Estimating Crop ET from Satellite Section 2. Calculate ET from Satellite Data-V1
Outline Calculate dT at hot and cold spots Choose area of interest Locate a cold spot and find the surface temperature Locate a hot spot and find the surface temperature Find the local weather data Calculate dT Calculate ET Obtain daily Etr Download the file “CalculateEt.xls” Calculate the following NDVI (Normalized vegetation index) Ln(Zom) (the natural logarithm of roughness length) H (soil heat flux) Albedo (ground reflectance) ET
Step 2 Drag mouse to choose an interested area
Step 3 Put mouse at the upper-left corner of the chosen area to obtain coordinates
Step 4 Put mouse at the bottom-right corner of the chosen area to obtain coordinates
The green circled areas are pecan orchard and alfalfa field
Step 5 Adjust the coordinates Upper-left corner (from step 3) 4104/6=684 do not need to be adjusted 821/6=136.8 adjusted to 137*6=822 Bottom-right corner (from step 4) 4315/6=719.1 adjusted to 719*6-1= /6=165.5 adjusted to 166*6-1=995
Choose area of interest step1 Open the “Image3N” image in the file of “AST_L1B_003_ _ hdf”
Step 6 Show the interested area only
Step 7 Press the “Magnifier” to magnify the image to find the Salopek pecan orchard
Step 8 put the mouse in the the orchard to find the coordinates
Using the same way to find a point coordinates in the alfalfa field for future locating NDVI (slide 53)
Step 9 open “Kinetic Temperature” in “ AST_08_ hdf”
Step 10 choose the interested area of upper-left (684, 137) and bottom-right (718,165) (see step 5)
Step 11 find the point coordinates in pecan orchard According to step 8 and the point coordinates in the pecan field are (24, 18) in the “ImageData3N” chosen area, and according to step 10, the starting coordinates of the upper-left coordinates in the chosen temperature image are (684, 137). So the point coordinates are /6~ /6~140
Step 12 find the pecan orchard temperature (688, 140) in the chosen area spreadsheet.
Locate a bare soil field and find its temperature Step 1 open the chosen surface area as an image
Step 2 magnify the image by click on “Magnifier”
Step 3 find the hottest point (assume it is a bare soil field)
Find the local weather data Step 1 go to:
Step 2 Scroll down and click on “2002” in “Old hourly data”
Step 3 The hourly data in 2002 is shown. Please record which columns are “Humidity Mean”, “Wind Speed Mean”, and “Solar Radiation Mean”
Step 4 Scroll down and find the data at 12:00, 09/04/02
Step 5 Scroll to right and find the needed data “Humidity Mean=28.19%”, “Wind Speed Mean=5.4 mph”, and “Solar Radiation Mean=28.86 L/h” using the recorded column positions in step 3.
Calculate dT Step 1 Download the Excel “DTSep xls” file at: lculation/DTSep xls
Step 2 Open “ DTSep xls” and input the obtained data.
The worksheet of “ETr calculation” worksheet calculates hourly Etr
The “Bare soil spot” worksheet calculates hot spot dT
The “dT graph” worksheet shows the linear equation for dT calculation
Calculate ET Obtain Daily Etr Step 1 Go to shl/cns/oldformat.pl
Step 2 fill out the date, choose “Metric (Excel)”, then fill in “ID” finally press “Retrieve Weather Data”
Then the Etr (PET) is calculated.
Download “CalculateEt.xls” Step 1 In Internet Explorer fill in the following URL teaching _Material/soil470/sebal/ETCalculation/calculateEt. xls Then click “Yes”
Step 2 click No
Step 3 Click on “File“ then“Save As”
Step 4 Click on “File“ then“Save As” and give a file name and then “Save”
Calculate NDVI Step 1 close the Internet Explorer so that the Excel software can open the dowloaded file.
Step 2 open Excel software and click “File” then “Open”
Step 3 choose the file and click “Open”
Step 4 click “Enable Macros”
Step 5 click “No” if the following dialog appears
Step 6 fill in the input values
Step 7 go to the opened “AST_L1B…” HDF file and copy the chosen area “ImageData3N” data. upper-left (4104, 822) and bottom-right (4313, 995). See slide 9
Step 8 go to “Band3” Excel worksheet and paste the copied data
Step 9 using the same way copy the HDF “ImageData 2” data to “Band2” worksheet. upper-left (4104, 822) and bottom-right (4313, 995).
The “NDVI 15by 15” worksheet automatically calculates the NDVI in 15 by 15 m resolution
Step 10 click “Tools”, “Macro”, “Visual Basic Editor”
Step 11 click “Windows”, then “Module 1”
Step 12 click the “run” button to calculate the 90 by 90 m NDVI
Within 1 minute, the calculation finished and the results are in “NDVI 90 by 90”
Calculate Ln(Zom) Step 1 find point (24, 21) in “NDVI 90 By90” and obtain the NDVI for bare soil according to coordinates (23, 20) from slide 19
Step 2 find point (24/6+1, 18/3+1) in “NDVI 90 By90” and obtain the NDVI for pecan according to coordinates (24,18) from slide 11
Step 3 find the point (120/6+1, 131/6+1), i.e. (21, 22) and obtain NDVI for alfalfa according to slide 12 coordinates (120,131)
Step 4 input the NDVIs and pecan alfalfa heights and bare soil roughness length in “NDVI LNZom” to obtain the regression equation for Ln(Zom)
Step 5 in “LnZom”, calculate Ln(zom) for each point using the regression equation
Calculate H Step 1 copy the chosen surface temperature data from HDF file (slide 14) to the Excel “temperature “
The “Iteration” worksheet will automatically do iterative H calculation considering stability effects until most H’s change within 10%
Albedo calculation step 1 open the reflectance file ” AST_07_ hdf1” Must choose “ All Files ” on the dialog, otherwise, the file will not be shown.
The opened file
Step 2 choose data area, the upper left coordinates are (2052, 411) and bottom-right (2156, 497)
Step 3 copy chosen area Band 9 data from HDF file to “Reflectance 9” of Excel file.
Step 4 using the same way copy the reflectance data of band 5, 6, 8 to the Excel worksheets of “Reflectance 5, 6, 8” respectively
The part of albedo calculation for band 5, 6, 8, and 9 in the albedo regression equation will be automatically calculated in “Reflectance by30m”
Step 5 Open the reflectance file of AST_07_ hdf0
Step 6 Copy the “Band3N” and “Band2” reflectance data from HDF file to Excel worksheets of “Reflectance 3n” and “Reflectance 1”. The upper-left coordinates are (4104, 822) and bottom-right (4313, 995)
The part of albedo calculation for band 1, and 3 in the albedo regression equation will be automatically calculated in “Reflectance by 15m”
Step 7 Open Visual Basic Editor to run the modules to convert the resulted 30 by 30 m and 15 by 15 m albedo calculation to 90 by 90 m
Step 8 click “Tools”, then “Macros”
Step 9 click “Reflectance13Band15to90m” and then “Run” to covert 15 m by 15 m results to 90 by 90 m
Step 10 click “Reflectance5689Band30to90m” and then “Run” to covert 30 m by 30 m results to 90 by 90 m
The results for band 5, 6, 8, and 9 in 90 by 90 m resolution are in the worksheet of “Reflectance by90m”
The results for band 1 and 3 are in the worksheet of “Reflectance by90m”
The final albedo is automatically calculated and is in “Albedo” worksheet.
ET calculation and visualization Step 1 The net radiation is automatically calculated in “Radiation net”
The regression equation for G/Rn is obtained in “G Div regression”
Step 2 The G/Rn is calculated in “G Div Rn” G is soil heat flux and Rn is the net radiation using the regression equation from last slide.
Step 3 Rn-G is obtained in the worksheet of “Rn-G”
Step 4 Et is calculated in “ET”
Step 5 Scroll down and then the Et is calculated in “mm/day”
Step 6 Scroll down, and then the Et is rounded to integer because to visualize it in HDFView2.1, the format must be integer.
Step 7 The ET results are visualized in HDFView2.1