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Convert Landsat 5&7 Thermal band to LST using Python
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#! /usr/bin/env python | |
####################################### | |
# GDALCalcNDVI.py | |
# | |
# A script using the GDAL Library to | |
# create a new image containing the LST | |
# of the original DN value from Landsat | |
# 5 or 7 imagery. | |
# | |
# Author: Tyler Dahlberg | |
####################################### | |
# Import required libraries from python | |
import sys | |
import os | |
import struct | |
import math | |
import osgeo.gdal as gdal | |
# Define the class GDALCalcNDVI | |
class GDALCalcLST(object): | |
# A function to create the output image | |
def createOutputImage(self, outFilename, inDataset): | |
# This defines the output file format (e.g., GeoTiff) | |
driver = gdal.GetDriverByName("GTiff") | |
# Check that this driver can create a new file. | |
metadata = driver.GetMetadata() | |
if metadata.has_key(gdal.DCAP_CREATE) and metadata[gdal.DCAP_CREATE] == 'YES': | |
print 'Driver GTiff supports Create() method.' | |
else: | |
print 'Driver GTIFF does not support Create()' | |
sys.exit(-1) | |
# Get the spatial information from the input file | |
geoTransform = inDataset.GetGeoTransform() | |
geoProjection = inDataset.GetProjection() | |
# Create an output file of the same size as the inputted | |
# image but with only 1 output image band. | |
newDataset = driver.Create(outFilename, inDataset.RasterXSize, \ | |
inDataset.RasterYSize, 1, gdal.GDT_Float32) | |
# Define the spatial information for the new image. | |
newDataset.SetGeoTransform(geoTransform) | |
newDataset.SetProjection(geoProjection) | |
return newDataset | |
# The function which loops through the input image and calculates the | |
# land surface temperature in degrees kelvin. | |
def calcLST(self, filePath, outFilePath, radianceup, radiancedown, lmin, lmax): ##, outFilePath after filepath | |
# Open the inputted dataset | |
dataset = gdal.Open(filePath, gdal.GA_ReadOnly) | |
# Check the dataset was successfully opened | |
if dataset is None: | |
print 'The dataset could not opened' | |
sys.exit(-1) | |
# Create the output dataset and file path | |
##outFilePath = filePath + '\\' + 'results' | |
##if not os.path.exists(outFilePath): os.makedirs(outFilePath) | |
outDataset = self.createOutputImage(outFilePath, dataset) | |
# Check the datasets was successfully created. | |
if outDataset is None: | |
print 'Could not create output image' | |
sys.exit(-1) | |
# Opens data from the sensor | |
band = dataset.GetRasterBand(1) # Input thermal band | |
# Retrieve the number of lines within the image | |
numLines = band.YSize | |
# Loop through each line in turn. | |
for line in range(numLines): | |
# Define variable for output line. | |
outputLine = '' | |
# Read in data for the current line from the | |
# image band representing the red wavelength | |
band_scanline = band.ReadRaster(0, line, band.XSize, 1, \ | |
band.XSize, 1, gdal.GDT_Float32) | |
# Unpack the line of data to be read as floating point data | |
band_tuple = struct.unpack('f' * band.XSize, band_scanline) | |
# Loop through the columns within the image | |
for i in range(len(band_tuple)): | |
# Calculate the TOA Radiance for the current pixel. | |
qcalmax = 255 # Given | |
qcalmin = 1 # Given | |
TOA = 0 | |
TOA = (((lmax - lmin) / (qcalmax - qcalmin)) * (band_tuple[i] \ | |
- qcalmin)) + lmin | |
# Converts top-of-atmosphere radiance to surface-leaving radiance | |
emissivity = 0.95 # emissivity from the YALE paper | |
transmissivity = 0.66 # transmissivity from the YALE paper | |
SLR = ((TOA - radianceup) / (emissivity * transmissivity)) - \ | |
((1 - emissivity) / (emissivity)) * radiancedown | |
if SLR <= 0: | |
SLR = 0.0001 | |
else: | |
SLR = SLR | |
# Converts top-of-atmosphere radiance to Temperature in Kelvin | |
k1 = 607.76 | |
k2 = 1260.56 | |
# Converts to degrees kelvin | |
tempkelvin = k2 / math.log((k1 / SLR) + 1) | |
# Add the current pixel to the output line | |
outputLine = outputLine + struct.pack('f', tempkelvin) | |
# Write the completed line to the output image | |
outDataset.GetRasterBand(1).WriteRaster(0, line, band.XSize, 1, | |
outputLine, buf_xsize=band.XSize, | |
buf_ysize=1, buf_type=gdal.GDT_Float32) | |
# Delete the output line following write | |
del outputLine | |
print 'LST Calculated and output to file' | |
# The function from which the script runs. | |
def run(self): | |
#Input parameters: | |
# Full path to input thermal image | |
filePath = 'D:\Landsat Downloader\Downloads\LE70290302002347EDC00.tar\LE70290302002347EDC00\LE70290302002347EDC00_B6_VCID_1.TIF' | |
# Full path with desired name of LST output image | |
outFilePath = 'D:\Landsat Downloader\Downloads\LE70290302002347EDC00.tar\LE70290302002347EDC00\lst_k.tif' | |
# Upwelling Radiance from NASA Atmospheric Parameter Calculator | |
radianceup = 2.2 | |
# Downwelling Radiance from NASA Atmospheric Parameter Calculator | |
radiancedown = 4.2 | |
# Lowest Radiance value from thermal image metadata | |
lmin = 1.50 | |
# Highest Radiance value from thermal image metadata | |
lmax = 15.0 | |
# Check the input file exists | |
if os.path.exists(filePath): | |
# Run calcNDVI function | |
self.calcLST(filePath, outFilePath, radianceup, radiancedown, lmin, lmax) | |
else: | |
print 'The file does not exist.' | |
# Start the script by calling the run function. | |
if __name__ == '__main__': | |
obj = GDALCalcLST() | |
obj.run() |
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