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EMLaue
While the EMLauemaster program produces a master pattern, similar to the EMEBSDmaster program, the EMLaue program can be used to compute individual transmission and reflection Laue patterns for a given detector geometry and an arbitrary crystal structure.
Using the standard command line approach, the template file can be obtained; this file contains the following parameters:
&LaueData
! The line above must not be changed
!
! The values below are the default values for this program
!
! crystal structure file name
xtalname = 'undefined',
! detector x-size (pixels)
numpx = 1024,
! detector y-size (pixels)
numpy = 768,
! number of parallel threads
nthreads = 1,
! detector pixel size (microns, square pixels)
pixelsize = 50.0,
! spot size weight factor (basically 1/(2*sigma^2) for Gaussian peaks)
spotw = 0.1,
! intensity scaling gamma factor
gammavalue = 1.0,
! x-ray tube accelerating voltage (kV)
maxVoltage = 30.0,
! cutoff lower voltage (kV)
minVoltage = 15.0,
! sample-detector distance (mm)
SDdistance = 100.0,
! do we need to store backprojections as well ? 'Yes' or 'No'
backprojection = 'No',
! dimension of square Lambert array for backprojection (actual will be 2*BPx+1 by 2*BPx+1)
BPx = 300,
! laue pattern mode 'transmission' or 'reflection'
Lauemode = 'transmission',
! input file with list of orientations
orientationfile = 'undefined'
! prefix for tiff output files with individual patterns
tiffprefix = 'undefined',
! HDF output file name (relative to EMdatapathname)
hdfname = 'undefined',
/
Most of the parameters are easily interpreted. The forward model employs a simple Gaussian for the intensity profile of individual pattern spots. The backprojected Laue patterns can also be stored on a square Lambert grid; this is sometimes useful for testing purposes in the context of spherical indexing. The examples below show the input files for transmission and reflection Laue patterns for the standard [10.0] zone axis orientation of trigonal calcite, using an x-ray tube voltage of 30 kV and a low energy cutoff at 15 kV
xtalname = 'Calcite.xtal',
numpx = 512,
numpy = 512,
nthreads = 1,
pixelsize = 100.0,
spotw = 0.5,
gammavalue = 0.33333,
maxVoltage = 30.0,
minVoltage = 15.0,
SDdistance = 12.5,
backprojection = 'No',
Lauemode = 'reflection',
orientationfile = 'path/eulers.txt'
tiffprefix = 'path/Calcite-reflection_',
hdfname = 'path/Calcite-reflection.h5',
/
The eulers.txt file has the following content:
eu
1
0.000000 0.000000 0.000000
Wiki pages are maintained by M. De Graef; they are part of the EMsoft package and fall under the same copyright (BSD2).
Information for Users
SEM Modalities
- Monte Carlo Simulations- EBSD Master Pattern Simulations
- EBSD Overlap Master Patterns
- EBSD Pattern Simulations
- EBSD Dictionary Indexing
- EBSD Spherical Indexing
- EBSD Reflector Ranking
- EBSD HREBSD
- ECP Master Pattern Simulations
- ECP Pattern Simulations
- TKD Master Pattern Simulations
- TKD Pattern Simulations
- ECCI Defect Image Simulations
TEM Modalities
- HH4- PED
- CBED Pattern Simulations
- STEM-DCI Image Simulations
- EMIntegrateSTEM utility
Utility Programs
- EMConvertOrientations- EMDisorientations
- EMHOLZ
- EMKikuchiMap
- EMOpenCLinfo
- EMZAgeom
- EMcuboMK
- EMdpextract
- EMdpmerge
- EMdrawcell
- EMeqvPS
- EMeqvrot
- EMfamily
- EMGBO
- EMGBOdm
- EMgetEulers
- EMgetOSM
- EMlatgeom
- EMlistSG
- EMlistTC
- EMmkxtal
- EMorbit
- EMorient
- EMqg
- EMsampleRFZ
- EMshowxtal
- EMsoftSlackTest
- EMsoftinit
- EMstar
- EMstereo
- EMxtalExtract
- EMxtalinfo
- EMzap
Complete Examples
- Crystal Data Entry Example
- EBSD Example
- ECP Example
- TKD Example
- ECCI Example
- CBED Example
- Dictionary Indexing Example
- DItutorial
Information for Developers