# numerical analysis equation

I have this equation and then find the polynomial from

I am trying to implement it like this:

``````for (int n=0;n<order;n++){
df[n][0]=y[n];
for (int i=0;i<N;i++){ //N number of points

df[n][i]+=factorial(n,i)*y[i+n-1];
}

}

for (int i=0;i<N;i++){

term=factorial(s,i);
result*=df[0][i]*term;
sum+=result;
}

return sum;
``````

1) I am not sure how to implement the sign of every argument in the function.As you can see it goes 'positive' , 'negative', 'positive' ...

2) I am not sure for any mistakes...

Thanks!

----------------------factorial-----------------------------

``````int fact(int n){
//3!=1*2*3
if (n==0) return 1;
else
return n*fact(n-1);

}

double factorial(double s,int n){
//(s 3)=s*(s-1)*(s-2)/6
if ((n==0) &&(s==0)) return 1;
else
return fact(s)/fact(n);

}
``````
-
`if(n%2==0) result *= -1.0` you need a line like this just after `result*=df[0][i]*term`. Alternatively you can use `result*=df[0][i]*term*(n%2==0?-1.0:1.0)` –  Dan Jan 14 at 17:19
@Dan Nice example of obfuscation. –  James Kanze Jan 14 at 17:42
@Dan:The positive-negative concept is in df argument and not in the result (which is df*term).So (and correct me if i mistake) i should out " if((i+n)%2!=0) y[i+n-1]= -1.0;" after the line "df[n][i]+=factorial(n,i)*y[i+n-1];", right? –  George Jan 14 at 17:46
@George oh, perhaps. I'm afraid I didn't pay too much attention to the actual equation. –  Dan Jan 14 at 18:38
@Dan, do you have a reference (bibliogr, WWW) to yours formulas. I cant understan your code, sorry, but I'm curious. –  qPCR4vir Jan 14 at 18:54

Well, I understand you want to approximately calculate the value f(x) for a given x=X, using Newton Interpolation polynomial with equidistant points (more specifically Newton-Gregory forward difference interpolation polynomial). Assuming s=(X-x0)/h, where x0 is the first x, and h the step to obtain the rest of the x for which you know the exact value of f : Considere:

``````double coef (double s, int k)
{
double c(1);
for (int i=1; i<=k ; ++i)
c *= (s-i+1)/i ;
return c;
}

double P_interp_value(double s, int Num_of_intervals , double f[] /* values of f in these points */)    // P_n_s
{

int N=Num_of_intervals ;

double *df0= new double[N+1]; // calculing df only for point 0

for (int n=0 ; n<=N ; ++n)  // n here is the order
{
df0[n]=0;
for (int k=0, sig=-1; k<=n; ++k, sig=-sig) // k here is the "x point"
{
df0[n] += sig * coef(n,k) * f[n-k];
}
}

double P_n_s = 0;

for (int k=0; k<=N ; ++k )   // here k is the order
{
P_n_s += coef(s,k)* df0[k];
}
delete []df0;

return P_n_s;
}

int main()
{
double s=0.415, f[]={0.0 , 1.0986 , 1.6094 , 1.9459 , 2.1972 };

int n=1; // Num of interval to use during aproximacion. Max = 4 in these example
while (true)
{
std::cin >> n;
std::cout << std::endl << "P(n=" << n <<", s=" << s << ")= " << P_interp_value(s, n, f)  << std::endl ;
}
}
``````

it print:

1

P(n=1, s=0.415)= 0.455919

2

P(n=2, s=0.415)= 0.527271

3

P(n=3, s=0.415)= 0.55379

4

P(n=4, s=0.415)= 0.567235

It works. Now we can start to optimize these code.

-
:One question,Where you have df0[n] += sig * coef(n,k) * f[n-k]; , according to the equation i have above ,where it says f_i+n,f_i+n-1,f_i+n-2...If i have i=0 i am taking "f_n,f_n-1,f_n-2..".For i=1 f_n+1,f_n,f_n-1..For i=2 f_n+2,f_n+1,f_n,f_n-1...You have "n-k" which results to n-1,n-2,n-3..The n+1,n+2 values?I am a bit confused .thanks for the help! –  George Jan 15 at 10:39
I have noted, to calcule the result we need only df0 (point 0), and in these formula it corresponde to i=0. I calcule only these first term. –  qPCR4vir Jan 15 at 10:54
I added some comments to make the things clear –  qPCR4vir Jan 16 at 9:54
@ qPCR4vir:Ok , thank you! –  George Jan 16 at 10:05
:I forgot.At the coef function are you sure it's ok?Because as i understand the (s k) = (s(s-1)..s-k+1)! / k! . The way you have it is (s k) = (s(s-1)..s-k+1)! / (s-k)!k!. Check my factorial function. –  George Jan 16 at 10:11

The simplest solution is probably to just keep the sign in a variable, and multiply it in each time through the loop. Something like:

``````sign = 1.0;
for ( int i = 0; i < N; ++ i ) {
term = factorial( s, i );
result *= df[0][i] * term;
sum += sign * result;
sign = - sign;
}
``````
-
:Thanks for the tip.But can you check my comment above?I think i must use " if((i+n)%2!=0 " . –  George Jan 14 at 17:49
The results will be exactly the same. Anytime you need to toggle the sign, toggle the sign, as above. Testing whether the index is even or odd, using `i % 2 != 0`, is an alternative, but it should be reserved for cases where the difference in treatment is more than just toggling the sign. –  James Kanze Jan 14 at 18:27
:Ok for the first question.Do you think from the code i have done that it solves right the equatio?Thank you! –  George Jan 14 at 20:55
@James Kanze : I could not understand yours: result *= ... some optimization? –  qPCR4vir Jan 15 at 9:24
@qPCR4vir Copied from the original. The example is just that: it shows `sign` being toggled. I've not done any real analysis of the original code compared to the equations. –  James Kanze Jan 15 at 9:39

You cannot do `pow( -1, m )`.

``````inline int minusOnePower( unsigned int m )
{
return (m & 1) ? -1 : 1;
}
``````

You may want to build up some tables of calculated values.

-
``````inline signed int minusOnePower( unsigned int m )