I'm doing some rigid-body rotation dynamics simulation, which means I have to compute many rotations by small angle, which has performance bottleneck in evaluation of trigonometric function. Now I do it by Taylor(McLaurin) series:

```
class double2{
double x,y;
// Intristic full sin/cos
final void rotate ( double a){
double x_=x;
double ca=Math.cos(a); double sa=Math.sin(a);
x=ca*x_-sa*y; y=sa*x_+ca*y;
}
// Taylor 7th-order aproximation
final void rotate_d7( double a){
double x_=x;
double a2=a*a;
double a4=a2*a2;
double a6=a4*a2;
double ca= 1.0d - a2 /2.0d + a4 /24.0d - a6/720.0d;
double sa= a - a2*a/6.0d + a4*a/120.0d - a6*a/5040.0d;
x=ca*x_-sa*y; y=sa*x_+ca*y;
}
}
```

but the trade of performance-speed is not so great as I would expect:

```
error(100x dphi=Pi/100 ) time [ns pre rotation]
v.rotate_d1() : -0.010044860504615213 9.314306 ns/op
v.rotate_d3() : 3.2624666136960023E-6 16.268745 ns/op
v.rotate_d5() : -4.600003294941146E-10 35.433617 ns/op
v.rotate_d7() : 3.416711358283919E-14 49.831547 ns/op
v.rotate() : 3.469446951953614E-16 75.70213 ns/op
```

Is there any faster method how to evaluate approximation of sin() and cos() for small angle ( like < Pi/100 )

I was thinking maybe some rational series, or continuous fraction approximation? Do you know any? ( Precomputed table doesn't make sense here )