645 lines
20 KiB
Python
645 lines
20 KiB
Python
"""
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Filters for operations on regular grids.
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The grids are defined as (x,y,z,...) where x is fastest and z is slowest.
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This convention is consistent with the layout in grid vti files.
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When converting to/from a plain list (e.g. storage in ASCII table),
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the following operations are required for tensorial data:
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- D3 = D1.reshape(cells+(-1,),order='F').reshape(cells+(3,3))
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- D1 = D3.reshape(cells+(-1,)).reshape(-1,9,order='F')
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"""
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from typing import Tuple as _Tuple
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from scipy import spatial as _spatial
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import numpy as _np
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from ._typehints import FloatSequence as _FloatSequence, IntSequence as _IntSequence
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def _ks(size: _FloatSequence,
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cells: _IntSequence,
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first_order: bool = False) -> _np.ndarray:
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"""
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Get wave numbers operator.
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Parameters
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----------
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size : sequence of float, len (3)
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Physical size of the periodic field.
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cells : sequence of int, len (3)
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Number of cells.
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first_order : bool, optional
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Correction for first order derivatives, defaults to False.
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"""
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k_sk = _np.where(_np.arange(cells[0])>cells[0]//2,
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_np.arange(cells[0])-cells[0],_np.arange(cells[0]))/size[0]
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if cells[0]%2 == 0 and first_order: k_sk[cells[0]//2] = 0 # Nyquist freq=0 for even cells (Johnson, MIT, 2011)
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k_sj = _np.where(_np.arange(cells[1])>cells[1]//2,
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_np.arange(cells[1])-cells[1],_np.arange(cells[1]))/size[1]
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if cells[1]%2 == 0 and first_order: k_sj[cells[1]//2] = 0 # Nyquist freq=0 for even cells (Johnson, MIT, 2011)
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k_si = _np.arange(cells[2]//2+1)/size[2]
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return _np.stack(_np.meshgrid(k_sk,k_sj,k_si,indexing = 'ij'), axis=-1)
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def curl(size: _FloatSequence,
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f: _np.ndarray) -> _np.ndarray:
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u"""
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Calculate curl of a vector or tensor field in Fourier space.
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Parameters
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----------
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size : sequence of float, len (3)
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Physical size of the periodic field.
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f : numpy.ndarray, shape (:,:,:,3) or (:,:,:,3,3)
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Periodic field of which the curl is calculated.
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Returns
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-------
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∇ × f : numpy.ndarray, shape (:,:,:,3) or (:,:,:,3,3)
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Curl of f.
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"""
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n = _np.prod(f.shape[3:])
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k_s = _ks(size,f.shape[:3],True)
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e = _np.zeros((3, 3, 3))
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e[0, 1, 2] = e[1, 2, 0] = e[2, 0, 1] = +1.0 # Levi-Civita symbol
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e[0, 2, 1] = e[2, 1, 0] = e[1, 0, 2] = -1.0
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f_fourier = _np.fft.rfftn(f,axes=(0,1,2))
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curl_ = (_np.einsum('slm,ijkl,ijkm ->ijks' if n == 3 else
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'slm,ijkl,ijknm->ijksn',e,k_s,f_fourier)*2.0j*_np.pi) # vector 3->3, tensor 3x3->3x3
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return _np.fft.irfftn(curl_,axes=(0,1,2),s=f.shape[:3])
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def divergence(size: _FloatSequence,
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f: _np.ndarray) -> _np.ndarray:
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u"""
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Calculate divergence of a vector or tensor field in Fourier space.
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Parameters
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----------
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size : sequence of float, len (3)
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Physical size of the periodic field.
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f : numpy.ndarray, shape (:,:,:,3) or (:,:,:,3,3)
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Periodic field of which the divergence is calculated.
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Returns
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-------
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∇ · f : numpy.ndarray, shape (:,:,:,1) or (:,:,:,3)
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Divergence of f.
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"""
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n = _np.prod(f.shape[3:])
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k_s = _ks(size,f.shape[:3],True)
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f_fourier = _np.fft.rfftn(f,axes=(0,1,2))
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divergence_ = (_np.einsum('ijkl,ijkl ->ijk' if n == 3 else
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'ijkm,ijklm->ijkl', k_s,f_fourier)*2.0j*_np.pi) # vector 3->1, tensor 3x3->3
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return _np.fft.irfftn(divergence_,axes=(0,1,2),s=f.shape[:3])
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def gradient(size: _FloatSequence,
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f: _np.ndarray) -> _np.ndarray:
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u"""
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Calculate gradient of a scalar or vector field in Fourier space.
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Parameters
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----------
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size : sequence of float, len (3)
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Physical size of the periodic field.
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f : numpy.ndarray, shape (:,:,:,1) or (:,:,:,3)
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Periodic field of which the gradient is calculated.
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Returns
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-------
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∇ f : numpy.ndarray, shape (:,:,:,3) or (:,:,:,3,3)
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Gradient of f.
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"""
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n = _np.prod(f.shape[3:])
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k_s = _ks(size,f.shape[:3],True)
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f_fourier = _np.fft.rfftn(f,axes=(0,1,2))
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gradient_ = (_np.einsum('ijkl,ijkm->ijkm' if n == 1 else
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'ijkl,ijkm->ijklm',f_fourier,k_s)*2.0j*_np.pi) # scalar 1->3, vector 3->3x3
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return _np.fft.irfftn(gradient_,axes=(0,1,2),s=f.shape[:3])
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def coordinates0_point(cells: _IntSequence,
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size: _FloatSequence,
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origin: _FloatSequence = _np.zeros(3)) -> _np.ndarray:
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"""
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Cell center positions (undeformed).
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Parameters
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----------
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cells : sequence of int, len (3)
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Number of cells.
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size : sequence of float, len (3)
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Physical size of the periodic field.
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origin : sequence of float, len(3), optional
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Physical origin of the periodic field. Defaults to [0.0,0.0,0.0].
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Returns
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-------
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x_p_0 : numpy.ndarray, shape (:,:,:,3)
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Undeformed cell center coordinates.
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"""
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size_ = _np.array(size,float)
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start = origin + size_/_np.array(cells,_np.int64)*.5
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end = origin + size_ - size_/_np.array(cells,_np.int64)*.5
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return _np.stack(_np.meshgrid(_np.linspace(start[0],end[0],cells[0]),
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_np.linspace(start[1],end[1],cells[1]),
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_np.linspace(start[2],end[2],cells[2]),indexing = 'ij'),
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axis = -1)
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def displacement_fluct_point(size: _FloatSequence,
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F: _np.ndarray) -> _np.ndarray:
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"""
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Cell center displacement field from fluctuation part of the deformation gradient field.
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Parameters
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----------
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size : sequence of float, len (3)
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Physical size of the periodic field.
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F : numpy.ndarray, shape (:,:,:,3,3)
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Deformation gradient field.
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Returns
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-------
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u_p_fluct : numpy.ndarray, shape (:,:,:,3)
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Fluctuating part of the cell center displacements.
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"""
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k_s = _ks(size,F.shape[:3],False)
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k_s_squared = _np.einsum('...l,...l',k_s,k_s)
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k_s_squared[0,0,0] = 1.0
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displacement = -_np.einsum('ijkml,ijkl,l->ijkm',
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_np.fft.rfftn(F,axes=(0,1,2)),
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k_s,
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_np.array([0.5j/_np.pi]*3),
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) / k_s_squared[...,_np.newaxis]
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return _np.fft.irfftn(displacement,axes=(0,1,2),s=F.shape[:3])
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def displacement_avg_point(size: _FloatSequence,
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F: _np.ndarray) -> _np.ndarray:
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"""
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Cell center displacement field from average part of the deformation gradient field.
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Parameters
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----------
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size : sequence of float, len (3)
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Physical size of the periodic field.
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F : numpy.ndarray, shape (:,:,:,3,3)
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Deformation gradient field.
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Returns
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-------
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u_p_avg : numpy.ndarray, shape (:,:,:,3)
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Average part of the cell center displacements.
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"""
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F_avg = _np.average(F,axis=(0,1,2))
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return _np.einsum('ml,ijkl->ijkm',F_avg - _np.eye(3),coordinates0_point(F.shape[:3],size))
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def displacement_point(size: _FloatSequence,
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F: _np.ndarray) -> _np.ndarray:
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"""
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Cell center displacement field from deformation gradient field.
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Parameters
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----------
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size : sequence of float, len (3)
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Physical size of the periodic field.
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F : numpy.ndarray, shape (:,:,:,3,3)
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Deformation gradient field.
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Returns
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-------
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u_p : numpy.ndarray, shape (:,:,:,3)
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Cell center displacements.
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"""
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return displacement_avg_point(size,F) + displacement_fluct_point(size,F)
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def coordinates_point(size: _FloatSequence,
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F: _np.ndarray,
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origin: _FloatSequence = _np.zeros(3)) -> _np.ndarray:
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"""
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Cell center positions.
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Parameters
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----------
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size : sequence of float, len (3)
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Physical size of the periodic field.
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F : numpy.ndarray, shape (:,:,:,3,3)
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Deformation gradient field.
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origin : sequence of float, len(3), optional
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Physical origin of the periodic field. Defaults to [0.0,0.0,0.0].
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Returns
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-------
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x_p : numpy.ndarray, shape (:,:,:,3)
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Cell center coordinates.
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"""
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return coordinates0_point(F.shape[:3],size,origin) + displacement_point(size,F)
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def cellsSizeOrigin_coordinates0_point(coordinates0: _np.ndarray,
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ordered: bool = True) -> _Tuple[_np.ndarray,_np.ndarray,_np.ndarray]:
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"""
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Return grid 'DNA', i.e. cells, size, and origin from 1D array of point positions.
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Parameters
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----------
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coordinates0 : numpy.ndarray, shape (:,3)
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Undeformed cell center coordinates.
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ordered : bool, optional
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Expect coordinates0 data to be ordered (x fast, z slow).
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Defaults to True.
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Returns
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-------
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cells, size, origin : Three numpy.ndarray, each of shape (3)
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Information to reconstruct grid.
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"""
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coords = [_np.unique(coordinates0[:,i]) for i in range(3)]
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mincorner = _np.array(list(map(min,coords)))
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maxcorner = _np.array(list(map(max,coords)))
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cells = _np.array(list(map(len,coords)),_np.int64)
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size = cells/_np.maximum(cells-1,1) * (maxcorner-mincorner)
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delta = size/cells
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origin = mincorner - delta*.5
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# 1D/2D: size/origin combination undefined, set origin to 0.0
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size [_np.where(cells == 1)] = origin[_np.where(cells == 1)]*2.
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origin[_np.where(cells == 1)] = 0.0
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if cells.prod() != len(coordinates0):
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raise ValueError(f'data count {len(coordinates0)} does not match cells {cells}')
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start = origin + delta*.5
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end = origin - delta*.5 + size
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atol = _np.max(size)*5e-2
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if not (_np.allclose(coords[0],_np.linspace(start[0],end[0],cells[0]),atol=atol) and \
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_np.allclose(coords[1],_np.linspace(start[1],end[1],cells[1]),atol=atol) and \
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_np.allclose(coords[2],_np.linspace(start[2],end[2],cells[2]),atol=atol)):
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raise ValueError('non-uniform cell spacing')
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if ordered and not _np.allclose(coordinates0.reshape(tuple(cells)+(3,),order='F'),
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coordinates0_point(list(cells),size,origin),atol=atol):
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raise ValueError('input data is not ordered (x fast, z slow)')
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return (cells,size,origin)
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def coordinates0_node(cells: _IntSequence,
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size: _FloatSequence,
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origin: _FloatSequence = _np.zeros(3)) -> _np.ndarray:
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"""
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Nodal positions (undeformed).
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Parameters
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----------
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cells : sequence of int, len (3)
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Number of cells.
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size : sequence of float, len (3)
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Physical size of the periodic field.
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origin : sequence of float, len(3), optional
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Physical origin of the periodic field. Defaults to [0.0,0.0,0.0].
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Returns
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-------
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x_n_0 : numpy.ndarray, shape (:,:,:,3)
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Undeformed nodal coordinates.
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"""
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return _np.stack(_np.meshgrid(_np.linspace(origin[0],size[0]+origin[0],cells[0]+1),
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_np.linspace(origin[1],size[1]+origin[1],cells[1]+1),
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_np.linspace(origin[2],size[2]+origin[2],cells[2]+1),indexing = 'ij'),
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axis = -1)
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def displacement_fluct_node(size: _FloatSequence,
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F: _np.ndarray) -> _np.ndarray:
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"""
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Nodal displacement field from fluctuation part of the deformation gradient field.
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Parameters
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----------
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size : sequence of float, len (3)
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Physical size of the periodic field.
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F : numpy.ndarray, shape (:,:,:,3,3)
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Deformation gradient field.
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Returns
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-------
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u_n_fluct : numpy.ndarray, shape (:,:,:,3)
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Fluctuating part of the nodal displacements.
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"""
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return point_to_node(displacement_fluct_point(size,F))
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def displacement_avg_node(size: _FloatSequence,
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F: _np.ndarray) -> _np.ndarray:
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"""
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Nodal displacement field from average part of the deformation gradient field.
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Parameters
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----------
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size : sequence of float, len (3)
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Physical size of the periodic field.
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F : numpy.ndarray, shape (:,:,:,3,3)
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Deformation gradient field.
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Returns
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-------
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u_n_avg : numpy.ndarray, shape (:,:,:,3)
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Average part of the nodal displacements.
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"""
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F_avg = _np.average(F,axis=(0,1,2))
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return _np.einsum('ml,ijkl->ijkm',F_avg - _np.eye(3),coordinates0_node(F.shape[:3],size))
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def displacement_node(size: _FloatSequence,
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F: _np.ndarray) -> _np.ndarray:
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"""
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Nodal displacement field from deformation gradient field.
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Parameters
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----------
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size : sequence of float, len (3)
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Physical size of the periodic field.
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F : numpy.ndarray, shape (:,:,:,3,3)
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Deformation gradient field.
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Returns
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-------
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u_n : numpy.ndarray, shape (:,:,:,3)
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Nodal displacements.
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"""
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return displacement_avg_node(size,F) + displacement_fluct_node(size,F)
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def coordinates_node(size: _FloatSequence,
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F: _np.ndarray,
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origin: _FloatSequence = _np.zeros(3)) -> _np.ndarray:
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"""
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Nodal positions.
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Parameters
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----------
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size : sequence of float, len (3)
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Physical size of the periodic field.
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F : numpy.ndarray, shape (:,:,:,3,3)
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Deformation gradient field.
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origin : sequence of float, len(3), optional
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Physical origin of the periodic field. Defaults to [0.0,0.0,0.0].
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Returns
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-------
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x_n : numpy.ndarray, shape (:,:,:,3)
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Nodal coordinates.
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"""
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return coordinates0_node(F.shape[:3],size,origin) + displacement_node(size,F)
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def cellsSizeOrigin_coordinates0_node(coordinates0: _np.ndarray,
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ordered: bool = True) -> _Tuple[_np.ndarray,_np.ndarray,_np.ndarray]:
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"""
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Return grid 'DNA', i.e. cells, size, and origin from 1D array of nodal positions.
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Parameters
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----------
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coordinates0 : numpy.ndarray, shape (:,3)
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Undeformed nodal coordinates.
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ordered : bool, optional
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Expect coordinates0 data to be ordered (x fast, z slow).
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Defaults to True.
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Returns
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-------
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cells, size, origin : Three numpy.ndarray, each of shape (3)
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Information to reconstruct grid.
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"""
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coords = [_np.unique(coordinates0[:,i]) for i in range(3)]
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mincorner = _np.array(list(map(min,coords)))
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maxcorner = _np.array(list(map(max,coords)))
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cells = _np.array(list(map(len,coords)),_np.int64) - 1
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size = maxcorner-mincorner
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origin = mincorner
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if (cells+1).prod() != len(coordinates0):
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raise ValueError(f'data count {len(coordinates0)} does not match cells {cells}')
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atol = _np.max(size)*5e-2
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if not (_np.allclose(coords[0],_np.linspace(mincorner[0],maxcorner[0],cells[0]+1),atol=atol) and \
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_np.allclose(coords[1],_np.linspace(mincorner[1],maxcorner[1],cells[1]+1),atol=atol) and \
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_np.allclose(coords[2],_np.linspace(mincorner[2],maxcorner[2],cells[2]+1),atol=atol)):
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raise ValueError('non-uniform cell spacing')
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if ordered and not _np.allclose(coordinates0.reshape(tuple(cells+1)+(3,),order='F'),
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coordinates0_node(list(cells),size,origin),atol=atol):
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raise ValueError('input data is not ordered (x fast, z slow)')
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return (cells,size,origin)
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def point_to_node(cell_data: _np.ndarray) -> _np.ndarray:
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"""
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Interpolate periodic point data to nodal data.
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Parameters
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----------
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cell_data : numpy.ndarray, shape (:,:,:,...)
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Data defined on the cell centers of a periodic grid.
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Returns
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-------
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||
node_data : numpy.ndarray, shape (:,:,:,...)
|
||
Data defined on the nodes of a periodic grid.
|
||
|
||
"""
|
||
n = ( cell_data + _np.roll(cell_data,1,(0,1,2))
|
||
+ _np.roll(cell_data,1,(0,)) + _np.roll(cell_data,1,(1,)) + _np.roll(cell_data,1,(2,))
|
||
+ _np.roll(cell_data,1,(0,1)) + _np.roll(cell_data,1,(1,2)) + _np.roll(cell_data,1,(2,0)))*0.125
|
||
|
||
return _np.pad(n,((0,1),(0,1),(0,1))+((0,0),)*len(cell_data.shape[3:]),mode='wrap')
|
||
|
||
|
||
def node_to_point(node_data: _np.ndarray) -> _np.ndarray:
|
||
"""
|
||
Interpolate periodic nodal data to point data.
|
||
|
||
Parameters
|
||
----------
|
||
node_data : numpy.ndarray, shape (:,:,:,...)
|
||
Data defined on the nodes of a periodic grid.
|
||
|
||
Returns
|
||
-------
|
||
cell_data : numpy.ndarray, shape (:,:,:,...)
|
||
Data defined on the cell centers of a periodic grid.
|
||
|
||
"""
|
||
c = ( node_data + _np.roll(node_data,1,(0,1,2))
|
||
+ _np.roll(node_data,1,(0,)) + _np.roll(node_data,1,(1,)) + _np.roll(node_data,1,(2,))
|
||
+ _np.roll(node_data,1,(0,1)) + _np.roll(node_data,1,(1,2)) + _np.roll(node_data,1,(2,0)))*0.125
|
||
|
||
return c[1:,1:,1:]
|
||
|
||
|
||
def coordinates0_valid(coordinates0: _np.ndarray) -> bool:
|
||
"""
|
||
Check whether coordinates form a regular grid.
|
||
|
||
Parameters
|
||
----------
|
||
coordinates0 : numpy.ndarray, shape (:,3)
|
||
Array of undeformed cell coordinates.
|
||
|
||
Returns
|
||
-------
|
||
valid : bool
|
||
Whether the coordinates form a regular grid.
|
||
|
||
"""
|
||
try:
|
||
cellsSizeOrigin_coordinates0_point(coordinates0,ordered=True)
|
||
return True
|
||
except ValueError:
|
||
return False
|
||
|
||
|
||
def unravel_index(idx: _np.ndarray) -> _np.ndarray:
|
||
"""
|
||
Convert flat indices to coordinate indices.
|
||
|
||
Parameters
|
||
----------
|
||
idx : numpy.ndarray, shape (:,:,:)
|
||
Grid of flat indices.
|
||
|
||
Returns
|
||
-------
|
||
unravelled : numpy.ndarray, shape (:,:,:,3)
|
||
Grid of coordinate indices.
|
||
|
||
Examples
|
||
--------
|
||
Unravel a linearly increasing sequence of material indices on a 3 × 2 × 1 grid.
|
||
|
||
>>> import numpy as np
|
||
>>> import damask
|
||
>>> seq = np.arange(6).reshape((3,2,1),order='F')
|
||
>>> (coord_idx := damask.grid_filters.unravel_index(seq))
|
||
array([[[[0, 0, 0]],
|
||
[[0, 1, 0]]],
|
||
[[[1, 0, 0]],
|
||
[[1, 1, 0]]],
|
||
[[[2, 0, 0]],
|
||
[[2, 1, 0]]]])
|
||
>>> coord_idx[1,1,0]
|
||
array([1, 1, 0])
|
||
|
||
"""
|
||
cells = idx.shape
|
||
idx_ = _np.expand_dims(idx,3)
|
||
return _np.block([ idx_ %cells[0],
|
||
(idx_//cells[0]) %cells[1],
|
||
((idx_//cells[0])//cells[1])%cells[2]])
|
||
|
||
def ravel_index(idx: _np.ndarray) -> _np.ndarray:
|
||
"""
|
||
Convert coordinate indices to flat indices.
|
||
|
||
Parameters
|
||
----------
|
||
idx : numpy.ndarray, shape (:,:,:,3)
|
||
Grid of coordinate indices.
|
||
|
||
Returns
|
||
-------
|
||
ravelled : numpy.ndarray, shape (:,:,:)
|
||
Grid of flat indices.
|
||
|
||
Examples
|
||
--------
|
||
Ravel a reversed sequence of coordinate indices on a 2 × 2 × 1 grid.
|
||
|
||
>>> import numpy as np
|
||
>>> import damask
|
||
>>> (rev := np.array([[1,1,0],[0,1,0],[1,0,0],[0,0,0]]).reshape((2,2,1,3)))
|
||
array([[[[1, 1, 0]],
|
||
[[0, 1, 0]]],
|
||
[[[1, 0, 0]],
|
||
[[0, 0, 0]]]])
|
||
>>> (flat_idx := damask.grid_filters.ravel_index(rev))
|
||
array([[[3],
|
||
[2]],
|
||
[[1],
|
||
[0]]])
|
||
|
||
"""
|
||
cells = idx.shape[:3]
|
||
return idx[:,:,:,0] \
|
||
+ idx[:,:,:,1]*cells[0] \
|
||
+ idx[:,:,:,2]*cells[0]*cells[1]
|
||
|
||
|
||
def regrid(size: _FloatSequence,
|
||
F: _np.ndarray,
|
||
cells: _IntSequence) -> _np.ndarray:
|
||
"""
|
||
Map a deformed grid A back to a rectilinear grid B.
|
||
|
||
The size of grid B is chosen as the average deformed size of grid A.
|
||
|
||
Parameters
|
||
----------
|
||
size : sequence of float, len (3)
|
||
Physical size of grid A.
|
||
F : numpy.ndarray, shape (:,:,:,3,3)
|
||
Deformation gradient field on grid A.
|
||
cells : sequence of int, len (3)
|
||
Cell count along x,y,z of grid B.
|
||
|
||
Returns
|
||
-------
|
||
idx : numpy.ndarray of int, shape (cells)
|
||
Flat index of closest point on deformed grid A for each point on grid B.
|
||
|
||
"""
|
||
box = _np.dot(_np.average(F,axis=(0,1,2)),size)
|
||
c = coordinates_point(size,F)%box
|
||
tree = _spatial.cKDTree(c.reshape((-1,3),order='F'),boxsize=box)
|
||
return tree.query(coordinates0_point(cells,box))[1]
|