625 lines
22 KiB
Python
625 lines
22 KiB
Python
"""Spectral biclustering algorithms."""
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# Authors : Kemal Eren
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# License: BSD 3 clause
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from abc import ABCMeta, abstractmethod
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from numbers import Integral
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import numpy as np
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from scipy.linalg import norm
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from scipy.sparse import dia_matrix, issparse
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from scipy.sparse.linalg import eigsh, svds
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from ..base import BaseEstimator, BiclusterMixin, _fit_context
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from ..utils import check_random_state, check_scalar
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from ..utils._param_validation import Interval, StrOptions
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from ..utils.extmath import make_nonnegative, randomized_svd, safe_sparse_dot
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from ..utils.validation import assert_all_finite
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from ._kmeans import KMeans, MiniBatchKMeans
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__all__ = ["SpectralCoclustering", "SpectralBiclustering"]
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def _scale_normalize(X):
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"""Normalize ``X`` by scaling rows and columns independently.
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Returns the normalized matrix and the row and column scaling
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factors.
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"""
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X = make_nonnegative(X)
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row_diag = np.asarray(1.0 / np.sqrt(X.sum(axis=1))).squeeze()
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col_diag = np.asarray(1.0 / np.sqrt(X.sum(axis=0))).squeeze()
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row_diag = np.where(np.isnan(row_diag), 0, row_diag)
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col_diag = np.where(np.isnan(col_diag), 0, col_diag)
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if issparse(X):
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n_rows, n_cols = X.shape
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r = dia_matrix((row_diag, [0]), shape=(n_rows, n_rows))
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c = dia_matrix((col_diag, [0]), shape=(n_cols, n_cols))
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an = r * X * c
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else:
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an = row_diag[:, np.newaxis] * X * col_diag
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return an, row_diag, col_diag
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def _bistochastic_normalize(X, max_iter=1000, tol=1e-5):
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"""Normalize rows and columns of ``X`` simultaneously so that all
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rows sum to one constant and all columns sum to a different
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constant.
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"""
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# According to paper, this can also be done more efficiently with
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# deviation reduction and balancing algorithms.
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X = make_nonnegative(X)
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X_scaled = X
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for _ in range(max_iter):
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X_new, _, _ = _scale_normalize(X_scaled)
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if issparse(X):
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dist = norm(X_scaled.data - X.data)
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else:
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dist = norm(X_scaled - X_new)
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X_scaled = X_new
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if dist is not None and dist < tol:
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break
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return X_scaled
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def _log_normalize(X):
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"""Normalize ``X`` according to Kluger's log-interactions scheme."""
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X = make_nonnegative(X, min_value=1)
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if issparse(X):
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raise ValueError(
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"Cannot compute log of a sparse matrix,"
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" because log(x) diverges to -infinity as x"
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" goes to 0."
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)
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L = np.log(X)
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row_avg = L.mean(axis=1)[:, np.newaxis]
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col_avg = L.mean(axis=0)
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avg = L.mean()
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return L - row_avg - col_avg + avg
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class BaseSpectral(BiclusterMixin, BaseEstimator, metaclass=ABCMeta):
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"""Base class for spectral biclustering."""
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_parameter_constraints: dict = {
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"svd_method": [StrOptions({"randomized", "arpack"})],
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"n_svd_vecs": [Interval(Integral, 0, None, closed="left"), None],
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"mini_batch": ["boolean"],
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"init": [StrOptions({"k-means++", "random"}), np.ndarray],
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"n_init": [Interval(Integral, 1, None, closed="left")],
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"random_state": ["random_state"],
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}
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@abstractmethod
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def __init__(
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self,
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n_clusters=3,
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svd_method="randomized",
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n_svd_vecs=None,
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mini_batch=False,
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init="k-means++",
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n_init=10,
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random_state=None,
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):
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self.n_clusters = n_clusters
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self.svd_method = svd_method
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self.n_svd_vecs = n_svd_vecs
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self.mini_batch = mini_batch
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self.init = init
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self.n_init = n_init
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self.random_state = random_state
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@abstractmethod
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def _check_parameters(self, n_samples):
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"""Validate parameters depending on the input data."""
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@_fit_context(prefer_skip_nested_validation=True)
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def fit(self, X, y=None):
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"""Create a biclustering for X.
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Parameters
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----------
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X : array-like of shape (n_samples, n_features)
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Training data.
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y : Ignored
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Not used, present for API consistency by convention.
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Returns
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-------
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self : object
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SpectralBiclustering instance.
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"""
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X = self._validate_data(X, accept_sparse="csr", dtype=np.float64)
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self._check_parameters(X.shape[0])
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self._fit(X)
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return self
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def _svd(self, array, n_components, n_discard):
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"""Returns first `n_components` left and right singular
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vectors u and v, discarding the first `n_discard`.
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"""
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if self.svd_method == "randomized":
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kwargs = {}
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if self.n_svd_vecs is not None:
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kwargs["n_oversamples"] = self.n_svd_vecs
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u, _, vt = randomized_svd(
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array, n_components, random_state=self.random_state, **kwargs
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)
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elif self.svd_method == "arpack":
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u, _, vt = svds(array, k=n_components, ncv=self.n_svd_vecs)
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if np.any(np.isnan(vt)):
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# some eigenvalues of A * A.T are negative, causing
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# sqrt() to be np.nan. This causes some vectors in vt
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# to be np.nan.
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A = safe_sparse_dot(array.T, array)
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random_state = check_random_state(self.random_state)
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# initialize with [-1,1] as in ARPACK
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v0 = random_state.uniform(-1, 1, A.shape[0])
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_, v = eigsh(A, ncv=self.n_svd_vecs, v0=v0)
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vt = v.T
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if np.any(np.isnan(u)):
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A = safe_sparse_dot(array, array.T)
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random_state = check_random_state(self.random_state)
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# initialize with [-1,1] as in ARPACK
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v0 = random_state.uniform(-1, 1, A.shape[0])
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_, u = eigsh(A, ncv=self.n_svd_vecs, v0=v0)
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assert_all_finite(u)
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assert_all_finite(vt)
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u = u[:, n_discard:]
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vt = vt[n_discard:]
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return u, vt.T
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def _k_means(self, data, n_clusters):
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if self.mini_batch:
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model = MiniBatchKMeans(
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n_clusters,
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init=self.init,
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n_init=self.n_init,
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random_state=self.random_state,
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)
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else:
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model = KMeans(
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n_clusters,
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init=self.init,
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n_init=self.n_init,
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random_state=self.random_state,
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)
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model.fit(data)
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centroid = model.cluster_centers_
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labels = model.labels_
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return centroid, labels
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def _more_tags(self):
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return {
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"_xfail_checks": {
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"check_estimators_dtypes": "raises nan error",
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"check_fit2d_1sample": "_scale_normalize fails",
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"check_fit2d_1feature": "raises apply_along_axis error",
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"check_estimator_sparse_matrix": "does not fail gracefully",
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"check_estimator_sparse_array": "does not fail gracefully",
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"check_methods_subset_invariance": "empty array passed inside",
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"check_dont_overwrite_parameters": "empty array passed inside",
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"check_fit2d_predict1d": "empty array passed inside",
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}
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}
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class SpectralCoclustering(BaseSpectral):
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"""Spectral Co-Clustering algorithm (Dhillon, 2001).
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Clusters rows and columns of an array `X` to solve the relaxed
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normalized cut of the bipartite graph created from `X` as follows:
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the edge between row vertex `i` and column vertex `j` has weight
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`X[i, j]`.
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The resulting bicluster structure is block-diagonal, since each
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row and each column belongs to exactly one bicluster.
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Supports sparse matrices, as long as they are nonnegative.
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Read more in the :ref:`User Guide <spectral_coclustering>`.
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Parameters
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----------
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n_clusters : int, default=3
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The number of biclusters to find.
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svd_method : {'randomized', 'arpack'}, default='randomized'
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Selects the algorithm for finding singular vectors. May be
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'randomized' or 'arpack'. If 'randomized', use
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:func:`sklearn.utils.extmath.randomized_svd`, which may be faster
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for large matrices. If 'arpack', use
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:func:`scipy.sparse.linalg.svds`, which is more accurate, but
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possibly slower in some cases.
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n_svd_vecs : int, default=None
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Number of vectors to use in calculating the SVD. Corresponds
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to `ncv` when `svd_method=arpack` and `n_oversamples` when
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`svd_method` is 'randomized`.
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mini_batch : bool, default=False
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Whether to use mini-batch k-means, which is faster but may get
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different results.
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init : {'k-means++', 'random'}, or ndarray of shape \
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(n_clusters, n_features), default='k-means++'
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Method for initialization of k-means algorithm; defaults to
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'k-means++'.
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n_init : int, default=10
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Number of random initializations that are tried with the
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k-means algorithm.
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If mini-batch k-means is used, the best initialization is
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chosen and the algorithm runs once. Otherwise, the algorithm
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is run for each initialization and the best solution chosen.
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random_state : int, RandomState instance, default=None
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Used for randomizing the singular value decomposition and the k-means
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initialization. Use an int to make the randomness deterministic.
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See :term:`Glossary <random_state>`.
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Attributes
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----------
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rows_ : array-like of shape (n_row_clusters, n_rows)
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Results of the clustering. `rows[i, r]` is True if
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cluster `i` contains row `r`. Available only after calling ``fit``.
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columns_ : array-like of shape (n_column_clusters, n_columns)
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Results of the clustering, like `rows`.
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row_labels_ : array-like of shape (n_rows,)
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The bicluster label of each row.
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column_labels_ : array-like of shape (n_cols,)
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The bicluster label of each column.
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biclusters_ : tuple of two ndarrays
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The tuple contains the `rows_` and `columns_` arrays.
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n_features_in_ : int
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Number of features seen during :term:`fit`.
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.. versionadded:: 0.24
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feature_names_in_ : ndarray of shape (`n_features_in_`,)
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Names of features seen during :term:`fit`. Defined only when `X`
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has feature names that are all strings.
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.. versionadded:: 1.0
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See Also
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--------
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SpectralBiclustering : Partitions rows and columns under the assumption
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that the data has an underlying checkerboard structure.
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References
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----------
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* :doi:`Dhillon, Inderjit S, 2001. Co-clustering documents and words using
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bipartite spectral graph partitioning.
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<10.1145/502512.502550>`
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Examples
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--------
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>>> from sklearn.cluster import SpectralCoclustering
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>>> import numpy as np
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>>> X = np.array([[1, 1], [2, 1], [1, 0],
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... [4, 7], [3, 5], [3, 6]])
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>>> clustering = SpectralCoclustering(n_clusters=2, random_state=0).fit(X)
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>>> clustering.row_labels_ #doctest: +SKIP
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array([0, 1, 1, 0, 0, 0], dtype=int32)
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>>> clustering.column_labels_ #doctest: +SKIP
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array([0, 0], dtype=int32)
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>>> clustering
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SpectralCoclustering(n_clusters=2, random_state=0)
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"""
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_parameter_constraints: dict = {
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**BaseSpectral._parameter_constraints,
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"n_clusters": [Interval(Integral, 1, None, closed="left")],
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}
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def __init__(
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self,
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n_clusters=3,
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*,
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svd_method="randomized",
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n_svd_vecs=None,
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mini_batch=False,
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init="k-means++",
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n_init=10,
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random_state=None,
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):
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super().__init__(
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n_clusters, svd_method, n_svd_vecs, mini_batch, init, n_init, random_state
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)
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def _check_parameters(self, n_samples):
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if self.n_clusters > n_samples:
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raise ValueError(
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f"n_clusters should be <= n_samples={n_samples}. Got"
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f" {self.n_clusters} instead."
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)
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def _fit(self, X):
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normalized_data, row_diag, col_diag = _scale_normalize(X)
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n_sv = 1 + int(np.ceil(np.log2(self.n_clusters)))
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u, v = self._svd(normalized_data, n_sv, n_discard=1)
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z = np.vstack((row_diag[:, np.newaxis] * u, col_diag[:, np.newaxis] * v))
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_, labels = self._k_means(z, self.n_clusters)
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n_rows = X.shape[0]
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self.row_labels_ = labels[:n_rows]
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self.column_labels_ = labels[n_rows:]
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self.rows_ = np.vstack([self.row_labels_ == c for c in range(self.n_clusters)])
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self.columns_ = np.vstack(
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[self.column_labels_ == c for c in range(self.n_clusters)]
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)
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class SpectralBiclustering(BaseSpectral):
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"""Spectral biclustering (Kluger, 2003).
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Partitions rows and columns under the assumption that the data has
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an underlying checkerboard structure. For instance, if there are
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two row partitions and three column partitions, each row will
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belong to three biclusters, and each column will belong to two
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biclusters. The outer product of the corresponding row and column
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label vectors gives this checkerboard structure.
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Read more in the :ref:`User Guide <spectral_biclustering>`.
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Parameters
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----------
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n_clusters : int or tuple (n_row_clusters, n_column_clusters), default=3
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The number of row and column clusters in the checkerboard
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structure.
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method : {'bistochastic', 'scale', 'log'}, default='bistochastic'
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Method of normalizing and converting singular vectors into
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biclusters. May be one of 'scale', 'bistochastic', or 'log'.
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The authors recommend using 'log'. If the data is sparse,
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however, log normalization will not work, which is why the
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default is 'bistochastic'.
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.. warning::
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if `method='log'`, the data must not be sparse.
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n_components : int, default=6
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Number of singular vectors to check.
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n_best : int, default=3
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Number of best singular vectors to which to project the data
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for clustering.
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svd_method : {'randomized', 'arpack'}, default='randomized'
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Selects the algorithm for finding singular vectors. May be
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'randomized' or 'arpack'. If 'randomized', uses
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:func:`~sklearn.utils.extmath.randomized_svd`, which may be faster
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for large matrices. If 'arpack', uses
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`scipy.sparse.linalg.svds`, which is more accurate, but
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possibly slower in some cases.
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n_svd_vecs : int, default=None
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Number of vectors to use in calculating the SVD. Corresponds
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to `ncv` when `svd_method=arpack` and `n_oversamples` when
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`svd_method` is 'randomized`.
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mini_batch : bool, default=False
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Whether to use mini-batch k-means, which is faster but may get
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different results.
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init : {'k-means++', 'random'} or ndarray of shape (n_clusters, n_features), \
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default='k-means++'
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Method for initialization of k-means algorithm; defaults to
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'k-means++'.
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n_init : int, default=10
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Number of random initializations that are tried with the
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k-means algorithm.
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If mini-batch k-means is used, the best initialization is
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chosen and the algorithm runs once. Otherwise, the algorithm
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is run for each initialization and the best solution chosen.
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random_state : int, RandomState instance, default=None
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Used for randomizing the singular value decomposition and the k-means
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initialization. Use an int to make the randomness deterministic.
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See :term:`Glossary <random_state>`.
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Attributes
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----------
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rows_ : array-like of shape (n_row_clusters, n_rows)
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Results of the clustering. `rows[i, r]` is True if
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cluster `i` contains row `r`. Available only after calling ``fit``.
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columns_ : array-like of shape (n_column_clusters, n_columns)
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Results of the clustering, like `rows`.
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row_labels_ : array-like of shape (n_rows,)
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Row partition labels.
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column_labels_ : array-like of shape (n_cols,)
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Column partition labels.
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biclusters_ : tuple of two ndarrays
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The tuple contains the `rows_` and `columns_` arrays.
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n_features_in_ : int
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Number of features seen during :term:`fit`.
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.. versionadded:: 0.24
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feature_names_in_ : ndarray of shape (`n_features_in_`,)
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Names of features seen during :term:`fit`. Defined only when `X`
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has feature names that are all strings.
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.. versionadded:: 1.0
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See Also
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--------
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SpectralCoclustering : Spectral Co-Clustering algorithm (Dhillon, 2001).
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References
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----------
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* :doi:`Kluger, Yuval, et. al., 2003. Spectral biclustering of microarray
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data: coclustering genes and conditions.
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<10.1101/gr.648603>`
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Examples
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--------
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>>> from sklearn.cluster import SpectralBiclustering
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>>> import numpy as np
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>>> X = np.array([[1, 1], [2, 1], [1, 0],
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... [4, 7], [3, 5], [3, 6]])
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>>> clustering = SpectralBiclustering(n_clusters=2, random_state=0).fit(X)
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>>> clustering.row_labels_
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array([1, 1, 1, 0, 0, 0], dtype=int32)
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>>> clustering.column_labels_
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array([1, 0], dtype=int32)
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>>> clustering
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SpectralBiclustering(n_clusters=2, random_state=0)
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"""
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_parameter_constraints: dict = {
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**BaseSpectral._parameter_constraints,
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"n_clusters": [Interval(Integral, 1, None, closed="left"), tuple],
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"method": [StrOptions({"bistochastic", "scale", "log"})],
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"n_components": [Interval(Integral, 1, None, closed="left")],
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"n_best": [Interval(Integral, 1, None, closed="left")],
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}
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def __init__(
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self,
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n_clusters=3,
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*,
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method="bistochastic",
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n_components=6,
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n_best=3,
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svd_method="randomized",
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n_svd_vecs=None,
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mini_batch=False,
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init="k-means++",
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n_init=10,
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random_state=None,
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):
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super().__init__(
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n_clusters, svd_method, n_svd_vecs, mini_batch, init, n_init, random_state
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)
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self.method = method
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self.n_components = n_components
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self.n_best = n_best
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def _check_parameters(self, n_samples):
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if isinstance(self.n_clusters, Integral):
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if self.n_clusters > n_samples:
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raise ValueError(
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f"n_clusters should be <= n_samples={n_samples}. Got"
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f" {self.n_clusters} instead."
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)
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else: # tuple
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try:
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n_row_clusters, n_column_clusters = self.n_clusters
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check_scalar(
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n_row_clusters,
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"n_row_clusters",
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target_type=Integral,
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min_val=1,
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max_val=n_samples,
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)
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check_scalar(
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n_column_clusters,
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"n_column_clusters",
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target_type=Integral,
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min_val=1,
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max_val=n_samples,
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)
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except (ValueError, TypeError) as e:
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raise ValueError(
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"Incorrect parameter n_clusters has value:"
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f" {self.n_clusters}. It should either be a single integer"
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" or an iterable with two integers:"
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" (n_row_clusters, n_column_clusters)"
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" And the values are should be in the"
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" range: (1, n_samples)"
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) from e
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if self.n_best > self.n_components:
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raise ValueError(
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f"n_best={self.n_best} must be <= n_components={self.n_components}."
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)
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def _fit(self, X):
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n_sv = self.n_components
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if self.method == "bistochastic":
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normalized_data = _bistochastic_normalize(X)
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n_sv += 1
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elif self.method == "scale":
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normalized_data, _, _ = _scale_normalize(X)
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n_sv += 1
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elif self.method == "log":
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normalized_data = _log_normalize(X)
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n_discard = 0 if self.method == "log" else 1
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u, v = self._svd(normalized_data, n_sv, n_discard)
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ut = u.T
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vt = v.T
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try:
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n_row_clusters, n_col_clusters = self.n_clusters
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except TypeError:
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n_row_clusters = n_col_clusters = self.n_clusters
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best_ut = self._fit_best_piecewise(ut, self.n_best, n_row_clusters)
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best_vt = self._fit_best_piecewise(vt, self.n_best, n_col_clusters)
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self.row_labels_ = self._project_and_cluster(X, best_vt.T, n_row_clusters)
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self.column_labels_ = self._project_and_cluster(X.T, best_ut.T, n_col_clusters)
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self.rows_ = np.vstack(
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[
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self.row_labels_ == label
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for label in range(n_row_clusters)
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|
for _ in range(n_col_clusters)
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|
]
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)
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self.columns_ = np.vstack(
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[
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self.column_labels_ == label
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for _ in range(n_row_clusters)
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for label in range(n_col_clusters)
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]
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)
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|
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def _fit_best_piecewise(self, vectors, n_best, n_clusters):
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"""Find the ``n_best`` vectors that are best approximated by piecewise
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|
constant vectors.
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The piecewise vectors are found by k-means; the best is chosen
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according to Euclidean distance.
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"""
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def make_piecewise(v):
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centroid, labels = self._k_means(v.reshape(-1, 1), n_clusters)
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return centroid[labels].ravel()
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|
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piecewise_vectors = np.apply_along_axis(make_piecewise, axis=1, arr=vectors)
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dists = np.apply_along_axis(norm, axis=1, arr=(vectors - piecewise_vectors))
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result = vectors[np.argsort(dists)[:n_best]]
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return result
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def _project_and_cluster(self, data, vectors, n_clusters):
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|
"""Project ``data`` to ``vectors`` and cluster the result."""
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|
projected = safe_sparse_dot(data, vectors)
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_, labels = self._k_means(projected, n_clusters)
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return labels
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