RosslerL Rossler chaotic generator

# x, y, z = RosslerL.ar(freq, a, b, c, h, xi, yi, zi, mul, add)

freq - iteration frequency in Hertz
a, b, c - equation variables
h - integration time step
xi - initial value of x
yi - initial value of y
zi - initial value of z

A strange attractor discovered by Otto Rossler based on work in chemical kinetics.
The system is composed of three ordinary differential equations:

x' = - y - z
y' = x + ay
z' = b + z(x - c)

The time step amount h determines the rate at which the ODE is evaluated. Higher values will increase the
rate, but cause more instability. A safe choice is the default amount of 0.05.

The following examples treat RosslerL as a single-output UGen (i.e. using x only):

// vary frequency - these parameters are for "one-pulse" orbit
{ RosslerL.ar(MouseX.kr(20, SampleRate.ir), 0.36, 0.35, 4.5) * 0.3 }.play(s);

// randomly modulate params
(
{ RosslerL.ar(
SampleRate.ir,
0.2, // First variable tends to lead to NaN if modulated in this example
LFNoise0.kr(1, 0.01, 0.2),
LFNoise0.kr(1, 0.2, 0.7)
) * 0.2 }.play(s);
)

// as a frequency control
{ SinOsc.ar(Lag.ar(RosslerL.ar(MouseX.kr(1, 200)))*800+900)*0.4 }.play(s);


An example utilising the three different outputs as pitch, PWM and pan values (respectively):

(
{
# x,y,z = RosslerL.ar(MouseX.kr(1, 200));
Pan2.ar(Pulse.ar(x.range(100,1000), y.range(0,1), 0.3), z)
}.play(s)
)