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Different basic undersampling methods.
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.gitignore
vendored
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.gitignore
vendored
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venv/
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*.cfl
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*.hdr
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fig/
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.ipynb_checkpoints/
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data/
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__pycache__/
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*.mat
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1355
ESMRMB_Educational.ipynb
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1355
ESMRMB_Educational.ipynb
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3
README.md
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README.md
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# ESMRMB Educational
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Testing different reconstruction methods.
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0
__init__.py
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0
__init__.py
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114
cfl.py
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cfl.py
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# Copyright 2013-2015. The Regents of the University of California.
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# Copyright 2021. Uecker Lab. University Center Göttingen.
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# All rights reserved. Use of this source code is governed by
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# a BSD-style license which can be found in the LICENSE file.
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#
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# Authors:
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# 2013 Martin Uecker <uecker@eecs.berkeley.edu>
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# 2015 Jonathan Tamir <jtamir@eecs.berkeley.edu>
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from __future__ import print_function
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from __future__ import with_statement
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import numpy as np
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import mmap
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import os
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def readcfl(name):
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# get dims from .hdr
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with open(name + ".hdr", "rt") as h:
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h.readline() # skip
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l = h.readline()
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dims = [int(i) for i in l.split()]
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# remove singleton dimensions from the end
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n = np.prod(dims)
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dims_prod = np.cumprod(dims)
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dims = dims[:np.searchsorted(dims_prod, n)+1]
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# load data and reshape into dims
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with open(name + ".cfl", "rb") as d:
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a = np.fromfile(d, dtype=np.complex64, count=n);
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return a.reshape(dims, order='F') # column-major
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def readmulticfl(name):
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# get dims from .hdr
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with open(name + ".hdr", "rt") as h:
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lines = h.read().splitlines()
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index_dim = 1 + lines.index('# Dimensions')
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total_size = int(lines[index_dim])
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index_sizes = 1 + lines.index('# SizesDimensions')
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sizes = [int(i) for i in lines[index_sizes].split()]
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index_dims = 1 + lines.index('# MultiDimensions')
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with open(name + ".cfl", "rb") as d:
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a = np.fromfile(d, dtype=np.complex64, count=total_size)
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offset = 0
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result = []
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for i in range(len(sizes)):
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dims = ([int(i) for i in lines[index_dims + i].split()])
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n = np.prod(dims)
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result.append(a[offset:offset+n].reshape(dims, order='F'))
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offset += n
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if total_size != offset:
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print("Error")
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return result
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def writecfl(name, array):
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with open(name + ".hdr", "wt") as h:
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h.write('# Dimensions\n')
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for i in (array.shape):
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h.write("%d " % i)
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h.write('\n')
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size = np.prod(array.shape) * np.dtype(np.complex64).itemsize
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with open(name + ".cfl", "a+b") as d:
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os.ftruncate(d.fileno(), size)
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mm = mmap.mmap(d.fileno(), size, flags=mmap.MAP_SHARED, prot=mmap.PROT_WRITE)
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if array.dtype != np.complex64:
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array = array.astype(np.complex64)
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mm.write(np.ascontiguousarray(array.T))
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mm.close()
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#with mmap.mmap(d.fileno(), size, flags=mmap.MAP_SHARED, prot=mmap.PROT_WRITE) as mm:
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# mm.write(array.astype(np.complex64).tobytes(order='F'))
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def writemulticfl(name, arrays):
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size = 0
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dims = []
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for array in arrays:
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size += array.size
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dims.append(array.shape)
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with open(name + ".hdr", "wt") as h:
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h.write('# Dimensions\n')
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h.write("%d\n" % size)
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h.write('# SizesDimensions\n')
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for dim in dims:
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h.write("%d " % len(dim))
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h.write('\n')
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h.write('# MultiDimensions\n')
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for dim in dims:
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for i in dim:
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h.write("%d " % i)
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h.write('\n')
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size = size * np.dtype(np.complex64).itemsize
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with open(name + ".cfl", "a+b") as d:
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os.ftruncate(d.fileno(), size)
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mm = mmap.mmap(d.fileno(), size, flags=mmap.MAP_SHARED, prot=mmap.PROT_WRITE)
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for array in arrays:
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if array.dtype != np.complex64:
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array = array.astype(np.complex64)
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mm.write(np.ascontiguousarray(array.T))
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mm.close()
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48
plotBoMap.py
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plotBoMap.py
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import scipy.io as sio
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import matplotlib.pyplot as plt
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import numpy as np
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import matplotlib.gridspec as gridspec
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import matplotlib.cm as cm
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from mpl_toolkits.axes_grid1 import make_axes_locatable
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# Bo Map
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mat_data_0=sio.loadmat('bo.mat')
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tmap = mat_data_0['boMap']
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print(np.min(tmap))
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print(np.max(tmap))
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vmin = -0.3
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vmax = 0.3
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def multiSlicePlot(data,nRow, nCol, nSlrep, vmin, vmax, sliceInit = 0):
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"""""
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data = imageMatrix3D [sl,ph,rd]
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nRow, nCol dimensions of the multislicePlot
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nSlRep = number of slices to represent
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sliceInit = slice in wihich we start representing
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"""""
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images = []
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fig = plt.figure(figsize=(nRow, nCol), dpi=500)
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gs1 = gridspec.GridSpec(nRow, nCol)
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gs1.update(wspace=0.020, hspace=0.020) # set the spacing between axes.
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for i in range(nSlrep):
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ii = i + sliceInit
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# print(ii)
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ax1 = plt.subplot(gs1[i])
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# plt.axis('off')
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ax1.set_xticklabels([])
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ax1.set_yticklabels([])
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ax1.set_aspect('equal')
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dataAux = data[int(ii), :, :]
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imgPlot = ax1.imshow(dataAux,vmin=vmin, vmax=vmax)
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images.append(imgPlot)
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ax1.axis('off')
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return fig
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fig = multiSlicePlot(tmap*1e3,3,6,16,vmin,vmax,0)
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cbar_ax = fig.add_axes([0.92, 0.15, 0.01, 0.7])
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norm = plt.Normalize(vmin=vmin, vmax=vmax)
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cbar = plt.colorbar(cm.ScalarMappable(norm=norm, cmap=cm.viridis), cax=cbar_ax)
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cbar.set_label('Bo [mT]', fontsize=2)
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cbar.ax.tick_params(labelsize=2)
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plt.show()
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plotComparativeTimes.py
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plotComparativeTimes.py
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import scipy.io as sio
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import matplotlib.pyplot as plt
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import numpy as np
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import matplotlib.gridspec as gridspec
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import matplotlib.cm as cm
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from mpl_toolkits.axes_grid1 import make_axes_locatable
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imagesPath=['T2_CPMG','T2_APCPMG', 'T2_APCP', 'T2_CP', 'T1']
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sliceRep = 12
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vmin = 0
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vmax = 200
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nMaps = len(imagesPath)
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fig = plt.figure(figsize=(1, 5), dpi=500)
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gs1 = gridspec.GridSpec(1, nMaps)
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gs1.update(wspace=0.020, hspace=0.020)
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for i in range(nMaps):
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if 'T1' in imagesPath[i]:
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mat_data = sio.loadmat(imagesPath[i]+'.mat')
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data = mat_data['t1map']
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print(data.shape)
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else:
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mat_data = sio.loadmat(imagesPath[i]+'.mat')
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data = mat_data['t2map']
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print(data.shape)
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ax1 = plt.subplot(gs1[i])
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ax1.set_xticklabels([])
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ax1.set_yticklabels([])
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ax1.set_aspect('equal')
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dataAux = data[sliceRep, :, :]
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imgPlot = ax1.imshow(abs(dataAux),vmin=vmin, vmax=vmax)
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ax1.axis('off')
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ax1.set_title(imagesPath[i], fontsize=4)
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cbar_ax = fig.add_axes([0.92, 0.35, 0.01, 0.30])
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norm = plt.Normalize(vmin=vmin, vmax=vmax)
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cbar = plt.colorbar(cm.ScalarMappable(norm=norm, cmap=cm.viridis), cax=cbar_ax)
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cbar.set_label('Time [ms]', fontsize=2)
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cbar.ax.tick_params(labelsize=2)
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plt.show()
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plotPDMap.py
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plotPDMap.py
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import scipy.io as sio
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import matplotlib.pyplot as plt
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import numpy as np
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import matplotlib.gridspec as gridspec
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import matplotlib.cm as cm
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from mpl_toolkits.axes_grid1 import make_axes_locatable
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# PD
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mat_data_0=sio.loadmat('PD.mat')
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img = mat_data_0['image3D']
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vmin = np.min(np.abs(img))
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vmax = np.max(np.abs(img))
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def multiSlicePlot(data,nRow, nCol, nSlrep, vmin, vmax, sliceInit = 0):
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"""""
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data = imageMatrix3D [sl,ph,rd]
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nRow, nCol dimensions of the multislicePlot
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nSlRep = number of slices to represent
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sliceInit = slice in wihich we start representing
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"""""
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images = []
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fig = plt.figure(figsize=(nRow, nCol), dpi=500)
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gs1 = gridspec.GridSpec(nRow, nCol)
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gs1.update(wspace=0.020, hspace=0.020) # set the spacing between axes.
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for i in range(nSlrep):
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ii = i + sliceInit
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# print(ii)
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ax1 = plt.subplot(gs1[i])
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# plt.axis('off')
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ax1.set_xticklabels([])
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ax1.set_yticklabels([])
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ax1.set_aspect('equal')
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dataAux = data[int(ii), :, :]
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imgPlot = ax1.imshow(dataAux,vmin=vmin, vmax=vmax)
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images.append(imgPlot)
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ax1.axis('off')
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return fig
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fig = multiSlicePlot(np.abs(img),3,6,16,vmin,vmax,0)
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cbar_ax = fig.add_axes([0.92, 0.15, 0.01, 0.7])
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norm = plt.Normalize(vmin=vmin, vmax=vmax)
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cbar = plt.colorbar(cm.ScalarMappable(norm=norm, cmap=cm.viridis), cax=cbar_ax)
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cbar.set_label('PD [a.u.]', fontsize=2)
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cbar.ax.tick_params(labelsize=2)
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plt.show()
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12
plotT1Map.py
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plotT1Map.py
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import scipy.io as sio
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import matplotlib.pyplot as plt
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import numpy as np
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from bart import bart
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# T1 dict
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T1_dict = sio.loadmat('T1.mat')
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rawName = 'T2_CPMG.mat'
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mat_data_0=sio.loadmat(rawName)
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print(mat_data_0.keys())
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52
plotTimesMap.py
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52
plotTimesMap.py
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import scipy.io as sio
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import matplotlib.pyplot as plt
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import numpy as np
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import matplotlib.gridspec as gridspec
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import matplotlib.cm as cm
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from mpl_toolkits.axes_grid1 import make_axes_locatable
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# Map
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rawName = 'T2_CPMG.mat'
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mat_data_0=sio.loadmat(rawName)
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if 'T1' in rawName:
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tmap = mat_data_0['t1map']
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else:
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tmap = mat_data_0['t2map']
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print(np.min(tmap))
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print(np.max(tmap))
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vmin = 0
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vmax = 200
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def multiSlicePlot(data,nRow, nCol, nSlrep, vmin, vmax, sliceInit = 0):
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"""""
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data = imageMatrix3D [sl,ph,rd]
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nRow, nCol dimensions of the multislicePlot
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nSlRep = number of slices to represent
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sliceInit = slice in wihich we start representing
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"""""
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images = []
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fig = plt.figure(figsize=(nRow, nCol), dpi=500)
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gs1 = gridspec.GridSpec(nRow, nCol)
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gs1.update(wspace=0.020, hspace=0.020) # set the spacing between axes.
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for i in range(nSlrep):
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ii = i + sliceInit
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# print(ii)
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ax1 = plt.subplot(gs1[i])
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# plt.axis('off')
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ax1.set_xticklabels([])
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ax1.set_yticklabels([])
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ax1.set_aspect('equal')
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dataAux = data[int(ii), :, :]
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imgPlot = ax1.imshow(dataAux,vmin=vmin, vmax=vmax)
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images.append(imgPlot)
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ax1.axis('off')
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return fig
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fig = multiSlicePlot(tmap,3,6,16,vmin,vmax,0)
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cbar_ax = fig.add_axes([0.92, 0.15, 0.01, 0.7])
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|
norm = plt.Normalize(vmin=vmin, vmax=vmax)
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cbar = plt.colorbar(cm.ScalarMappable(norm=norm, cmap=cm.viridis), cax=cbar_ax)
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cbar.set_label(rawName+ '[ms]', fontsize=2)
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cbar.ax.tick_params(labelsize=2)
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plt.show()
|
36
rawDatasExplanation.txt
Normal file
36
rawDatasExplanation.txt
Normal file
|
@ -0,0 +1,36 @@
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# T2 Maps
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|
t2maps_dict = {
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'kSpaces3D': sampled, # kSpace [kRd, kPh, kSl, kSpace_echo_1, kSpace_echo_2, ..., kSpace_echo_nETL]
|
||||||
|
'images3D': imgMSE, # images [nSl, nPh, nETL, nRD]
|
||||||
|
'echoSpacing': echoSpacing, # Echo spacing
|
||||||
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'FOV': fov, # FOV [sl,ph,rd]
|
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|
't2map': t2Map # t2Map (ms) [nSl, nPh, nRD]
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|
}
|
||||||
|
|
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# T1 Map
|
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|
t1map_dict = {
|
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'kSpaces3D': sampled, # kSpace [kRd, kPh, kSl, kSpace_echo_1, kSpace_echo_2, ..., kSpace_echo_nETL]
|
||||||
|
'images3D': imgAll, # images [nSl, nPh, nImg, nRD]
|
||||||
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'inversionTimes': tI_vector, # Inversion times corresponding each image
|
||||||
|
'FOV': fov, # FOV [sl,ph,rd]
|
||||||
|
't1map': t1Map # t2Map (ms) [nSl, nPh, nRD]
|
||||||
|
}
|
||||||
|
|
||||||
|
# Bo Map
|
||||||
|
bomap_dict = {
|
||||||
|
'kSpace3D_0': sampled_0, # kSpace delay 0 [kRd, kPh, kSl, kSpace]
|
||||||
|
'image3D_0': img0, # images delay 0 [nSl, nPh, nRD]
|
||||||
|
'kSpace3D_delay': sampled_delay, # kSpace delay [kRd, kPh, kSl, kSpace]
|
||||||
|
'image3D_delay': img80, # images delay [nSl, nPh, nRD]
|
||||||
|
'delay': delay, # delay (s)
|
||||||
|
'FOV': fov, # FOV [sl,ph,rd]
|
||||||
|
'boMap': boCeros # boMap (T) [nSl, nPh, nRD]
|
||||||
|
}
|
||||||
|
|
||||||
|
# PD
|
||||||
|
pd_dict = {
|
||||||
|
'kSpace3D': sampled_0, # kSpace [kRd, kPh, kSl, kSpace]
|
||||||
|
'image3D': img0, # images [nSl, nPh, nRD]
|
||||||
|
'FOV': fov, # FOV [sl,ph,rd]
|
||||||
|
}
|
78
reco.py
Normal file
78
reco.py
Normal file
|
@ -0,0 +1,78 @@
|
||||||
|
import scipy.io as sio
|
||||||
|
import matplotlib.pyplot as plt
|
||||||
|
import numpy as np
|
||||||
|
from scipy.optimize import curve_fit
|
||||||
|
import sys,os
|
||||||
|
from cfl import writecfl
|
||||||
|
|
||||||
|
os.environ['TOOLBOX_PATH'] = '/home/jpfitzer/bart-0.9.00'
|
||||||
|
os.environ['BART_TOOLBOX_PATH'] = '/home/jpfitzer/bart-0.9.00'
|
||||||
|
sys.path.append('/home/jpfitzer/bart-0.9.00/bart/python')
|
||||||
|
|
||||||
|
rawName = 'T2_CPMG.mat'
|
||||||
|
mat_data_0=sio.loadmat(rawName)
|
||||||
|
|
||||||
|
# Format: sampled, # kSpace [kRd, kPh, kSl, kSpace_echo_1, kSpace_echo_2, ..., kSpace_echo_nETL] (102400, 23)
|
||||||
|
# So the first three are the coordinates of the kspace, and the rest are the echoes
|
||||||
|
print(mat_data_0['kSpaces3D'].shape)
|
||||||
|
|
||||||
|
kSpaces3D = mat_data_0['kSpaces3D']
|
||||||
|
# self.mapVals['sampled'] = np.concatenate((kRD, kPH, kSL, dataAll_sampled), axis=1)
|
||||||
|
|
||||||
|
# nReadout, nPhase, nSlice
|
||||||
|
nPoints = (80, 80, 16)
|
||||||
|
|
||||||
|
echo_train_length = mat_data_0['kSpaces3D'].shape[1] - 3 # Because the first 3 are kRD, kPH, kSL -> should give 20
|
||||||
|
print(f"Echo train length: {echo_train_length}")
|
||||||
|
|
||||||
|
echo_spacing = mat_data_0['echoSpacing'][0][0]
|
||||||
|
print(f"Echo spacing: {echo_spacing}")
|
||||||
|
|
||||||
|
k_readout = kSpaces3D[:, 0]
|
||||||
|
k_phase = kSpaces3D[:, 1]
|
||||||
|
k_slice = kSpaces3D[:, 2]
|
||||||
|
|
||||||
|
# The rest of the data is the echoes
|
||||||
|
echos = kSpaces3D[:, 3:]
|
||||||
|
|
||||||
|
# Reshape the kspace data for bart
|
||||||
|
kSpace = echos.reshape(nPoints[2], nPoints[1], nPoints[0], echo_train_length)
|
||||||
|
|
||||||
|
|
||||||
|
|
||||||
|
print(kSpace.shape)
|
||||||
|
|
||||||
|
# cfl = writecfl('kSpace', kSpace)
|
||||||
|
|
||||||
|
# Create the image with bart fft -i 7 kSpace fft -> three dimensional
|
||||||
|
# Put the echos on the fifth dimension:
|
||||||
|
# bart transpose 3 5
|
||||||
|
# Put the slices on the correct dimension
|
||||||
|
# bart transpose 0 2
|
||||||
|
|
||||||
|
# traj = writecfl('traj', np.stack((k_readout, k_phase, k_slice), axis=1))
|
||||||
|
|
||||||
|
# Echo times with echo spacing
|
||||||
|
TE = np.linspace(echo_spacing, echo_spacing * echo_train_length, echo_train_length, endpoint=True)
|
||||||
|
print("TE: ", TE)
|
||||||
|
|
||||||
|
# Create the echotimes file:
|
||||||
|
# bart vec ... echo_times
|
||||||
|
# bart scale 0.001 echo_times echo_times_scaled
|
||||||
|
# Move the echo_times to the correct dimension:
|
||||||
|
# bart transpose 0 5 echo_times_scaled echo_times_final
|
||||||
|
|
||||||
|
# Fit the model:
|
||||||
|
# bart mobafit -T echo_times_final fft_transposed fit
|
||||||
|
|
||||||
|
# Now some values will be very large so we can apply a threshold to obtain a mask
|
||||||
|
# bart threshold -M 1000 reco/fit reco/mask
|
||||||
|
|
||||||
|
# Multiply the fit with the mask
|
||||||
|
# bart fmac reco/fit reco/fit reco/fit_mask
|
||||||
|
|
||||||
|
# Select slice
|
||||||
|
# bart slice 6 1 reco/fit_mask reco/R2_map
|
||||||
|
|
||||||
|
# Invert the data to get T2
|
||||||
|
# bart invert reco/R2_map reco/T2_map
|
Loading…
Reference in a new issue