# Is there any numerical solver in python with control of each iteration?

I am solving a linear system of equation currently i am using

``````   numpy.linalg.solve
``````

It returns the solution of the linear system. I want to have a control such that i can execute iterations

Considering another option

``````    scipy.optimize.minimize
``````

Documentation describes that we can specify a function which is called after every iteration and we could have current parameters. I am not sure if they meant that we could get the current resultant vector. e.g Simply I want to access x after every iteration, while we are solving Ax=b

I am wondering if somebody has worked with it and can explain!

Thanks

-
What do you mean by the "resultant vector"? The function gets the parameters, i.e. initially `x0`, and must return their cost/objective value. – Fred Foo Feb 21 '13 at 17:44
we are solving Ax=b, I mean to get access to x after every iteration, which i call the resultant vector – Shan Feb 21 '13 at 17:51
I have updated the question as well, +1 for mentioning it – Shan Feb 21 '13 at 17:53

The `callback` keyword argument to `scipy.optimize.minimize` specifies a function that will be called with the current estimate of the argument that minimizes the function at each iteration.

But `minimize` is intended for a scalar function (one returning a single value) so I don't see how that is applicable to your example. You may want to try `scipy.optimize.fsolve` instead. It doesn't accept the `callback` keyword though. To get around that, you could wrap your linear equation in a callable function object (that returns `Ax-b`) and then just take the argument that is passed to your callable object.

``````class Ab:
def __init__(self, A, b):
self.A = A
self.b = b
def __call__(self, x):
print 'x =', x
return A.dot(x) - b
``````

Then use it like this:

``````>>> A = np.array([[2, 3], [4, 9]], float)
>>> b = np.array([5, 5])
>>> f = Ab(A, b)
>>> optimize.fsolve(f, [0, 0])
x = [0 0]
x = [ 0.  0.]
x = [ 0.  0.]
x = [  1.49011612e-08   0.00000000e+00]
x = [  0.00000000e+00   1.49011612e-08]
x = [ 5.         -1.66666667]
x = [ 5.         -1.66666667]
array([ 5.        , -1.66666667])
``````

`fsolve` reported only taking 5 iterations so it appears the first two calls may be not actually used for convergence.

-
But surely, `minimize` can be used to find a least-squares solution of Ax=b (though probably slower than a dedicated solver)? – Fred Foo Feb 21 '13 at 18:26
Yes, I guess you could just write a function that returns the sum of squared values of `Ax-b` and pass that to `minimize`. – bogatron Feb 21 '13 at 18:32