.*}; done
To keep the raw material untouched, we create another Mapset inside the same Location and copy over the bands giving, optionally at the same time, a new name for each.
g.mapset -c pre-processing
g.copy rast=po_58204_blu_0000000,Blue_DNs
g.copy rast=po_58204_grn_0000000,Green_DNs
g.copy rast=po_58204_red_0000000,Red_DNs
g.copy rast=po_58204_nir_0000000,NIR_DNs
g.copy rast=po_58204_pan_0000000,Pan_DNs
Deriving Physical Quantities
Conversions are implemented in a GRASS module available at https://github.com/NikosAlexandris/i.ikonos.toar.
Details
Converting Digital Numbers to Radiance/Reflectance requires knowledge about the sensor's specific spectral band parameters. Those are, as extracted from the document IKONOS Planetary Reflectance and Mean Solar Exoatmospheric Irradiance, by Martin Taylor (see references):
Pan_CalCoef=161 ; Pan_Width=403 ; Pan_Esun=1375.8
Blue_CalCoef=728 ; Blue_Width=71.3 ; Blue_Esun=1930.9
Green_CalCoef=720 ; Green_Width=88.6 ; Green_Esun=1854.8
Red_CalCoef=949 ; Red_Width=65.8 ; Red_Esun=1556.5
NIR_CalCoef=843 ; NIR_Width=95.4 ; NIR_Esun=1156.9
The following examples exemplify the conversion of raw Blue band digital numbers into Radiance and Reflectance.
Spectral Radiance
Converting a Blue Band (Digital Numbers) in to Spectral at-sensor Radiance in the correct units to be further used for the conversion in to unitless Reflectance:
# set the region
g.region rast=Blue_DNs -p
# convert DNs to spectral Radiance values
r.mapcalc "Blue_Radiance = ( (10000 * IKONOS_Blue_DNs) / (728 * 71.3) )"
Planetary Reflectance
The equation to derive Reflectance values incorporates in addition:
- The mathematical constant Pi
PI=3.14159265358
. - The Earth-Sun distance in astronomical units which depends on the acquisition's day of year (DOY -- also referred to as Julian day, Ordinal_date) and can be retrieved from the following spreadsheet <http://landsathandbook.gsfc.nasa.gov/excel_docs/d.xls>.
- The mean solar exoatmospheric irradiance in . See 3rd column of (interplated) values given above.
- The cosine of the Solar Zenith Angle (SZA) at the time of the acquisition. The SZA can be calculated from its complementary Solar Elevation Angle (SEA) given in the image acquisition's metadata.
In the following example we accept as the acquisition's DOY=166
and SEA=52.78880
. Hence, we get the Earth-Sun distance ESD=1.0157675
and SZA = 37.21120 deg
.
Converting the in-Blue spectral band at-sensor Radiance in to Planerary Reflectance:
PI=3.14159265358; ESD=1.0157675; BAND_Esun=1930.9; SZA=37.21120
r.mapcalc"Blue_Reflectance = ( ${PI} * Blue_Radiance * ${ESD}^2 ) / ( ${BAND_Esun} * cos(${SZA}) )"
Automatising Conversions
The conversion process can be scripted to avoid repeating the same steps for each band separately.
Python
A custom python script, performing the operations of interest, might be like i.ikonos.toar (for GRASS 7.x)
Bash
In bash, such a script might be as the following example. Note, however, in this example script constants, band parameters and acquisition related metadata are hard-coded!
#!/bin/bash
Pan_CalCoef=161 ; Pan_Width=403 ; Pan_Esun=1375.8
Blue_CalCoef=728 ; Blue_Width=71.3 ; Blue_Esun=1930.9
Green_CalCoef=720 ; Green_Width=88.6 ; Green_Esun=1854.8
Red_CalCoef=949 ; Red_Width=65.8 ; Red_Esun=1556.5
NIR_CalCoef=843 ; NIR_Width=95.4 ; NIR_Esun=1156.9
# set constants, band parameters and acquisition related metadata here!
# Pi, first 11 decimals
PI=3.14159265358
# Acquisition's Day of Year and estimated Earth-Sun Distance
DOY=166; ESD=1.0157675
# Sun Zenith Angle based on the acquisition's Sun Elevation Angle
SEA=52.78880; SZA=$(echo "90 - ${SEA}" | bc )
# bands to process
Spectral_Bands="Pan Blue Green Red NIR"
# loop over all bands
for BAND in ${Spectral_Bands}; do
echo "Processing the ${BAND} spectral band"
# set region
g.region rast=${BAND}_DNs
# set band parameters as variables
eval BAND_CalCoef="${BAND}_CalCoef"
eval BAND_Width="${BAND}_Width";
echo "Band Parameters set to CalCoef=${!BAND_CalCoef}, Bandwidth=${!BAND_Width}"
# conversion to Radiance
r.mapcalc "${BAND}_Radiance = ( ( 10^4 * ${BAND}_DNs ) / ( ${!BAND_CalCoef} * ${!BAND_Width} ) )"
# add info
r.support map=${BAND}_Radiance \
title="" \
units="W / m2 / μm / ster" \
description="At-sensor `echo ${BAND}` band spectral Radiance (W/m2/μm/sr)" \
source1='"IKONOS Planetary Reflectance and Mean Solar Exoatmospheric Irradiance", by Martin Taylor, Geoeye'
# set Earth-Sun distance
eval BAND_Esun="${BAND}_Esun"; echo "Using Esun=${!BAND_Esun}"
# calculate ToAR
r.mapcalc "${BAND}_ToAR = \
( ${PI} * ${BAND}_Radiance * ${ESD}^2 ) / ( ${!BAND_Esun} * cos(${SZA}) )"
# add some metadata
r.support map=${BAND}_ToAR \
title="echo ${BAND} band (Top of Atmosphere Reflectance)" \
units="Unitless" \
description="Top of Atmosphere `echo ${BAND}` band spectral Reflectance (unitless)" \
source1='"IKONOS Planetary Reflectance and Mean Solar Exoatmospheric Irradiance", by Martin Taylor, Geoeye' \
source2="e.g., the Image Provider!" \
history="PI=3.14159265358; ESD=1.0157675; BAND_Esun=1930.9; SZA=37.21120"
done
Atmospheric correction
Post-Processing
Having beforehand satellite image data expressed in physical quantities (radiance or reflectance) is preferred to follow-up with digital image analysis techniques. A few common post-processing practices are Contrast-Enhancement, Pan-Sharpening and creating Pseudo- or True-Color Composites. Other well known enhancing manipualtions to support the analyses of satellite imagery, include deriving Vegetation Indices, transforming multi-spectral data based on PCA and Segmenting images.
Contrast Enhancement
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Pan-Sharpening
Pan-Sharpening / Fusion is the process of merging high-resolution panchromatic and lower resolution multi-spectral imagery. GRASS 7 holds a dedicated pan-sharpening module, i.pansharpen which features three techniques for sharpening, namely the Brovey transformation, the classical IHS method and one that is based on Principal Components Analysis (PCA). Another algorithm deriving excellent detail and a realistic representation of original multispectral scene colors, is the High-Pass Filter Addition (HPFA) technique. It is available through the add-on i.fusion.hpf (src) (for GRASS 6, please refer to a bash shell script https://github.com/NikosAlexandris/i.fusion.hpf.sh which is, however, unmaintained).
One approach inside GRASS-GIS to get an acceptable color-balanced composite image after Pan-sharpening 11-bit IKONOS spectral bands comprises the following steps
- rescale the 11-bit IKONOS spectral bands to 8-bit ranging in [0, 255] (r.rescale)
- pan-sharpen with any of the featured methods (Brovey, IHS, PCA) (i.pansharpen)
- color-balance by using the i.landsat.rgb module or manually adjusting the color tables of the bands of interest
- create a composite image by using the r.compose module
Example Instructions for i.pansharpen
i.pansharpen works fine with 8-bit raster maps as an input. If the data to be processed are out of this range, that is out of , they can be rescaled to fit into this range by using GRASS' r.rescale module.
Given an IKONOS set of 11-bit spectral bands (Blue, Green, Red, NIR and Pan) ranging between , and then querying for example the Blue band
r.info Blue_DNs -r
, would return
min=0
max=2047
Rescaling single bands
Rescaling the Blue band to range between `[0, 255]`
r.rescale in=Blue_DNs out=Blue_DNs_255 from=0,2047 to=0,255
The same step applies to both the rest of the multi-spectral bands and the Panchromatic band of interest. If working under Bash, To repeat the same command (given, it was the last on used in the GRASS' terminal), one can isntruct
!!:gs/Blue/Green
This would substitute everywhere found on the last command the string "Blue" with the string "Green" and re-execute it. The same can be done for the rest of the bands, namely Red, NIR and Pan. Some attention is required to instruct substitution of the last used string.
Rescaling all bands at once
Of course, one can always use a for loop
for DN in `g.mlist rast pat=*DNs`; do r.rescale in=${DN} out=${DN}_255 from=0,2047 to=0,255; done
Pan-Sharpening
As usual when working with GRASS, it is required to set the region of interest, i.e. g.region rast=Blue_DNs_255
to match the extent of the band(s) or else. The resolution itself is taken care in this particular case by the module and the resulting pan-sharpened raster maps will of the same high(er) resolution as the Panchromatic band.
An example command for an IHS-based Pan-Sharpening action might look like
i.pansharpen pan=Pan_DNs_255 ms1=Blue_DNs_255 ms2=Green_DNs_255 ms3=Red_DNs_255 output=sharptest255 sharpen=ihs
Color Re-Balancnig
After the process completion, the module outputs
...
The following pan-sharpened output maps have been generated:
sharptest255_red
sharptest255_green
sharptest255_blue
To visualize output, run: g.region -p rast=sharptest255.red
d.rgb r=sharptest255_red g=sharptest255_green b=sharptest255_blue
If desired, combine channels into a single RGB map with 'r.composite'.
Normally it should be enough to re-balance the colors after the pan-sharpening action by using for example the i.landsat.rgb module or manual adjustment of each of the three bands that would compose an RGB image.
i.landsat.rgb r=sharptest255_red g=sharptest255_green b=sharptest255_blue -p
Automatising Sharpening & RGB Composition
An experimental bash script to automatise the sharpening/fusion and RGB composition process is demonstrated here. The script uses the Spectral Reflectance values (double precision values), gained from previous steps (see above), and produces Pan-sharpened images by applying all of the three methods that Template:Addon offers. In addition, it attempts to produce True-Color composite images, without and with re-balancing the color tables by using the i.landsat.rgb module.
Initial tests indicate that at least one of the three sharpening methods, combined with re-balancing, produces very clear and balanced True-Color composites. Note, there is no 100% confidence that it will produce nice looking True-Color composites. Some of the methods might simply work, others might deliver fancy-colored images. As usual, some manual action might be required to get the re-balancing to work as best as possible.
The script can be expanded in terms of using more inputs by utilising bash's positional parameters. However, care has to be taken to alter the instruction that concerns the conversion from double precision values to 8-bit integers.
#!/bash/sh
# use in G7 only :-)
echo "Rescaling all images to 8-bit"
# convert to 8-bit first :-!
for Method_Input in \
"Pan ToAR" \
"Blue ToAR" \
"Green ToAR" \
"Red ToAR" \
"NIR ToAR"
do
# parse "${Method_STR}" and set positional parameters
set -- $Method_Input ; echo -e "\n" #echo $1 $2
# input BAND is...
eval BAND="${1}_${2}"
# set region
g.region rast=${BAND}
# integerise
r.mapcalc --v \
"${BAND}_integerised = round( 1000000 * ${BAND} )" # how many decimals?
# integerised BAND is...
eval BAND="${1}_${2}_integerised"
# get ${min} and ${max}
eval `r.info -r ${BAND}`
#
r.rescale in=${1}_${2}_integerised out=${1}_${2}_255 from=${min},${max} to=0,255
done ########################################################################
echo "Rescaling done!"
# pan-sharpen High Resolution imagery ---------------------------------------
# needs setting some naming conventions
for Method_Input in \
"ihs ToAR" \
"brovey ToAR" \
"pca ToAR"
do
# parse "${Method_STR}" and set positional parameters
set -- $Method_Input ; echo $1 $2
# some echo
echo "Pan-Sharpening the <${2}> images based on the <${1}> method"
i.pansharpen \
sharpen=${1} \
pan=Pan_${2}_255 \
ms1=Blue_${2}_255 \
ms2=Green_${2}_255 \
ms3=Red_${2}_255 \
output=sharp_${1}_${2}_255
done ########################################################################
# compose BGRs --------------------------------------------------------------
# loop over Methods and Input Types, compose RGBs
for Method_Input in \
"ihs ToAR" \
"brovey ToAR" \
"pca ToAR"
do
# parse "${Method_STR}" and set positional parameters
set -- $Method_Input ; echo $1 $2
# region
g.region rast=sharp_"${1}"_"${2}"_255_blue
# compose
r.composite --o \
r=sharp_"${1}"_"${2}"_255_red \
g=sharp_"${1}"_"${2}"_255_green \
b=sharp_"${1}"_"${2}"_255_blue \
out=rgb_sharpened_"${1}"_"${2}"_255
done #######################################################################
# re-balance & re-compose colors --------------------------------------------
for Method_Input in \
"ihs ToAR" \
"brovey ToAR" \
"pca ToAR"
do
# parse "${Method_STR}" and set positional parameters
set -- $Method_Input ; echo $1 $2
# re-balance
i.landsat.rgb -p \
r=sharp_"${1}"_"${2}"_255_red \
g=sharp_"${1}"_"${2}"_255_green \
b=sharp_"${1}"_"${2}"_255_blue
# region -- Really necessary, again?
g.region rast=sharp_"${1}"_"${2}"_255_blue
# re-compose
r.composite --o \
r=sharp_"${1}"_"${2}"_255_red \
g=sharp_"${1}"_"${2}"_255_green \
b=sharp_"${1}"_"${2}"_255_blue \
out=rgb_sharpened_"${1}"_"${2}"_255_rebalanced
done ########################################################################
Pan-Sharpening based on the HPFA technique
The technique, implemented via the GRASS add-on i.fusion.hpf (src), as indicated above, involves a convolution using a High Pass Filter (HPF) on the high resolution data, then combining this with the lower resolution multispectral data.
Source: "Optimizing the High-Pass Filter Addition Technique for Image Fusion", Ute G. Gangkofner, Pushkar S. Pradhan, and Derrold W. Holcomb (2008)
The algorithm's steps are:
- Computing the ratio of the low (Multi-Spectral) to the high (Panchromatic) resolution
- High Pass Filtering the Panchromatic Image
- Resampling the Multi-Spectral image to the higher resolution
- Adding a weighted High-Pass-Filtered image to the upsampled Multi-Spectral image
- Optionally, matching the histogram of the Pan-Sharpened image to the one of the original Multi-Spectral image
Color Composites
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Vegetation Indices
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PCA
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IKONOS Image classification
References / Sources
- IKONOS Planetary Reflectance and Me an Solar Exoatmospheric Irradiance, by Martin Taylor
- Ikonos DN Value Conversion to Planetary Reflectance Values, by David Fleming
- Landsat7 Science Data Users Handbook, Chapter 11, Section 3
- Calibrated Landsat Digital Number (DN) to Top of Atmosphere (TOA) Reflectance Conversion, by Richard Irish
- from FAQs about the Landsat Missions
See also
- GRASS-Wiki page about Image Processing
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