I'm looking to construct an algorithm which gives the arrangements with repetition of n sequences of a given step S (which can be a positive real number), under the constraint that the sum of all combinations is k, with k a positive integer.

My problem is thus to find the solutions to the equation:

x 1 + x 2 + ⋯ + x n = k where

0 ≤ x i ≤ b i and S (the step) a real number with finite decimal.

For instance, if 0≤xi≤50, and S=2.5 then xi = {0, 2.5 , 5,..., 47.5, 50}.

The point here is to look only through the combinations having a sum=k because if n is big it is not possible to generate all the arrangements, so I would like to bypass this to generate only the combinations that match the constraint.

I was thinking to start with n=2 for instance, and find all linear combinations that match the constraint.

ex: if xi = {0, 2.5 , 5,..., 47.5, 50} and k=100, then we only have one combination={50,50} For n=3, we have the combination for n=2 times 3, i.e. {50,50,0},{50,0,50} and {0,50,50} plus the combinations {50,47.5,2.5} * 3! etc...

If xi = {0, 2.5 , 5,..., 37.5, 40} and k=100, then we have 0 combinations for n=2 because 2*40<100, and we have {40,40,20} times 3 for n=3... (if I'm not mistaken)

I'm a bit lost as I can't seem to find a proper way to start the algorithm, knowing that I should have the step S and b as inputs.

Do you have any suggestions?

Thanks

`x_i`

always 0 und`x_{i+1} = x_i + S`

? I don't really understand the question to be honest, maybe you should clarify it a bit – Niklas B. Mar 3 '14 at 18:16S? – Niklas B. Mar 3 '14 at 18:19