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We know that sin(x)=x-x^3/3!+x^5/5!-x^7/7!+x^9/9! and so on. I have written this code:

#include <iostream>
#include <math.h>
using namespace std;

const int m=19;

int factorial(int n) {

    if (n==0){ return 1;}
    return n*factorial(n-1);

int main() {
   float x;
   cin >> x;

   float sum=0;
   int k=1;
   for (int i=1;i<=m;i+=2) {

   cout<<"series sum is equal :"<<sum<<endl;
   return 0;

One problem is that when I enter x=3 it gives me -10.9136, but I know that values range of sin(x) is [-1, 1] what is problem? Please help me.

share|improve this question
You could try formatting your code a little better - it may not fix the bug but it should make it a little easier to spot... – Paul R Sep 17 '11 at 6:19
up vote 4 down vote accepted

The problem is that you're running out of precision due to destructive cancellation.

You have an alternating series where some of the terms get very large. But those terms cancel each other out to a small result. Since float has limited precision, your round off error is larger than your final value.

You can "reduce" the problem by using double-precision. But it won't go away. Standard implementations of sin/cos involve taking the modulo of the argument by 2 pi to make it small.


I found the other problem. You have an integer overflow in your factorial function when i = 19.

share|improve this answer
so one solution is that use double or int? – dato datuashvili Sep 17 '11 at 6:19
The standard solution is to reduce the argument so that it's between -pi and pi. – Mysticial Sep 17 '11 at 6:23
Actually, I think there's more going than just destructive cancellation. The argument of 3 shouldn't be large enough make the answer that inaccurate. I'll take a closer look. – Mysticial Sep 17 '11 at 6:24
Also for the sake of both efficiency and accuracy you shouldn't be evaluating the power and factorial terms for every iteration - hint: think about the relationship between successive terms... – Paul R Sep 17 '11 at 6:34
Throwing more precision at it will only "delay" the problem to larger x. The full-proof method is just to do x %= 2 * PI before you start the algorithm. (You can get Pi either from the C-library or just hard-code it.) – Mysticial Sep 17 '11 at 6:52

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