adjnuf_ob = adjnuf_ob.to(gpu)
coilimages = torch.zeros((1, nch, 2, nx, nx))
# A=lambda x: nuf_ob(x,ktrajT)
# At=lambda x:adjnuf_ob(x,ktrajT)
# AtA=lambda x:At(A(x))
for i in range(nch):
coilimages[:, i] = adjnuf_ob(kdata_ch[:, i].unsqueeze(1),
ktrajT_ch)
#ini=torch.zeros_like(temp)
#coilimages[:,i]=sf.pt_cg(AtA,temp,ini,50,1e-15)
X = coilimages.cpu().numpy()
x = X[:, :, 0] + X[:, :, 1] * 1j
x = np.transpose(x, (2, 3, 0, 1))
x_f = fft(x, (0, 1, 2))
csmTrn = espirit(x_f, 6, 24, 0.03, 0.9925)
csm = csmTrn[:, :, 0, :, 0]
csm = np.transpose(csm, (2, 0, 1))
smap = np.stack((np.real(csm), np.imag(csm)), axis=1)
smap = np.tile(smap, (nbasis, 1, 1, 1, 1))
smapT = torch.tensor(smap).to(dtype)
smapT = smapT.to(gpu)
del kdata_ch, coilimages
#%%
adjnufft_ob = AdjMriSenseNufft(im_size=im_size, smap=smapT).to(dtype)
adjnufft_ob = adjnufft_ob.to(gpu)
def __init__(self, params):
self.params = params
dtype = params['dtype']
gpu = torch.device(params['device'])
self.gpu = gpu
# Reading h data from mat file
#----------------------------------------------
if (params['filename'][-3:-1] == 'ma'): # mat file
fnamepickle = params['filename'].replace('.mat', '.pickle')
if (not (path.exists(fnamepickle))):
data_dict = mat73.loadmat(params['filename'])
kdata = data_dict['kdata']
ktraj = np.asarray(data_dict['k'])
dcf = np.asarray(data_dict['dcf'])
# save with pickle for fast reading
with open(fnamepickle, 'wb') as f:
pickle.dump([kdata, ktraj, dcf], f, protocol=4)
else:
with open(fnamepickle, 'rb') as f:
[kdata, ktraj, dcf] = pickle.load(f)
else: # read pickle file
fname = params['filename']
with open(fname, 'rb') as f:
[kdata, ktraj, dcf] = pickle.load(f)
#Reshaping the variables
#----------------------------------------------
kdata = np.squeeze(kdata[:, :, :, params['slice']])
kdata = kdata.astype(np.complex64)
ktraj = ktraj.astype(np.complex64)
kdata = np.transpose(kdata, (1, 2, 0))
dcf = np.transpose(dcf, (1, 0))
ktraj = np.transpose(ktraj, (1, 0))
# Reducing the image size if factor < 1
#----------------------------------------------
im_size = np.int_(np.divide(params["im_size"], params["factor"]))
self.im_size = im_size
# ktrajsq = np.max(np.abs(ktraj),axis=0)
# indices = np.squeeze(np.argwhere(ktrajsq< 0.5/params['factor']))
# ktraj = ktraj[:,indices]*params['factor']
# kdata = kdata[:,:,indices]
# dcf = dcf[:,indices]
ktraj = np.squeeze(ktraj) * 2 * np.pi
nintlvs = np.size(kdata, 1)
nintlvsToDelete = 240
nintlvsLeft = nintlvs - nintlvsToDelete
self.nintlvs = nintlvsLeft
#CoilCombination
#----------------------------------------------
nch = np.size(kdata, 0)
nkpts = np.size(kdata, 2)
self.nkpts = nkpts
kdata = kdata[:, nintlvsToDelete:nintlvs, :]
ktraj = ktraj[nintlvsToDelete:nintlvs, :]
dcf = dcf[nintlvsToDelete:nintlvs, :]
kdataSingleFrame = np.reshape(kdata, (nch, nintlvsLeft * nkpts))
ktrajSingleFrame = np.reshape(ktraj, (1, nintlvsLeft * nkpts))
# Coil combine
#----------------------------------------------
thres = 0.95
Rs = np.real(
kdataSingleFrame @ np.transpose(np.conj(kdataSingleFrame)))
[w, v] = np.linalg.eig(Rs)
ind = np.flipud(np.argsort(w))
# ind=np.argsort(w)
w = w[ind]
v = v[:, ind]
w = w / sum(w)
w = np.cumsum(w)
nvch = np.min(np.where(w > thres))
kdataSingleFrame = np.transpose(v[:, 0:nvch]) @ kdataSingleFrame
nch = kdataSingleFrame[:, 0].size
self.nch = nch
# Estimating coil images and coil senstivity maps
#----------------------------------------------
ktrajSingleFrame = np.stack(
(np.real(ktrajSingleFrame), np.imag(ktrajSingleFrame)), axis=1)
dcfSingleFrame = np.reshape(dcf, (1, nintlvsLeft * nkpts))
kdataSingleFrameUW = kdataSingleFrame
kdataSingleFrame = kdataSingleFrame * dcfSingleFrame[None, :]
kdataSingleFrame = np.stack(
(np.real(kdataSingleFrame), np.imag(kdataSingleFrame)), axis=2)
kdataSingleFrameUW = np.stack(
(np.real(kdataSingleFrameUW), np.imag(kdataSingleFrameUW)), axis=1)
kdataSingleFrameUW = np.expand_dims(kdataSingleFrameUW, axis=0)
nintlPerFrame = params['nintlPerFrame']
Nframes = np.int(nintlvsLeft / nintlPerFrame)
if (Nframes > params['nFramesDesired']):
Nframes = params['nFramesDesired']
# startval = Nframes*nintlPerFrame*nkpts
#endval = Nframes*nintlPerFrame*nkpts
# startval = 20*nintlPerFrame*nkpts
endval = Nframes * nintlPerFrame * nkpts
self.kdataSingleFrameUW = kdataSingleFrameUW
self.ktrajSingleFrame = ktrajSingleFrame
self.dcfSingleFrame = dcfSingleFrame
# Omitting two initial frames
kdata = np.reshape(kdataSingleFrameUW[:, :, :, 0:endval],
(1, nch, 2, Nframes, nintlPerFrame * nkpts))
ktraj = np.reshape(ktrajSingleFrame[:, :, 0:endval],
(1, 2, Nframes, nintlPerFrame * nkpts))
dcf = np.reshape(dcfSingleFrame[:, 0:endval],
(Nframes, 1, 1, nintlPerFrame * nkpts))
# kdata = np.reshape(kdataSingleFrameUW[:,:,:,-startval-1:-1],(1,nch,2,Nframes,nintlPerFrame*nkpts))
# ktraj = np.reshape(ktrajSingleFrame[:,:,-startval-1:-1],(1,2,Nframes,nintlPerFrame*nkpts))
# dcf = np.reshape(dcfSingleFrame[:,-startval-1:-1],(Nframes,1,1,nintlPerFrame*nkpts))
kdata = np.transpose(kdata, (3, 1, 2, 4, 0))
ktraj = np.transpose(ktraj, (2, 1, 3, 0))
dcf = dcf / nintlPerFrame / nintlPerFrame
kdataSingleFrame = torch.tensor(kdataSingleFrame).to(dtype)
ktrajSingleFrame = torch.tensor(ktrajSingleFrame).to(dtype)
# convert them to gpu
kdataSingleFrame = kdataSingleFrame.to(gpu)
ktrajSingleFrame = ktrajSingleFrame.to(gpu)
adjnuf_ob = AdjKbNufft(im_size=im_size).to(dtype)
adjnuf_ob = adjnuf_ob.to(gpu)
#nuf_ob = KbNufft(im_size=im_size).to(dtype)
#nuf_ob=nuf_ob.to(gpu)
coilimages = torch.zeros((1, nch, 2, im_size[0], im_size[1]))
for i in range(nch):
coilimages[:, i, ...] = adjnuf_ob(
kdataSingleFrame[:, i, :, :].unsqueeze(1), ktrajSingleFrame)
X = coilimages.cpu().numpy()
X = X[:, :, 0, ...] + X[:, :, 1, ...] * 1j
X = np.transpose(X, (2, 3, 0, 1))
# ESPIRI
x_f = fft(X, (0, 1))
csmTrn = espirit(x_f, 6, 24, 0.04, 0.8925)
csm = csmTrn[:, :, 0, :, 0]
csm = np.transpose(csm, (2, 0, 1))
smap = np.stack((np.real(csm), np.imag(csm)), axis=1)
smapT = torch.tensor(smap).to(dtype)
smapT = smapT.unsqueeze(0)
smapT = smapT.to(gpu)
ktrajSingleFrame = 1
kdataSingleFrame = 1
coilimages = 1
dcfSingleFrame = 1
adjnuf_ob = 1
# convert them to gpu
kdata = torch.tensor(kdata).to(dtype).squeeze(4)
ktraj = torch.tensor(ktraj).to(dtype).squeeze(3)
dcf = torch.tensor(dcf).to(dtype)
kdata = kdata.to(gpu)
ktraj = ktraj.to(gpu)
dcf = dcf.to(gpu)
#dcomp = dcomp_calc.calculate_radial_dcomp_pytorch(nufft_ob, adjnufft_ob, ktraj)
self.smap = smap
smap = np.tile(np.expand_dims(smap, axis=0), [Nframes, 1, 1, 1, 1])
smapT = torch.tensor(smap).to(dtype)
smapT = smapT.to(gpu)
nufft_ob = MriSenseNufft(im_size=tuple(im_size), smap=smapT).to(dtype)
nufft_ob = nufft_ob.to(gpu)
adjnufft_ob = AdjMriSenseNufft(im_size=tuple(im_size),
smap=smapT).to(dtype)
adjnufft_ob = adjnufft_ob.to(gpu)
self.toep_ob = ToepSenseNufft(smap=smapT)
Atb = adjnufft_ob(kdata * dcf, ktraj)
maxvalue = Atb.max()
Atb = Atb / maxvalue / 2
self.toep_ob = self.toep_ob.to(gpu)
self.dcomp_kern = calc_toep_kernel(
adjnufft_ob, ktraj, weights=dcf) # with density compensation
self.Atb = Atb
temp = self.toep_ob(self.Atb, self.dcomp_kern)
maxvalue = temp.max()
self.dcomp_kern = self.dcomp_kern / maxvalue
self.dcomp_kern.cpu()
self.toep_ob = self.toep_ob.cpu()
self.Atb.cpu()
self.mask = self.Atb.squeeze(1).abs() == 0.00
