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For an ocean shader, I need a fast function that computes a very approximate value for sin(x). The only requirements are that it is periodic, and roughly resembles a sine wave.

The taylor series of sin is too slow, since I'd need to compute up to the 9th power of x just to get a full period.

Any suggestions?

EDIT: Sorry I didn't mention, I can't use a lookup table since this is on the vertex shader. A lookup table would involve a texture sample, which on the vertex shader is slower than the built in sin function. It doesn't have to be in any way accurate, it just has to look nice.

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Is the Taylor series slow for x between 0 and π/2? If it's acceptable, then you can use the symmetries of sin to compute it for other values. –  lhf Aug 23 '11 at 23:21
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5 Answers 5

up vote 6 down vote accepted

Use a Chebyshev approximation for as many terms as you need. This is particularly easy if your input angles are constrained to be well behaved (-π .. +π or 0 .. 2π) so you do not have to reduce the argument to a sensible value first. You might use 2 or 3 terms instead of 9.

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+1 for Chebyshev, it's the best way to go. However, range reduction is a huge advantage if possible. –  Jason S Aug 24 '11 at 0:46
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You can make a look-up table with sin values for some values and use linear interpolation between that values.

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Unfortunatly I can't use a lookup, see edit –  Hannesh Aug 23 '11 at 15:36
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Well, you don't say how accurate you need it to be. The sine can be approximated by straight lines of slopes 2/pi and -2/pi on intervals [0, pi/2], [pi/2, 3*pi/2], [3*pi/2, 2*pi]. This approximation can be had for the cost of a multiplication and an addition after reducing the angle mod 2*pi.

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Well, more accurate than that :P It doesn't need to be 'accurate' in that sense, I'm not concerned about finding the approximate sine of a given angle. I'm just trying to find smooth function that looks like a wave. –  Hannesh Aug 24 '11 at 9:51
    
@Hannesh: Ha, ok, at least I didn't say it could be approximated by the function f(x) = 0. –  GregS Aug 24 '11 at 11:19
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A rational algebraic function approximation to sin(x) is:

f = (C1 * x) / (C2 * x^2 + 1.) 

with the constants:

c1 =   1.043406062 
c2 =  .2508691922 

These constants were found with a least-squares subroutine, DHFTI, by Lawson & Hanson. This is valid only over 0 to π / 2, so reduce the input with something like:

IF (t  < pi) THEN
  IF (t < pi/2) THEN
    x = t
  ELSE
      x = pi - t
   END IF
 ELSE 
   IF (t < (3./2)*pi) THEN
     x = t - pi
  ELSE
     x = twopi - t
   END IF
END IF

Then calculate:

f = (C1 * x) / (C2 * x*x + 1.0)
IF (t > pi) f = -f

If the input is outside [0, 2π], you'll need to take x mod 2 π
The results should be within about 5% of the real sine.

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Using a lookup table is probably the best way to control the tradeoff between speed and accuracy.

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-1 because this justisn't true today i guess, especially when the clock rates go way more up in the future –  Quonux Feb 12 at 23:30
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