# -*- coding: utf-8 -*- """ ===================== Statistical inference ===================== Here we will briefly cover multiple concepts of inferential statistics in an introductory manner, and demonstrate how to use some MNE statistical functions. .. contents:: Topics :local: :depth: 3 """ # Authors: Eric Larson # License: BSD (3-clause) from functools import partial import numpy as np from scipy import stats import matplotlib.pyplot as plt from mpl_toolkits.mplot3d import Axes3D # noqa, analysis:ignore import mne from mne.stats import (ttest_1samp_no_p, bonferroni_correction, fdr_correction, permutation_t_test, permutation_cluster_1samp_test) print(__doc__) ############################################################################### # Hypothesis testing # ------------------ # Null hypothesis # ^^^^^^^^^^^^^^^ # From `Wikipedia `__: # # In inferential statistics, a general statement or default position that # there is no relationship between two measured phenomena, or no # association among groups. # # We typically want to reject a **null hypothesis** with # some probability (e.g., p < 0.05). This probability is also called the # significance level :math:`\alpha`. # To think about what this means, let's follow the illustrative example from # [1]_ and construct a toy dataset consisting of a 40 x 40 square with a # "signal" present in the center with white noise added and a Gaussian # smoothing kernel applied. width = 40 n_subjects = 10 signal_mean = 100 signal_sd = 100 noise_sd = 0.01 gaussian_sd = 5 alpha = 0.05 sigma = 1e-3 # sigma for the "hat" method n_permutations = 'all' # run an exact test n_src = width * width # For each "subject", make a smoothed noisy signal with a centered peak rng = np.random.RandomState(2) X = noise_sd * rng.randn(n_subjects, width, width) # Add a signal at the center X[:, width // 2, width // 2] = signal_mean + rng.randn(n_subjects) * signal_sd # Spatially smooth with a 2D Gaussian kernel size = width // 2 - 1 gaussian = np.exp(-(np.arange(-size, size + 1) ** 2 / float(gaussian_sd ** 2))) for si in range(X.shape[0]): for ri in range(X.shape[1]): X[si, ri, :] = np.convolve(X[si, ri, :], gaussian, 'same') for ci in range(X.shape[2]): X[si, :, ci] = np.convolve(X[si, :, ci], gaussian, 'same') ############################################################################### # The data averaged over all subjects looks like this: fig, ax = plt.subplots() ax.imshow(X.mean(0), cmap='inferno') ax.set(xticks=[], yticks=[], title="Data averaged over subjects") ############################################################################### # In this case, a null hypothesis we could test for each voxel is: # # There is no difference between the mean value and zero # (:math:`H_0 \colon \mu = 0`). # # The alternative hypothesis, then, is that the voxel has a non-zero mean # (:math:`H_1 \colon \mu \neq 0`). # This is a *two-tailed* test because the mean could be less than # or greater than zero, whereas a *one-tailed* test would test only one of # these possibilities, i.e. :math:`H_1 \colon \mu \geq 0` or # :math:`H_1 \colon \mu \leq 0`. # # .. note:: Here we will refer to each spatial location as a "voxel". # In general, though, it could be any sort of data value, # including cortical vertex at a specific time, pixel in a # time-frequency decomposition, etc. # # Parametric tests # ^^^^^^^^^^^^^^^^ # Let's start with a **paired t-test**, which is a standard test # for differences in paired samples. Mathematically, it is equivalent # to a 1-sample t-test on the difference between the samples in each condition. # The paired t-test is **parametric** # because it assumes that the underlying sample distribution is Gaussian, and # is only valid in this case. This happens to be satisfied by our toy dataset, # but is not always satisfied for neuroimaging data. # # In the context of our toy dataset, which has many voxels # (:math:`40 \cdot 40 = 1600`), applying the paired t-test is called a # *mass-univariate* approach as it treats each voxel independently. titles = ['t'] out = stats.ttest_1samp(X, 0, axis=0) ts = [out[0]] ps = [out[1]] mccs = [False] # these are not multiple-comparisons corrected def plot_t_p(t, p, title, mcc, axes=None): if axes is None: fig = plt.figure(figsize=(6, 3)) axes = [fig.add_subplot(121, projection='3d'), fig.add_subplot(122)] show = True else: fig = axes[0].figure show = False p_lims = [0.1, 0.001] t_lims = -stats.distributions.t.ppf(p_lims, n_subjects - 1) p_lims = [-np.log10(p) for p in p_lims] # t plot x, y = np.mgrid[0:width, 0:width] surf = axes[0].plot_surface(x, y, np.reshape(t, (width, width)), rstride=1, cstride=1, linewidth=0, vmin=t_lims[0], vmax=t_lims[1], cmap='viridis') axes[0].set(xticks=[], yticks=[], zticks=[], xlim=[0, width - 1], ylim=[0, width - 1]) axes[0].view_init(30, 15) cbar = plt.colorbar(ax=axes[0], shrink=0.75, orientation='horizontal', fraction=0.1, pad=0.025, mappable=surf) cbar.set_ticks(t_lims) cbar.set_ticklabels(['%0.1f' % t_lim for t_lim in t_lims]) cbar.set_label('t-value') cbar.ax.get_xaxis().set_label_coords(0.5, -0.3) if not show: axes[0].set(title=title) if mcc: axes[0].title.set_weight('bold') # p plot use_p = -np.log10(np.reshape(np.maximum(p, 1e-5), (width, width))) img = axes[1].imshow(use_p, cmap='inferno', vmin=p_lims[0], vmax=p_lims[1], interpolation='nearest') axes[1].set(xticks=[], yticks=[]) cbar = plt.colorbar(ax=axes[1], shrink=0.75, orientation='horizontal', fraction=0.1, pad=0.025, mappable=img) cbar.set_ticks(p_lims) cbar.set_ticklabels(['%0.1f' % p_lim for p_lim in p_lims]) cbar.set_label(r'$-\log_{10}(p)$') cbar.ax.get_xaxis().set_label_coords(0.5, -0.3) if show: text = fig.suptitle(title) if mcc: text.set_weight('bold') plt.subplots_adjust(0, 0.05, 1, 0.9, wspace=0, hspace=0) mne.viz.utils.plt_show() plot_t_p(ts[-1], ps[-1], titles[-1], mccs[-1]) ############################################################################### # "Hat" variance adjustment # ~~~~~~~~~~~~~~~~~~~~~~~~~ # The "hat" technique regularizes the variance values used in the t-test # calculation [1]_ to compensate for implausibly small variances. ts.append(ttest_1samp_no_p(X, sigma=sigma)) ps.append(stats.distributions.t.sf(np.abs(ts[-1]), len(X) - 1) * 2) titles.append(r'$\mathrm{t_{hat}}$') mccs.append(False) plot_t_p(ts[-1], ps[-1], titles[-1], mccs[-1]) ############################################################################### # Non-parametric tests # ^^^^^^^^^^^^^^^^^^^^ # Instead of assuming an underlying Gaussian distribution, we could instead # use a **non-parametric resampling** method. In the case of a paired t-test # between two conditions A and B, which is mathematically equivalent to a # one-sample t-test between the difference in the conditions A-B, under the # null hypothesis we have the principle of **exchangeability**. This means # that, if the null is true, we can exchange conditions and not change # the distribution of the test statistic. # # When using a paired t-test, exchangeability thus means that we can flip the # signs of the difference between A and B. Therefore, we can construct the # **null distribution** values for each voxel by taking random subsets of # samples (subjects), flipping the sign of their difference, and recording the # absolute value of the resulting statistic (we record the absolute value # because we conduct a two-tailed test). The absolute value of the statistic # evaluated on the veridical data can then be compared to this distribution, # and the p-value is simply the proportion of null distribution values that # are smaller. # # .. warning:: In the case of a true one-sample t-test, i.e. analyzing a single # condition rather than the difference between two conditions, # it is not clear where/how exchangeability applies; see # `this FieldTrip discussion `_. # # In the case where ``n_permutations`` is large enough (or "all") so # that the complete set of unique resampling exchanges can be done # (which is :math:`2^{N_{samp}}-1` for a one-tailed and # :math:`2^{N_{samp}-1}-1` for a two-tailed test, not counting the # veridical distribution), instead of randomly exchanging conditions # the null is formed from using all possible exchanges. This is known # as a permutation test (or exact test). # Here we have to do a bit of gymnastics to get our function to do # a permutation test without correcting for multiple comparisons: X.shape = (n_subjects, n_src) # flatten the array for simplicity titles.append('Permutation') ts.append(np.zeros(width * width)) ps.append(np.zeros(width * width)) mccs.append(False) for ii in range(n_src): ts[-1][ii], ps[-1][ii] = permutation_t_test(X[:, [ii]], verbose=False)[:2] plot_t_p(ts[-1], ps[-1], titles[-1], mccs[-1]) ############################################################################### # Multiple comparisons # -------------------- # So far, we have done no correction for multiple comparisons. This is # potentially problematic for these data because there are # :math:`40 \cdot 40 = 1600` tests being performed. If we use a threshold # p < 0.05 for each individual test, we would expect many voxels to be declared # significant even if there were no true effect. In other words, we would make # many **type I errors** (adapted from `here `_): # # .. rst-class:: skinnytable # # +----------+--------+------------------+------------------+ # | | Null hypothesis | # | +------------------+------------------+ # | | True | False | # +==========+========+==================+==================+ # | | | Type I error | Correct | # | | Yes | False positive | True positive | # + Reject +--------+------------------+------------------+ # | | | Correct | Type II error | # | | No | True Negative | False negative | # +----------+--------+------------------+------------------+ # # To see why, consider a standard :math:`\alpha = 0.05`. # For a single test, our probability of making a type I error is 0.05. # The probability of making at least one type I error in # :math:`N_{\mathrm{test}}` independent tests is then given by # :math:`1 - (1 - \alpha)^{N_{\mathrm{test}}}`: N = np.arange(1, 80) alpha = 0.05 p_type_I = 1 - (1 - alpha) ** N fig, ax = plt.subplots(figsize=(4, 3)) ax.scatter(N, p_type_I, 3) ax.set(xlim=N[[0, -1]], ylim=[0, 1], xlabel=r'$N_{\mathrm{test}}$', ylabel=u'Probability of at least\none type I error') ax.grid(True) fig.tight_layout() fig.show() ############################################################################### # To combat this problem, several methods exist. Typically these # provide control over either one of the following two measures: # # 1. `Familywise error rate (FWER) `_ # The probability of making one or more type I errors: # # .. math:: # \mathrm{P}(N_{\mathrm{type\ I}} >= 1 \mid H_0) # # 2. `False discovery rate (FDR) `_ # The expected proportion of rejected null hypotheses that are # actually true: # # .. math:: # \mathrm{E}(\frac{N_{\mathrm{type\ I}}}{N_{\mathrm{reject}}} # \mid N_{\mathrm{reject}} > 0) \cdot # \mathrm{P}(N_{\mathrm{reject}} > 0 \mid H_0) # # We cover some techniques that control FWER and FDR below. # # Bonferroni correction # ^^^^^^^^^^^^^^^^^^^^^ # Perhaps the simplest way to deal with multiple comparisons, `Bonferroni # correction `__ # conservatively multiplies the p-values by the number of comparisons to # control the FWER. titles.append('Bonferroni') ts.append(ts[-1]) ps.append(bonferroni_correction(ps[0])[1]) mccs.append(True) plot_t_p(ts[-1], ps[-1], titles[-1], mccs[-1]) ############################################################################### # False discovery rate (FDR) correction # ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ # Typically FDR is performed with the Benjamini-Hochberg procedure, which # is less restrictive than Bonferroni correction for large numbers of # comparisons (fewer type II errors), but provides less strict control of type # I errors. titles.append('FDR') ts.append(ts[-1]) ps.append(fdr_correction(ps[0])[1]) mccs.append(True) plot_t_p(ts[-1], ps[-1], titles[-1], mccs[-1]) ############################################################################### # Non-parametric resampling test with a maximum statistic # ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ # **Non-parametric resampling tests** can also be used to correct for multiple # comparisons. In its simplest form, we again do permutations using # exchangeability under the null hypothesis, but this time we take the # *maximum statistic across all voxels* in each permutation to form the # null distribution. The p-value for each voxel from the veridical data # is then given by the proportion of null distribution values # that were smaller. # # This method has two important features: # # 1. It controls FWER. # 2. It is non-parametric. Even though our initial test statistic # (here a 1-sample t-test) is parametric, the null # distribution for the null hypothesis rejection (the mean value across # subjects is indistinguishable from zero) is obtained by permutations. # This means that it makes no assumptions of Gaussianity # (which do hold for this example, but do not in general for some types # of processed neuroimaging data). titles.append(r'$\mathbf{Perm_{max}}$') out = permutation_t_test(X, verbose=False)[:2] ts.append(out[0]) ps.append(out[1]) mccs.append(True) plot_t_p(ts[-1], ps[-1], titles[-1], mccs[-1]) ############################################################################### # Clustering # ^^^^^^^^^^ # Each of the aforementioned multiple comparisons corrections have the # disadvantage of not fully incorporating the correlation structure of the # data, namely that points close to one another (e.g., in space or time) tend # to be correlated. However, by defining the connectivity/adjacency/neighbor # structure in our data, we can use **clustering** to compensate. # # To use this, we need to rethink our null hypothesis. Instead # of thinking about a null hypothesis about means per voxel (with one # independent test per voxel), we consider a null hypothesis about sizes # of clusters in our data, which could be stated like: # # The distribution of spatial cluster sizes observed in two experimental # conditions are drawn from the same probability distribution. # # Here we only have a single condition and we contrast to zero, which can # be thought of as: # # The distribution of spatial cluster sizes is independent of the sign # of the data. # # In this case, we again do permutations with a maximum statistic, but, under # each permutation, we: # # 1. Compute the test statistic for each voxel individually. # 2. Threshold the test statistic values. # 3. Cluster voxels that exceed this threshold (with the same sign) based on # adjacency. # 4. Retain the size of the largest cluster (measured, e.g., by a simple voxel # count, or by the sum of voxel t-values within the cluster) to build the # null distribution. # # After doing these permutations, the cluster sizes in our veridical data # are compared to this null distribution. The p-value associated with each # cluster is again given by the proportion of smaller null distribution # values. This can then be subjected to a standard p-value threshold # (e.g., p < 0.05) to reject the null hypothesis (i.e., find an effect of # interest). # # This reframing to consider *cluster sizes* rather than *individual means* # maintains the advantages of the standard non-parametric permutation # test -- namely controlling FWER and making no assumptions of parametric # data distribution. # Critically, though, it also accounts for the correlation structure in the # data -- which in this toy case is spatial but in general can be # multidimensional (e.g., spatio-temporal) -- because the null distribution # will be derived from data in a way that preserves these correlations. # # However, there is a drawback. If a cluster significantly deviates from # the null, no further inference on the cluster (e.g., peak location) can be # made, as the entire cluster as a whole is used to reject the null. # Moreover, because the test statistic concerns the full data, the null # hypothesis (and our rejection of it) refers to the structure of the full # data. For more information, see also the comprehensive # `FieldTrip tutorial `_. # # Defining the connectivity/neighbor/adjacency matrix # ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ # First we need to define our connectivity/neighbor/adjacency matrix. # This is a square array (or sparse matrix) of shape ``(n_src, n_src)`` that # contains zeros and ones to define which spatial points are connected, i.e., # which voxels are adjacent to each other. In our case this # is quite simple, as our data are aligned on a rectangular grid. # # Let's pretend that our data were smaller -- a 3 x 3 grid. Thinking about # each voxel as being connected to the other voxels it touches, we would # need a 9 x 9 connectivity matrix. The first row of this matrix contains the # voxels in the flattened data that the first voxel touches. Since it touches # the second element in the first row and the first element in the second row # (and is also a neighbor to itself), this would be:: # # [1, 1, 0, 1, 0, 0, 0, 0, 0] # # :mod:`sklearn.feature_extraction` provides a convenient function for this: from sklearn.feature_extraction.image import grid_to_graph # noqa: E402 mini_connectivity = grid_to_graph(3, 3).toarray() assert mini_connectivity.shape == (9, 9) print(mini_connectivity[0]) ############################################################################### # In general the connectivity between voxels can be more complex, such as # those between sensors in 3D space, or time-varying activation at brain # vertices on a cortical surface. MNE provides several convenience functions # for computing connectivity/neighbor/adjacency matrices (see the # :ref:`Statistics API `). # # Standard clustering # ~~~~~~~~~~~~~~~~~~~ # Here, since our data are on a grid, we can use ``connectivity=None`` to # trigger optimized grid-based code, and run the clustering algorithm. titles.append('Clustering') # Reshape data to what is equivalent to (n_samples, n_space, n_time) X.shape = (n_subjects, width, width) # Compute threshold from t distribution (this is also the default) threshold = stats.distributions.t.ppf(1 - alpha, n_subjects - 1) t_clust, clusters, p_values, H0 = permutation_cluster_1samp_test( X, n_jobs=1, threshold=threshold, connectivity=None, n_permutations=n_permutations) # Put the cluster data in a viewable format p_clust = np.ones((width, width)) for cl, p in zip(clusters, p_values): p_clust[cl] = p ts.append(t_clust) ps.append(p_clust) mccs.append(True) plot_t_p(ts[-1], ps[-1], titles[-1], mccs[-1]) ############################################################################### # "Hat" variance adjustment # ~~~~~~~~~~~~~~~~~~~~~~~~~ # This method can also be used in this context to correct for small # variances [1]_: titles.append(r'$\mathbf{C_{hat}}$') stat_fun_hat = partial(ttest_1samp_no_p, sigma=sigma) t_hat, clusters, p_values, H0 = permutation_cluster_1samp_test( X, n_jobs=1, threshold=threshold, connectivity=None, n_permutations=n_permutations, stat_fun=stat_fun_hat, buffer_size=None) p_hat = np.ones((width, width)) for cl, p in zip(clusters, p_values): p_hat[cl] = p ts.append(t_hat) ps.append(p_hat) mccs.append(True) plot_t_p(ts[-1], ps[-1], titles[-1], mccs[-1]) ############################################################################### # .. _tfce_example: # # Threshold-free cluster enhancement (TFCE) # ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ # TFCE eliminates the free parameter initial ``threshold`` value that # determines which points are included in clustering by approximating # a continuous integration across possible threshold values with a standard # `Riemann sum `__ [2]_. # This requires giving a starting threshold ``start`` and a step # size ``step``, which in MNE is supplied as a dict. # The smaller the ``step`` and closer to 0 the ``start`` value, # the better the approximation, but the longer it takes. # # A significant advantage of TFCE is that, rather than modifying the # statistical null hypothesis under test (from one about individual voxels # to one about the distribution of clusters in the data), it modifies the *data # under test* while still controlling for multiple comparisons. # The statistical test is then done at the level of individual voxels rather # than clusters. This allows for evaluation of each point # independently for significance rather than only as cluster groups. titles.append(r'$\mathbf{C_{TFCE}}$') threshold_tfce = dict(start=0, step=0.2) t_tfce, _, p_tfce, H0 = permutation_cluster_1samp_test( X, n_jobs=1, threshold=threshold_tfce, connectivity=None, n_permutations=n_permutations) ts.append(t_tfce) ps.append(p_tfce) mccs.append(True) plot_t_p(ts[-1], ps[-1], titles[-1], mccs[-1]) ############################################################################### # We can also combine TFCE and the "hat" correction: titles.append(r'$\mathbf{C_{hat,TFCE}}$') t_tfce_hat, _, p_tfce_hat, H0 = permutation_cluster_1samp_test( X, n_jobs=1, threshold=threshold_tfce, connectivity=None, n_permutations=n_permutations, stat_fun=stat_fun_hat, buffer_size=None) ts.append(t_tfce_hat) ps.append(p_tfce_hat) mccs.append(True) plot_t_p(ts[-1], ps[-1], titles[-1], mccs[-1]) ############################################################################### # Visualize and compare methods # ----------------------------- # Let's take a look at these statistics. The top row shows each test statistic, # and the bottom shows p-values for various statistical tests, with the ones # with proper control over FWER or FDR with bold titles. fig = plt.figure(facecolor='w', figsize=(14, 3)) assert len(ts) == len(titles) == len(ps) for ii in range(len(ts)): ax = [fig.add_subplot(2, 10, ii + 1, projection='3d'), fig.add_subplot(2, 10, 11 + ii)] plot_t_p(ts[ii], ps[ii], titles[ii], mccs[ii], ax) fig.tight_layout(pad=0, w_pad=0.05, h_pad=0.1) plt.show() ############################################################################### # The first three columns show the parametric and non-parametric statistics # that are not corrected for multiple comparisons: # # - Mass univariate **t-tests** result in jagged edges. # - **"Hat" variance correction** of the t-tests produces less peaky edges, # correcting for sharpness in the statistic driven by low-variance voxels. # - **Non-parametric resampling tests** are very similar to t-tests. This is to # be expected: the data are drawn from a Gaussian distribution, and thus # satisfy parametric assumptions. # # The next three columns show multiple comparison corrections of the # mass univariate tests (parametric and non-parametric). These # too conservatively correct for multiple comparisons because neighboring # voxels in our data are correlated: # # - **Bonferroni correction** eliminates any significant activity. # - **FDR correction** is less conservative than Bonferroni. # - A **permutation test with a maximum statistic** also eliminates any # significant activity. # # The final four columns show the non-parametric cluster-based permutation # tests with a maximum statistic: # # - **Standard clustering** identifies the correct region. However, the whole # area must be declared significant, so no peak analysis can be done. # Also, the peak is broad. # - **Clustering with "hat" variance adjustment** tightens the estimate of # significant activity. # - **Clustering with TFCE** allows analyzing each significant point # independently, but still has a broadened estimate. # - **Clustering with TFCE and "hat" variance adjustment** tightens the area # declared significant (again FWER corrected). # # Statistical functions in MNE # ---------------------------- # The complete listing of statistical functions provided by MNE are in # the :ref:`Statistics API list `, but we will give # a brief overview here. # # MNE provides several convenience parametric testing functions that can be # used in conjunction with the non-parametric clustering methods. However, # the set of functions we provide is not meant to be exhaustive. # # If the univariate statistical contrast of interest is not listed here # (e.g., interaction term in an unbalanced ANOVA), consider checking out the # :mod:`statsmodels` package. It offers many functions for computing # statistical contrasts, e.g., :func:`statsmodels.stats.anova.anova_lm`. # To use these functions in clustering: # # 1. Determine which test statistic (e.g., t-value, F-value) you would use # in a univariate context to compute your contrast of interest. In other # words, if there were only a single output such as reaction times, what # test statistic might you compute on the data? # 2. Wrap the call to that function within a function that takes an input of # the same shape that is expected by your clustering function, # and returns an array of the same shape without the "samples" dimension # (e.g., :func:`mne.stats.permutation_cluster_1samp_test` takes an array # of shape ``(n_samples, p, q)`` and returns an array of shape ``(p, q)``). # 3. Pass this wrapped function to the ``stat_fun`` argument to the clustering # function. # 4. Set an appropriate ``threshold`` value (float or dict) based on the # values your statistical contrast function returns. # # Parametric methods provided by MNE # ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ # # - :func:`mne.stats.ttest_1samp_no_p` # Paired t-test, optionally with hat adjustment. # This is used by default for contrast enhancement in paired cluster tests. # # - :func:`mne.stats.f_oneway` # One-way ANOVA for independent samples. # This can be used to compute various F-contrasts. It is used by default # for contrast enhancement in non-paired cluster tests. # # - :func:`mne.stats.f_mway_rm` # M-way ANOVA for repeated measures and balanced designs. # This returns F-statistics and p-values. The associated helper function # :func:`mne.stats.f_threshold_mway_rm` can be used to determine the # F-threshold at a given significance level. # # - :func:`mne.stats.linear_regression` # Compute ordinary least square regressions on multiple targets, e.g., # sensors, time points across trials (samples). # For each regressor it returns the beta value, t-statistic, and # uncorrected p-value. While it can be used as a test, it is # particularly useful to compute weighted averages or deal with # continuous predictors. # # Non-parametric methods # ^^^^^^^^^^^^^^^^^^^^^^ # # - :func:`mne.stats.permutation_cluster_test` # Unpaired contrasts with connectivity. # # - :func:`mne.stats.spatio_temporal_cluster_test` # Unpaired contrasts with spatio-temporal connectivity. # # - :func:`mne.stats.permutation_t_test` # Paired contrast with no connectivity. # # - :func:`mne.stats.permutation_cluster_1samp_test` # Paired contrasts with connectivity. # # - :func:`mne.stats.spatio_temporal_cluster_1samp_test` # Paired contrasts with spatio-temporal connectivity. # # .. warning:: In most MNE functions, data has shape # ``(..., n_space, n_time)``, where the spatial dimension can # be e.g. sensors or source vertices. But for our spatio-temporal # clustering functions, the spatial dimensions need to be **last** # for computational efficiency reasons. For example, for # :func:`mne.stats.spatio_temporal_cluster_1samp_test`, ``X`` # needs to be of shape ``(n_samples, n_time, n_space)``. You can # use :func:`numpy.transpose` to transpose axes if necessary. # # References # ---------- # .. [1] Ridgway et al. 2012, "The problem of low variance voxels in # statistical parametric mapping; a new hat avoids a 'haircut'", # NeuroImage. 2012 Feb 1;59(3):2131-41. # # .. [2] Smith and Nichols 2009, "Threshold-free cluster enhancement: # addressing problems of smoothing, threshold dependence, and # localisation in cluster inference", NeuroImage 44 (2009) 83-98. # # .. include:: ../tutorial_links.inc