The coefficients are identical to those given in the *Handbook of Mathematical Functions*, ed. Abramowitz and Stegan (1964), page 76, and are attributed to Carlson and Goldstein, Rational approximations of functions, Los Alamos Scientific Laboratory (1955).

The first can be found in http://www.jonsson.eu/resources/hmf/pdfwrite_600dpi/hmf_600dpi_page_76.pdf.

And the second at http://www.osti.gov/bridge/servlets/purl/4374577-0deJO9/4374577.pdf. Page 37 gives:

Regarding your third question, "Can I extend this to get more precision?", http://lol.zoy.org/wiki/doc/maths/remez has a downloadable C++ implementation of the Remez algorithm; it provides (unchecked by me) the coefficients for the 6th-order polynomial for `sin`

:

```
error: 3.9e-14
9.99999999999624e-1
-1.66666666660981e-1
8.33333330841468e-3
-1.98412650240363e-4
2.75568408741356e-6
-2.50266363478673e-8
1.53659375573646e-10
```

Or course, you would need to change from float to double to realize any improvement. And this may also answer your second question, regarding `cos`

and `tan`

.

Also, I see in the comments that a fixed-point answer is required in the end. I implemented a 32-bit fixed-point version in 8031-assembler about 26 years ago; I'll try digging it up to see whether it has anything useful in it.

**Update**: If you are stuck with 32-bit doubles, then the only way I can see for you to increase the accuracy by a "digit or two" is to forget floating-point and use fixed-point. Surprisingly, google doesn't seem to turn up anything. The following code provides proof-of-concept, run on a standard Linux machine:

```
#include <stdio.h>
#include <math.h>
#include <stdint.h>
// multiply two 32-bit fixed-point fractions (no rounding)
#define MUL32(a, b) ((uint64_t)(a) * (b) >> 32)
// sin32: Fixed-point sin calculation for first octant, coefficients from
// Handbook for Computing Elementary Functions, by Lyusternik et al, p. 89.
// input: 0 to 0xFFFFFFFF, giving fraction of octant 0 to PI/8, relative to 2**32
// output: 0 to 0.7071, relative to 2**32
static uint32_t sin32(uint32_t x) { // x in 1st octant, = radians/PI*8*2**32
uint32_t y, x2 = MUL32(x, x); // x2 = x * x
y = 0x000259EB; // a7 = 0.000 035 877 1
y = 0x00A32D1E - MUL32(x2, y); // a5 = 0.002 489 871 8
y = 0x14ABBA77 - MUL32(x2, y); // a3 = 0.080 745 367 2
y = 0xC90FDA73u - MUL32(x2, y); // a1 = 0.785 398 152 4
return MUL32(x, y);
}
int main(void) {
int i;
for (i = 0; i < 45; i += 2) { // 0 to 44 degrees
const double two32 = 1LL << 32;
const double radians = i * M_PI / 180;
const uint32_t octant = i / 45. * two32; // fraction of 1st octant
printf("%2d %+.10f %+.10f %+.10f %+.0f\n", i,
sin(radians) - sin32(octant) / two32,
sin(radians) - sinf(radians),
sin(radians) - (float)sin(radians),
sin(radians) * two32 - sin32(octant));
}
return 0;
}
```

The coefficients are from the *Handbook for Computing Elementary Functions*, by Lyusternik *et al*, p. 89, here:

The only reason I choose this particular function is that it has one less term than your original series.

The results are:

```
0 +0.0000000000 +0.0000000000 +0.0000000000 +0
2 +0.0000000007 +0.0000000003 +0.0000000012 +3
4 +0.0000000010 +0.0000000005 +0.0000000031 +4
6 +0.0000000012 -0.0000000029 -0.0000000011 +5
8 +0.0000000014 +0.0000000011 -0.0000000044 +6
10 +0.0000000014 +0.0000000050 -0.0000000009 +6
12 +0.0000000011 -0.0000000057 +0.0000000057 +5
14 +0.0000000006 -0.0000000018 -0.0000000061 +3
16 -0.0000000000 +0.0000000021 -0.0000000026 -0
18 -0.0000000005 -0.0000000083 -0.0000000082 -2
20 -0.0000000009 +0.0000000095 -0.0000000107 -4
22 -0.0000000010 -0.0000000007 +0.0000000139 -4
24 -0.0000000009 -0.0000000106 +0.0000000010 -4
26 -0.0000000005 +0.0000000065 -0.0000000049 -2
28 -0.0000000001 -0.0000000032 -0.0000000110 -0
30 +0.0000000005 -0.0000000126 -0.0000000000 +2
32 +0.0000000010 +0.0000000037 -0.0000000025 +4
34 +0.0000000015 +0.0000000193 +0.0000000076 +7
36 +0.0000000013 -0.0000000141 +0.0000000083 +6
38 +0.0000000007 +0.0000000011 -0.0000000266 +3
40 -0.0000000005 +0.0000000156 -0.0000000256 -2
42 -0.0000000009 -0.0000000152 -0.0000000170 -4
44 -0.0000000005 -0.0000000011 -0.0000000282 -2
```

Thus we see that this fixed-point calculation is about *ten times* more accurate than `sinf()`

or `(float)sin()`

, and is correct to 29 bits. Using rounding rather than truncation in `MUL32()`

made only a marginal improvement.

`tan`

and`cos`

can be calculated the same way. In the formula that I have to calculate on 8 bit slow MCU I have`tan`

and`cos`

. Division is very slow so prefer to avoid it. – Pablo Dec 7 '12 at 22:06`tan=sin/cos`

where you don't know divisor. Unless I missed your point. – Pablo Dec 7 '12 at 22:13`tan`

is x+x^3/3+(2 x^5)/15+..., you don't need to calculate it as`sin/cos`

. – Andrei Dec 7 '12 at 22:14