# -*- coding: utf-8 -*- from collections.abc import Iterable import numpy as np from scipy._lib._util import _asarray_validated from scipy.linalg import block_diag, LinAlgError from .lapack import _compute_lwork, get_lapack_funcs __all__ = ['cossin'] def cossin(X, p=None, q=None, separate=False, swap_sign=False, compute_u=True, compute_vh=True): """ Compute the cosine-sine (CS) decomposition of an orthogonal/unitary matrix. X is an ``(m, m)`` orthogonal/unitary matrix, partitioned as the following where upper left block has the shape of ``(p, q)``:: ┌ ┐ │ I 0 0 │ 0 0 0 │ ┌ ┐ ┌ ┐│ 0 C 0 │ 0 -S 0 │┌ ┐* │ X11 │ X12 │ │ U1 │ ││ 0 0 0 │ 0 0 -I ││ V1 │ │ │ ────┼──── │ = │────┼────││─────────┼─────────││────┼────│ │ X21 │ X22 │ │ │ U2 ││ 0 0 0 │ I 0 0 ││ │ V2 │ └ ┘ └ ┘│ 0 S 0 │ 0 C 0 │└ ┘ │ 0 0 I │ 0 0 0 │ └ ┘ ``U1``, ``U2``, ``V1``, ``V2`` are square orthogonal/unitary matrices of dimensions ``(p,p)``, ``(m-p,m-p)``, ``(q,q)``, and ``(m-q,m-q)`` respectively, and ``C`` and ``S`` are ``(r, r)`` nonnegative diagonal matrices satisfying ``C^2 + S^2 = I`` where ``r = min(p, m-p, q, m-q)``. Moreover, the rank of the identity matrices are ``min(p, q) - r``, ``min(p, m - q) - r``, ``min(m - p, q) - r``, and ``min(m - p, m - q) - r`` respectively. X can be supplied either by itself and block specifications p, q or its subblocks in an iterable from which the shapes would be derived. See the examples below. Parameters ---------- X : array_like, iterable complex unitary or real orthogonal matrix to be decomposed, or iterable of subblocks ``X11``, ``X12``, ``X21``, ``X22``, when ``p``, ``q`` are omitted. p : int, optional Number of rows of the upper left block ``X11``, used only when X is given as an array. q : int, optional Number of columns of the upper left block ``X11``, used only when X is given as an array. separate : bool, optional if ``True``, the low level components are returned instead of the matrix factors, i.e. ``(u1,u2)``, ``theta``, ``(v1h,v2h)`` instead of ``u``, ``cs``, ``vh``. swap_sign : bool, optional if ``True``, the ``-S``, ``-I`` block will be the bottom left, otherwise (by default) they will be in the upper right block. compute_u : bool, optional if ``False``, ``u`` won't be computed and an empty array is returned. compute_vh : bool, optional if ``False``, ``vh`` won't be computed and an empty array is returned. Returns ------- u : ndarray When ``compute_u=True``, contains the block diagonal orthogonal/unitary matrix consisting of the blocks ``U1`` (``p`` x ``p``) and ``U2`` (``m-p`` x ``m-p``) orthogonal/unitary matrices. If ``separate=True``, this contains the tuple of ``(U1, U2)``. cs : ndarray The cosine-sine factor with the structure described above. If ``separate=True``, this contains the ``theta`` array containing the angles in radians. vh : ndarray When ``compute_vh=True`, contains the block diagonal orthogonal/unitary matrix consisting of the blocks ``V1H`` (``q`` x ``q``) and ``V2H`` (``m-q`` x ``m-q``) orthogonal/unitary matrices. If ``separate=True``, this contains the tuple of ``(V1H, V2H)``. References ---------- .. [1] Brian D. Sutton. Computing the complete CS decomposition. Numer. Algorithms, 50(1):33-65, 2009. Examples -------- >>> import numpy as np >>> from scipy.linalg import cossin >>> from scipy.stats import unitary_group >>> x = unitary_group.rvs(4) >>> u, cs, vdh = cossin(x, p=2, q=2) >>> np.allclose(x, u @ cs @ vdh) True Same can be entered via subblocks without the need of ``p`` and ``q``. Also let's skip the computation of ``u`` >>> ue, cs, vdh = cossin((x[:2, :2], x[:2, 2:], x[2:, :2], x[2:, 2:]), ... compute_u=False) >>> print(ue) [] >>> np.allclose(x, u @ cs @ vdh) True """ if p or q: p = 1 if p is None else int(p) q = 1 if q is None else int(q) X = _asarray_validated(X, check_finite=True) if not np.equal(*X.shape): raise ValueError("Cosine Sine decomposition only supports square" " matrices, got {}".format(X.shape)) m = X.shape[0] if p >= m or p <= 0: raise ValueError("invalid p={}, 0
= m or q <= 0:
raise ValueError("invalid q={}, 0 0:
raise LinAlgError("{} did not converge: {}".format(method_name, info))
if separate:
return (u1, u2), theta, (v1h, v2h)
U = block_diag(u1, u2)
VDH = block_diag(v1h, v2h)
# Construct the middle factor CS
c = np.diag(np.cos(theta))
s = np.diag(np.sin(theta))
r = min(p, q, m - p, m - q)
n11 = min(p, q) - r
n12 = min(p, m - q) - r
n21 = min(m - p, q) - r
n22 = min(m - p, m - q) - r
Id = np.eye(np.max([n11, n12, n21, n22, r]), dtype=theta.dtype)
CS = np.zeros((m, m), dtype=theta.dtype)
CS[:n11, :n11] = Id[:n11, :n11]
xs = n11 + r
xe = n11 + r + n12
ys = n11 + n21 + n22 + 2 * r
ye = n11 + n21 + n22 + 2 * r + n12
CS[xs: xe, ys:ye] = Id[:n12, :n12] if swap_sign else -Id[:n12, :n12]
xs = p + n22 + r
xe = p + n22 + r + + n21
ys = n11 + r
ye = n11 + r + n21
CS[xs:xe, ys:ye] = -Id[:n21, :n21] if swap_sign else Id[:n21, :n21]
CS[p:p + n22, q:q + n22] = Id[:n22, :n22]
CS[n11:n11 + r, n11:n11 + r] = c
CS[p + n22:p + n22 + r, r + n21 + n22:2 * r + n21 + n22] = c
xs = n11
xe = n11 + r
ys = n11 + n21 + n22 + r
ye = n11 + n21 + n22 + 2 * r
CS[xs:xe, ys:ye] = s if swap_sign else -s
CS[p + n22:p + n22 + r, n11:n11 + r] = -s if swap_sign else s
return U, CS, VDH