This should be pretty damn fast if you can optimize it further please do and post the code on like pastie.org or something.

Computer Specifications -> 512MB Ram , Visual Studio 2010 , Windows XP Professional SP3 Version 2002 , Intel (R) Pentium (R) 4 CPU 2.8GHZ.

This is insanely accurate and will actually provide slightly better results in some situations. E.g. 90, 180, 270 degrees in C++ returns a non 0 decimal.

FULL TABLE OF 0 through 359 Degrees: https://pastee.org/dhwbj

FORMAT -> DEGREE # -> MINE_X(#) , CosX(#) , MINE_Z(#) , SinZ(#).

Below is the code used to construct the above shown table. You can probably make it even more accurate if you use a larger data type. I utilized an unsigned short and did N/64000. So What ever the cos(##) and sin(##) where closest to I rounded to that index. I also tried to use as little extra data as possible so this wouldn't be some cluttered table with 720 float values for cos and sin. Which would probably give better results, but be a complete waste of memory. The table below is as small as I could make it. I'd like to see if it's possible to make an equation that could round to all these short values and use that instead. I'm not sure if it would be any faster, but it would eliminate the table completely and probably not reduce speed by anything or much.

So the accuracy in comparison to the C++ cos/sin operations is 99.99998% through 100%.

Below is the table used to calculate the cos/sin values.

```
static const unsigned __int16 DEGREE_LOOKUP_TABLE[91] =
{
64000, 63990, 63961, 63912, 63844, 63756,
63649, 63523, 63377, 63212, 63028, 62824,
62601, 62360, 62099, 61819, 61521, 61204,
60868, 60513, 60140, 59749, 59340, 58912,
58467, 58004, 57523, 57024, 56509, 55976,
55426, 54859, 54275, 53675, 53058, 52426,
51777, 51113, 50433, 49737, 49027, 48301,
47561, 46807, 46038, 45255, 44458, 43648,
42824, 41988, 41138, 40277, 39402, 38516,
37618, 36709, 35788, 34857, 33915, 32962,
32000, 31028, 30046, 29055, 28056, 27048,
26031, 25007, 23975, 22936, 21889, 20836,
19777, 18712, 17641, 16564, 15483, 14397,
13306, 12212, 11113, 10012, 8907, 7800,
6690, 5578, 4464, 3350, 2234, 1117,
0,
};
```

Below is the actual code that does the cos/sin calculations.

```
int deg1 = (int)degrees;
int deg2 = 90 - deg1;
float module = degrees - deg1;
double vX = DEGREE_LOOKUP_TABLE[deg1] * 0.000015625;
double vZ = DEGREE_LOOKUP_TABLE[deg2] * 0.000015625;
double mX = DEGREE_LOOKUP_TABLE[deg1 + 1] * 0.000015625;
double mZ = DEGREE_LOOKUP_TABLE[deg2 - 1] * 0.000015625;
float vectorX = vX + (mX - vX) * module;
float vectorZ = vZ + (mZ - vZ) * module;
if (quadrant & 1)
{
float tmp = vectorX;
if (quadrant == 1)
{
vectorX = -vectorZ;
vectorZ = tmp;
} else {
vectorX = vectorZ;
vectorZ = -tmp;
}
} else if (quadrant == 2) {
vectorX = -vectorX;
vectorZ = -vectorZ;
}
```

SPEEDS BELOW using the originally mention computer specifications. I was running it in debug mode before this is debug mode, but is ran through the executable which I believe is debug without debugging.

**MY METHOD**

```
1,000 Iterations -> 0.004641 MS or 4641 NanoSeconds.
100,000 Iterations -> 4.4328 MS.
100,000,000 Iterations -> 454.079 MS.
1,000,000,000 Iterations -> 4065.19 MS.
```

**COS/SIN METHOD**

```
1,000 Iterations -> 0.581016 MS or 581016 NanoSeconds.
100,000 Iterations -> 25.0049 MS.
100,000,000 Iterations -> 24,731.6 MS.
1,000,000,000 Iterations -> 246,096 MS.
```

So to summarize the above performing both cos(###) and sin(###) with my strategy allows roughly 220,000,000 executions per second. Utilizing the computer specifications shown originally. This is fairly quick and utilizes very little memory so it's a great substitute to math cos/sin functions normally found in C++. If you'd like to see the accuracy open the link shown above and there is a print out of degrees 0 trough 359. Also this supports 0 through 89 and quadrants 0 through 3. So you'd need to either use that or perform (DEGREES % 90).

two times fasterthan math.h ' s sine function however I used a very small lookup table(20 floats). it's accuracy is also not bad at all;average relative error rate is 0.095%. you can check it out from http://www.hevi.info/tag/fast-sine-function/ – hevi Dec 27 '11 at 23:32