The Taylor series of sin(x) = x - x^3/3! + x^5/5! - ...

Any number 0 > *x* > 1 is represented in base 10 as

x = a*10^-n, where 1<=a<10 e.g. x=0.003 = 3*10^-3

x^3 = a^3 * 10^-3n

then the magnitude of the next term is about b*10^-3n (ignoring the factorial).
As *n* grows (or *x* approaches zero) the next terms start to vanish pretty fast.

for x=0.003 the few first terms are

```
0.003000000000000000 = 10^-3 * 3000000000000000 <-- x
- 0,000000004500000000 = 10^-3 * 0000004500000000 <-- x^3/3!
+ 0,000000000000002025 = 10^-3 * 0000000000002025 <-- x^5/5!
---------------------- -----------------------------
= 0.002999995500002025 = 10^-3 * 2999995500002025
```

There are 16 digits ignoring the leading zeroes and the 4th term x^7/7! doesn't affect any more the result. When x goes even smaller, next the x^5/5! term can't be added to the result and finally the x^3/3! term can't be added (or subtracted). Only the term x can be represented with 16 digit accuracy.

sin(x) = x only for x=0. exactly. Everything else is approximation.
Even sin(pi/2)=1 is approximation in math libraries, as the argument pi/2 can't be represented as a floating point number.

exactly. well, almost nothing. – Vlad Nov 8 '12 at 10:59