# Best way to do an iteration scheme

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.

-
Does `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

I'm not sure if it's the best method, but I'd just use plain old memoization. You can represent an individual step as

``````xstep[x_] := Inverse[A[x]](B[x].x + f[x])
``````

and then

``````u[0] = x0
u[n_] := u[n] = xstep[u[n-1]]
``````

If you know how many values you need in advance, and it's advantageous to precompute them all for some reason (e.g. you want to open a file, use its contents to calculate `xN`, and then free the memory), you could use `NestList`. Instead of the previous two lines, you'd do

``````xlist = NestList[xstep, x0, 10];
u[n_] := xlist[[n]]
``````

This will break if `n > 10`, of course (obviously, change 10 to suit your actual requirements).

Of course, it may be worth looking at your specific functions to see if you can make some algebraic simplifications.

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The matrices are almost constants, but as the scheme is intended to be numerical, it doesn't matter. Should've clarified it in the question. Let me take a look at your answer at home, `tic-toc` it against a `for-loop`, and I'll get back to you. –  Pragabhava Jan 13 '12 at 1:15
Ended up using your solution. Thanks a lot. –  Pragabhava Jan 16 '12 at 23:18

I would probably write a function that accepts A0, B0, x0, and f0, and then returns A1, B1, x1, and f1 - say

``````step[A0_?MatrixQ, B0_?MatrixQ, x0_?VectorQ, f0_?VectorQ] := Module[...]
``````

I would then `Nest` that function. It's hard to be more precise without more precise information.

Also, if your procedure is numerical, then you certainly don't want to compute `Inverse[A0]`, as this is not a numerically stable operation. Rather, you should write

``````A0.x1 == B0.x0+f0
``````

and then use a numerically stable solver to find `x1`. Of course, Mathematica's `LinearSolve` provides such an algorithm.

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It'd be useful to have `step` take a list, e.g. `step[{A0_, ...}]`, to be able to use it more easily in `Nest`. –  Szabolcs Jan 13 '12 at 14:32
More details are provided in first EDIT. `LinearSolve` is a great suggestion; I suppose it works like the `\` operator in MATLAB. –  Pragabhava Jan 13 '12 at 21:41