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OperatorSinkhorn.m
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OperatorSinkhorn.m
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%% OPERATORSINKHORN Performs the operator Sinkhorn iteration
% This function has one required argument:
% RHO: a density matrix
%
% SIGMA = OperatorSinkhorn(RHO) is a density matrix that is locally
% equivalent to RHO, but has both of its partial traces proportional to
% the identity (RHO must be bipartite; if it is multipartite, see the
% optional arguments below).
%
% Such a density matrix SIGMA does not always exist if RHO is low-rank.
% An error is returned in these cases.
%
% This function has two optional input arguments:
% DIM (default has two subsystems of equal dimension)
% TOL (default sqrt(eps))
%
% This function has one optional output argument:
% F: a cell containing local matrices
%
% [SIGMA,F] = OperatorSinkhorn(RHO,DIM,TOL) returns SIGMA and F such that
% SIGMA has all of its (single-party) reduced density matrices
% proportional to the identity, and SIGMA = Tensor(F)*RHO*Tensor(F)'. In
% other words, F contains invertible local operations that demonstrate
% that RHO and SIGMA are locally equivalent.
%
% DIM is a 1-by-2 vector containing the dimensions of the subsystems on
% which RHO acts (RHO can act on any number of parties). TOL is the
% numerical tolerance used when determining when the operator Sinkhorn
% iteration has converged.
%
% URL: http://www.qetlab.com/OperatorSinkhorn
% requires: opt_args.m, PartialTrace.m, PermuteSystems.m
%
% author: Nathaniel Johnston ([email protected])
% package: QETLAB
% last updated: October 3, 2014
function [sigma,F] = OperatorSinkhorn(rho,varargin)
dX = length(rho);
sdX = round(sqrt(dX));
tr_rho = trace(rho);
% set optional argument defaults: dim=sqrt(length(rho)), tol=sqrt(eps)
[dim,tol] = opt_args({ [sdX, sdX], sqrt(eps) },varargin{:});
num_sys = length(dim);
% allow the user to enter a single number for dim
if(num_sys == 1)
dim = [dim,dX/dim];
if abs(dim(2) - round(dim(2))) >= 2*dX*eps
error('OperatorSinkhorn:InvalidDim','If DIM is a scalar, X must be square and DIM must evenly divide length(X); please provide the DIM array containing the dimensions of the subsystems.');
end
dim(2) = round(dim(2));
num_sys = 2;
end
tr_rho_p = tr_rho^(1/(2*num_sys));
% Prepare the iteration.
for j = num_sys:-1:1
Prho{j} = eye(dim(j))/dim(j);
Prho_tmp{j} = Prho{j};
F{j} = eye(dim(j))*tr_rho_p;
ldim(j) = prod(dim(1:j-1));
rdim(j) = prod(dim(j+1:end));
end
% Perform the operator Sinkhorn iteration.
lastwarn(''); % clears any previous warnings
warning('off','MATLAB:singularMatrix'); % we want to catch invertibility warnings, but not display them
warning('off','MATLAB:nearlySingularMatrix'); % we want to catch invertibility warnings, but not display them
it_err = 1;
while it_err > tol
it_err = 0;
max_cond = 0;
% Loop over each of the systems and apply a filter on each one.
try
for j = 1:num_sys
% Compute the reduced density matrix on the j-th system.
Prho_tmp{j} = PartialTrace(rho,setdiff(1:num_sys,j),dim);
Prho_tmp{j} = (Prho_tmp{j}+Prho_tmp{j}')/2; % for numerical stability
it_err = it_err + norm(Prho{j}-Prho_tmp{j});
Prho{j} = Prho_tmp{j};
% Apply the filter.
T = sqrtm(inv(Prho{j}))/sqrt(dim(j));
Tk = kron(speye(ldim(j)),kron(T,speye(rdim(j))));
rho = Tk*rho*Tk';
F{j} = T*F{j};
max_cond = max(max_cond,cond(F{j}));
end
catch err
it_err = 1;
end
% Make sure that the local transformation performed is invertible --
% otherwise, the iteration will typically not converge and the results
% will be meaningless.
[~,warnid] = lastwarn;
if(it_err == 1 || max_cond >= 1/tol || strcmpi('MATLAB:nearlySingularMatrix',warnid) || strcmpi('MATLAB:singularMatrix',warnid))
error('OperatorSinkhorn:LowRank','The operator Sinkhorn iteration does not converge for RHO. This is often the case if RHO is not of full rank.');
end
end
warning('on','MATLAB:singularMatrix')
warning('on','MATLAB:nearlySingularMatrix')
sigma = (rho+rho')/2; % done for numerical stability reasons
sigma = tr_rho*sigma/trace(sigma); % correct the scaling of the output