From my understanding you have a few functions.

fb(A) = B

fc(A) = C

Do you know the functions listed above, that is do you know the mappings from A to each of these?
If you want to try to optimize, so that B is close to D, you need to pick:

- What close means. You can look at some vector norm for the B and D case, like minimizing ||B-D||^2. The standard sum of the squares of the elements of this different will probably do the trick and is computationally nice.
- How to optimize. This depends a lot on your functions, whether you want local or global mimina, etc.

So basically, now we've boiled the problem down to minimizing:

Cost = ||fb(A) - fd(A)||^2

One thing you can certainly do is to compute the gradient of this cost function with respect to the individual elements of A, and then perform minimization steps with forward Euler method with a suitable "time step". This might not be fast, but with small enough time step and well-behaved enough functions it will at least get you to a local minima.

Computing the gradient of this

grad_A(cost) = 2*||fb(A)-fd(A)||*(grad_A(fb)(A)-grad_A(fd)(A))

Where grad_A means gradient with respect to A, and grad_A(fb)(A) means gradient with respect to A of the function fb evaluated at A, etc.

Computing the grad_A(fb)(A) depends on the form of fb, but here are some pages have "Matrix calculus" identities and explanations.

Matrix calculus identities
Matrix calculus explanation

Then you simply perform gradient descent on A by doing forward Euler updates:

A_next = A_prev - timestep * grad_A(cost)

`A`

,`B`

etc and post a minimal example that reproduces the problem that you have? It's hard going through such a wall of code with long variable names that mean nothing to me. – r.m. Apr 23 '11 at 0:00`1)`

and`2)`

. I'm not sure if that will be helpful towards the objective of the problem. I'll change the variable names in the question to`A`

,`B`

etc.. – Pupil Apr 23 '11 at 0:06