Difference between revisions of "Interpolation/Cosine"

Cosine interpolation of f0 and f1 with fraction t. <lsl> float fCos(float f0,float f1,float t) {

   float F = (1 - llCos(t*PI))/2;
   return f0*(1-F)+f1*F;

} </lsl>

Input Description float f0 Start (t = 0.0) float f1 End (t = 1.0) float t Fraction of interpolation Output Description return float fCos Returns cosine interpolation of two floats

Cosine interpolation of v0 and v1 with fraction t. <lsl> vector vCos(vector v0,vector v1,float t){

   float F = (1 - llCos(t*PI))/2;
   return v0*(1-F)+v1*F;}

</lsl>

Spherical Cosine interpolation of r0 and r1 with fraction t. I liken to call it as SCORP <lsl> rotation rCos(rotation r0,rotation r1,float t){

   // Spherical-Cosine Interpolation
   float f = (1 - llCos(t*PI))/2;
   float ang = llAngleBetween(r0, r1);
   if( ang > PI) ang -= TWO_PI;
   return r0 * llAxisAngle2Rot( llRot2Axis(r1/r0)*r0, ang*f);}

</lsl>

Spherical Cosine interpolation of r0 and r1 with speed regulation. Does the entire animation loop to rotate between r0 to r1 up to peak speed, using the cosine interpolation it makes it appear to accelerate and decelerate realistically. <lsl> rCosAim( rotation r0, rotation r1, float speed ){

   float ang = llAngleBetween(r0, r1) * RAD_TO_DEG;
   if( ang > PI) ang -= TWO_PI;
   float x; float y = (ang/speed)/0.2;
   for( x = 0.0; x < y; x += 1.0 )
       llSetRot( rCos( r0, r1, x/y ) );

} </lsl>