192 lines
6.5 KiB
Python
192 lines
6.5 KiB
Python
import numpy as np
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from .iterative import _get_atol_rtol
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from .utils import make_system
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from scipy._lib.deprecation import _NoValue, _deprecate_positional_args
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__all__ = ['tfqmr']
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@_deprecate_positional_args(version="1.14.0")
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def tfqmr(A, b, x0=None, *, tol=_NoValue, maxiter=None, M=None,
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callback=None, atol=None, rtol=1e-5, show=False):
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"""
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Use Transpose-Free Quasi-Minimal Residual iteration to solve ``Ax = b``.
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Parameters
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----------
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A : {sparse matrix, ndarray, LinearOperator}
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The real or complex N-by-N matrix of the linear system.
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Alternatively, `A` can be a linear operator which can
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produce ``Ax`` using, e.g.,
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`scipy.sparse.linalg.LinearOperator`.
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b : {ndarray}
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Right hand side of the linear system. Has shape (N,) or (N,1).
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x0 : {ndarray}
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Starting guess for the solution.
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rtol, atol : float, optional
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Parameters for the convergence test. For convergence,
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``norm(b - A @ x) <= max(rtol*norm(b), atol)`` should be satisfied.
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The default is ``rtol=1e-5``, the default for ``atol`` is ``rtol``.
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.. warning::
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The default value for ``atol`` will be changed to ``0.0`` in
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SciPy 1.14.0.
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maxiter : int, optional
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Maximum number of iterations. Iteration will stop after maxiter
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steps even if the specified tolerance has not been achieved.
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Default is ``min(10000, ndofs * 10)``, where ``ndofs = A.shape[0]``.
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M : {sparse matrix, ndarray, LinearOperator}
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Inverse of the preconditioner of A. M should approximate the
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inverse of A and be easy to solve for (see Notes). Effective
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preconditioning dramatically improves the rate of convergence,
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which implies that fewer iterations are needed to reach a given
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error tolerance. By default, no preconditioner is used.
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callback : function, optional
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User-supplied function to call after each iteration. It is called
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as `callback(xk)`, where `xk` is the current solution vector.
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show : bool, optional
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Specify ``show = True`` to show the convergence, ``show = False`` is
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to close the output of the convergence.
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Default is `False`.
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tol : float, optional, deprecated
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.. deprecated:: 1.12.0
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`tfqmr` keyword argument ``tol`` is deprecated in favor of ``rtol``
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and will be removed in SciPy 1.14.0.
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Returns
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-------
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x : ndarray
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The converged solution.
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info : int
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Provides convergence information:
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- 0 : successful exit
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- >0 : convergence to tolerance not achieved, number of iterations
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- <0 : illegal input or breakdown
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Notes
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-----
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The Transpose-Free QMR algorithm is derived from the CGS algorithm.
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However, unlike CGS, the convergence curves for the TFQMR method is
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smoothed by computing a quasi minimization of the residual norm. The
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implementation supports left preconditioner, and the "residual norm"
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to compute in convergence criterion is actually an upper bound on the
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actual residual norm ``||b - Axk||``.
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References
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----------
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.. [1] R. W. Freund, A Transpose-Free Quasi-Minimal Residual Algorithm for
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Non-Hermitian Linear Systems, SIAM J. Sci. Comput., 14(2), 470-482,
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1993.
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.. [2] Y. Saad, Iterative Methods for Sparse Linear Systems, 2nd edition,
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SIAM, Philadelphia, 2003.
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.. [3] C. T. Kelley, Iterative Methods for Linear and Nonlinear Equations,
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number 16 in Frontiers in Applied Mathematics, SIAM, Philadelphia,
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1995.
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Examples
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--------
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>>> import numpy as np
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>>> from scipy.sparse import csc_matrix
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>>> from scipy.sparse.linalg import tfqmr
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>>> A = csc_matrix([[3, 2, 0], [1, -1, 0], [0, 5, 1]], dtype=float)
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>>> b = np.array([2, 4, -1], dtype=float)
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>>> x, exitCode = tfqmr(A, b)
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>>> print(exitCode) # 0 indicates successful convergence
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0
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>>> np.allclose(A.dot(x), b)
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True
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"""
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# Check data type
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dtype = A.dtype
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if np.issubdtype(dtype, np.int64):
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dtype = float
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A = A.astype(dtype)
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if np.issubdtype(b.dtype, np.int64):
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b = b.astype(dtype)
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A, M, x, b, postprocess = make_system(A, M, x0, b)
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# Check if the R.H.S is a zero vector
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if np.linalg.norm(b) == 0.:
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x = b.copy()
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return (postprocess(x), 0)
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ndofs = A.shape[0]
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if maxiter is None:
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maxiter = min(10000, ndofs * 10)
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if x0 is None:
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r = b.copy()
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else:
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r = b - A.matvec(x)
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u = r
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w = r.copy()
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# Take rstar as b - Ax0, that is rstar := r = b - Ax0 mathematically
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rstar = r
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v = M.matvec(A.matvec(r))
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uhat = v
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d = theta = eta = 0.
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# at this point we know rstar == r, so rho is always real
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rho = np.inner(rstar.conjugate(), r).real
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rhoLast = rho
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r0norm = np.sqrt(rho)
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tau = r0norm
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if r0norm == 0:
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return (postprocess(x), 0)
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# we call this to get the right atol and raise warnings as necessary
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atol, _ = _get_atol_rtol('tfqmr', r0norm, tol, atol, rtol)
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for iter in range(maxiter):
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even = iter % 2 == 0
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if (even):
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vtrstar = np.inner(rstar.conjugate(), v)
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# Check breakdown
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if vtrstar == 0.:
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return (postprocess(x), -1)
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alpha = rho / vtrstar
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uNext = u - alpha * v # [1]-(5.6)
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w -= alpha * uhat # [1]-(5.8)
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d = u + (theta**2 / alpha) * eta * d # [1]-(5.5)
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# [1]-(5.2)
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theta = np.linalg.norm(w) / tau
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c = np.sqrt(1. / (1 + theta**2))
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tau *= theta * c
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# Calculate step and direction [1]-(5.4)
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eta = (c**2) * alpha
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z = M.matvec(d)
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x += eta * z
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if callback is not None:
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callback(x)
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# Convergence criterion
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if tau * np.sqrt(iter+1) < atol:
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if (show):
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print("TFQMR: Linear solve converged due to reach TOL "
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f"iterations {iter+1}")
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return (postprocess(x), 0)
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if (not even):
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# [1]-(5.7)
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rho = np.inner(rstar.conjugate(), w)
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beta = rho / rhoLast
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u = w + beta * u
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v = beta * uhat + (beta**2) * v
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uhat = M.matvec(A.matvec(u))
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v += uhat
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else:
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uhat = M.matvec(A.matvec(uNext))
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u = uNext
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rhoLast = rho
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if (show):
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print("TFQMR: Linear solve not converged due to reach MAXIT "
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f"iterations {iter+1}")
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return (postprocess(x), maxiter)
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