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Here is the question..

This is what I've done so far,

#include <stdio.h>
#include <math.h>

long int factorial(int m)
{
    if (m==0 || m==1) return (1);
    else      return (m*factorial(m-1));
}
double power(double x,int n)
{
    double val=1;
    int i;
    for (i=1;i<=n;i++)
    {
        val*=x;
    }
    return val;
}

double sine(double x)
{
    int n;
    double val=0;
    for (n=0;n<8;n++)
    {
        double p = power(-1,n);
        double px = power(x,2*n+1);
        long fac = factorial(2*n+1);
        val += p * px / fac;
    }
    return val;
}

int main()
{
    double x;
    printf("Enter angles in degrees: ");
    scanf("%lf",&x);
    printf("\nValue of sine of %.2f is %.2lf\n",x,sine(x * M_PI / 180));
    printf("\nValue of sine of %.2f from library function is %.2lf\n",x,sin(x * M_PI / 180));
    return 0;
}

The problem is that the program works perfectly fine from 0 to 180 degrees, but beyond that it gives error.. Also when I increase the value of n in for (n=0;n<8;n++) beyond 8, i get significant error.. There is nothing wrong with the algorithm, I've tested it in my calculator, and the program seems to be fine as well.. I think the problem is due to the range of the data type.. what should i correct to get rid of this error?
Thanks..

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What error exactly? –  rene Dec 27 '11 at 16:59
    
I don't know for sure if this is it, but you were talking about datatype range... Have you tried having factorial return a long long int? –  Platinum Azure Dec 27 '11 at 17:02
    
@rene the value differs from the standard value.. for example at 270 degrees i get -0.44, but the standard value is -1. –  Shashwat Mehta Dec 27 '11 at 17:02
    
@PlatinumAzure yes, tried that.. didn't help.. –  Shashwat Mehta Dec 27 '11 at 17:05
    
(I assume you mean "from 0 to pi" rather than "from 0 to 180 degrees" because the Taylor expansion works in radians, not degrees.) You need to reduce the magnitude of the px and fac variables. For example, refactor the expression from x^(2n+1)/(2n+1)! to product(i=1 step 2 to 2n+1){x/i}. Note also that convergence is slow when you get far away from 0. –  Raymond Chen Dec 27 '11 at 17:05

5 Answers 5

You are correct that the error is due to the range of the data type. In sine(), you are calculating the factorial of 15, which is a huge number and does not fit in 32 bits (which is presumably what long int is implemented as on your system). To fix this, you could either:

  1. Redefine factorial to return a double.
  2. Rework your code to combine power and factorial into one loop, which alternately multiplies by x, and divides by i. This will be messier-looking but will avoid the possibility of overflowing a double (granted, I don't think that's a problem for your use case).
share|improve this answer
    
did that... no change... –  Shashwat Mehta Dec 28 '11 at 17:02
    
Did what, option #1 or #2? I've tried out option #1 and it works fine, on both 32-bit and 64-bit machines. Did you remember to change both the long int return type of factorial to double, as well as the long storage type of fac to double? –  Chris K Dec 29 '11 at 14:44

15! is indeed beyond range that a 32bit integer can hold. I'd use doubles throughout if I were you.

The taylor series for sin(x) converges more slowly for large values of x. For x outside -π,π. I'd add/subtract multiples of 2*π to get as small an x as possible.

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You may be having a problem with 15!.

I would print out the values for p, px, fac, and the value for the term for each iteration, and check them out.

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i used long long int for that.. didn't help.. –  Shashwat Mehta Dec 28 '11 at 17:01

You're only including 8 terms in an infinite series. If you think about it for a second in terms of a polynomial, you should see that you don't have a good enough fit for the entire curve.

The fact is that you only need to write the function for 0 <= x <=\pi; all other values will follow using these relationships:

  sin(-x) = -sin(x)

and

sin(x+\pi;) = -sin(x)

and

sin(x+2n\pi) = sin(x)

I'd recommend that you normalize your input angle using these to make your function work for all angles as written.

There's a lot of inefficiency built into your code (e.g. you keep recalculating factorials that would easily fit in a table lookup; you use power() to oscillate between -1 and +1). But first make it work correctly, then make it faster.

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His code works fine with only 8 terms on my 64-bit system; I'm pretty sure the problem is simply overflow of the long int. (Of course what you mention will improve accuracy for large angles, but I don't think that's the source of his problem.) –  Chris K Dec 27 '11 at 17:14
    
Why the downvote? All of this is still correct and relevant and will apply even when the data type range issue is fixed. –  Platinum Azure Dec 27 '11 at 17:16
    
Thank you, Platinum. I agree - my points don't address the root cause that is the factorial, but the rest of it is quite correct. –  duffymo Dec 27 '11 at 17:22
    
@Platinum, I didn't downvote it; I agree the comment is correct, just that this is likely not the root cause. –  Chris K Dec 27 '11 at 19:02
    
yes that is not the cause.. the algorithm works fine even for the range 0 to 8 on my calculator.. and for higher angles, even without using the trigonometric manipulations.. –  Shashwat Mehta Dec 28 '11 at 17:05

You need range reduction. Note that a Taylor series is best near zero and that in the negative range it is the (negative) mirror image of it's positive range. So, in short: reduce the range (by the modula of 2 PI) to wrap it it the range where you have the highest accuracy. The range beyond 1/2 PI is getting less accurate, so you also want to use the formula: sin(1/2 PI + x) = sin(1/2 PI - x). For negative vales use the formula: sin(-x) = -sin(x). Now you only need to evaluate the interval 0 - 1/2 PI while spanning the whole range. Of course for VERY large values accuracy of the modula of 2 PI will suffer.

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