Source code for qutip.simdiag

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__all__ = ['simdiag']

import numpy as np
import scipy.linalg as la
from qutip.qobj import Qobj


[docs]def simdiag(ops, evals=True): """Simulateous diagonalization of communting Hermitian matrices.. Parameters ---------- ops : list/array ``list`` or ``array`` of qobjs representing commuting Hermitian operators. Returns -------- eigs : tuple Tuple of arrays representing eigvecs and eigvals of quantum objects corresponding to simultaneous eigenvectors and eigenvalues for each operator. """ tol = 1e-14 start_flag = 0 if not any(ops): raise ValueError('Need at least one input operator.') if not isinstance(ops, (list, np.ndarray)): ops = np.array([ops]) num_ops = len(ops) for jj in range(num_ops): A = ops[jj] shape = A.shape if shape[0] != shape[1]: raise TypeError('Matricies must be square.') if start_flag == 0: s = shape[0] if s != shape[0]: raise TypeError('All matrices. must be the same shape') if not A.isherm: raise TypeError('Matricies must be Hermitian') for kk in range(jj): B = ops[kk] if (A * B - B * A).norm() / (A * B).norm() > tol: raise TypeError('Matricies must commute.') A = ops[0] eigvals, eigvecs = la.eig(A.full()) zipped = zip(-eigvals, range(len(eigvals))) zipped.sort() ds, perm = zip(*zipped) ds = -np.real(np.array(ds)) perm = np.array(perm) eigvecs_array = np.array( [np.zeros((A.shape[0], 1), dtype=complex) for k in range(A.shape[0])]) for kk in range(len(perm)): # matrix with sorted eigvecs in columns eigvecs_array[kk][:, 0] = eigvecs[:, perm[kk]] k = 0 rng = np.arange(len(eigvals)) while k < len(ds): # find degenerate eigenvalues, get indicies of degenerate eigvals inds = np.array(abs(ds - ds[k]) < max(tol, tol * abs(ds[k]))) inds = rng[inds] if len(inds) > 1: # if at least 2 eigvals are degenerate eigvecs_array[inds] = degen( tol, eigvecs_array[inds], np.array([ops[kk] for kk in range(1, num_ops)])) k = max(inds) + 1 eigvals_out = np.zeros((num_ops, len(ds)), dtype=float) kets_out = np.array([Qobj(eigvecs_array[j] / la.norm(eigvecs_array[j]), dims=[ops[0].dims[0], [1]], shape=[ops[0].shape[0], 1]) for j in range(len(ds))]) if not evals: return kets_out else: for kk in range(num_ops): for j in range(len(ds)): eigvals_out[kk, j] = np.real(np.dot( eigvecs_array[j].conj().T, ops[kk].data * eigvecs_array[j])) return eigvals_out, kets_out
def degen(tol, in_vecs, ops): """ Private function that finds eigen vals and vecs for degenerate matrices.. """ n = len(ops) if n == 0: return in_vecs A = ops[0] vecs = np.column_stack(in_vecs) eigvals, eigvecs = la.eig(np.dot(vecs.conj().T, A.data.dot(vecs))) zipped = zip(-eigvals, range(len(eigvals))) zipped.sort() ds, perm = zip(*zipped) ds = -np.real(np.array(ds)) perm = np.array(perm) vecsperm = np.zeros(eigvecs.shape, dtype=complex) for kk in range(len(perm)): # matrix with sorted eigvecs in columns vecsperm[:, kk] = eigvecs[:, perm[kk]] vecs_new = np.dot(vecs, vecsperm) vecs_out = np.array( [np.zeros((A.shape[0], 1), dtype=complex) for k in range(len(ds))]) for kk in range(len(perm)): # matrix with sorted eigvecs in columns vecs_out[kk][:, 0] = vecs_new[:, kk] k = 0 rng = np.arange(len(ds)) while k < len(ds): inds = np.array(abs(ds - ds[k]) < max( tol, tol * abs(ds[k]))) # get indicies of degenerate eigvals inds = rng[inds] if len(inds) > 1: # if at least 2 eigvals are degenerate vecs_out[inds] = degen(tol, vecs_out[inds], np.array([ops[jj] for jj in range(1, n)])) k = max(inds) + 1 return vecs_out