# RSolve not solving discrete Rossler system

I'm working with chaotic attractors, and testing some continuous-> discrete equivalences. I've made a continuous simulation of the Rossler system this way

``````a = 0.432; b = 2; c = 4;
Rossler = {
x'[t] == -y[t] - z[t],
y'[t] == x[t] + a*y[t],
z'[t] == b + x[t]*z[t]-c*z[t]};
sol = NDSolve[
{Rossler, x[0] == y[0] == z[0] == 0.5},
{x, y, z}, {t,500}, MaxStepSize -> 0.001, MaxSteps -> Infinity]
``````

Now, when trying to evaluate a discrete equivalent system with RSolve, Mma doesn't do anything, not even an error, it just can't solve it.

``````RosslerDiscreto = {
x[n + 1] == x[n] - const1*(y[n] + z[n]),
y[n + 1] == 1 - a*const2)*y[n] + const2*x[n],
z[n + 1] == (z[n]*(1 - const3) + b*const3)/(1 - const3*x[n])}
``````

I want to know if there is a numerical function for RSolve, analogous as the NDSolve is for DSolve. I know i can make the computation with some For[] cycles, just want to know if it exists such function.

-
Did you really mean to divide in third RSolve eqn? –  Daniel Lichtblau Jun 4 '11 at 15:48

`RecurrenceTable` is the numeric analogue to RSolve:

``````rosslerDiscreto = {
x[n+1] == x[n] - C[1]*(y[n] + z[n]),
y[n+1] == (1 - a*C[2])*y[n] + C[2]*x[n],
z[n+1] == (z[n]*(1 - C[3]) + b*C[3]) / (1 - C[3]*x[n]),
x[0] == y[0] == z[0] == 0.5
} /. {a->0.432, b->2, c->4, C[1]->0.1, C[2]->0.1, C[3]->0.1};
coords = RecurrenceTable[rosslerDiscreto, {x,y,z}, {n,0,1000}];
Graphics3D@Point[coords]
``````

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Thanks, that's what i was looking for. I'm working better now, without all those For cycles around. –  Javier Abrego Jun 5 '11 at 5:55