382 lines
11 KiB
Python
382 lines
11 KiB
Python
"""
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arpack - Scipy module to find a few eigenvectors and eigenvalues of a matrix
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Uses ARPACK: http://www.caam.rice.edu/software/ARPACK/
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"""
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__all___=['eigen','eigen_symmetric']
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import _arpack
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import numpy as sb
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import warnings
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# inspired by iterative.py
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# so inspired, in fact, that some of it was copied directly
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try:
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False, True
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except NameError:
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False, True = 0, 1
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_type_conv = {'f':'s', 'd':'d', 'F':'c', 'D':'z'}
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class get_matvec:
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methname = 'matvec'
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def __init__(self, obj, *args):
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self.obj = obj
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self.args = args
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if isinstance(obj, sb.matrix):
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self.callfunc = self.type1m
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return
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if isinstance(obj, sb.ndarray):
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self.callfunc = self.type1
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return
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meth = getattr(obj,self.methname,None)
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if not callable(meth):
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raise ValueError, "Object must be an array "\
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"or have a callable %s attribute." % (self.methname,)
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self.obj = meth
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self.callfunc = self.type2
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def __call__(self, x):
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return self.callfunc(x)
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def type1(self, x):
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return sb.dot(self.obj, x)
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def type1m(self, x):
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return sb.dot(self.obj.A, x)
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def type2(self, x):
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return self.obj(x,*self.args)
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def eigen(A,k=6,M=None,ncv=None,which='LM',
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maxiter=None,tol=0, return_eigenvectors=True):
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""" Return k eigenvalues and eigenvectors of the matrix A.
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Solves A * x[i] = w[i] * x[i], the standard eigenvalue problem for
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w[i] eigenvalues with corresponding eigenvectors x[i].
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Inputs:
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A -- A matrix, array or an object with matvec(x) method to perform
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the matrix vector product A * x. The sparse matrix formats
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in scipy.sparse are appropriate for A.
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k -- The number of eigenvalue/eigenvectors desired
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M -- (Not implemented)
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A symmetric positive-definite matrix for the generalized
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eigenvalue problem A * x = w * M * x
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Outputs:
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w -- An array of k eigenvalues
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v -- An array of k eigenvectors, k[i] is the eigenvector corresponding
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to the eigenvector w[i]
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Optional Inputs:
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ncv -- Number of Lanczos vectors generated, ncv must be greater than k
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and is recommended to be ncv > 2*k
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which -- String specifying which eigenvectors to compute.
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Compute the k eigenvalues of:
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'LM' - largest magnitude.
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'SM' - smallest magnitude.
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'LR' - largest real part.
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'SR' - smallest real part.
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'LI' - largest imaginary part.
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'SI' - smallest imaginary part.
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maxiter -- Maximum number of Arnoldi update iterations allowed
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tol -- Relative accuracy for eigenvalues (stopping criterion)
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return_eigenvectors -- True|False, return eigenvectors
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"""
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try:
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n,ny=A.shape
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n==ny
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except:
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raise AttributeError("matrix is not square")
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if M is not None:
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raise NotImplementedError("generalized eigenproblem not supported yet")
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# some defaults
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if ncv is None:
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ncv=2*k+1
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ncv=min(ncv,n)
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if maxiter==None:
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maxiter=n*10
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# guess type
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resid = sb.zeros(n,'f')
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try:
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typ = A.dtype.char
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except AttributeError:
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typ = A.matvec(resid).dtype.char
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if typ not in 'fdFD':
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raise ValueError("matrix type must be 'f', 'd', 'F', or 'D'")
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# some sanity checks
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if k <= 0:
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raise ValueError("k must be positive, k=%d"%k)
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if k == n:
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raise ValueError("k must be less than rank(A), k=%d"%k)
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if maxiter <= 0:
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raise ValueError("maxiter must be positive, maxiter=%d"%maxiter)
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whiches=['LM','SM','LR','SR','LI','SI']
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if which not in whiches:
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raise ValueError("which must be one of %s"%' '.join(whiches))
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if ncv > n or ncv < k:
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raise ValueError("ncv must be k<=ncv<=n, ncv=%s"%ncv)
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# assign solver and postprocessor
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ltr = _type_conv[typ]
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eigsolver = _arpack.__dict__[ltr+'naupd']
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eigextract = _arpack.__dict__[ltr+'neupd']
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matvec = get_matvec(A)
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v = sb.zeros((n,ncv),typ) # holds Ritz vectors
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resid = sb.zeros(n,typ) # residual
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workd = sb.zeros(3*n,typ) # workspace
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workl = sb.zeros(3*ncv*ncv+6*ncv,typ) # workspace
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iparam = sb.zeros(11,'int') # problem parameters
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ipntr = sb.zeros(14,'int') # pointers into workspaces
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info = 0
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ido = 0
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if typ in 'FD':
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rwork = sb.zeros(ncv,typ.lower())
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# only supported mode is 1: Ax=lx
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ishfts = 1
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mode1 = 1
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bmat = 'I'
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iparam[0] = ishfts
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iparam[2] = maxiter
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iparam[6] = mode1
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while True:
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if typ in 'fd':
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ido,resid,v,iparam,ipntr,info =\
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eigsolver(ido,bmat,which,k,tol,resid,v,iparam,ipntr,
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workd,workl,info)
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else:
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ido,resid,v,iparam,ipntr,info =\
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eigsolver(ido,bmat,which,k,tol,resid,v,iparam,ipntr,
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workd,workl,rwork,info)
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if (ido == -1 or ido == 1):
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# compute y = A * x
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xslice = slice(ipntr[0]-1, ipntr[0]-1+n)
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yslice = slice(ipntr[1]-1, ipntr[1]-1+n)
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workd[yslice]=matvec(workd[xslice])
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else: # done
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break
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if info < -1 :
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raise RuntimeError("Error info=%d in arpack"%info)
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return None
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if info == -1:
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warnings.warn("Maximum number of iterations taken: %s"%iparam[2])
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# if iparam[3] != k:
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# warnings.warn("Only %s eigenvalues converged"%iparam[3])
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# now extract eigenvalues and (optionally) eigenvectors
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rvec = return_eigenvectors
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ierr = 0
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howmny = 'A' # return all eigenvectors
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sselect = sb.zeros(ncv,'int') # unused
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sigmai = 0.0 # no shifts, not implemented
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sigmar = 0.0 # no shifts, not implemented
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workev = sb.zeros(3*ncv,typ)
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if typ in 'fd':
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dr=sb.zeros(k+1,typ)
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di=sb.zeros(k+1,typ)
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zr=sb.zeros((n,k+1),typ)
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dr,di,z,info=\
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eigextract(rvec,howmny,sselect,sigmar,sigmai,workev,
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bmat,which,k,tol,resid,v,iparam,ipntr,
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workd,workl,info)
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# make eigenvalues complex
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d=dr+1.0j*di
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# futz with the eigenvectors:
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# complex are stored as real,imaginary in consecutive columns
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z=zr.astype(typ.upper())
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for i in range(k): # fix c.c. pairs
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if di[i] > 0 :
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z[:,i]=zr[:,i]+1.0j*zr[:,i+1]
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z[:,i+1]=z[:,i].conjugate()
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else:
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d,z,info =\
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eigextract(rvec,howmny,sselect,sigmar,workev,
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bmat,which,k,tol,resid,v,iparam,ipntr,
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workd,workl,rwork,ierr)
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if ierr != 0:
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raise RuntimeError("Error info=%d in arpack"%info)
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return None
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if return_eigenvectors:
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return d,z
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return d
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def eigen_symmetric(A,k=6,M=None,ncv=None,which='LM',
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maxiter=None,tol=0, return_eigenvectors=True):
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""" Return k eigenvalues and eigenvectors of the real symmetric matrix A.
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Solves A * x[i] = w[i] * x[i], the standard eigenvalue problem for
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w[i] eigenvalues with corresponding eigenvectors x[i].
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A must be real and symmetric.
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See eigen() for nonsymmetric or complex symmetric (Hermetian) matrices.
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Inputs:
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A -- A symmetric matrix, array or an object with matvec(x) method
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to perform the matrix vector product A * x.
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The sparse matrix formats in scipy.sparse are appropriate for A.
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k -- The number of eigenvalue/eigenvectors desired
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M -- (Not implemented)
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A symmetric positive-definite matrix for the generalized
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eigenvalue problem A * x = w * M * x
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Outputs:
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w -- An real array of k eigenvalues
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v -- An array of k real eigenvectors, k[i] is the eigenvector corresponding
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to the eigenvector w[i]
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Optional Inputs:
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ncv -- Number of Lanczos vectors generated, ncv must be greater than k
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and is recommended to be ncv > 2*k
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which -- String specifying which eigenvectors to compute.
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Compute the k
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'LA' - largest (algebraic) eigenvalues.
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'SA' - smallest (algebraic) eigenvalues.
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'LM' - largest (in magnitude) eigenvalues.
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'SM' - smallest (in magnitude) eigenvalues.
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'BE' - eigenvalues, half from each end of the
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spectrum. When NEV is odd, compute one more from the
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high end than from the low end.
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maxiter -- Maximum number of Arnoldi update iterations allowed
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tol -- Relative accuracy for eigenvalues (stopping criterion)
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return_eigenvectors -- True|False, return eigenvectors
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"""
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try:
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n,ny=A.shape
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n==ny
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except:
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raise AttributeError("matrix is not square")
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if M is not None:
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raise NotImplementedError("generalized eigenproblem not supported yet")
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if ncv is None:
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ncv=2*k+1
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ncv=min(ncv,n)
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if maxiter==None:
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maxiter=n*10
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# guess type
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resid = sb.zeros(n,'f')
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try:
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typ = A.dtype.char
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except AttributeError:
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typ = A.matvec(resid).dtype.char
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if typ not in 'fd':
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raise ValueError("matrix type must be 'f' or 'd'")
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# some sanity checks
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if k <= 0:
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raise ValueError("k must be positive, k=%d"%k)
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if k == n:
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raise ValueError("k must be less than rank(A), k=%d"%k)
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if maxiter <= 0:
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raise ValueError("maxiter must be positive, maxiter=%d"%maxiter)
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whiches=['LM','SM','LA','SA','BE']
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if which not in whiches:
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raise ValueError("which must be one of %s"%' '.join(whiches))
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if ncv > n or ncv < k:
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raise ValueError("ncv must be k<=ncv<=n, ncv=%s"%ncv)
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# assign solver and postprocessor
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ltr = _type_conv[typ]
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eigsolver = _arpack.__dict__[ltr+'saupd']
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eigextract = _arpack.__dict__[ltr+'seupd']
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matvec = get_matvec(A)
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v = sb.zeros((n,ncv),typ)
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resid = sb.zeros(n,typ)
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workd = sb.zeros(3*n,typ)
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workl = sb.zeros(ncv*(ncv+8),typ)
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iparam = sb.zeros(11,'int')
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ipntr = sb.zeros(11,'int')
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info = 0
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ido = 0
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# only supported mode is 1: Ax=lx
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ishfts = 1
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mode1 = 1
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bmat='I'
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iparam[0] = ishfts
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iparam[2] = maxiter
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iparam[6] = mode1
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while True:
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ido,resid,v,iparam,ipntr,info =\
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eigsolver(ido,bmat,which,k,tol,resid,v,iparam,ipntr,
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workd,workl,info)
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if (ido == -1 or ido == 1):
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xslice = slice(ipntr[0]-1, ipntr[0]-1+n)
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yslice = slice(ipntr[1]-1, ipntr[1]-1+n)
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workd[yslice]=matvec(workd[xslice])
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else:
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break
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if info < -1 :
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raise RuntimeError("Error info=%d in arpack"%info)
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return None
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if info == -1:
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warnings.warn("Maximum number of iterations taken: %s"%iparam[2])
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# now extract eigenvalues and (optionally) eigenvectors
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rvec = return_eigenvectors
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ierr = 0
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howmny = 'A' # return all eigenvectors
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sselect = sb.zeros(ncv,'int') # unused
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sigma = 0.0 # no shifts, not implemented
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d,z,info =\
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eigextract(rvec,howmny,sselect,sigma,
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bmat,which, k,tol,resid,v,iparam[0:7],ipntr,
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workd[0:2*n],workl,ierr)
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if ierr != 0:
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raise RuntimeError("Error info=%d in arpack"%info)
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return None
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if return_eigenvectors:
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return d,z
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return d
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