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fourier_bkg_modl.py
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fourier_bkg_modl.py
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import numpy as np
import matplotlib
import numpy as np
from astropy.io import fits
import matplotlib.pyplot as plt
from astropy.stats import sigma_clipped_stats
from image_eval import psf_poly_fit, image_model_eval
from scipy.ndimage import gaussian_filter
def compute_marginalized_templates(n_terms, data, error, imsz=None, \
psf_fwhm=3., ridge_fac = None, ridge_fac_alpha=None,\
show=True, x_max_pivot=None, verbose=False, \
bt_siginv_b=None, bt_siginv_b_inv=None, ravel_temps=None, fourier_templates=None, \
return_temp_A_hat=False, compute_nanmask=True):
'''
NOTE -- this only works for single band at the moment. Is there a way to compute the Moore-Penrose inverse for
backgrounds observed over several bands with a fixed color prior?
also , I think that using the full noise model in the matrix product is necessary when using multiband and multi-region
evaluations. This might already be handled in the code by zeroing out NaNs.
Ridge factor is inversely proportional to fluctuation power in each mode.
Parameters
----------
n_terms : `int`.
data :
error :
imsz (optional) : `tuple` of length 2.
Default is None.
bt_siginv_b, bt_siginv_b_inv : `~np.array~` of type `float`
Default is None.
ravel_temps :
fourier_templates :
psf_fwhm : `float`.
Default is 3.
ridge_fac : `float`.
Default is None.
ridge_fac_alpha (optional) : `float`.
Default is None.
show : `bool`.
Default is True.
x_max_pivot :
Default is None.
verbose : `bool`.
Default is False.
Returns
-------
fourier_templates :
ravel_temps :
bt_siginv_b :
bt_siginv_b_inv :
mp_coeffs :
temp_A_hat :
'''
if imsz is None:
imsz = error.shape
if verbose:
print('n_terms is ', n_terms)
if ravel_temps is None:
if fourier_templates is None:
fourier_templates, meshx_idx, meshy_idx = make_fourier_templates(imsz[0], imsz[1], n_terms, psf_fwhm=psf_fwhm, x_max_pivot=x_max_pivot, return_idxs=True)
else:
meshx_idx, meshy_idx = np.meshgrid(np.arange(n_terms), np.arange(n_terms))
ravel_temps = ravel_temps_from_ndtemp(fourier_templates, n_terms)
kx_idx_rav = meshx_idx.ravel()
ky_idx_rav = meshy_idx.ravel()
im_cut_rav = data.copy().ravel()
err_cut_rav = error.copy().ravel()
if compute_nanmask:
# compress system of equations excluding any nan-valued entries
nanmask = np.logical_or((err_cut_rav ==0), np.logical_or(np.isnan(err_cut_rav), np.isnan(im_cut_rav)))
ravel_temps = ravel_temps.compress(~nanmask, axis=1)
im_cut_rav = im_cut_rav.compress(~nanmask)
err_cut_rav = err_cut_rav.compress(~nanmask)
if verbose:
print('nan values in ', np.sum(nanmask), ' of ', len(nanmask))
else:
nanmask = None
if bt_siginv_b_inv is None:
print('computing bt siginv b inv')
bt_siginv_b = np.dot(ravel_temps, np.dot(np.diag(err_cut_rav**(-2)), ravel_temps.transpose()))
assert ~np.isnan(np.linalg.cond(bt_siginv_b))
if verbose:
print('condition number of (B^T S^{-1} B)^{-1}: ', np.linalg.cond(bt_siginv_b))
if ridge_fac is not None:
if verbose:
print('adding regularization')
if ridge_fac_alpha is not None:
kmag = np.sqrt((kx_idx_rav+1)**2 + (ky_idx_rav+1)**2)/np.sqrt(2.) # sqrt of 2 is for kx=1 & ky=1, since its relative to fundamental mode
ridge_fac /= kmag**(-ridge_fac_alpha)
# print('ridge fac is now ', ridge_fac)
lambda_I = np.zeros_like(bt_siginv_b)
np.fill_diagonal(lambda_I, ridge_fac)
bt_siginv_b += lambda_I
bt_siginv_b_inv = np.linalg.inv(bt_siginv_b)
siginv_K_rav = im_cut_rav*err_cut_rav**(-2) # Sigma^-1 Y
bt_siginv_K = np.dot(ravel_temps, siginv_K_rav) # B^T Sigma^-1 Y
A_hat = np.dot(bt_siginv_b_inv, bt_siginv_K) # (B^T Sigma^-1 B^-1 + Lambda I) B^T Sigma^-1 Y
mp_coeffs = np.reshape(A_hat, (n_terms, n_terms, 4))
temp_A_hat = None
if return_temp_A_hat:
temp_A_hat = generate_template(mp_coeffs, n_terms, fourier_templates=fourier_templates, N=imsz[0], M=imsz[1], x_max_pivot=x_max_pivot)
if show:
plot_mp_fit(temp_A_hat, n_terms, A_hat, data)
return fourier_templates, ravel_temps, bt_siginv_b, bt_siginv_b_inv, mp_coeffs, temp_A_hat, nanmask
def compute_Ahat_templates(n_terms, error, imsz=None, bt_siginv_b=None, bt_siginv_b_inv=None,\
ravel_temps=None, fourier_templates=None, data=None, psf_fwhm=3., \
mean_sig=True, ridge_fac = None, show=False, inpaint_nans=True, x_max_pivot=None):
# NOTE -- this only works for single band at the moment. Is there a way to compute the Moore-Penrose inverse for
# backgrounds observed over several bands with a fixed color prior?
# also , I think that using the full noise model in the matrix product is necessary when using multiband and multi-region
# evaluations. This migth already be handled in the code by zeroing out NaNs.
if imsz is None:
imsz = error.shape
if ravel_temps is None:
if fourier_templates is None:
fourier_templates = make_fourier_templates(imsz[0], imsz[1], n_terms, psf_fwhm=psf_fwhm, x_max_pivot=x_max_pivot)
ravel_temps = ravel_temps_from_ndtemp(fourier_templates, n_terms)
err_cut_rav = error.ravel()
if bt_siginv_b_inv is None:
if mean_sig:
bt_siginv_b = np.dot(ravel_temps, ravel_temps.transpose())
else:
bt_siginv_b = np.dot(ravel_temps, np.dot(np.diag(err_cut_rav**(-2)), ravel_temps.transpose()))
print('condition number of (B^T S^{-1} B)^{-1}: ', np.linalg.cond(bt_siginv_b))
if ridge_fac is not None:
print('adding regularization')
lambda_I = np.zeros_like(bt_siginv_b)
np.fill_diagonal(lambda_I, ridge_fac)
bt_siginv_b_inv = np.linalg.inv(bt_siginv_b + lambda_I)
else:
bt_siginv_b_inv = np.linalg.inv(bt_siginv_b)
if mean_sig:
bt_siginv_b_inv *= np.nanmean(error.astype(np.float64))**2
if data is not None:
im_cut_rav = data.ravel()
if inpaint_nans:
nan_idxs = np.where(np.isnan(im_cut_rav))[0]
for nan_idx in nan_idxs:
im_cut_rav[nan_idx] = np.nanmean(im_cut_rav)
if mean_sig:
siginv_K_rav = im_cut_rav*np.nanmean(error)**(-2)
else:
siginv_K_rav = im_cut_rav*err_cut_rav**(-2)
siginv_K_rav[np.isinf(siginv_K_rav)] = 0.
bt_siginv_K = np.dot(ravel_temps, siginv_K_rav)
A_hat = np.dot(bt_siginv_b_inv, bt_siginv_K)
mp_coeffs = np.reshape(A_hat, (n_terms, n_terms, 4))
temp_A_hat = generate_template(mp_coeffs, n_terms, fourier_templates=fourier_templates, N=imsz[0], M=imsz[1], x_max_pivot=x_max_pivot)
if show:
plot_mp_fit(temp_A_hat, n_terms, A_hat, data)
return fourier_templates, ravel_temps, bt_siginv_b, bt_siginv_b_inv, mp_coeffs
return fourier_templates, ravel_temps, bt_siginv_b_inv, None
def plot_mp_fit(temp_A_hat, n_terms, A_hat, data):
plt.figure(figsize=(10,10))
plt.suptitle('Moore-Penrose inverse, $N_{FC}$='+str(n_terms), fontsize=20)
plt.subplot(2,2,1)
plt.title('Background estimate', fontsize=18)
plt.imshow(temp_A_hat, origin='lower', cmap='Greys', vmax=np.percentile(temp_A_hat, 99), vmin=np.percentile(temp_A_hat, 1))
plt.colorbar(fraction=0.046, pad=0.04)
plt.subplot(2,2,2)
plt.hist(np.abs(A_hat), bins=np.logspace(-5, 1, 30))
plt.xscale('log')
plt.xlabel('Absolute value of Fourier coefficients', fontsize=14)
plt.ylabel('N')
plt.subplot(2,2,3)
plt.title('Image', fontsize=18)
plt.imshow(data, origin='lower', cmap='Greys', vmax=np.percentile(temp_A_hat, 95), vmin=np.percentile(temp_A_hat, 5))
plt.colorbar(fraction=0.046, pad=0.04)
plt.subplot(2,2,4)
plt.title('Image - Background estimate', fontsize=18)
plt.imshow(data-temp_A_hat, origin='lower', cmap='Greys', vmax=np.percentile(temp_A_hat, 95), vmin=np.percentile(temp_A_hat, 5))
plt.colorbar(fraction=0.046, pad=0.04)
plt.tight_layout()
plt.show()
def ravel_temps_from_ndtemp(templates, n_terms, auxdim=4):
''' Faster version of previous function '''
ravel_templates_all = np.reshape(templates, (templates.shape[0], templates.shape[1], auxdim, templates.shape[-2]*templates.shape[-1]))
ravel_temps = ravel_templates_all[:n_terms, :n_terms]
ravel_temps = np.reshape(ravel_temps, (ravel_temps.shape[0]*ravel_temps.shape[1]*ravel_temps.shape[2], ravel_temps.shape[-1]))
return ravel_temps
def multiband_fourier_templates(imszs, n_terms, show_templates=False, psf_fwhms=None, x_max_pivot_list=None, scale_fac=None):
'''
Given a list of image and beam sizes, produces multiband fourier templates for background modeling.
Parameters
----------
imszs : list of lists
List containing image dimensions for each of the three observations
n_terms : int
Order of Fourier expansion for templates. the number of templates (currently) scales as 2*n_terms^2
show_templates : bool, optional
if True, plots the array of templates. Default is False.
psf_fwhms : list, optional
List of beam sizes across observations. If left unspecified, all PSFs assumed to have 3 pixel FWHM.
Default is 'None'.
Returns
-------
all_templates : list of `numpy.ndarray's
The set of Fourier templates for each observation.
'''
all_templates = []
for b in range(len(imszs)):
if psf_fwhms is None:
psf_fwhm = None
else:
psf_fwhm = psf_fwhms[b]
x_max_pivot = None
if x_max_pivot_list is not None:
x_max_pivot = x_max_pivot_list[b]
all_templates.append(make_fourier_templates(imszs[b][0], imszs[b][1], n_terms, show_templates=show_templates, psf_fwhm=psf_fwhm, x_max_pivot=x_max_pivot, scale_fac=scale_fac))
return all_templates
def make_fourier_templates(N, M, n_terms, show_templates=False, psf_fwhm=None, shift=False, x_max_pivot=None, scale_fac=None, return_idxs=False):
'''
Given image dimensions and order of the series expansion, generates a set of 2D fourier templates.
Parameters
----------
N : int
length of image
M : int
width of image
n_terms : int
Order of Fourier expansion for templates. the number of templates (currently) scales as 2*n_terms^2
show_templates : bool, optional
if True, plots the array of templates. Default is False.
psf_fwhm : float, optional
Observation PSF full width at half maximum (FWHM). This can be used to pre-convolve templates for background modeling
Default is 'None'.
x_max_pivot : float, optional
Indicating pixel coordinate for boundary of FOV in each dimension. Default is 'None'.
return_idxs : bool, optional
If True, returns mesh grids of Fourier component indices for x and y.
Default is False.
Returns
-------
templates : `numpy.ndarray' of shape (n_terms, n_terms, 4, N, M)
Contains 2D Fourier templates for truncated series
'''
templates = np.zeros((n_terms, n_terms, 4, N, M))
if scale_fac is None:
scale_fac = 1.
x = np.arange(N)
y = np.arange(M)
meshkx, meshky = np.meshgrid(np.arange(n_terms), np.arange(n_terms))
meshx, meshy = np.meshgrid(x, y)
xtemps_cos = np.zeros((n_terms, N, M))
ytemps_cos = np.zeros((n_terms, N, M))
xtemps_sin = np.zeros((n_terms, N, M))
ytemps_sin = np.zeros((n_terms, N, M))
N_denom = N
M_denom = M
if x_max_pivot is not None:
N_denom = x_max_pivot
M_denom = x_max_pivot
for n in range(n_terms):
# modified series
if shift:
xtemps_sin[n] = np.sin((n+1-0.5)*np.pi*meshx/N_denom)
ytemps_sin[n] = np.sin((n+1-0.5)*np.pi*meshy/M_denom)
else:
xtemps_sin[n] = np.sin((n+1)*np.pi*meshx/N_denom)
ytemps_sin[n] = np.sin((n+1)*np.pi*meshy/M_denom)
xtemps_cos[n] = np.cos((n+1)*np.pi*meshx/N_denom)
ytemps_cos[n] = np.cos((n+1)*np.pi*meshy/M_denom)
for i in range(n_terms):
for j in range(n_terms):
if psf_fwhm is not None: # if beam size given, convolve with PSF assumed to be Gaussian
templates[i,j,0,:,:] = gaussian_filter(xtemps_sin[i]*ytemps_sin[j], sigma=psf_fwhm/2.355)
templates[i,j,1,:,:] = gaussian_filter(xtemps_sin[i]*ytemps_cos[j], sigma=psf_fwhm/2.355)
templates[i,j,2,:,:] = gaussian_filter(xtemps_cos[i]*ytemps_sin[j], sigma=psf_fwhm/2.355)
templates[i,j,3,:,:] = gaussian_filter(xtemps_cos[i]*ytemps_cos[j], sigma=psf_fwhm/2.355)
else:
templates[i,j,0,:,:] = xtemps_sin[i]*ytemps_sin[j]
templates[i,j,1,:,:] = xtemps_sin[i]*ytemps_cos[j]
templates[i,j,2,:,:] = xtemps_cos[i]*ytemps_sin[j]
templates[i,j,3,:,:] = xtemps_cos[i]*ytemps_cos[j]
templates *= scale_fac
if show_templates:
for k in range(4):
counter = 1
plt.figure(figsize=(8,8))
for i in range(n_terms):
for j in range(n_terms):
plt.subplot(n_terms, n_terms, counter)
plt.title('i = '+ str(i)+', j = '+str(j))
plt.imshow(templates[i,j,k,:,:])
counter +=1
plt.tight_layout()
plt.show()
if return_idxs:
return templates, meshkx, meshky
return templates
def generate_template(fourier_coeffs, n_terms, fourier_templates=None, imsz=None, N=None, M=None, psf_fwhm=None, x_max_pivot=None):
'''
Given a set of coefficients and Fourier templates, computes their dot product.
Parameters
----------
fourier_coeffs : `~numpy.ndarray' of shape (n_terms, n_terms, 2)
Coefficients of truncated Fourier expansion.
n_terms : int
Order of Fourier expansion to compute sum over. This is left explicit as an input
in case one wants the flexibility of calling it for different numbers of terms, even
if the underlying truncated series has more terms.
fourier_templates : `~numpy.ndarray' of shape (n_terms, n_terms, 2, N, M), optional
Contains 2D Fourier templates for truncated series. If left unspecified, a set of Fourier templates is generated
on the fly. Default is 'None'.
N : int, optional
length of image. Default is 'None'.
M : int
width of image. Default is 'None.'
psf_fwhm : float, optional
Observation PSF full width at half maximum (FWHM). This can be used to pre-convolve templates for background modeling
Default is 'None'.
x_max_pivot : float, optional
Because of different image resolution across bands and the use of multiple region proposals, the non pivot band images may cover a larger
field of view than the pivot band image. When modeling structured emission across several bands, it is important that the Fourier components
model a consistent field of view. Extra pixels in the non-pivot bands do not contribute to the log-likelihood, so I think the solution is to
compute the Fourier templates where the period is based on the WCS transformations across bands, which can translate coordinates bounding
the pivot image to coordinates in the non-pivot band images.
Default is 'None'.
Returns
-------
sum_temp : `~numpy.ndarray' of shape (N, M)
The summed template.
'''
if imsz is None and N is None and M is None:
if fourier_templates is not None:
imsz = [fourier_templates.shape[-2], fourier_templates.shape[-1]]
else:
print('need to provide input dimensions through either imsz or (N, M)')
return None
if imsz is None:
imsz = [N,M]
if fourier_templates is None:
fourier_templates = make_fourier_templates(imsz[0], imsz[1], n_terms, psf_fwhm=psf_fwhm, x_max_pivot=x_max_pivot)
sum_temp = np.sum([fourier_coeffs[i,j,k]*fourier_templates[i,j,k] for i in range(n_terms) for j in range(n_terms) for k in range(fourier_coeffs.shape[-1])], axis=0)
return sum_temp
def fit_coeffs_to_observed_comb(observed_comb, obs_noise_sig,ftemplates, true_fcoeffs = None, true_comb=None, n_terms=None, sig_dtemp=0.1, niter=100, init_nsig=1.):
if true_fcoeffs is not None:
init_fcoeffs = np.random.normal(0, obs_noise_sig, size=(true_fcoeffs.shape[0], true_fcoeffs.shape[1], 4))
n_terms = init_fcoeffs.shape[0]
elif n_terms is not None:
init_fcoeffs = np.random.normal(0, obs_noise_sig, size=(n_terms, n_terms, 4))
running_fcoeffs = init_fcoeffs.copy()
all_running_fcoeffs = np.zeros((niter//1000, n_terms, n_terms, 4))
temper_schedule = np.logspace(np.log10(init_nsig), np.log10(1.), niter)
print('temper schedule: ', temper_schedule)
print(init_fcoeffs.shape, n_terms, ftemplates.shape)
lazy_temp = generate_template(init_fcoeffs, n_terms, ftemplates)
running_temp = lazy_temp.copy()
lnLs = np.zeros((niter,))
lnL = -0.5*np.sum((1./obs_noise_sig**2)*(observed_comb - running_temp)*(observed_comb-running_temp))
lnLs[0] = lnL
accepts= np.zeros((niter,))
perts = np.random.normal(0, sig_dtemp, niter)
nsamp = 0
for n in range(niter):
sig_dtemp_it = temper_schedule[n]*sig_dtemp
idxk = np.random.randint(0, 2)
idx0, idx1 = np.random.randint(0, n_terms), np.random.randint(0, n_terms)
prop_dtemp = ftemplates[idx0,idx1,idxk,:,:]*perts[n]
plogL = -0.5*np.sum((1./obs_noise_sig**2)*(observed_comb - running_temp - prop_dtemp)*(observed_comb-running_temp - prop_dtemp))
dlogP = plogL - lnL
accept_or_not = (np.log(np.random.uniform()) < dlogP)
accepts[n] = int(accept_or_not)
if accept_or_not:
running_temp += prop_dtemp
running_fcoeffs[idx0, idx1, idxk] += perts[n]
lnLs[n] = plogL
lnL = plogL
else:
lnLs[n] = lnL
if n%5000==0:
print('n = ', n)
if n%1000==0:
all_running_fcoeffs[nsamp,:,:,:] = running_fcoeffs
nsamp += 1
if n%(niter//10)==0:
plt.figure(figsize=(16, 4))
plt.suptitle('n = '+str(n), fontsize=20, y=1.02)
plt.subplot(1,4,3)
plt.title('model', fontsize=16)
plt.imshow(running_temp)
plt.colorbar()
plt.subplot(1,4,2)
plt.title('observed', fontsize=16)
plt.imshow(observed_comb)
plt.colorbar()
plt.subplot(1,4,1)
if true_comb is not None:
plt.title('truth')
plt.imshow(true_comb - np.mean(true_comb))
else:
plt.title('observed - model')
plt.imshow(observed_comb-running_temp)
plt.colorbar()
plt.subplot(1,4,4)
plt.title('$\\delta b(x,y)/\\sigma(x,y)$', fontsize=16)
if true_comb is not None:
resid = (observed_comb - running_temp)/obs_noise_sig
plt.imshow(resid, vmin=np.percentile(resid, 5), vmax=np.percentile(resid, 95))
plt.colorbar()
plt.tight_layout()
plt.show()
print(np.mean(accepts))
def plot_logL(lnlz, N=100, M=100):
plt.figure(figsize=(8, 5))
plt.plot(np.arange(len(lnlz)), -2*lnlz, label='Chain min $\\chi_{red.}^2 = $'+str(np.round(np.min(-2*lnlz)/(N*M), 2)))
plt.axhline(N*M, linestyle='dashed', label='$\\chi_{red.}^2 = 1$')
plt.legend(fontsize=14)
plt.yscale('log')
plt.ylabel('$-2\\ln\\mathcal{L}$', fontsize=18)
plt.xlabel('Sample iteration', fontsize=18)
plt.tight_layout()
plt.show()
def plot_mp_fit(temp_A_hat, n_terms, A_hat, data):
''' plot comparing data before and after FC marginalization step '''
plt.figure(figsize=(10,10))
plt.suptitle('Moore-Penrose inverse, $N_{FC}$='+str(n_terms), fontsize=20, y=1.02)
plt.subplot(2,2,1)
plt.title('Background estimate', fontsize=18)
plt.imshow(temp_A_hat, origin='lower', cmap='Greys', vmax=np.percentile(temp_A_hat, 99), vmin=np.percentile(temp_A_hat, 1))
plt.colorbar(fraction=0.046, pad=0.04)
plt.subplot(2,2,2)
plt.hist(np.abs(A_hat), bins=np.logspace(-5, 1, 30))
plt.xscale('log')
plt.xlabel('Absolute value of Fourier coefficients', fontsize=14)
plt.ylabel('N')
plt.subplot(2,2,3)
plt.title('Image', fontsize=18)
plt.imshow(data, origin='lower', cmap='Greys', vmax=np.percentile(temp_A_hat, 95), vmin=np.percentile(temp_A_hat, 5))
plt.colorbar(fraction=0.046, pad=0.04)
plt.subplot(2,2,4)
plt.title('Image - Background estimate', fontsize=18)
plt.imshow(data-temp_A_hat, origin='lower', cmap='Greys', vmax=np.percentile(data-temp_A_hat, 95), vmin=np.percentile(data-temp_A_hat, 5))
plt.colorbar(fraction=0.046, pad=0.04)
plt.tight_layout()
plt.show()
def compute_BT_B(n_terms, M, auxdim=4):
# this is supposed to be for computing the analytic covariance matrix of the fourier components, don't think it works, don't bother
bt_b = np.zeros((auxdim*n_terms**2, auxdim*n_terms**2))
for i_d in range(n_terms):
for j_d in range(n_terms):
for k_d in range(auxdim):
for i in range(n_terms):
for j in range(n_terms):
for k in range(auxdim):
term1 = 0.
term2 = 0.
if i==i_d:
if (k==0 and k_d==1) or (k==1 and k_d==0) or (k==2 and k_d==3) or (k==3 and k_d==2) or (k==0 and k_d==0) or (k==1 and k_d==1) or (k==2 and k_d==2) or (k==3 and k_d==3):
term1 = M/2.
else:
if (k==0 and k_d==2) or (k==0 and k_d==3) or (k==1 and k_d==2) or (k==1 and k_d==3) or (k==2 and k_d==0) or (k==2 and k_d==1) or (k==3 and k_d==0) or (k==3 and k_d==1):
term1 = (M/np.pi)*((1/(2*(i-i_d)))*(1-np.cos(np.pi*(i-i_d))) +(1/(2*(i+i_d+2.)))*(1-np.cos(np.pi*(i+i_d))))
if j==j_d:
if (k==0 and k_d==2) or (k==1 and k_d==3) or (k==2 and k_d==0) or (k==3 and k_d==1):
term2 = M/2.
elif (k==0 and k_d==0) or (k==1 and k_d==1) or (k==2 and k_d==2) or (k==3 and k_d==3):
term2 = M/2.
else:
if (k==0 and k_d==1) or (k==0 and k_d==3) or (k==1 and k_d==0) or (k==1 and k_d==2) or (k==2 and k_d==1) or (k==2 and k_d==3) or (k==3 and k_d==0) or (k==3 and k_d==2):
term2 = (M/np.pi)*((1./(2.*(j-j_d)))*(1.-np.cos(np.pi*(j-j_d))) +(1./(2.*(j+j_d+2.)))*(1.-np.cos(np.pi*(j+j_d))))
bt_b[i_d*j_d*auxdim + j_d*auxdim + k_d, i*j*auxdim + j*auxdim + k] = term1*term2
return bt_b