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i am applying Regula Falsi method in C++ but the problem is with == operator when F(x3) become 0 then if (fabs( f(x3))==0 should stop and comes out from the loop but it does not stop why why why.... like output below after 12th iteration f(x3)=0 but if(fabs(f(x3)==0)) does not run. loop does not stop it should not go to 13th iteration

float f(float x)
{

float  f_x;
f_x= pow(x,3)+(3*x)-5;
return f_x;
 }
int main(int argc, char** argv) 
{

float  a,b,tol,x3;

int itr,n;

cout << "enter the iterations";
cin >> itr;
cout << "enter the interval a";
cin >> a;
cout <<"enter the interval b";
cin >> b;
cout << "enter the toleration";
cin >> tol;

cout.setf(std::ios_base::fixed, std::ios_base::floatfield);
cout.precision(5);

//cout<<"fa="<<f(a)<<"fb"<<f(b);
cout<<"n\t\ta\t\tb\t\tx3\t\tf(a)\t\tf(b)\t\tf(x3)" <<endl;
if (f(a)*f(b)<0 && a<b)
{
    for (n=0;n<itr;n++)
    {
        x3=a-((b-a)*f(a))/(f(b)-f(a));
       cout << "xx"<<fabs(f(x3));

       if (fabs( f(x3))==0)
       {
             cout << "Solution"<<fabs(f(x3));
                break;
       }
        else
         {
            cout<<n+1 <<"\t\t"<<a <<"\t\t"<<b <<"\t\t"<<x3<<"\t\t"<<f(a) 
            <<"\t"<<f(b)<<"\t\t"<<f(x3) <<endl; 
             if(f(x3)*f(a)<0)
                     b=x3;
              else
                    if(f(x3)*f(b)<0)
                     a=x3;
         }
    }
}
else
    cout<< "No Solution Exist";

return 0;

}

OUTPUT

enter the iterations13

enter the interval a1

enter the interval b2

enter the toleration1

**n   a          b             x3          f(a)           f(b)          f(x3)**


 1  1.00000    2.00000        1.10000     -1.00000        9.00000      -0.36900

 2  1.10000    2.00000        1.13545     -0.36900        9.00000      -0.12980

 3  1.13545    2.00000        1.14774     -0.12980        9.00000      -0.04487

 4  1.14774    2.00000        1.15197     -0.04487        9.00000      -0.01542

 5  1.15197    2.00000        1.15342     -0.01542        9.00000      -0.00529

 6  1.15342    2.00000        1.15391     -0.00529        9.00000      -0.00181

 7  1.15391    2.00000        1.15408     -0.00181        9.00000      -0.00062

 8  1.15408    2.00000        1.15414     -0.00062        9.00000      -0.00021

 9  1.15414    2.00000        1.15416     -0.00021        9.00000      -0.00007

 10 1.15416    2.00000         1.15417    -0.00007        9.00000      -0.00003

 11 1.15417    2.00000         1.15417    -0.00003        9.00000      -0.00001

 12 1.15417    2.00000         1.15417    -0.00001        9.00000       0.00000

 13 1.15417    2.00000         1.15417    -0.00000        9.00000       0.00000
share|improve this question
    
It could be a very small value without being zero yet (and you wont see it in the printing) - can you try changing the condition from "== 0" to " < threshold_value" (make that as small as you like) –  Leeor Sep 21 '13 at 12:06
    
This is horrible code. The condition that a floating point number equals another one is hardly every met by computations. Never do that. –  Walter Sep 21 '13 at 13:31

3 Answers 3

up vote 1 down vote accepted

The issue here is not floating-point precision; it's the tolerance that you're willing to accept in your result. In most cases, regula falsi will get you closer and closer to the correct result as you run through more iterations, but it will not give you the exact answer. So the decision you have to make is, how close do you want the result to be? That's a tradeoff between the real-world requirements for accuracy and the time it takes to get the result; more accuracy requires more computing time. So choose a tolerance that's acceptable for your task, and repeat the loop until the result is within that tolerance. If it turns out to be too slow, you'll have to increase the tolerance.

share|improve this answer
    
you are absolutely right i have just put 0.1 and it stop thanks you so much –  Artemis Sep 21 '13 at 13:13

Floating point arithmetic has precision errors, so in most cases is better to not compare floating point values directly, use an epsilon:

bool float_equal(float a , float b)
{
    return std::abs(a-b) < 0.001;
}

Note that in your case (comparison with zero) the precision is more important: Floating point implementations are dessigned to provide more precision around the zero. So you could have, for example, numbers like 0,000000000001 or 0,0000000000000000001 which are not considered equal to zero.

Check this thread for more considerations: Most effective way for float and double comparison

In addition, note that std::setprecision is a manipulator which changes the precision of the output (printing) operations, not the precision of the floating-point "system".

share|improve this answer
1  
Um, using an error range is appropriate here, because the loop will often not produce exactly zero in theory, even with an unlimited number of iterations. This does not mean that comparisons should always use a range. That's an advanced technique, and has significant drawbacks; in particular, float_equal(x, y) being true and float_equal(y, z) being true does not imply that float_equal(x, y) is true. –  Pete Becker Sep 21 '13 at 12:23
    
@PeteBecker is because that cases (x vs y vs z) I have included a link to a thread which talks about that. (Specifically this answer) –  Manu343726 Sep 21 '13 at 12:27
1  
Yes, that link explains that your assertion "never compare floating point values directly" is wrong. –  Pete Becker Sep 21 '13 at 12:29
1  
@Artemis - don't use anything named "epsilon". What you're looking for here is a tolerance, that is, you need to decide how close to 0 you want the result to be, since additional iterations will get the result closer to 0. To get things going, just try 0.1; once that's working (and producing rather sloppy results), refine it. –  Pete Becker Sep 21 '13 at 12:51
1  
@Artemis yes: As Peter have said, you have to decide the tolerance of your comparisons. Choose a tolerance which considers floating-point numbers with differences passed the first five decimal digits are equal. That is, a tolerance of 0,000001 –  Manu343726 Sep 21 '13 at 13:03

Are you certain f(x3) is exactly 0, and not - say - 0.0000000001 ?

Floating point numbers can be very accurate around 0, sometimes even down to 45 digits after the dot.

share|improve this answer
    
i am using cout<<fabs(f(x3)) it gives me only 0 and also i have set cout.precesion(5) upto 5 decimal –  Artemis Sep 21 '13 at 12:12
3  
That's the point. If you set the printing precision to 5, you will see 0, when the real value is 0.000001 (and below). cout.precision sets only the printing precision, not the computational precision. –  CygnusX1 Sep 21 '13 at 12:16
    
thank you so much 0.000001032 value after thirteen iteration not zero wow you just rock –  Artemis Sep 21 '13 at 12:34
    
can i limit the float number upto 5 or 3 or 2 decimal digits is their any way to do this?? –  Artemis Sep 21 '13 at 12:57
    
@Artemis that is essentially what comparing the difference against an epsilon does. –  drescherjm Sep 21 '13 at 13:04

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