# nth term of series

we have to find the nth term of this series http://oeis.org/A028859

n<=1000000000

i have written the code but time limit exceeds when n a is huge number.

``````#include<iostream>
using namespace std

int main()
{
long long int n;
cin>>n;

long long int a,b,c;
a=1;
b=3;

int i;
for(i=3;i<=n;i++)
{
c=(2ll*(a+b))%1000000007;
a=b;
b=c;
}

cout<<c;
}
``````
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Any chance you could paste in a cleaner code sample than this one, using proper indentation and avoiding the excessive white space? –  Robert Harvey Jul 1 '12 at 20:56
What does this have to do with dynamic programming? –  Mathias Jul 1 '12 at 20:58
Two simple optimizations -- you can start out doing three steps for each iteration in your loop with no copies, doing "c=2(a+b)..." "b=2(c+a)..." "a=2(b+c)...". You can also then do the mod only once per loop, on c in the first step. That should more than double your speed. –  David Schwartz Jul 1 '12 at 21:06
? sorry dude, you are misunderstand the DP meaning. Dp is about storing computed values in order to use them in futur computation and not having to compute them again. –  Samy Arous Jul 1 '12 at 21:12
–  Jim Balter Jul 2 '12 at 0:18

The standard technique for solving this type of problem is to rewrite it as a matrix multiplication and then use exponentiation by squaring to efficiently compute powers of the matrix.

In this case:

``````a(n+2) = 2 a(n+1) + 2 a(n)
a(n+1) = a(n+1)

(a(n+2)) = (2  2) * ( a(n+1) )
(a(n+1))   (1  0)   ( a(n)   )
``````

So if we define the matrix A=[2,2 ; 1,0], then you can compute the n th term by

``````[1,0] * A^(n-2) * [3;1]
``````

All of these operations can be done modulo 1000000007 so no big number library is required.

It requires O(log(n)) 2*2 matrix multiplications to compute A^N, so overall this method is O(log(n)), while your original method was O(n).

EDIT

Here is a good explanation and a C++ implementation of this method.

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When `long long` is not enough, you probably want to use a bignum library. For example GNU MP.