882 lines
24 KiB
Python
882 lines
24 KiB
Python
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#
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# Author: Travis Oliphant, March 2002
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#
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from itertools import product
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import numpy as np
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from numpy import (Inf, dot, diag, prod, logical_not, ravel, transpose,
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conjugate, absolute, amax, sign, isfinite)
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from numpy.lib.scimath import sqrt as csqrt
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# Local imports
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from scipy.linalg import LinAlgError, bandwidth
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from ._misc import norm
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from ._basic import solve, inv
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from ._special_matrices import triu
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from ._decomp_svd import svd
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from ._decomp_schur import schur, rsf2csf
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from ._expm_frechet import expm_frechet, expm_cond
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from ._matfuncs_sqrtm import sqrtm
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from ._matfuncs_expm import pick_pade_structure, pade_UV_calc
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__all__ = ['expm', 'cosm', 'sinm', 'tanm', 'coshm', 'sinhm', 'tanhm', 'logm',
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'funm', 'signm', 'sqrtm', 'fractional_matrix_power', 'expm_frechet',
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'expm_cond', 'khatri_rao']
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eps = np.finfo('d').eps
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feps = np.finfo('f').eps
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_array_precision = {'i': 1, 'l': 1, 'f': 0, 'd': 1, 'F': 0, 'D': 1}
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###############################################################################
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# Utility functions.
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def _asarray_square(A):
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"""
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Wraps asarray with the extra requirement that the input be a square matrix.
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The motivation is that the matfuncs module has real functions that have
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been lifted to square matrix functions.
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Parameters
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----------
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A : array_like
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A square matrix.
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Returns
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-------
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out : ndarray
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An ndarray copy or view or other representation of A.
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"""
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A = np.asarray(A)
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if len(A.shape) != 2 or A.shape[0] != A.shape[1]:
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raise ValueError('expected square array_like input')
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return A
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def _maybe_real(A, B, tol=None):
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"""
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Return either B or the real part of B, depending on properties of A and B.
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The motivation is that B has been computed as a complicated function of A,
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and B may be perturbed by negligible imaginary components.
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If A is real and B is complex with small imaginary components,
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then return a real copy of B. The assumption in that case would be that
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the imaginary components of B are numerical artifacts.
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Parameters
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----------
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A : ndarray
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Input array whose type is to be checked as real vs. complex.
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B : ndarray
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Array to be returned, possibly without its imaginary part.
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tol : float
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Absolute tolerance.
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Returns
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-------
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out : real or complex array
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Either the input array B or only the real part of the input array B.
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"""
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# Note that booleans and integers compare as real.
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if np.isrealobj(A) and np.iscomplexobj(B):
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if tol is None:
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tol = {0:feps*1e3, 1:eps*1e6}[_array_precision[B.dtype.char]]
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if np.allclose(B.imag, 0.0, atol=tol):
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B = B.real
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return B
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###############################################################################
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# Matrix functions.
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def fractional_matrix_power(A, t):
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"""
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Compute the fractional power of a matrix.
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Proceeds according to the discussion in section (6) of [1]_.
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Parameters
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----------
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A : (N, N) array_like
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Matrix whose fractional power to evaluate.
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t : float
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Fractional power.
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Returns
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-------
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X : (N, N) array_like
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The fractional power of the matrix.
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References
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----------
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.. [1] Nicholas J. Higham and Lijing lin (2011)
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"A Schur-Pade Algorithm for Fractional Powers of a Matrix."
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SIAM Journal on Matrix Analysis and Applications,
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32 (3). pp. 1056-1078. ISSN 0895-4798
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Examples
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--------
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>>> import numpy as np
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>>> from scipy.linalg import fractional_matrix_power
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>>> a = np.array([[1.0, 3.0], [1.0, 4.0]])
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>>> b = fractional_matrix_power(a, 0.5)
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>>> b
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array([[ 0.75592895, 1.13389342],
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[ 0.37796447, 1.88982237]])
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>>> np.dot(b, b) # Verify square root
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array([[ 1., 3.],
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[ 1., 4.]])
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"""
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# This fixes some issue with imports;
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# this function calls onenormest which is in scipy.sparse.
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A = _asarray_square(A)
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import scipy.linalg._matfuncs_inv_ssq
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return scipy.linalg._matfuncs_inv_ssq._fractional_matrix_power(A, t)
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def logm(A, disp=True):
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"""
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Compute matrix logarithm.
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The matrix logarithm is the inverse of
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expm: expm(logm(`A`)) == `A`
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Parameters
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----------
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A : (N, N) array_like
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Matrix whose logarithm to evaluate
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disp : bool, optional
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Print warning if error in the result is estimated large
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instead of returning estimated error. (Default: True)
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Returns
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-------
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logm : (N, N) ndarray
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Matrix logarithm of `A`
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errest : float
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(if disp == False)
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1-norm of the estimated error, ||err||_1 / ||A||_1
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References
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----------
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.. [1] Awad H. Al-Mohy and Nicholas J. Higham (2012)
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"Improved Inverse Scaling and Squaring Algorithms
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for the Matrix Logarithm."
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SIAM Journal on Scientific Computing, 34 (4). C152-C169.
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ISSN 1095-7197
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.. [2] Nicholas J. Higham (2008)
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"Functions of Matrices: Theory and Computation"
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ISBN 978-0-898716-46-7
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.. [3] Nicholas J. Higham and Lijing lin (2011)
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"A Schur-Pade Algorithm for Fractional Powers of a Matrix."
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SIAM Journal on Matrix Analysis and Applications,
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32 (3). pp. 1056-1078. ISSN 0895-4798
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Examples
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--------
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>>> import numpy as np
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>>> from scipy.linalg import logm, expm
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>>> a = np.array([[1.0, 3.0], [1.0, 4.0]])
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>>> b = logm(a)
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>>> b
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array([[-1.02571087, 2.05142174],
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[ 0.68380725, 1.02571087]])
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>>> expm(b) # Verify expm(logm(a)) returns a
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array([[ 1., 3.],
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[ 1., 4.]])
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"""
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A = _asarray_square(A)
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# Avoid circular import ... this is OK, right?
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import scipy.linalg._matfuncs_inv_ssq
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F = scipy.linalg._matfuncs_inv_ssq._logm(A)
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F = _maybe_real(A, F)
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errtol = 1000*eps
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#TODO use a better error approximation
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errest = norm(expm(F)-A,1) / norm(A,1)
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if disp:
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if not isfinite(errest) or errest >= errtol:
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print("logm result may be inaccurate, approximate err =", errest)
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return F
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else:
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return F, errest
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def expm(A):
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"""Compute the matrix exponential of an array.
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Parameters
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----------
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A : ndarray
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Input with last two dimensions are square ``(..., n, n)``.
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Returns
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-------
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eA : ndarray
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The resulting matrix exponential with the same shape of ``A``
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Notes
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-----
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Implements the algorithm given in [1], which is essentially a Pade
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approximation with a variable order that is decided based on the array
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data.
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For input with size ``n``, the memory usage is in the worst case in the
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order of ``8*(n**2)``. If the input data is not of single and double
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precision of real and complex dtypes, it is copied to a new array.
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For cases ``n >= 400``, the exact 1-norm computation cost, breaks even with
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1-norm estimation and from that point on the estimation scheme given in
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[2] is used to decide on the approximation order.
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References
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----------
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.. [1] Awad H. Al-Mohy and Nicholas J. Higham, (2009), "A New Scaling
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and Squaring Algorithm for the Matrix Exponential", SIAM J. Matrix
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Anal. Appl. 31(3):970-989, :doi:`10.1137/09074721X`
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.. [2] Nicholas J. Higham and Francoise Tisseur (2000), "A Block Algorithm
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for Matrix 1-Norm Estimation, with an Application to 1-Norm
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Pseudospectra." SIAM J. Matrix Anal. Appl. 21(4):1185-1201,
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:doi:`10.1137/S0895479899356080`
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Examples
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--------
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>>> import numpy as np
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>>> from scipy.linalg import expm, sinm, cosm
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Matrix version of the formula exp(0) = 1:
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>>> expm(np.zeros((3, 2, 2)))
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array([[[1., 0.],
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[0., 1.]],
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<BLANKLINE>
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[[1., 0.],
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[0., 1.]],
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<BLANKLINE>
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[[1., 0.],
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[0., 1.]]])
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Euler's identity (exp(i*theta) = cos(theta) + i*sin(theta))
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applied to a matrix:
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>>> a = np.array([[1.0, 2.0], [-1.0, 3.0]])
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>>> expm(1j*a)
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array([[ 0.42645930+1.89217551j, -2.13721484-0.97811252j],
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[ 1.06860742+0.48905626j, -1.71075555+0.91406299j]])
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>>> cosm(a) + 1j*sinm(a)
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array([[ 0.42645930+1.89217551j, -2.13721484-0.97811252j],
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[ 1.06860742+0.48905626j, -1.71075555+0.91406299j]])
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"""
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a = np.asarray(A)
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if a.size == 1 and a.ndim < 2:
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return np.array([[np.exp(a.item())]])
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if a.ndim < 2:
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raise LinAlgError('The input array must be at least two-dimensional')
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if a.shape[-1] != a.shape[-2]:
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raise LinAlgError('Last 2 dimensions of the array must be square')
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n = a.shape[-1]
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# Empty array
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if min(*a.shape) == 0:
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return np.empty_like(a)
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# Scalar case
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if a.shape[-2:] == (1, 1):
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return np.exp(a)
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if not np.issubdtype(a.dtype, np.inexact):
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a = a.astype(float)
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elif a.dtype == np.float16:
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a = a.astype(np.float32)
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# Explicit formula for 2x2 case, formula (2.2) in [1]
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# without Kahan's method numerical instabilities can occur.
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if a.shape[-2:] == (2, 2):
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a1, a2, a3, a4 = (a[..., [0], [0]],
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a[..., [0], [1]],
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a[..., [1], [0]],
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a[..., [1], [1]])
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mu = csqrt((a1-a4)**2 + 4*a2*a3)/2. # csqrt slow but handles neg.vals
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eApD2 = np.exp((a1+a4)/2.)
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AmD2 = (a1 - a4)/2.
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coshMu = np.cosh(mu)
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sinchMu = np.ones_like(coshMu)
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mask = mu != 0
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sinchMu[mask] = np.sinh(mu[mask]) / mu[mask]
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eA = np.empty((a.shape), dtype=mu.dtype)
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eA[..., [0], [0]] = eApD2 * (coshMu + AmD2*sinchMu)
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eA[..., [0], [1]] = eApD2 * a2 * sinchMu
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eA[..., [1], [0]] = eApD2 * a3 * sinchMu
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eA[..., [1], [1]] = eApD2 * (coshMu - AmD2*sinchMu)
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if np.isrealobj(a):
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return eA.real
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return eA
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# larger problem with unspecified stacked dimensions.
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n = a.shape[-1]
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eA = np.empty(a.shape, dtype=a.dtype)
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# working memory to hold intermediate arrays
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Am = np.empty((5, n, n), dtype=a.dtype)
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# Main loop to go through the slices of an ndarray and passing to expm
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for ind in product(*[range(x) for x in a.shape[:-2]]):
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aw = a[ind]
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lu = bandwidth(aw)
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if not any(lu): # a is diagonal?
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eA[ind] = np.diag(np.exp(np.diag(aw)))
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continue
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# Generic/triangular case; copy the slice into scratch and send.
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# Am will be mutated by pick_pade_structure
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Am[0, :, :] = aw
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m, s = pick_pade_structure(Am)
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if s != 0: # scaling needed
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Am[:4] *= [[[2**(-s)]], [[4**(-s)]], [[16**(-s)]], [[64**(-s)]]]
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pade_UV_calc(Am, n, m)
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eAw = Am[0]
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if s != 0: # squaring needed
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if (lu[1] == 0) or (lu[0] == 0): # lower/upper triangular
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# This branch implements Code Fragment 2.1 of [1]
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diag_aw = np.diag(aw)
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# einsum returns a writable view
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np.einsum('ii->i', eAw)[:] = np.exp(diag_aw * 2**(-s))
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# super/sub diagonal
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sd = np.diag(aw, k=-1 if lu[1] == 0 else 1)
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for i in range(s-1, -1, -1):
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eAw = eAw @ eAw
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# diagonal
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np.einsum('ii->i', eAw)[:] = np.exp(diag_aw * 2.**(-i))
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exp_sd = _exp_sinch(diag_aw * (2.**(-i))) * (sd * 2**(-i))
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if lu[1] == 0: # lower
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np.einsum('ii->i', eAw[1:, :-1])[:] = exp_sd
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else: # upper
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np.einsum('ii->i', eAw[:-1, 1:])[:] = exp_sd
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else: # generic
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for _ in range(s):
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eAw = eAw @ eAw
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# Zero out the entries from np.empty in case of triangular input
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if (lu[0] == 0) or (lu[1] == 0):
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eA[ind] = np.triu(eAw) if lu[0] == 0 else np.tril(eAw)
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else:
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eA[ind] = eAw
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return eA
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def _exp_sinch(x):
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# Higham's formula (10.42), might overflow, see GH-11839
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lexp_diff = np.diff(np.exp(x))
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l_diff = np.diff(x)
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mask_z = l_diff == 0.
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lexp_diff[~mask_z] /= l_diff[~mask_z]
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lexp_diff[mask_z] = np.exp(x[:-1][mask_z])
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return lexp_diff
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def cosm(A):
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"""
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Compute the matrix cosine.
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This routine uses expm to compute the matrix exponentials.
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Parameters
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----------
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A : (N, N) array_like
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Input array
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Returns
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-------
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cosm : (N, N) ndarray
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Matrix cosine of A
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Examples
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--------
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>>> import numpy as np
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>>> from scipy.linalg import expm, sinm, cosm
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Euler's identity (exp(i*theta) = cos(theta) + i*sin(theta))
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applied to a matrix:
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>>> a = np.array([[1.0, 2.0], [-1.0, 3.0]])
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||
|
>>> expm(1j*a)
|
||
|
array([[ 0.42645930+1.89217551j, -2.13721484-0.97811252j],
|
||
|
[ 1.06860742+0.48905626j, -1.71075555+0.91406299j]])
|
||
|
>>> cosm(a) + 1j*sinm(a)
|
||
|
array([[ 0.42645930+1.89217551j, -2.13721484-0.97811252j],
|
||
|
[ 1.06860742+0.48905626j, -1.71075555+0.91406299j]])
|
||
|
|
||
|
"""
|
||
|
A = _asarray_square(A)
|
||
|
if np.iscomplexobj(A):
|
||
|
return 0.5*(expm(1j*A) + expm(-1j*A))
|
||
|
else:
|
||
|
return expm(1j*A).real
|
||
|
|
||
|
|
||
|
def sinm(A):
|
||
|
"""
|
||
|
Compute the matrix sine.
|
||
|
|
||
|
This routine uses expm to compute the matrix exponentials.
|
||
|
|
||
|
Parameters
|
||
|
----------
|
||
|
A : (N, N) array_like
|
||
|
Input array.
|
||
|
|
||
|
Returns
|
||
|
-------
|
||
|
sinm : (N, N) ndarray
|
||
|
Matrix sine of `A`
|
||
|
|
||
|
Examples
|
||
|
--------
|
||
|
>>> import numpy as np
|
||
|
>>> from scipy.linalg import expm, sinm, cosm
|
||
|
|
||
|
Euler's identity (exp(i*theta) = cos(theta) + i*sin(theta))
|
||
|
applied to a matrix:
|
||
|
|
||
|
>>> a = np.array([[1.0, 2.0], [-1.0, 3.0]])
|
||
|
>>> expm(1j*a)
|
||
|
array([[ 0.42645930+1.89217551j, -2.13721484-0.97811252j],
|
||
|
[ 1.06860742+0.48905626j, -1.71075555+0.91406299j]])
|
||
|
>>> cosm(a) + 1j*sinm(a)
|
||
|
array([[ 0.42645930+1.89217551j, -2.13721484-0.97811252j],
|
||
|
[ 1.06860742+0.48905626j, -1.71075555+0.91406299j]])
|
||
|
|
||
|
"""
|
||
|
A = _asarray_square(A)
|
||
|
if np.iscomplexobj(A):
|
||
|
return -0.5j*(expm(1j*A) - expm(-1j*A))
|
||
|
else:
|
||
|
return expm(1j*A).imag
|
||
|
|
||
|
|
||
|
def tanm(A):
|
||
|
"""
|
||
|
Compute the matrix tangent.
|
||
|
|
||
|
This routine uses expm to compute the matrix exponentials.
|
||
|
|
||
|
Parameters
|
||
|
----------
|
||
|
A : (N, N) array_like
|
||
|
Input array.
|
||
|
|
||
|
Returns
|
||
|
-------
|
||
|
tanm : (N, N) ndarray
|
||
|
Matrix tangent of `A`
|
||
|
|
||
|
Examples
|
||
|
--------
|
||
|
>>> import numpy as np
|
||
|
>>> from scipy.linalg import tanm, sinm, cosm
|
||
|
>>> a = np.array([[1.0, 3.0], [1.0, 4.0]])
|
||
|
>>> t = tanm(a)
|
||
|
>>> t
|
||
|
array([[ -2.00876993, -8.41880636],
|
||
|
[ -2.80626879, -10.42757629]])
|
||
|
|
||
|
Verify tanm(a) = sinm(a).dot(inv(cosm(a)))
|
||
|
|
||
|
>>> s = sinm(a)
|
||
|
>>> c = cosm(a)
|
||
|
>>> s.dot(np.linalg.inv(c))
|
||
|
array([[ -2.00876993, -8.41880636],
|
||
|
[ -2.80626879, -10.42757629]])
|
||
|
|
||
|
"""
|
||
|
A = _asarray_square(A)
|
||
|
return _maybe_real(A, solve(cosm(A), sinm(A)))
|
||
|
|
||
|
|
||
|
def coshm(A):
|
||
|
"""
|
||
|
Compute the hyperbolic matrix cosine.
|
||
|
|
||
|
This routine uses expm to compute the matrix exponentials.
|
||
|
|
||
|
Parameters
|
||
|
----------
|
||
|
A : (N, N) array_like
|
||
|
Input array.
|
||
|
|
||
|
Returns
|
||
|
-------
|
||
|
coshm : (N, N) ndarray
|
||
|
Hyperbolic matrix cosine of `A`
|
||
|
|
||
|
Examples
|
||
|
--------
|
||
|
>>> import numpy as np
|
||
|
>>> from scipy.linalg import tanhm, sinhm, coshm
|
||
|
>>> a = np.array([[1.0, 3.0], [1.0, 4.0]])
|
||
|
>>> c = coshm(a)
|
||
|
>>> c
|
||
|
array([[ 11.24592233, 38.76236492],
|
||
|
[ 12.92078831, 50.00828725]])
|
||
|
|
||
|
Verify tanhm(a) = sinhm(a).dot(inv(coshm(a)))
|
||
|
|
||
|
>>> t = tanhm(a)
|
||
|
>>> s = sinhm(a)
|
||
|
>>> t - s.dot(np.linalg.inv(c))
|
||
|
array([[ 2.72004641e-15, 4.55191440e-15],
|
||
|
[ 0.00000000e+00, -5.55111512e-16]])
|
||
|
|
||
|
"""
|
||
|
A = _asarray_square(A)
|
||
|
return _maybe_real(A, 0.5 * (expm(A) + expm(-A)))
|
||
|
|
||
|
|
||
|
def sinhm(A):
|
||
|
"""
|
||
|
Compute the hyperbolic matrix sine.
|
||
|
|
||
|
This routine uses expm to compute the matrix exponentials.
|
||
|
|
||
|
Parameters
|
||
|
----------
|
||
|
A : (N, N) array_like
|
||
|
Input array.
|
||
|
|
||
|
Returns
|
||
|
-------
|
||
|
sinhm : (N, N) ndarray
|
||
|
Hyperbolic matrix sine of `A`
|
||
|
|
||
|
Examples
|
||
|
--------
|
||
|
>>> import numpy as np
|
||
|
>>> from scipy.linalg import tanhm, sinhm, coshm
|
||
|
>>> a = np.array([[1.0, 3.0], [1.0, 4.0]])
|
||
|
>>> s = sinhm(a)
|
||
|
>>> s
|
||
|
array([[ 10.57300653, 39.28826594],
|
||
|
[ 13.09608865, 49.86127247]])
|
||
|
|
||
|
Verify tanhm(a) = sinhm(a).dot(inv(coshm(a)))
|
||
|
|
||
|
>>> t = tanhm(a)
|
||
|
>>> c = coshm(a)
|
||
|
>>> t - s.dot(np.linalg.inv(c))
|
||
|
array([[ 2.72004641e-15, 4.55191440e-15],
|
||
|
[ 0.00000000e+00, -5.55111512e-16]])
|
||
|
|
||
|
"""
|
||
|
A = _asarray_square(A)
|
||
|
return _maybe_real(A, 0.5 * (expm(A) - expm(-A)))
|
||
|
|
||
|
|
||
|
def tanhm(A):
|
||
|
"""
|
||
|
Compute the hyperbolic matrix tangent.
|
||
|
|
||
|
This routine uses expm to compute the matrix exponentials.
|
||
|
|
||
|
Parameters
|
||
|
----------
|
||
|
A : (N, N) array_like
|
||
|
Input array
|
||
|
|
||
|
Returns
|
||
|
-------
|
||
|
tanhm : (N, N) ndarray
|
||
|
Hyperbolic matrix tangent of `A`
|
||
|
|
||
|
Examples
|
||
|
--------
|
||
|
>>> import numpy as np
|
||
|
>>> from scipy.linalg import tanhm, sinhm, coshm
|
||
|
>>> a = np.array([[1.0, 3.0], [1.0, 4.0]])
|
||
|
>>> t = tanhm(a)
|
||
|
>>> t
|
||
|
array([[ 0.3428582 , 0.51987926],
|
||
|
[ 0.17329309, 0.86273746]])
|
||
|
|
||
|
Verify tanhm(a) = sinhm(a).dot(inv(coshm(a)))
|
||
|
|
||
|
>>> s = sinhm(a)
|
||
|
>>> c = coshm(a)
|
||
|
>>> t - s.dot(np.linalg.inv(c))
|
||
|
array([[ 2.72004641e-15, 4.55191440e-15],
|
||
|
[ 0.00000000e+00, -5.55111512e-16]])
|
||
|
|
||
|
"""
|
||
|
A = _asarray_square(A)
|
||
|
return _maybe_real(A, solve(coshm(A), sinhm(A)))
|
||
|
|
||
|
|
||
|
def funm(A, func, disp=True):
|
||
|
"""
|
||
|
Evaluate a matrix function specified by a callable.
|
||
|
|
||
|
Returns the value of matrix-valued function ``f`` at `A`. The
|
||
|
function ``f`` is an extension of the scalar-valued function `func`
|
||
|
to matrices.
|
||
|
|
||
|
Parameters
|
||
|
----------
|
||
|
A : (N, N) array_like
|
||
|
Matrix at which to evaluate the function
|
||
|
func : callable
|
||
|
Callable object that evaluates a scalar function f.
|
||
|
Must be vectorized (eg. using vectorize).
|
||
|
disp : bool, optional
|
||
|
Print warning if error in the result is estimated large
|
||
|
instead of returning estimated error. (Default: True)
|
||
|
|
||
|
Returns
|
||
|
-------
|
||
|
funm : (N, N) ndarray
|
||
|
Value of the matrix function specified by func evaluated at `A`
|
||
|
errest : float
|
||
|
(if disp == False)
|
||
|
|
||
|
1-norm of the estimated error, ||err||_1 / ||A||_1
|
||
|
|
||
|
Notes
|
||
|
-----
|
||
|
This function implements the general algorithm based on Schur decomposition
|
||
|
(Algorithm 9.1.1. in [1]_).
|
||
|
|
||
|
If the input matrix is known to be diagonalizable, then relying on the
|
||
|
eigendecomposition is likely to be faster. For example, if your matrix is
|
||
|
Hermitian, you can do
|
||
|
|
||
|
>>> from scipy.linalg import eigh
|
||
|
>>> def funm_herm(a, func, check_finite=False):
|
||
|
... w, v = eigh(a, check_finite=check_finite)
|
||
|
... ## if you further know that your matrix is positive semidefinite,
|
||
|
... ## you can optionally guard against precision errors by doing
|
||
|
... # w = np.maximum(w, 0)
|
||
|
... w = func(w)
|
||
|
... return (v * w).dot(v.conj().T)
|
||
|
|
||
|
References
|
||
|
----------
|
||
|
.. [1] Gene H. Golub, Charles F. van Loan, Matrix Computations 4th ed.
|
||
|
|
||
|
Examples
|
||
|
--------
|
||
|
>>> import numpy as np
|
||
|
>>> from scipy.linalg import funm
|
||
|
>>> a = np.array([[1.0, 3.0], [1.0, 4.0]])
|
||
|
>>> funm(a, lambda x: x*x)
|
||
|
array([[ 4., 15.],
|
||
|
[ 5., 19.]])
|
||
|
>>> a.dot(a)
|
||
|
array([[ 4., 15.],
|
||
|
[ 5., 19.]])
|
||
|
|
||
|
"""
|
||
|
A = _asarray_square(A)
|
||
|
# Perform Shur decomposition (lapack ?gees)
|
||
|
T, Z = schur(A)
|
||
|
T, Z = rsf2csf(T,Z)
|
||
|
n,n = T.shape
|
||
|
F = diag(func(diag(T))) # apply function to diagonal elements
|
||
|
F = F.astype(T.dtype.char) # e.g., when F is real but T is complex
|
||
|
|
||
|
minden = abs(T[0,0])
|
||
|
|
||
|
# implement Algorithm 11.1.1 from Golub and Van Loan
|
||
|
# "matrix Computations."
|
||
|
for p in range(1,n):
|
||
|
for i in range(1,n-p+1):
|
||
|
j = i + p
|
||
|
s = T[i-1,j-1] * (F[j-1,j-1] - F[i-1,i-1])
|
||
|
ksl = slice(i,j-1)
|
||
|
val = dot(T[i-1,ksl],F[ksl,j-1]) - dot(F[i-1,ksl],T[ksl,j-1])
|
||
|
s = s + val
|
||
|
den = T[j-1,j-1] - T[i-1,i-1]
|
||
|
if den != 0.0:
|
||
|
s = s / den
|
||
|
F[i-1,j-1] = s
|
||
|
minden = min(minden,abs(den))
|
||
|
|
||
|
F = dot(dot(Z, F), transpose(conjugate(Z)))
|
||
|
F = _maybe_real(A, F)
|
||
|
|
||
|
tol = {0:feps, 1:eps}[_array_precision[F.dtype.char]]
|
||
|
if minden == 0.0:
|
||
|
minden = tol
|
||
|
err = min(1, max(tol,(tol/minden)*norm(triu(T,1),1)))
|
||
|
if prod(ravel(logical_not(isfinite(F))),axis=0):
|
||
|
err = Inf
|
||
|
if disp:
|
||
|
if err > 1000*tol:
|
||
|
print("funm result may be inaccurate, approximate err =", err)
|
||
|
return F
|
||
|
else:
|
||
|
return F, err
|
||
|
|
||
|
|
||
|
def signm(A, disp=True):
|
||
|
"""
|
||
|
Matrix sign function.
|
||
|
|
||
|
Extension of the scalar sign(x) to matrices.
|
||
|
|
||
|
Parameters
|
||
|
----------
|
||
|
A : (N, N) array_like
|
||
|
Matrix at which to evaluate the sign function
|
||
|
disp : bool, optional
|
||
|
Print warning if error in the result is estimated large
|
||
|
instead of returning estimated error. (Default: True)
|
||
|
|
||
|
Returns
|
||
|
-------
|
||
|
signm : (N, N) ndarray
|
||
|
Value of the sign function at `A`
|
||
|
errest : float
|
||
|
(if disp == False)
|
||
|
|
||
|
1-norm of the estimated error, ||err||_1 / ||A||_1
|
||
|
|
||
|
Examples
|
||
|
--------
|
||
|
>>> from scipy.linalg import signm, eigvals
|
||
|
>>> a = [[1,2,3], [1,2,1], [1,1,1]]
|
||
|
>>> eigvals(a)
|
||
|
array([ 4.12488542+0.j, -0.76155718+0.j, 0.63667176+0.j])
|
||
|
>>> eigvals(signm(a))
|
||
|
array([-1.+0.j, 1.+0.j, 1.+0.j])
|
||
|
|
||
|
"""
|
||
|
A = _asarray_square(A)
|
||
|
|
||
|
def rounded_sign(x):
|
||
|
rx = np.real(x)
|
||
|
if rx.dtype.char == 'f':
|
||
|
c = 1e3*feps*amax(x)
|
||
|
else:
|
||
|
c = 1e3*eps*amax(x)
|
||
|
return sign((absolute(rx) > c) * rx)
|
||
|
result, errest = funm(A, rounded_sign, disp=0)
|
||
|
errtol = {0:1e3*feps, 1:1e3*eps}[_array_precision[result.dtype.char]]
|
||
|
if errest < errtol:
|
||
|
return result
|
||
|
|
||
|
# Handle signm of defective matrices:
|
||
|
|
||
|
# See "E.D.Denman and J.Leyva-Ramos, Appl.Math.Comp.,
|
||
|
# 8:237-250,1981" for how to improve the following (currently a
|
||
|
# rather naive) iteration process:
|
||
|
|
||
|
# a = result # sometimes iteration converges faster but where??
|
||
|
|
||
|
# Shifting to avoid zero eigenvalues. How to ensure that shifting does
|
||
|
# not change the spectrum too much?
|
||
|
vals = svd(A, compute_uv=False)
|
||
|
max_sv = np.amax(vals)
|
||
|
# min_nonzero_sv = vals[(vals>max_sv*errtol).tolist().count(1)-1]
|
||
|
# c = 0.5/min_nonzero_sv
|
||
|
c = 0.5/max_sv
|
||
|
S0 = A + c*np.identity(A.shape[0])
|
||
|
prev_errest = errest
|
||
|
for i in range(100):
|
||
|
iS0 = inv(S0)
|
||
|
S0 = 0.5*(S0 + iS0)
|
||
|
Pp = 0.5*(dot(S0,S0)+S0)
|
||
|
errest = norm(dot(Pp,Pp)-Pp,1)
|
||
|
if errest < errtol or prev_errest == errest:
|
||
|
break
|
||
|
prev_errest = errest
|
||
|
if disp:
|
||
|
if not isfinite(errest) or errest >= errtol:
|
||
|
print("signm result may be inaccurate, approximate err =", errest)
|
||
|
return S0
|
||
|
else:
|
||
|
return S0, errest
|
||
|
|
||
|
|
||
|
def khatri_rao(a, b):
|
||
|
r"""
|
||
|
Khatri-rao product
|
||
|
|
||
|
A column-wise Kronecker product of two matrices
|
||
|
|
||
|
Parameters
|
||
|
----------
|
||
|
a : (n, k) array_like
|
||
|
Input array
|
||
|
b : (m, k) array_like
|
||
|
Input array
|
||
|
|
||
|
Returns
|
||
|
-------
|
||
|
c: (n*m, k) ndarray
|
||
|
Khatri-rao product of `a` and `b`.
|
||
|
|
||
|
See Also
|
||
|
--------
|
||
|
kron : Kronecker product
|
||
|
|
||
|
Notes
|
||
|
-----
|
||
|
The mathematical definition of the Khatri-Rao product is:
|
||
|
|
||
|
.. math::
|
||
|
|
||
|
(A_{ij} \bigotimes B_{ij})_{ij}
|
||
|
|
||
|
which is the Kronecker product of every column of A and B, e.g.::
|
||
|
|
||
|
c = np.vstack([np.kron(a[:, k], b[:, k]) for k in range(b.shape[1])]).T
|
||
|
|
||
|
Examples
|
||
|
--------
|
||
|
>>> import numpy as np
|
||
|
>>> from scipy import linalg
|
||
|
>>> a = np.array([[1, 2, 3], [4, 5, 6]])
|
||
|
>>> b = np.array([[3, 4, 5], [6, 7, 8], [2, 3, 9]])
|
||
|
>>> linalg.khatri_rao(a, b)
|
||
|
array([[ 3, 8, 15],
|
||
|
[ 6, 14, 24],
|
||
|
[ 2, 6, 27],
|
||
|
[12, 20, 30],
|
||
|
[24, 35, 48],
|
||
|
[ 8, 15, 54]])
|
||
|
|
||
|
"""
|
||
|
a = np.asarray(a)
|
||
|
b = np.asarray(b)
|
||
|
|
||
|
if not (a.ndim == 2 and b.ndim == 2):
|
||
|
raise ValueError("The both arrays should be 2-dimensional.")
|
||
|
|
||
|
if not a.shape[1] == b.shape[1]:
|
||
|
raise ValueError("The number of columns for both arrays "
|
||
|
"should be equal.")
|
||
|
|
||
|
# c = np.vstack([np.kron(a[:, k], b[:, k]) for k in range(b.shape[1])]).T
|
||
|
c = a[..., :, np.newaxis, :] * b[..., np.newaxis, :, :]
|
||
|
return c.reshape((-1,) + c.shape[2:])
|