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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 )

share|improve this question
Is there any reason why you want to use the series rather than the sincos() function? Could you also state what language you are using? – camelccc Aug 9 '13 at 12:35
have a look here – camelccc Aug 9 '13 at 12:43
why doesn't precomputed table make sense in your situation? memory limitations? reducing precision would limit the number of values you need to store, which is already limited since angle < pi/100 – Graham Griffiths Aug 9 '13 at 12:47
Have a look at CORDIC. – Sven Aug 9 '13 at 12:52
what language and platform are you running on? it will make a big difference. @Sven - I doubt CORDIC coded up in software will be fast - although it definitely is running on an FPGA. – Graham Griffiths Aug 9 '13 at 12:59

Two ways : reduce the precision if possible (as often in video games, use minimal acceptable precision if you aim performance)

the you should try to use tabulated values. Once per execution (when the game loads ?) compute an array of sinus/ cosinus/ that you then access in constant time.

float cosAlpha = COSINUS[(int)(k*alpha)]; // e.g: k = 1000 

tune k and the array size to choose angle resolution vs. memory footprint.

edit: Don't forget to use parity of cosinus/sinus functions to avoid duplicate values in the tab edit2: try floats instead of double. Difference will be insignificant for the player, and the performance impact way be interesting. Test it !

share|improve this answer
This is a pretty old-school optimization technique that might turn out to be quite a bit slower on recent hardware if the data doesn't fit in cache it can cost you 100s of cycles more than the actual calculation. Measure. – Jasper Bekkers Aug 9 '13 at 14:52
I don't want very coarse approximation ower the whole period. I want very precise approximation for small angle. I want to improve precission of one movement iteration (rotating vector by some small differential of angle dphi = Omega*dt ) – Prokop Hapala Aug 14 '13 at 23:09

You might find that adjusting your calculations can improve performance. E.g.:

const double c7 = -1/5040d;
const double c5 = 1/120d;
const double c3 = -1/6d;

double a2 = a * a;

double sa = (((c7 * a2 + c5) * a2 + c3) * a2 + 1) * a;
// similarly for cos

Now the optimiser might be doing some of this itself anyway, so your mileage may vary. Would be interested to know the results either way.

share|improve this answer
Yes, never do division by a constant. The strict rules of floating point probably preclude the compiler doing algebraic manipulations, though -flags may allow that. And this representation of polynomials is nice too since it reduces operation count and breaks it into MAC, MAC, MAC, MUL. – phkahler Aug 9 '13 at 13:05
OK this I got speedup 2x. – Prokop Hapala Aug 9 '13 at 13:51

can you add some inline assembler? Targetting the i386 'fsincos' instruction is probably the fastest method :

Vector2 unit_vector ( Angle angle ) {
  Vector2 r;

//now the normal processor detection
//and various platform specific vesions

#  if defined (__i386__) && !defined (NO_ASM)
#    if defined __GNUC__
#      define ASM_SINCOS
      asm ("fsincos" : "=t" (r.x), "=u" (r.y) : "0" (angle.radians()));

#    elif defined _MSC_VER
#      define ASM_SINCOS
      double a = angle.radians();
      __asm fld a
      __asm fsincos
      __asm fstp r.x
      __asm fstp r.y
#    endif
#  endif

from here. This has the added bonus of calculating both sin and cos in a single call.

EDIT : it's Java.

Are your rotations suitably self-contained that you can offload thousands at a time over JNI? Otherwise this hardware-specific approach is no good.

share|improve this answer

Instead of optimizing the trig functions, see if you can do without them. Rigid-body simulations tend to be a perfectly natural fit for vector math.

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Yes, I'm using vector math ( or even better complex numbers in 2D and Quaternions in 3D ) but still I wan't to go beyond first order exapnsion (to make time step longer and keep high precision). And the exact solution is rotation matrix composed of sinus and cosisnus. So it is good to expand the exact solution into higher order taylor (or other) series. – Prokop Hapala Aug 14 '13 at 23:04

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