Diagonal scaling to improve eigenvalue accuracy
[T,B] = balance(A)
[S,P,B] = balance(A)
B = balance(A)
B = balance(A,'noperm')
[T,B] = balance(A) returns
a similarity transformation
T such that
= T\A*T, and
as nearly as possible, approximately equal row and column norms.
a permutation of a diagonal matrix whose elements are integer powers
of two to prevent the introduction of roundoff error. If
B == A and
T is the identity matrix.
[S,P,B] = balance(A) returns
the scaling vector
S and the permutation vector
T and balanced matrix
T(:,P) = diag(S) and
B(P,P) = diag(1./S)*A*diag(S).
B = balance(A) returns
just the balanced matrix
B = balance(A,'noperm') scales
permuting its rows and columns.
This example shows the basic idea. The matrix
large elements in the upper right and small elements in the lower
left. It is far from being symmetric.
A = [1 100 10000; .01 1 100; .0001 .01 1] A = 1.0e+04 * 0.0001 0.0100 1.0000 0.0000 0.0001 0.0100 0.0000 0.0000 0.0001
Balancing produces a diagonal matrix
elements that are powers of two and a balanced matrix
is closer to symmetric than
[T,B] = balance(A) T = 1.0e+03 * 2.0480 0 0 0 0.0320 0 0 0 0.0003 B = 1.0000 1.5625 1.2207 0.6400 1.0000 0.7813 0.8192 1.2800 1.0000
To see the effect on eigenvectors, first compute the eigenvectors
A, shown here as the columns of
[V,E] = eig(A); V V = 0.9999 -0.9999 -0.9999 0.0100 0.0059 + 0.0085i 0.0059 - 0.0085i 0.0001 0.0000 - 0.0001i 0.0000 + 0.0001i
Note that all three vectors have the first component the largest.
V is badly conditioned; in fact
Next, look at the eigenvectors of
[V,E] = eig(B); V V = 0.6933 -0.6993 -0.6993 0.4437 0.2619 + 0.3825i 0.2619 - 0.3825i 0.5679 0.2376 - 0.4896i 0.2376 + 0.4896i
Now the eigenvectors are well behaved and
The ill conditioning is concentrated in the scaling matrix;
This example is small and not really badly scaled, so the computed
within roundoff error; balancing has little effect on the computed
Balancing can destroy the properties of certain matrices; use it with some care. If a matrix contains small elements that are due to roundoff error, balancing might scale them up to make them as significant as the other elements of the original matrix.
Nonsymmetric matrices can have poorly conditioned eigenvalues. Small perturbations in the matrix, such as roundoff errors, can lead to large perturbations in the eigenvalues. The condition number of the eigenvector matrix,
cond(V) = norm(V)*norm(inv(V))
[V,T] = eig(A)
relates the size of the matrix perturbation to the size of the
eigenvalue perturbation. Note that the condition number of
is irrelevant to the eigenvalue problem.
Balancing is an attempt to concentrate any ill conditioning of the eigenvector matrix into a diagonal scaling. Balancing usually cannot turn a nonsymmetric matrix into a symmetric matrix; it only attempts to make the norm of each row equal to the norm of the corresponding column.
The MATLAB® eigenvalue function,
A before computing its eigenvalues.
Turn off the balancing with
backgroundPoolor accelerate code with Parallel Computing Toolbox™
This function fully supports thread-based environments. For more information, see Run MATLAB Functions in Thread-Based Environment.