Accuracy Problem when solving linear equation system using: lu(S) vs. decomposition(S,'lu')

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Sebastian Raabe
Sebastian Raabe on 20 Dec 2021
Commented: Sebastian Raabe on 23 Dec 2021
Hello Matlab Community,
I want to solve an equation system B = S * X with a sparse coefficient matrix S by using LU factorisation.
There are two ways to do that:
  1. [l,u,p,q,d] = lu(S) (with the 2 triangular matrices l and u, the 2 permutation matrices p and q and a scaling matrix d)
  2. dS = decomposition(S,'lu') (with the decomposition object dS).
To solve the equation system I use:
  1. X = q * (u \ (l \ (p * (d \ B)))) (see Matlab documentation)
  2. X = dS \ B (where mldivide is a member function of dS).
I calculate the error of the two solutions by using norm(B - S * X). The following code evaluates the error for different sizes of S.
rng(42)
DeltaSize = 500;
M = DeltaSize:DeltaSize:10000;
ErrorLU = zeros(numel(M),1);
ErrorLUObject = zeros(numel(M),1);
for cnt = 1:numel(M)
disp(num2str(cnt))
MatrixDimension = M(cnt);
NumberOfNNZ = 0.1 * MatrixDimension^2;
% Build S and B
row = randi([1,MatrixDimension],NumberOfNNZ,1);
col = randi([1,MatrixDimension],NumberOfNNZ,1);
v = rand(NumberOfNNZ,1) + 1i * rand(NumberOfNNZ,1);
S = sparse(row,col,v,MatrixDimension,MatrixDimension) + speye(MatrixDimension);
B = rand(MatrixDimension,1) + 1i * rand(MatrixDimension,1);
% use LU
[l,u,p,q,d] = lu(S);
X = q * (u \ (l \ (p * (d \ B))));
ErrorLU(cnt) = norm(full(B - S * X));
% use decomposition object
dS = decomposition(S,'lu');
X = dS \ B;
ErrorLUObject(cnt) = norm(full(B - S * X));
end
LogErrorLU = log10(ErrorLU);
LogErrorLUObject = log10(ErrorLUObject);
figure(1)
plot(M,LogErrorLU,'.-','Displayname','lu(S)')
hold on
plot(M,LogErrorLUObject,'.-','Displayname','decomposition(S,lu)')
hold off
ylim([-17 -5])
legend show
grid on
When I run the code, I get a difference of more than three orders of magnitude...see the following figure.
Why is the error of lu(S) bigger than the error of dS? When I go into the decomposition.m file and from that into SparseLU.m I can see that the same matrices are computed in SparseLU like in lu(S) (Line 43 in SparseLU: only with: p -> Pleft, q -> Pright, d -> S).
The only difference I've spotted so far is, that when matlab computes X = dS \ B it uses the MuPAD (see: solve.m line 293).
Is this the only reason for the big difference between the two errors?
Thank you for your hlep.

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Accepted Answer

Christine Tobler
Christine Tobler on 23 Dec 2021
Ran in:
The version in decomposition does some optional steps of iterative refinement: It uses the same solution you have above based on calling lu (up to minor round-off because things are stored in different format). However, it then checks the resulting residual and does another solve with just that residual as a right-hand side if necessary:
rng(42)
DeltaSize = 500;
M = DeltaSize:DeltaSize:2000; % Reduced length for run-time
ErrorLU = zeros(numel(M),1);
ErrorLUrefined = zeros(numel(M),1);
ErrorLUObject = zeros(numel(M),1);
for cnt = 1:numel(M)
disp(num2str(cnt))
MatrixDimension = M(cnt);
NumberOfNNZ = 0.1 * MatrixDimension^2;
% Build S and B
row = randi([1,MatrixDimension],NumberOfNNZ,1);
col = randi([1,MatrixDimension],NumberOfNNZ,1);
v = rand(NumberOfNNZ,1) + 1i * rand(NumberOfNNZ,1);
S = sparse(row,col,v,MatrixDimension,MatrixDimension) + speye(MatrixDimension);
B = rand(MatrixDimension,1) + 1i * rand(MatrixDimension,1);
% use LU
[l,u,p,q,d] = lu(S);
X = q * (u \ (l \ (p * (d \ B))));
ErrorLU(cnt) = norm(full(B - S * X));
% use LU with iterative refinement
R = B - S * X;
Xerr = q * (u \ (l \ (p * (d \ R))));
X = X + Xerr;
ErrorLUrefined(cnt) = norm(full(B - S * X));
% use decomposition object
dS = decomposition(S,'lu');
X = dS \ B;
ErrorLUObject(cnt) = norm(full(B - S * X));
end
1 2 3 4
LogErrorLU = log10(ErrorLU);
LogErrorLUObject = log10(ErrorLUObject);
figure(1)
semilogy(M,ErrorLU,'.-','Displayname','lu(S)')
hold on
semilogy(M,ErrorLUrefined,'x-','Displayname','lu(S) iterative refinement')
semilogy(M,ErrorLUObject,'.-','Displayname','decomposition(S,lu)')
hold off
ylim([1e-17 1e-5])
legend show
grid on;
ax = gca;
ax.YMinorGrid = 'off';
This is because decomposition does its best to match exactly what S\B does.

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