I hope this hasn't been asked before, if so I apologize.

*EDIT: For clarity, the following notation will be used: boldface uppercase for matrices, boldface lowercase for vectors, and italics for scalars.*

Suppose **x0** is a vector, **A** and **B** are matrix functions, and **f** is a vector function.

I'm looking for the best way to do the following iteration scheme in Mathematica:

```
A0 = A(x0), B0=B(x0), f0 = f(x0)
x1 = Inverse(A0)(B0.x0 + f0)
A1 = A(x1), B1=B(x1), f1 = f(x1)
x2 = Inverse(A1)(B1.x1 + f1)
...
```

I know that a `for-loop`

can do the trick, but I'm not quite familiar with Mathematica, and I'm concerned that this is the most efficient way to do it. This is a justified concern as I would like to define a function `u(N):=xN`

and use it in further calculations.

I guess my questions are:

What's the most efficient way to program the scheme?

Is `RecurrenceTable`

a way to go?

**EDIT**

It was a bit more complicated than I tought. I'm providing more details in order to obtain a more thorough response.

Before doing the recurrence, I'm having problems understanding how to program the functions **A**, **B** and **f**.

Matrices **A** and **B** are functions of the time step *dt = 1/T* and the space step *dx = 1/M*, where *T* and *M* are the number of points in the {*0 < x < 1*, *0 < t*} region. This is also true for vector the function **f**.

The dependance of **A**, **B** and **f** on **x** is rather tricky:

**A** and **B** are *upper* and *lower triangular* matrices (like a *tridiagonal* matrix; I suppose we can call them *multidiagonal*), with defined constant values on their diagonals.

Given a point *0 < xs < 1*, I need to determine it's representative *xn* in the mesh (the closest), and *then* substitute the *nth* row of **A** and **B** with the function **v**( **x**) (transposed, of course), and the *nth* row of **f** with the function *w*( **x**).

Summarizing, **A** = **A**(*dt*, *dx*, *xs*, **x**). The same is true for **B** and **f**.

Then I need do the loop mentioned above, to define **u**( **x**) = `step[T]`

.

Hope I've explained myself.

`f`

map vectors to numbers? And`A`

and`B`

, are they mappings which can be represented by matrices (vector-vector mappings), or matrix-valued functions (vector-matrix mappings), or functions of matrices (matrix-number mappings)? – David Z Jan 12 '12 at 23:55`x`

is a vector in say,`Rn`

,`f:Rn -> Rn`

,`A,B:Rn -> Rn x Rn`

. And all the scheme is numerical. – Pragabhava Jan 13 '12 at 1:11