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DAMASK_EICMD
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grain growth not maintained and has issues 

the grain growth model is based on the Voronoi Implicit Interface Method
(https://doi.org/10.1016/j.jcp.2012.04.004). The last step in this
algorithm is the assignment of the new phase/material ID to the voxels
in the 'thick boundary' which is done with distance_transform_edt from
ndimage. This problem can have multiple solution and can lead to the
translation of grains.

In the original publication, the position of the boundary is calculated
with subvoxel resolution by solving the eikonal equation. The following
python packages might help:
https://pypi.org/project/eikonalfm
https://pypi.org/project/scikit-fmm
https://github.com/malcolmw/pykonal
This commit is contained in:
Martin Diehl 2022-01-12 07:48:09 +01:00
parent 771e8acdb9
commit 29cbf1304b
1 changed files with 0 additions and 178 deletions
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178
processing/legacy/geom_grainGrowth.py vendored
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#!/usr/bin/env python3
import os
import sys
from io import StringIO
from optparse import OptionParser
import numpy as np
from scipy import ndimage
import damask
scriptName = os.path.splitext(os.path.basename(__file__))[0]
scriptID = ' '.join([scriptName,damask.version])
getInterfaceEnergy = lambda A,B: np.float32((A != B)*1.0) # 1.0 if A & B are distinct, 0.0 otherwise
struc = ndimage.generate_binary_structure(3,1) # 3D von Neumann neighborhood
#--------------------------------------------------------------------------------------------------
# MAIN
#--------------------------------------------------------------------------------------------------
parser = OptionParser(option_class=damask.extendableOption, usage='%prog option(s) [geomfile(s)]', description = """
Smoothen interface roughness by simulated curvature flow.
This is achieved by the diffusion of each initially sharply bounded grain volume within the periodic domain
up to a given distance 'd' voxels.
The final geometry is assembled by selecting at each voxel that grain index for which the concentration remains largest.
References 10.1073/pnas.1111557108 (10.1006/jcph.1994.1105)
""", version = scriptID)
parser.add_option('-d', '--distance',
dest = 'd',
type = 'float', metavar = 'float',
help = 'diffusion distance in voxels [%default]')
parser.add_option('-N', '--iterations',
dest = 'N',
type = 'int', metavar = 'int',
help = 'curvature flow iterations [%default]')
parser.add_option('-i', '--immutable',
action = 'extend', dest = 'immutable', metavar = '<int LIST>',
help = 'list of immutable material indices')
parser.add_option('--ndimage',
dest = 'ndimage', action='store_true',
help = 'use ndimage.gaussian_filter in lieu of explicit FFT')
parser.set_defaults(d = 1,
N = 1,
immutable = [],
ndimage = False,
)
(options, filenames) = parser.parse_args()
options.immutable = list(map(int,options.immutable))
if filenames == []: filenames = [None]
for name in filenames:
damask.util.report(scriptName,name)
geom = damask.Grid.load(StringIO(''.join(sys.stdin.read())) if name is None else name)
grid_original = geom.cells
damask.util.croak(geom)
material = np.tile(geom.material,np.where(grid_original == 1, 2,1)) # make one copy along dimensions with grid == 1
grid = np.array(material.shape)
# --- initialize support data ---------------------------------------------------------------------
# store a copy of the initial material indices to find locations of immutable indices
material_original = np.copy(material)
if not options.ndimage:
X,Y,Z = np.mgrid[0:grid[0],0:grid[1],0:grid[2]]
# Calculates gaussian weights for simulating 3d diffusion
gauss = np.exp(-(X*X + Y*Y + Z*Z)/(2.0*options.d*options.d),dtype=np.float32) \
/np.power(2.0*np.pi*options.d*options.d,(3.0 - np.count_nonzero(grid_original == 1))/2.,dtype=np.float32)
gauss[:,:,:grid[2]//2:-1] = gauss[:,:,1:(grid[2]+1)//2] # trying to cope with uneven (odd) grid size
gauss[:,:grid[1]//2:-1,:] = gauss[:,1:(grid[1]+1)//2,:]
gauss[:grid[0]//2:-1,:,:] = gauss[1:(grid[0]+1)//2,:,:]
gauss = np.fft.rfftn(gauss).astype(np.complex64)
for smoothIter in range(options.N):
interfaceEnergy = np.zeros(material.shape,dtype=np.float32)
for i in (-1,0,1):
for j in (-1,0,1):
for k in (-1,0,1):
# assign interfacial energy to all voxels that have a differing neighbor (in Moore neighborhood)
interfaceEnergy = np.maximum(interfaceEnergy,
getInterfaceEnergy(material,np.roll(np.roll(np.roll(
material,i,axis=0), j,axis=1), k,axis=2)))
# periodically extend interfacial energy array by half a grid size in positive and negative directions
periodic_interfaceEnergy = np.tile(interfaceEnergy,(3,3,3))[grid[0]//2:-grid[0]//2,
grid[1]//2:-grid[1]//2,
grid[2]//2:-grid[2]//2]
# transform bulk volume (i.e. where interfacial energy remained zero), store index of closest boundary voxel
index = ndimage.morphology.distance_transform_edt(periodic_interfaceEnergy == 0.,
return_distances = False,
return_indices = True)
# want array index of nearest voxel on periodically extended boundary
periodic_bulkEnergy = periodic_interfaceEnergy[index[0],
index[1],
index[2]].reshape(2*grid) # fill bulk with energy of nearest interface
if options.ndimage:
periodic_diffusedEnergy = ndimage.gaussian_filter(
np.where(ndimage.morphology.binary_dilation(periodic_interfaceEnergy > 0.,
structure = struc,
iterations = int(round(options.d*2.))-1, # fat boundary
),
periodic_bulkEnergy, # ...and zero everywhere else
0.),
sigma = options.d)
else:
diffusedEnergy = np.fft.irfftn(np.fft.rfftn(
np.where(
ndimage.morphology.binary_dilation(interfaceEnergy > 0.,
structure = struc,
iterations = int(round(options.d*2.))-1),# fat boundary
periodic_bulkEnergy[grid[0]//2:-grid[0]//2, # retain filled energy on fat boundary...
grid[1]//2:-grid[1]//2,
grid[2]//2:-grid[2]//2], # ...and zero everywhere else
0.)).astype(np.complex64) *
gauss).astype(np.float32)
periodic_diffusedEnergy = np.tile(diffusedEnergy,(3,3,3))[grid[0]//2:-grid[0]//2,
grid[1]//2:-grid[1]//2,
grid[2]//2:-grid[2]//2] # periodically extend the smoothed bulk energy
# transform voxels close to interface region
index = ndimage.morphology.distance_transform_edt(periodic_diffusedEnergy >= 0.95*np.amax(periodic_diffusedEnergy),
return_distances = False,
return_indices = True) # want index of closest bulk grain
periodic_material = np.tile(material,(3,3,3))[grid[0]//2:-grid[0]//2,
grid[1]//2:-grid[1]//2,
grid[2]//2:-grid[2]//2] # periodically extend the geometry
material = periodic_material[index[0],
index[1],
index[2]].reshape(2*grid)[grid[0]//2:-grid[0]//2,
grid[1]//2:-grid[1]//2,
grid[2]//2:-grid[2]//2] # extent grains into interface region
# replace immutable materials with closest mutable ones
index = ndimage.morphology.distance_transform_edt(np.in1d(material,options.immutable).reshape(grid),
return_distances = False,
return_indices = True)
material = material[index[0],
index[1],
index[2]]
immutable = np.zeros(material.shape, dtype=np.bool)
# find locations where immutable materials have been in original structure
for micro in options.immutable:
immutable += material_original == micro
# undo any changes involving immutable materials
material = np.where(immutable, material_original,material)
damask.Grid(material = material[0:grid_original[0],0:grid_original[1],0:grid_original[2]],
size = geom.size,
origin = geom.origin,
comments = geom.comments + [scriptID + ' ' + ' '.join(sys.argv[1:])],
)\
.save(sys.stdout if name is None else name)