```
#define PARTPERDEGREE 1
double mysinlut[PARTPERDEGREE * 90 + 1];
double mycoslut[PARTPERDEGREE * 90 + 1];
void MySinCosCreate()
{
int i;
double angle, angleinc;
// Each degree also divided into 10 parts
angleinc = (M_PI / 180) / PARTPERDEGREE;
for (i = 0, angle = 0.0; i <= (PARTPERDEGREE * 90 + 1); ++i, angle += angleinc)
{
mysinlut[i] = sin(angle);
}
angleinc = (M_PI / 180) / PARTPERDEGREE;
for (i = 0, angle = 0.0; i <= (PARTPERDEGREE * 90 + 1); ++i, angle += angleinc)
{
mycoslut[i] = cos(angle);
}
}
double MySin(double rad)
{
int ix;
int sign = 1;
double angleinc = (M_PI / 180) / PARTPERDEGREE;
if(rad > (M_PI / 2))
rad = M_PI / 2 - (rad - M_PI / 2);
if(rad < -(M_PI / 2))
rad = -M_PI / 2 - (rad + M_PI / 2);
if(rad < 0)
{
sign = -1;
rad *= -1;
}
ix = (rad * 180) / M_PI * PARTPERDEGREE;
double h = rad - ix*angleinc;
return sign*(mysinlut[ix] + h*mycoslut[ix]);
}
double MyCos(double rad)
{
int ix;
int sign = 1;
double angleinc = (M_PI / 180) / PARTPERDEGREE;
if(rad > M_PI / 2)
{
rad = M_PI / 2 - (rad - M_PI / 2);
sign = -1;
}
else if(rad < -(M_PI / 2))
{
rad = M_PI / 2 + (rad + M_PI / 2);
sign = -1;
}
else if(rad > -M_PI / 2 && rad < M_PI / 2)
{
rad = abs(rad);
sign = 1;
}
ix = (rad * 180) / M_PI * PARTPERDEGREE;
double h = rad - ix*angleinc;
return sign*(mycoslut[ix] - h*mysinlut[ix]);
}
double MyTan(double rad)
{
return MySin(rad) / MyCos(rad);
}
```

It turns out that calculating `tan`

using division is even more expensive than original `tan`

function.

Is there any way to calculate `tan`

using sin/cos lookup table values without division operation, since division is expensive on my MCU.

Is it better to have `tan`

LUT and extract result using tan/sin or tan/cos as it's done now for sin/cos?

`sin (x+h) ≈ sin x + h*cos x`

and`cos (x+h) ≈ cos x - h*sin x`

the accuracy is not enough. Second of all I am not sure how to use`tan`

to approximate it with sin or cos LUT. Need some practical help with that. – Pablo Dec 7 '12 at 14:58`tan`

(do you even need the`sin`

and`cos`

tables then?). You can then either approximate using the derivative,`tan (x+h) ≈ tan x + h*(1 + tan² x)`

or linear interpolation,`double t = (rad * 180) / M_PI * PARTPERDEGREE; ix = (int)t; t -= ix; return t*mytanlut[ix+1] + (1-t)*mytanlut[ix];`

. The linear interpolation would generally give better approximations, but has the problem that it would produce garbage if the two angles straddle`π/2`

since one value would be very large and positive, the other very large and negative [possibly ±∞]. – Daniel Fischer Dec 7 '12 at 15:35