Interpolation

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

   return f0*(1-t) + f1*t;}

</lsl>

Input Description float f0 Start, 0.0 float f1 End, 1.0 float t Fraction of interpolation Output Description return float fLin Returns linear interpolation of two floats

Cosine interpolation of f0 and f1 with fraction t. <lsl> float fCos(float v0,float v1,float t){

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

</lsl>

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

Cubic interpolation of f0, f1, f2 and f3 with fraction t. <lsl> float fCub(float f0,float f1,float f2,float f3,float t){

   float P = (f3-f2)-(f0-f1);float Q = (f0-f1)-P;float R = f2-f0;float S = f1;
   return P*llPow(t,3) + Q*llPow(t,2) + R*t + S;}

</lsl>

Input Description float f0 Modifier, 0.33~ float f1 Start, 0.0 float f2 End, 1.0 float f3 Modifier, 0.66~ float t Fraction of interpolation Output Description return float fCub Returns cubic interpolation of four floats

Hermite interpolation of f0, f1, f2 and f3 with fraction t, tension and bias. <lsl> float fHem(float f0,float f1,float f2,float f3,float t,float tens,float bias){

   float t2 = t*t;float t3 = t2*t;
   float a0 =  (f1-f0)*(1+bias)*(1-tens)/2;
         a0 += (f2-f1)*(1-bias)*(1-tens)/2;
   float a1 =  (f2-f1)*(1+bias)*(1-tens)/2;
         a1 += (f3-f2)*(1-bias)*(1-tens)/2;
   float b0 =  2*t3 - 3*t2 + 1;
   float b1 =    t3 - 2*t2 + t;
   float b2 =    t3 -   t2;
   float b3 = -2*t3 + 3*t2;
   return (  b0  *  f1+b1  *  a0+b2  *  a1+b3  *  f2  );}

</lsl>

Rescales a value from one range to another range. <lsl> float fScl( float from0, float from1, float to0, float to1, float t ) {

   return to0 + ( (to1 - to0) * ( (from0 - t) / (from0-from1) ) ); }

</lsl>

Rescales a value from one range to another range. The value is clamped between the range. <lsl> float fSclFix( float from0, float from1, float to0, float to1, float t ) {

   t = to0 + ( (to1 - to0) * ( (from0 - t) / (from0-from1) ) );
   if(t < to0) t = to0; else if(t > to1) t = to1; return t; }

</lsl>

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

   return v0*(1-t) + v1*t;}

</lsl>

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>

Cubic interpolation of v0, v1, v2 and v3 with fraction t. <lsl> vector vCub(vector v0,vector v1,vector v2,vector v3,float t){

   vector P = (v3-v2)-(v1-v0);vector Q = (v1-v0)-P;vector R = v2-v1;vector S = v0;
   return P*llPow(t,3) + Q*llPow(t,2) + R*t + S;}

</lsl>

Hermite interpolation of v0, v1, v2 and v3 with fraction t, tension and bias. <lsl> vector vHem(vector v0,vector v1,vector v2,vector v3,float t,float tens,float bias){

   float t2 = t*t;float t3 = t2*t;
   vector a0 =  (v1-v0)*(1+bias)*(1-tens)/2;
          a0 += (v2-v1)*(1-bias)*(1-tens)/2;
   vector a1 =  (v2-v1)*(1+bias)*(1-tens)/2;
          a1 += (v3-v2)*(1-bias)*(1-tens)/2;
   float b0 =  2*t3 - 3*t2 + 1;
   float b1 =    t3 - 2*t2 + t;
   float b2 =    t3 -   t2;
   float b3 = -2*t3 + 3*t2;
   return (  b0  *  v1+b1  *  a0+b2  *  a1+b3  *  v2  );}

</lsl>

Spherical Linear interpolation of r0 and r1 with fraction t. Also known as SLERP <lsl> rotation rLin(rotation r0,rotation r1,float t){

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

</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 Cubic interpolation of r0 and r1 with fraction t. I liken to call it as SCURP <lsl> rotation rCub(rotation r0,rotation r1,rotation r2,rotation r3,float t){

   // Spherical-Cubic Interpolation
   // r0 = Start, r1 = End, r2 and r3 affect path of curve!
   return rLin( rLin(r0,r1,t), rLin(r2,r3,t), 2*t*(1-t) );}

</lsl>

Interpolates between two vectors in a list of vectors. <lsl> vector pLin(list v, float t, integer Loop ){

 float l = llGetListLength(v); t *= l-1;
 float f = (float)llFloor(t);
 integer i1 = 0; integer i2 = 0;
 if(Loop){ i1 = (integer)(f-llFloor(f/l)*l);
       ++f;i2 = (integer)(f-llFloor(f/l)*l);}
 else {
   if(  f > l-1 ) i1 = (integer)l-1;
   else if(  f >= 0 ) i1 = (integer)f;
   if(f+1 > l-1 ) i2 = (integer)l-1;
   else if(f+1 >= 0 ) i2 = (integer)f+1; }
 vector v1 = llList2Vector(v, i1);
 vector v2 = llList2Vector(v, i2);
 return vLin( v1, v2, t-f );}

</lsl>

Spherical Cosine interpolation of r0 and r1 with speed regulation. Does the entire animation loop to rotate between r0 to r1 with a specific speed, with the cosine interpolation it makes it appear to accelerate and deccelerate 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>