# Sum of even fibonacci numbers

This is a Project Euler problem. If you don't want to see candidate solutions don't look here.

Hello you all! I'm developing an application that will find the sum of all even terms of the fibonacci sequence. The last term of this sequence is 4,000,000 . There is something wrong in my code but I cannot find the problem since it makes sense to me. Can you please help me?

using System.Collections.Generic;
using System.Linq;
using System.Text;

namespace ConsoleApplication1
{
class Program
{
static void Main(string[] args)
{
long[] arr = new long [1000000] ;
long i= 2;
arr[i-2]=1;
arr[i-1]=2;
long n= arr[i];

long s=0;
for (i=2 ; n <= 4000000; i++)
{
arr[i] = arr[(i - 1)] + arr[(i - 2)];
}
for (long f = 0; f <= arr.Length - 1; f++)
{
if (arr[f] % 2 == 0)
s += arr[f];
}
Console.Write(s);
}
}
}

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I bet there is a shortcut to computing that stuff. en.wikipedia.org/wiki/Fibonacci_number#Closed-form_expression Always try to simplify the formula before trying to compute it. – Hamish Grubijan Apr 4 '10 at 14:11
I cannot see any reason to store previously generated terms of the sequence. Just compute the next term, check it for evenness, and conditionally sum it. – James K Polk Apr 4 '10 at 14:31

Change the first for loop to this:

for (i = 2; arr[i - 1] < 4000000; i++)

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Third identity This identity has slightly different forms for Fj, depending on whether j is odd or even. The sum of the first n − 1 Fibonacci numbers, Fj, such that j is odd, is the (2n)th Fibonacci number.

The sum of the first n Fibonacci numbers, Fj, such that j is even, is the (2n + 1)th Fibonacci number minus 1.

[16]

The only problem is potential loss of precision when you raise phi to the (2n + 1)th power.

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There's absolutely no point in giving a closed form if they can't prove it themselves using recurrences or generating functions. – Wes Nov 12 '12 at 20:13

In this section:

       long n= arr[i];

long s=0;
for (i=2 ; n <= 4000000; i++)
{

arr[i] = arr[(i - 1)] + arr[(i - 2)];
}


You've only assigned n once; n never updates, so your loop will never terminate.

n is not bound to i; n is set to arr[2] because i was 2 at that point. So, i will be 3 from the first iteration of the loop forever.

To fix this, one approach would be to get rid of n altogether and make your loop condition

for (i = 2; arr[i] <= 4000000; i++)

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I have already tried your fix and it didnt work. VS says that the index is out of range. – user300484 Apr 4 '10 at 14:14
What are the values of i and arr[i] before the IndexOutOfRangeException occurs? – Mark Rushakoff Apr 4 '10 at 14:18

try this (and use this for your big integer requirements: http://intx.codeplex.com/Wikipage ) :

using System;
using System.Collections;
using System.Linq;
using System.Collections.Generic;

using Oyster.Math;

namespace Application
{

public class Test
{

public static void Main()
{
IntX even = 0;
Console.WriteLine("Sum of even fibonacci {0}\n",
Fibonacci(20).Where(x => x % 2 == 0).Sum());
Console.WriteLine("Sum of odd fibonacci {0}",
Fibonacci(20).Where(x => x % 2 == 1).Sum());

Console.Write("\nFibonacci samples");
foreach (IntX i in Fibonacci(20))
Console.Write(" {0}", i);

}

public static IEnumerable<IntX> Fibonacci(int range)
{
int i = 0;

IntX very = 0;
yield return very;
++i;

IntX old = 1;
yield return old;
++i;

IntX fib = 0;
while (i < range)
{
fib = very + old;
yield return fib;
++i;

very = old;
old = fib;
}

}
}

public static class Helper
{
public static IntX Sum(this IEnumerable<IntX> v)
{
int s = 0;
foreach (int i in v) s += i;
return s;
}
}

}


Sample Output:

Sum of even fibonacci 3382

Sum of odd fibonacci 7563

Fibonacci samples 0 1 1 2 3 5 8 13 21 34 55 89 144 233 377 610 987 1597 2584 4181

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hello there, i found this code by Michael very helpful but there are some parts i did not understand, due to the fact that i am new to C#.... y do we put the argument value of 20 in this line? Fibonacci(20).Where(x => x % 2 == 0).Sum()); – user629917 Feb 23 '11 at 12:08
Just take a fibonacci number that is even and go 2 fibonacci's above that number. Subtract 1 from that number and divide by 2. It gives you the sum of even fibonacci numbers up to where you started. E.g. 34, two higher is 89. Subtract 1 is 88. Divide by 2 yields 44. That's the sum of 2+8+34. – Stefan Gruenwald Jun 23 '15 at 5:22

I'll admit that I would do this entirely differently. I would probably use the paired sequence of Lucas and Fibonacci numbers, plus the simple formulas

F(n+a) = (F(a)*L(n) + L(a)*F(n))/2

L(n+a) = (5*F(a)*F(n) + L(a)*L(n))/2

Note that only every third Fibonacci number is even. So since F(3) = 2, and L(3) = 4, we get

F(n+3) = L(n) + 2*F(n)

L(n+3) = 5*F(n) + 2*L(n)

Now just sum the terms.

(edit: There is an even easier solution to this, that does rely on some mathematical sophistication to derive, or some knowledge of the Fibonacci sequence and identities for that sequence, or perhaps a search through the encyclopedia of integer sequences. Sadly, any more than this hint seems inappropriate for a PE problem, so I'll leave that solution in the margins of this note. Thus, the sum of the first k even Fibonacci numbers is...)

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