I'm running an optimization algorithm that requires calculation of the inverse of a matrix. The goal of the algorithm is to eliminate negative values from the matrix A and obtain the new matrix B. Basically, I start with known square matrices B and C of the same size.

I start by calculating the matrix A which is equal to:

A = B^-1 * C

Or in Matlab:

`A = B\C;`

I use this because Matlab told me `B\C`

is more accurate than `inv(B)*C`

.

The negative values in A are then divided by two and A is then normalised so that it's rows have length of 1. Using this new A, I calculate a new B with:

(1/N) * A * C' = B^-1

where N is just a scaling factor (# of columns in A). This new B would then be used again in the first step and these iterations continue until the negatives in A are gone.

My problem is I have to calculate B from the second equation and then normalise it.

`invB = (1/N)*A*C'; B = inv(invB);`

I've been calculating B using `inv(B^-1)`

but after a few iterations I start getting messages that `B^-1`

is "close to singular or badly scaled."

This algorithm actually works for smaller matrices (around 70x70) but when it gets up to about 500x500 I start getting these messages.

Are there any better ways to calculate `inv(B^-1)`

?

`B = eye(N) \ invB`

? – Darhuuk Mar 9 '12 at 19:28`B = eye(N) \ invB`

I no longer get that error for that equation, but it gives me the error every time the`A = B\C`

is calculated... – user1259832 Mar 9 '12 at 19:43