If `B`

is sparse, it may be efficient (i.e., O(n), assuming good condition number of `B`

) to solve for `x_i`

in

```
B x_i = a_i
```

(sample Conjugate Gradient code is given on Wikipedia). Taking `a_i`

to be the column vectors of `A`

, you get the matrix `B^{-1} A`

in O(n^2). Then you can sum the diagonal elements to get the trace. Generally, it's easier to do this sparse inverse multiplication than to get the full set of eigenvalues. ~~For comparison, Cholesky decomposition is O(n^3).~~ (*see Darren Engwirda's comment below about Cholesky*).

If you only need an approximation to the trace, you can actually reduce the cost to O(q n) by averaging

```
r^T (A B^{-1}) r
```

over `q`

random vectors `r`

. Usually `q << n`

. This is an unbiased estimate provided that the components of the random vector `r`

satisfy

```
< r_i r_j > = \delta_{ij}
```

where `< ... >`

indicates an average over the distribution of `r`

. For example, components `r_i`

could be independent gaussian distributed with unit variance. Or they could be selected uniformly from +-1. Typically the trace scales like O(n) and the error in the trace estimate scales like O(sqrt(n/q)), so the *relative* error scales as O(sqrt(1/nq)).