Exemplo n.º 1
0
def ica(mock, ell=0, rebin=None): 
    ''' *** TESTED *** 
    Test that the ICA works!
    '''
    Pk = NG.dataX(mock, ell=ell, rebin=rebin)
    X, _ = NG.meansub(Pk)
    X_w, W = NG.whiten(X) # whitened data
    X_ica, W = NG.Ica(X_w)
    
    # compare covariance? 
    C_X = np.cov(X.T)
    C_Xica = np.cov(X_ica.T) 

    prettyplot()
    fig = plt.figure(figsize=(20, 8))
    sub = fig.add_subplot(121)
    im = sub.imshow(np.log10(C_X), interpolation='none')
    sub.set_title('log(Cov.) of Data')
    fig.colorbar(im, ax=sub) 

    sub = fig.add_subplot(122)
    im = sub.imshow(C_Xica, interpolation='none')
    fig.colorbar(im, ax=sub) 
    sub.set_title('Cov. of ICA transformed Data')
    # save fig
    if rebin is None: 
        f = ''.join([UT.fig_dir(), 'tests/test.ICAcov.', mock, '.ell', str(ell), '.png'])
    else: 
        f = ''.join([UT.fig_dir(), 'tests/test.ICAcov.', mock, '.ell', str(ell), '.rebin', str(rebin), '.png'])
    fig.savefig(f, bbox_inches='tight') 
    return None
Exemplo n.º 2
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def whiten(mock, ell=0, rebin=None, krange=None, method='choletsky'): 
    ''' ***TESTED: Choletsky decomposition fails for full binned Nseries
    P(k) because the precision matrix estimate is not positive definite***
    test the data whitening. 
    '''
    Pk = NG.dataX(mock, ell=ell, rebin=rebin, krange=krange)
    X, _ = NG.meansub(Pk)
    X_w, W = NG.whiten(X, method=method) # whitened data
    
    prettyplot()
    fig = plt.figure(figsize=(15,7))
    sub = fig.add_subplot(121)
    for i in range(X.shape[1]): 
        sub.plot(range(X_w.shape[0]), X_w[:,i])
    
    sub.set_xlim([0, X.shape[0]]) 
    sub.set_xlabel('$\mathtt{k}$ bins', fontsize=25)
    sub.set_ylim([-7., 7.])
    sub.set_ylabel('$\mathtt{W^{T} (P^i_'+str(ell)+'- \overline{P_'+str(ell)+'})}$', fontsize=25)
    
    C_Xw = np.cov(X_w.T)
    sub = fig.add_subplot(122)
    im = sub.imshow(C_Xw, interpolation='none')
    fig.colorbar(im, ax=sub) 
    
    if rebin is None: 
        f = ''.join([UT.fig_dir(), 'tests/test.whiten.', method, '.', mock, '.ell', str(ell), '.png'])
    else: 
        f = ''.join([UT.fig_dir(), 'tests/test.whiten.', method, '.', mock, '.ell', str(ell), '.rebin', str(rebin), '.png'])
    fig.savefig(f, bbox_inches='tight') 
    return None 
Exemplo n.º 3
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def whiten_recon(mock, ell=0, rebin=None, krange=None, method='choletsky'): 
    ''' ***TESTED: The whitening matrices reconstruct the P(k)s*** 
    Test whether P(k) can be reconstructed using the whitening matrix  
    '''
    Pk, k = NG.dataX(mock, ell=ell, rebin=rebin, krange=krange, k_arr=True)
    X, mu_X = NG.meansub(Pk)
    X_w, W = NG.whiten(X, method=method) # whitened data
    
    prettyplot()
    fig = plt.figure(figsize=(15,7))
    sub = fig.add_subplot(121)
    for i in range(X.shape[0]): 
        sub.plot(k, Pk[i,:])
    if krange is None: 
        sub.set_xlim([1e-3, 0.5])
    else: 
        sub.set_xlim(krange)
    sub.set_xscale('log')
    sub.set_xlabel('$\mathtt{k}$', fontsize=25)
    sub.set_yscale('log') 
    sub.set_ylim([2e3, 2.5e5])
    
    np.random.seed(7)
    sub = fig.add_subplot(122)
    for i in range(X.shape[0]): 
        X_noise = np.random.normal(size=X_w.shape[1])
        X_rec = np.linalg.solve(W.T, X_noise.T)
        sub.plot(k, X_rec.T + mu_X)
    if krange is None: 
        sub.set_xlim([1e-3, 0.5])
    else: 
        sub.set_xlim(krange)
    sub.set_xscale('log')
    sub.set_xlabel('$\mathtt{k}$', fontsize=25)
    sub.set_yscale('log') 
    sub.set_ylim([2e3, 2.5e5])

    if rebin is None: 
        f = ''.join([UT.fig_dir(), 'tests/test.whiten_recon.', method, '.', mock, '.ell', str(ell), '.png'])
    else: 
        f = ''.join([UT.fig_dir(), 'tests/test.whiten_recon.', method, '.', mock, '.ell', str(ell), '.rebin', str(rebin), '.png'])
    fig.savefig(f, bbox_inches='tight') 
    return None 
Exemplo n.º 4
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def p_Xw_i_MISE(mock, ell=0, rebin=None, krange=None, method='choletsky', b=0.1):
    ''' Examine the pdf of X_w^i components that deviate significantly from  
    N(0,1) based on MISE 
    '''
    Pk = NG.dataX(mock, ell=ell, rebin=rebin, krange=krange)
    X, _ = NG.meansub(Pk)
    X_w, W = NG.whiten(X, method=method) # whitened data
    
    # calculate the chi-squared values of each p(X_w^i)  
    x = np.arange(-5., 5.1, 0.1)
    mise = np.zeros(X_w.shape[1])
    for i_bin in range(X_w.shape[1]): 
        mise[i_bin] = NG.MISE(X_w[:,i_bin], b=b) 

    # plot the most discrepant components. 
    prettyplot()
    fig = plt.figure()
    sub = fig.add_subplot(111)
    i_sort = np.argsort(mise)
    print 'outlier bins = ', i_sort[-5:]
    print 'mise = ', mise[i_sort[-5:]]

    nbin = int(10./b)
    for i_bin in i_sort[-10:]: 
        hb_Xi, Xi_edges = np.histogram(X_w[:,i_bin], bins=nbin, range=[-5., 5.], normed=True) 
        p_X_w_arr = UT.bar_plot(Xi_edges, hb_Xi)
        sub.plot(p_X_w_arr[0], p_X_w_arr[1])

    sub.plot(x, UT.gauss(x, 1., 0.), c='k', lw=3, label='$\mathcal{N}(0,1)$')
    sub.set_xlim([-2.5, 2.5])
    sub.set_xlabel('$\mathtt{X^{i}_{W}}$', fontsize=25) 
    sub.set_ylim([0., 0.6])
    sub.set_ylabel('$\mathtt{P(X^{i}_{W})}$', fontsize=25) 
    sub.legend(loc='upper right') 
    
    str_rebin = ''
    if rebin is not None: 
        str_rebin = '.rebin'+str(rebin)

    f = ''.join([UT.fig_dir(), 'tests/test.p_Xw_i_outlier.', method, '.', mock, '.ell', str(ell), 
        str_rebin, '.b', str(b), '.png'])
    fig.savefig(f, bbox_inches='tight') 
    return None
Exemplo n.º 5
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def p_Xw_i_outlier(mock, ell=0, rebin=None, krange=None, method='choletsky'):
    ''' Examine the pdf of X_w^i components that deviate significantly from  
    N(0,1) 
    '''
    Pk = NG.dataX(mock, ell=ell, rebin=rebin, krange=krange)
    X, _ = NG.meansub(Pk)
    X_w, W = NG.whiten(X, method=method) # whitened data
    
    # calculate the chi-squared values of each p(X_w^i)  
    x = np.arange(-5., 5.1, 0.1)
    chi2 = np.zeros(X_w.shape[1])
    for i_bin in range(X_w.shape[1]): 
        kern = gkde(X_w[:,i_bin]) # gaussian KDE kernel using "rule of thumb" scott's rule. 
        chi2[i_bin] = np.sum((UT.gauss(x, 1., 0.) - kern.evaluate(x))**2)/np.float(len(x))
    
    # plot the most discrepant components. 
    prettyplot()
    fig = plt.figure()
    sub = fig.add_subplot(111)
    i_sort = np.argsort(chi2)
    print 'outlier bins = ', i_sort[-5:]
    for i_bin in i_sort[-10:]: 
        kern = gkde(X_w[:,i_bin]) # gaussian KDE kernel using "rule of thumb" scott's rule. 
        sub.plot(x, kern.evaluate(x))
    sub.plot(x, UT.gauss(x, 1., 0.), c='k', lw=3, label='$\mathcal{N}(0,1)$')
    sub.set_xlim([-2.5, 2.5])
    sub.set_xlabel('$\mathtt{X^{i}_{W}}$', fontsize=25) 
    sub.set_ylim([0., 0.6])
    sub.set_ylabel('$\mathtt{P(X^{i}_{W})}$', fontsize=25) 
    sub.legend(loc='upper right') 
    
    if rebin is None: 
        f = ''.join([UT.fig_dir(), 'tests/test.p_Xw_i_outlier.', method, '.', mock, '.ell', str(ell), '.png'])
    else: 
        f = ''.join([UT.fig_dir(), 'tests/test.p_Xw_i_outlier.', method, '.', mock, '.ell', str(ell), '.rebin', str(rebin), '.png'])
    fig.savefig(f, bbox_inches='tight') 
    return None
Exemplo n.º 6
0
def p_Xw_i(mock, ell=0, rebin=None, krange=None, ica=False, pca=False): 
    ''' Test the probability distribution function of each X_w^i
    component -- p(X_w^i). First compare the histograms of p(X_w^i) 
    with N(0,1). Then compare the gaussian KDE of p(X_w^i).
    '''
    Pk = NG.dataX(mock, ell=ell, rebin=rebin, krange=krange)
    X, _ = NG.meansub(Pk)
    str_w = 'W'
    if ica and pca: 
        raise ValueError
    if ica: # ICA components
        # ICA components do not need to be Gaussian.
        # in fact the whole point of the ICA transform
        # is to capture the non-Gaussianity...
        X_white, _ = NG.whiten(X) # whitened data
        X_w, _ = NG.Ica(X_white) 
        str_w = 'ICA'
    if pca: # PCA components
        X_w, _ = NG.whiten(X, method='pca') # whitened data
        str_w = 'PCA'
    if not ica and not pca: # just whitened 
        X_w, W = NG.whiten(X) # whitened data
    
    # p(X_w^i) histograms
    fig = plt.figure(figsize=(15,7))
    sub = fig.add_subplot(121)
    for i_bin in range(X_w.shape[1]): 
        p_X_w, edges = np.histogram(X_w[:,i_bin], normed=True)
        p_X_w_arr = UT.bar_plot(edges, p_X_w)
        sub.plot(p_X_w_arr[0], p_X_w_arr[1])
    x = np.arange(-5., 5.1, 0.1)
    sub.plot(x, UT.gauss(x, 1., 0.), c='k', lw=3, label='$\mathcal{N}(0,1)$')
    sub.set_xlim([-2.5, 2.5])
    sub.set_xlabel('$\mathtt{X_{'+str_w+'}}$', fontsize=25) 
    sub.set_ylim([0., 0.6])
    sub.set_ylabel('$\mathtt{P(X_{'+str_w+'})}$', fontsize=25) 
    sub.legend(loc='upper right') 

    # p(X_w^i) gaussian KDE fits  
    pdfs = NG.p_Xw_i(X_w, range(X_w.shape[1]), x=x)

    sub = fig.add_subplot(122)
    for i_bin in range(X_w.shape[1]): 
        sub.plot(x, pdfs[i_bin])
    sub.plot(x, UT.gauss(x, 1., 0.), c='k', lw=3, label='$\mathcal{N}(0,1)$')
    sub.set_xlim([-2.5, 2.5])
    sub.set_xlabel('$\mathtt{X_{W}}$', fontsize=25) 
    sub.set_ylim([0., 0.6])
    sub.set_ylabel('$\mathtt{P(X_{W})}$', fontsize=25) 
    sub.legend(loc='upper right') 

    str_ica, str_pca = '', ''
    if ica: 
        str_ica = '.ICA'
    if pca: 
        str_pca = '.PCA'

    if rebin is None: 
        f = ''.join([UT.fig_dir(), 'tests/test.p_Xw_i', str_pca, str_ica, '.', mock, '.ell', str(ell), '.png'])
    else: 
        f = ''.join([UT.fig_dir(), 'tests/test.p_Xw_i', str_pca, str_ica, '.', mock, '.ell', str(ell), '.rebin', str(rebin), '.png'])
    fig.savefig(f, bbox_inches='tight') 
    return None 
Exemplo n.º 7
0
def p_Xwi_Xwj_outlier(mock, ell=0, rebin=None, krange=None, ica=False, pca=False): 
    ''' Compare the joint pdfs of whitened X components (i.e. X_w^i, X_w^j)
    p(X_w^i, X_w^j) to p(X_w^i) p(X_w^j) in order to test the independence 
    argument. 
    '''
    Pk = NG.dataX(mock, ell=ell, rebin=rebin, krange=krange)
    X, _ = NG.meansub(Pk)
    if ica and pca: 
        raise ValueError
    if ica: # ICA components
        X_white, _ = NG.whiten(X) # whitened data
        X_w, _ = NG.Ica(X_white) 
    if pca: # PCA components
        X_w, _ = NG.whiten(X, method='pca') # whitened data
    if not ica and not pca: # just whitened 
        X_w, _ = NG.whiten(X, method='choletsky') # whitened data
    
    x, y = np.linspace(-5., 5., 50), np.linspace(-5., 5., 50)
    xx, yy = np.meshgrid(x,y)
    pos = np.vstack([xx.ravel(), yy.ravel()])
    
    ij_i, ij_j = np.meshgrid(range(X_w.shape[1]), range(X_w.shape[1]))
    ij = np.vstack([ij_i.ravel(), ij_j.ravel()])

    # joint pdfs of X_w^i and X_w^j estimated from mocks  
    # i.e. p(X_w^i, X_w^j)
    pdfs_2d = NG.p_Xwi_Xwj(X_w, ij, x=x, y=y)

    # p(X_w^i) * p(X_w^j) estimated from mocks
    pXwi = NG.p_Xw_i(X_w, range(X_w.shape[1]), x=x)
    pXwj = pXwi 

    # calculate L2 norm difference betwen joint pdf and 2d gaussian 
    chi2 = np.zeros(len(pdfs_2d))
    for i in range(len(pdfs_2d)): 
        if not isinstance(pdfs_2d[i], float): 
            pXwipXwj = np.dot(pXwi[ij[0,i]][:,None], pXwj[ij[1,i]][None,:]).T.flatten()
            chi2[i] = np.sum((pXwipXwj - pdfs_2d[i])**2)
    
    # ij values with the highest chi-squared
    ii_out = np.argsort(chi2)[-10:]
    inc = np.where(ij[0,ii_out] > ij[1,ii_out]) 

    prettyplot()
    fig = plt.figure(figsize=(len(inc[0])*10, 8))
    for ii, i_sort_i in enumerate(ii_out[inc]): 
        sub = fig.add_subplot(1, len(inc[0]), ii+1)
        # plot p(X_w^i) * p(X_w^j) 
        pXwipXwj = np.dot(pXwi[ij[0,i_sort_i]][:,None], pXwj[ij[1,i_sort_i]][None,:]).T
        sub.contourf(xx, yy, pXwipXwj, cmap='gray_r', levels=[0.05, 0.1, 0.15, 0.2])
    
        # p(X_w^i, X_w^j) 
        Z = np.reshape(pdfs_2d[i_sort_i], xx.shape)
        cs = sub.contour(xx, yy, Z, colors='k', linestyles='dashed', levels=[0.05, 0.1, 0.15, 0.2])
        cs.collections[0].set_label('$\mathtt{p(X_w^i, X_w^j)}$') 

        sub.set_xlim([-3., 3.])
        sub.set_xlabel('$\mathtt{X_w^{i='+str(ij[0,i_sort_i])+'}}$', fontsize=25)
        sub.set_ylim([-3., 3.])
        sub.set_ylabel('$\mathtt{X_w^{j='+str(ij[1,i_sort_i])+'}}$', fontsize=25)
        if ii == 0: 
            sub.legend(loc='upper right', prop={'size':25})
        else: 
            sub.set_yticklabels([])
    
    str_ica, str_pca = '', ''
    if ica: 
        str_ica = '.ICA'
    if pca: 
        str_pca = '.PCA'
    if rebin is None: 
        f = ''.join([UT.fig_dir(), 'tests/test.p_Xwi_Xwj_outlier', str_ica, str_pca, '.', mock, '.ell', str(ell), '.png'])
    else: 
        f = ''.join([UT.fig_dir(), 'tests/test.p_Xwi_Xwj_outlier', str_ica, str_pca, '.', mock, '.ell', str(ell), '.rebin', str(rebin), '.png'])
    fig.savefig(f, bbox_inches='tight') 
    return None
Exemplo n.º 8
0
def GMF_p_Xw_i(ica=False, pca=False): 
    ''' Test the probability distribution function of each transformed X
    component -- p(X^i). First compare the histograms of p(X_w^i) 
    with N(0,1). Then compare the gaussian KDE of p(X_w^i).
    '''
    gmf = NG.X_gmf_all() # import all the GMF mocks 
    X, _ = NG.meansub(gmf)
    str_w = 'W'
    if ica and pca: raise ValueError
    if ica: # ICA components
        # ICA components do not need to be Gaussian.
        # in fact the whole point of the ICA transform
        # is to capture the non-Gaussianity...
        X_white, _ = NG.whiten(X) # whitened data
        X_w, _ = NG.Ica(X_white) 
        str_w = 'ICA'
    if pca: # PCA components
        X_w, _ = NG.whiten(X, method='pca') # whitened data
        str_w = 'PCA'
    if not ica and not pca: # just whitened 
        X_w, W = NG.whiten(X) # whitened data
    
    # p(X_w^i) histograms
    fig = plt.figure(figsize=(5*gmf.shape[1],4))
    for icomp in range(gmf.shape[1]): 
        sub = fig.add_subplot(1, gmf.shape[1], icomp+1)
        # histogram of X_w^i s 
        hh = np.histogram(X_w[:,icomp], normed=True, bins=50, range=[-5., 5.])
        p_X_w_arr = UT.bar_plot(*hh)
        sub.fill_between(p_X_w_arr[0], np.zeros(len(p_X_w_arr[1])), p_X_w_arr[1], 
                color='k', alpha=0.25)
        x = np.linspace(-5., 5., 100)
        sub.plot(x, UT.gauss(x, 1., 0.), c='k', lw=2, ls=':', label='$\mathcal{N}(0,1)$')
        # p(X_w^i) gaussian KDE fits  
        t_start = time.time() 
        pdf = NG.p_Xw_i(X_w, icomp, x=x, method='gkde')
        sub.plot(x, pdf, lw=2.5, label='Gaussian KDE')
        print 'scipy Gaussian KDE ', time.time()-t_start
        # p(X_w^i) SKlearn KDE fits  
        t_start = time.time() 
        pdf = NG.p_Xw_i(X_w, icomp, x=x, method='sk_kde')
        sub.plot(x, pdf, lw=2.5, label='SKlearn KDE')
        print 'SKlearn CV best-fit KDE ', time.time()-t_start
        # p(X_w^i) statsmodels KDE fits  
        t_start = time.time() 
        pdf = NG.p_Xw_i(X_w, icomp, x=x, method='sm_kde')
        sub.plot(x, pdf, lw=2.5, label='StatsModels KDE')
        print 'Stats Models KDE ', time.time()-t_start
        # p(X_w^i) GMM fits  
        pdf = NG.p_Xw_i(X_w, icomp, x=x, method='gmm', n_comp_max=20)
        sub.plot(x, pdf, lw=2.5, ls='--', label='GMM')
        sub.set_xlim([-3., 3.])
        sub.set_xlabel('$X_{'+str_w+'}^{('+str(icomp)+')}$', fontsize=25) 
        sub.set_ylim([0., 0.6])
        if icomp == 0: 
            sub.set_ylabel('$P(X_{'+str_w+'})$', fontsize=25) 
            sub.legend(loc='upper left', prop={'size': 15}) 

    str_ica, str_pca = '', ''
    if ica: str_ica = '.ICA'
    if pca: str_pca = '.PCA'

    f = ''.join([UT.fig_dir(), 'tests/test.GMF_p_Xw_i', str_pca, str_ica, '.png'])
    fig.savefig(f, bbox_inches='tight') 
    return None 
Exemplo n.º 9
0
def divGMF(div_func='kl', Nref=1000, K=5, n_mc=10, n_comp_max=10, n_mocks=2000):
    ''' compare the divergence estimates between 
    D( gauss(C_gmf) || gauss(C_gmf) ),  D( gmfs || gauss(C_gmf) ), 
    D( gmfs || p(gmfs) KDE), D( gmfs || p(gmfs) GMM), 
    D( gmfs || PI p(gmfs^i_ICA) KDE), and D( gmfs || PI p(gmfs^i_ICA) GMM)
    '''
    if isinstance(Nref, float): 
        Nref = int(Nref)
    # read in mock GMFs from all HOD realizations (20,000 mocks)
    gmfs_mock = NG.X_gmf_all()[:n_mocks]
    n_mock = gmfs_mock.shape[0] # number of mocks 
    print("%i mocks" % n_mock) 

    gmfs_mock_meansub, _ = NG.meansub(gmfs_mock) # mean subtract
    X_w, W = NG.whiten(gmfs_mock_meansub)
    X_ica, _ = NG.Ica(X_w)  # ICA transformation 

    C_gmf = np.cov(X_w.T) # covariance matrix

    # p(gmfs) GMM
    gmms, bics = [], [] 
    for i_comp in range(1,n_comp_max+1):
        gmm = GMix(n_components=i_comp)
        gmm.fit(X_w) 
        gmms.append(gmm)
        bics.append(gmm.bic(X_w))
    ibest = np.array(bics).argmin() 
    kern_gmm = gmms[ibest]

    # p(gmfs) KDE 
    t0 = time.time() 
    grid = GridSearchCV(skKDE(),
            {'bandwidth': np.linspace(0.1, 1.0, 30)},
            cv=10) # 10-fold cross-validation
    grid.fit(X_w)
    kern_kde = grid.best_estimator_
    dt = time.time() - t0 
    print('%f sec' % dt) 
    
    # PI p(gmfs^i_ICA) GMM
    kern_gmm_ica = [] 
    for ibin in range(X_ica.shape[1]): 
        gmms, bics = [], [] 
        for i_comp in range(1,n_comp_max+1):
            gmm = GMix(n_components=i_comp)
            gmm.fit(X_ica[:,ibin][:,None]) 
            gmms.append(gmm)
            bics.append(gmm.bic(X_ica[:,ibin][:,None]))
        ibest = np.array(bics).argmin() 
        kern_gmm_ica.append(gmms[ibest])
    
    # PI p(gmfs^i_ICA) KDE  
    kern_kde_ica = [] 
    for ibin in range(X_ica.shape[1]): 
        t0 = time.time() 
        grid = GridSearchCV(skKDE(),
                {'bandwidth': np.linspace(0.1, 1.0, 30)},
                cv=10) # 10-fold cross-validation
        grid.fit(X_ica[:,ibin][:,None]) 
        kern_kde_ica.append(grid.best_estimator_) 
        dt = time.time() - t0 
        print('%f sec' % dt) 

    # caluclate the divergences now 
    div_gauss_ref, div_gauss = [], []
    div_gmm, div_gmm_ica = [], [] 
    div_kde, div_kde_ica = [], [] 
    for i in range(n_mc): 
        print('%i montecarlo' % i)
        t_start = time.time() 
        # reference divergence in order to showcase the estimator's scatter
        # Gaussian distribution described by C_gmf with same n_mock mocks 
        gauss = mvn(np.zeros(gmfs_mock.shape[1]), C_gmf, size=n_mock)
        div_gauss_ref_i = NG.kNNdiv_gauss(gauss, C_gmf, Knn=K, div_func=div_func, Nref=Nref)
        div_gauss_ref.append(div_gauss_ref_i)
        # estimate divergence between gmfs_white and a 
        # Gaussian distribution described by C_gmf
        div_gauss_i = NG.kNNdiv_gauss(X_w, C_gmf, Knn=K, div_func=div_func, Nref=Nref)
        div_gauss.append(div_gauss_i)
        # D( gmfs || p(gmfs) GMM)
        div_gmm_i = NG.kNNdiv_Kernel(X_w, kern_gmm, Knn=K, div_func=div_func, 
                Nref=Nref, compwise=False) 
        div_gmm.append(div_gmm_i)
        # D( gmfs || p(gmfs) KDE)
        div_kde_i = NG.kNNdiv_Kernel(X_w, kern_kde, Knn=K, div_func=div_func, 
                Nref=Nref, compwise=False) 
        div_kde.append(div_kde_i)
        # D( gmfs || PI p(gmfs^i_ICA) GMM), 
        div_gmm_ica_i = NG.kNNdiv_Kernel(X_ica, kern_gmm_ica, Knn=K, div_func=div_func, 
                Nref=Nref, compwise=True)
        div_gmm_ica.append(div_gmm_ica_i)
        # D( gmfs || PI p(gmfs^i_ICA) KDE), 
        div_kde_ica_i = NG.kNNdiv_Kernel(X_ica, kern_kde_ica, Knn=K, div_func=div_func, 
                Nref=Nref, compwise=True)
        div_kde_ica.append(div_kde_ica_i)
        print('t= %f sec' % round(time.time()-t_start,2))

    fig = plt.figure(figsize=(10,5))
    sub = fig.add_subplot(111)
    hrange = [-0.15, 0.6]
    nbins = 50
    
    divs = [div_gauss_ref, div_gauss, div_gmm, div_kde, div_gmm_ica, div_kde_ica]
    labels = ['Ref.', r'$D(\{\zeta_i^{(m)}\}\parallel \mathcal{N}({\bf C}^{(m)}))$', 
            r'$D(\{\zeta^{(m)}\}\parallel p_\mathrm{GMM}(\{\zeta^{m}\}))$',
            r'$D(\{\zeta^{(m)}\}\parallel p_\mathrm{KDE}(\{\zeta^{m}\}))$',
            r'$D(\{\zeta_\mathrm{ICA}^{(m)}\}\parallel \prod_{i} p^\mathrm{GMM}(\{\zeta_{i, \mathrm{ICA}}^{m}\}))$', 
            r'$D(\{\zeta_\mathrm{ICA}^{(m)}\}\parallel \prod_{i} p^\mathrm{KDE}(\{\zeta_{i, \mathrm{ICA}}^{m}\}))$']
    y_max = 0.
    for div, lbl in zip(divs, labels): 
        hh = np.histogram(np.array(div), normed=True, range=hrange, bins=nbins)
        bp = UT.bar_plot(*hh) 
        sub.fill_between(bp[0], np.zeros(len(bp[0])), bp[1], edgecolor='none', 
                alpha=0.5, label=lbl) 
        y_max = max(y_max, bp[1].max()) 
        if (np.average(div) < hrange[0]) or (np.average(div) > hrange[1]): 
            print('divergence of %s (%f) is outside range' % (lbl, np.average(div)))
    sub.set_xlim(hrange) 
    sub.set_ylim([0., y_max*1.2]) 
    sub.legend(loc='upper left', prop={'size': 15})
    # xlabels
    if 'renyi' in div_func: 
        alpha = float(div_func.split(':')[-1])
        sub.set_xlabel(r'Renyi-$\alpha='+str(alpha)+'$ divergence', fontsize=20)
    elif 'kl' in div_func: 
        sub.set_xlabel(r'KL divergence', fontsize=20)
    if 'renyi' in div_func: str_div = 'renyi'+str(alpha) 
    elif div_func == 'kl': str_div = 'kl'
    f_fig = ''.join([UT.fig_dir(), 'tests/kNN_divergence.gmf.K', str(K), '.', str(n_mocks), 
        '.', str_div, '.png'])
    fig.savefig(f_fig, bbox_inches='tight') 
    return None
Exemplo n.º 10
0
def diverge(obvs,
            diver,
            div_func='kl',
            Nref=1000,
            K=5,
            n_mc=10,
            n_comp_max=10,
            n_mocks=20000,
            pk_mock='patchy.z1',
            NorS='ngc',
            njobs=1):
    ''' calculate the divergences: 

    - D( gauss(C_X) || gauss(C_X) ) 
    - D( mock X || gauss(C_X))
    - D( mock X || p(X) KDE)
    - D( mock X || p(X) GMM) 
    - D( mock X || PI p(X^i_ICA) KDE)
    - D( mock X || PI p(X^i_ICA) GMM)
    '''
    if isinstance(Nref, float): Nref = int(Nref)
    if diver not in [
            'ref', 'pX_gauss', 'pX_gauss_hartlap', 'pX_GMM', 'pX_GMM_ref',
            'pX_KDE', 'pX_KDE_ref', 'pX_scottKDE', 'pX_scottKDE_ref',
            'pXi_ICA_GMM', 'pXi_ICA_GMM_ref', 'pXi_parICA_GMM',
            'pXi_parICA_GMM_ref', 'pXi_ICA_KDE', 'pXi_ICA_KDE_ref',
            'pXi_parICA_KDE', 'pXi_parICA_KDE_ref', 'pXi_ICA_scottKDE',
            'pXi_ICA_scottKDE_ref', 'pXi_parICA_scottKDE',
            'pXi_parICA_scottKDE_ref'
    ]:
        raise ValueError
    str_obvs = ''
    if obvs == 'pk': str_obvs = '.' + NorS
    if 'renyi' in div_func:
        alpha = float(div_func.split(':')[-1])
        str_div = 'renyi' + str(alpha)
    elif div_func == 'kl':
        str_div = 'kl'
    str_comp = ''
    if 'GMM' in diver: str_comp = '.ncomp' + str(n_comp_max)

    f_dat = ''.join([
        UT.dat_dir(), 'diverg/', 'diverg.', obvs, str_obvs, '.', diver, '.K',
        str(K), str_comp, '.Nref',
        str(Nref), '.', str_div, '.dat'
    ])
    if not os.path.isfile(f_dat):
        print('-- writing to -- \n %s' % f_dat)
        f_out = open(f_dat, 'w')
    else:
        print('-- appending to -- \n %s' % f_dat)

    # read in mock data X
    if obvs == 'pk':
        X_mock = NG.X_pk_all(pk_mock, NorS=NorS, sys='fc')
    elif obvs == 'gmf':
        if n_mocks is not None:
            X_mock = NG.X_gmf_all()[:n_mocks]
        else:
            X_mock = NG.X_gmf_all()
    else:
        raise ValueError("obvs = 'pk' or 'gmf'")
    n_mock = X_mock.shape[0]  # number of mocks
    print("%i mocks" % n_mock)

    X_mock_meansub, _ = NG.meansub(X_mock)  # mean subtract
    X_w, W = NG.whiten(X_mock_meansub)
    if '_ICA' in diver:
        X_ica, W_ica = NG.Ica(X_w)  # ICA transformation
        W_ica_inv = sp.linalg.pinv(W_ica.T)
    elif '_parICA' in diver:
        # FastICA transformation using parallel algorithm
        X_ica, W_ica = NG.Ica(X_w, algorithm='parallel')
        W_ica_inv = sp.linalg.pinv(W_ica.T)

    if diver in ['pX_gauss', 'ref']:
        C_X = np.cov(X_w.T)  # covariance matrix
    elif diver in ['pX_gauss_hartlap']:
        C_X = np.cov(X_w.T)  # covariance matrix
        f_hartlap = (n_mock - float(X_mock.shape[1]) - 2.) / (n_mock - 1.)
        print("hartlap factor = %f" % f_hartlap)
        C_X = C_X / f_hartlap  # scale covariance matrix by hartlap factor
    elif diver in ['pX_GMM', 'pX_GMM_ref']:  # p(mock X) GMM
        gmms, bics = [], []
        for i_comp in range(1, n_comp_max + 1):
            gmm = GMix(n_components=i_comp)
            gmm.fit(X_w)
            gmms.append(gmm)
            bics.append(gmm.bic(X_w))
        ibest = np.array(bics).argmin()
        kern_gmm = gmms[ibest]
    elif diver in ['pX_KDE', 'pX_KDE_ref']:  # p(mock X) KDE
        t0 = time.time()
        grid = GridSearchCV(skKDE(), {'bandwidth': np.linspace(0.1, 1.0, 30)},
                            cv=10,
                            n_jobs=njobs)  # 10-fold cross-validation
        grid.fit(X_w)
        kern_kde = grid.best_estimator_
        dt = time.time() - t0
        print('%f sec' % dt)
    elif diver in ['pX_scottKDE', 'pX_scottKDE_ref']:  # p(mock X) KDE
        # calculate Scott's Rule KDE
        t0 = time.time()
        kern_kde = UT.KayDE(X_w)
        dt = time.time() - t0
        print('%f sec' % dt)
    elif diver in [
            'pXi_ICA_GMM', 'pXi_ICA_GMM_ref', 'pXi_parICA_GMM',
            'pXi_parICA_GMM_ref'
    ]:
        # PI p(X^i_ICA) GMM
        kern_gmm_ica = []
        for ibin in range(X_ica.shape[1]):
            gmms, bics = [], []
            for i_comp in range(1, n_comp_max + 1):
                gmm = GMix(n_components=i_comp)
                gmm.fit(X_ica[:, ibin][:, None])
                gmms.append(gmm)
                bics.append(gmm.bic(X_ica[:, ibin][:, None]))
            ibest = np.array(bics).argmin()
            kern_gmm_ica.append(gmms[ibest])
    elif diver in [
            'pXi_ICA_KDE', 'pXi_ICA_KDE_ref', 'pXi_parICA_KDE',
            'pXi_parICA_KDE_ref'
    ]:
        # PI p(X^i_ICA) KDE
        kern_kde_ica = []
        for ibin in range(X_ica.shape[1]):
            t0 = time.time()
            grid = GridSearchCV(skKDE(),
                                {'bandwidth': np.linspace(0.1, 1.0, 30)},
                                cv=10,
                                n_jobs=njobs)  # 10-fold cross-validation
            grid.fit(X_ica[:, ibin][:, None])
            kern_kde_ica.append(grid.best_estimator_)
            dt = time.time() - t0
            print('%f sec' % dt)
    elif diver in [
            'pXi_ICA_scottKDE', 'pXi_ICA_scottKDE_ref', 'pXi_parICA_scottKDE',
            'pXi_parICA_scottKDE_ref'
    ]:
        # PI p(X^i_ICA) KDE
        kern_kde_ica = []
        for ibin in range(X_ica.shape[1]):
            kern_kde_i = UT.KayDE(X_ica[:, ibin])
            kern_kde_ica.append(kern_kde_i)

    # caluclate the divergences now
    divs = []
    for i in range(n_mc):
        print('%i montecarlo' % i)
        t0 = time.time()
        if diver in ['pX_gauss', 'pX_gauss_hartlap']:
            # estimate divergence between gmfs_white and a
            # Gaussian distribution described by C_gmf
            div_i = NG.kNNdiv_gauss(X_w,
                                    C_X,
                                    Knn=K,
                                    div_func=div_func,
                                    Nref=Nref,
                                    njobs=njobs)
        elif diver == 'ref':
            # reference divergence in order to showcase the estimator's scatter
            # Gaussian distribution described by C_gmf with same n_mock mocks
            gauss = mvn(np.zeros(X_mock.shape[1]), C_X, size=n_mock)
            div_i = NG.kNNdiv_gauss(gauss,
                                    C_X,
                                    Knn=K,
                                    div_func=div_func,
                                    Nref=Nref,
                                    njobs=njobs)
        elif diver == 'pX_GMM':  # D( mock X || p(X) GMM)
            div_i = NG.kNNdiv_Kernel(X_w,
                                     kern_gmm,
                                     Knn=K,
                                     div_func=div_func,
                                     Nref=Nref,
                                     compwise=False,
                                     njobs=njobs)
        elif diver == 'pX_GMM_ref':  # D( sample from p(X) GMM || p(X) GMM)
            samp = kern_gmm.sample(n_mock)
            div_i = NG.kNNdiv_Kernel(samp[0],
                                     kern_gmm,
                                     Knn=K,
                                     div_func=div_func,
                                     Nref=Nref,
                                     compwise=False,
                                     njobs=njobs)
        elif diver in ['pX_KDE', 'pX_scottKDE']:  # D( mock X || p(X) KDE)
            div_i = NG.kNNdiv_Kernel(X_w,
                                     kern_kde,
                                     Knn=K,
                                     div_func=div_func,
                                     Nref=Nref,
                                     compwise=False,
                                     njobs=njobs)
            divs.append(div_i)
        elif diver in ['pX_KDE_ref', 'pX_scottKDE_ref'
                       ]:  # D( sample from p(X) KDE || p(X) KDE)
            samp = kern_kde.sample(n_mock)
            div_i = NG.kNNdiv_Kernel(samp,
                                     kern_kde,
                                     Knn=K,
                                     div_func=div_func,
                                     Nref=Nref,
                                     compwise=False,
                                     njobs=njobs)
            divs.append(div_i)
        elif diver in ['pXi_ICA_GMM',
                       'pXi_parICA_GMM']:  # D( mock X || PI p(X^i_ICA) GMM),
            div_i = NG.kNNdiv_Kernel(X_w,
                                     kern_gmm_ica,
                                     Knn=K,
                                     div_func=div_func,
                                     Nref=Nref,
                                     compwise=True,
                                     njobs=njobs,
                                     W_ica_inv=W_ica_inv)
        elif diver in ['pXi_ICA_GMM_ref', 'pXi_parICA_GMM_ref']:
            # D( ref. sample || PI p(X^i_ICA) GMM),
            samp = np.zeros((n_mock, X_ica.shape[1]))
            for icomp in range(X_ica.shape[1]):
                samp_i = kern_gmm_ica[icomp].sample(n_mock)
                samp[:, icomp] = samp_i[0].flatten()
            samp = np.dot(samp, W_ica_inv.T)
            div_i = NG.kNNdiv_Kernel(samp,
                                     kern_gmm_ica,
                                     Knn=K,
                                     div_func=div_func,
                                     Nref=Nref,
                                     compwise=True,
                                     njobs=njobs,
                                     W_ica_inv=W_ica_inv)
        elif diver in [
                'pXi_ICA_KDE', 'pXi_ICA_scottKDE', 'pXi_parICA_KDE',
                'pXi_parICA_scottKDE'
        ]:  # D( mock X || PI p(X^i_ICA) KDE),
            div_i = NG.kNNdiv_Kernel(X_w,
                                     kern_kde_ica,
                                     Knn=K,
                                     div_func=div_func,
                                     Nref=Nref,
                                     compwise=True,
                                     njobs=njobs,
                                     W_ica_inv=W_ica_inv)
        elif diver in [
                'pXi_ICA_KDE_ref', 'pXi_ICA_scottKDE_ref',
                'pXi_parICA_KDE_ref', 'pXi_parICA_scottKDE_ref'
        ]:
            # D( ref sample || PI p(X^i_ICA) KDE),
            samp = np.zeros((n_mock, X_ica.shape[1]))
            for icomp in range(X_ica.shape[1]):
                samp_i = kern_kde_ica[icomp].sample(n_mock)
                samp[:, icomp] = samp_i.flatten()
            samp = np.dot(samp, W_ica_inv.T)
            div_i = NG.kNNdiv_Kernel(samp,
                                     kern_kde_ica,
                                     Knn=K,
                                     div_func=div_func,
                                     Nref=Nref,
                                     compwise=True,
                                     njobs=njobs,
                                     W_ica_inv=W_ica_inv)
        print(div_i)
        f_out = open(f_dat, 'a')
        f_out.write('%f \n' % div_i)
        f_out.close()
    return None