I need to invert a large, dense matrix which I hoped to use Scipy's `gmres`

to do. Fortunately, the dense matrix `A`

follows a pattern and I do not need to store the matrix in memory. The `LinearOperator`

class allows us to construct an object which acts as the matrix for GMRES and can compute directly the matrix vector product `A*v`

. That is, we write a function `mv(v)`

which takes as input a vector `v`

and returns `mv(v) = A*v`

. Then, we can use the `LinearOperator`

class to create `A_LinOp = LinearOperator(shape = shape, matvec = mv)`

. We can put the linear operator into the Scipy `gmres`

command to evaluate the matrix vector products without ever having to fully load `A`

into memory.

The documentation for the `LinearOperator`

is found here: `LinearOperator`

Documentation.

Here is my problem: to write the routine to compute the matrix vector product `mv(v) = A*v`

, I need another input vector `C`

. The entries in `A`

are of the form `A[i,j] = f(C[i] - C[j])`

. So, what I really want is for `mv`

to be of two inputs, one fixed vector input `C`

, and one variable input `v`

which we want to compute `A*v`

.

MATLAB has a similar setup, where would write `x = gmres(@(v) mv(v,C),b)`

where `b`

is the right hand side of the problem `Ax = b`

, , and `mv`

is the function that takes as variable input `v`

which we want to compute `A*v`

and `C`

is the fixed, known vector which we need for the assembly of `A`

.

My problem is that I can't figure out how to allow the `LinearOperator`

class to accept two inputs, one variable and one "fixed" like I can in MATLAB.

Is there a way to do the analogous operation in SciPy? Alternatively, if anyone knows of a better way of inverting a large, dense matrix `(50000, 50000)`

where the entries follow a pattern, I would greatly appreciate any suggestions.

Thanks!

EDIT: I should have stated this information actually. The matrix is actually (in block form) `[A C; C^T 0]`

, where `A`

is `N x N`

(`N`

large) and `C`

is `N x 3`

, and the `0`

is `3 x 3`

and `C^T`

is the transpose of `C`

. This array `C`

is the same array as the one mentioned above. The entries of `A`

follow a pattern `A[i,j] = f(C[i] - C[j])`

.

I wrote `mv(v,C)`

to go row by row construct `A*v[i]`

for `i=0,N`

, by computing sum `f(C[i]-C[j)*v[j]`

(actually, I do `numpy.dot(FC,v)`

where `FC[j] = f(C[i]-C[j])`

which works well). Then, at the end doing the computations for the `C^T`

rows. I was hoping to eventually replace the large for loop with a `multiprocessing`

call to parallelize the for loop, but that's a future thing to consider. I will also look into using Cython to speed up the computations.

`functools.partial`

) instead:`make_mv = lambda c: lambda v: sum(f(c[i] - c[j])...`

(but you'd write it using`def`

so that it's readable) and probably the function should be in Cython or it may be too slow for such a big matrix. – jorgeca Nov 27 '13 at 18:27`mv2`

function will use whatever`C`

is in scope, not the one that was in scope when you created the function. If you want`mv2`

to refer to a particular`C`

, you absolutely need one of the two methods above, and then`mv = make_mv(C)`

. – jorgeca Nov 28 '13 at 6:17