generating function: faster generation of F(n)

i recently gave a test... the question was long story and the solution boiled down to F(n) = 2*F(n-1) + 2*F(n-2)...

I had an O(n) solution using dynamic programming... However, the examiner wasn't satisfied...

my solution was to simply store every F(n) in an array as it is calculated. it took O(n) time. as we need just the previous two elements, by using just two variables, the space problem can be solved.

however O(n) isn't fast enough...

the function looks like the fibonacci function, and a fibonacci number can be generated in O(lg n) time... but am unable to get a O(lg n) soln for my problem..

so my question is how do i improve the time-complexity of the function?

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–  Daniel Fischer Jul 8 '12 at 19:54
This looks awfully similar to a question asked a few hours ago: stackoverflow.com/questions/11381277/… –  tskuzzy Jul 8 '12 at 20:17
This is around the fifth time I see this question in the last 2-3 weeks. Some professor somewhere must really love mentioning this site in his/her lectures. –  IVlad Jul 8 '12 at 22:11

Exactly the same way. Express your recurrence in matrix form; this reduces the problem to finding the n-th power of a matrix, which can be done in log(n) time.

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Short clever and simple. +1. –  amit Jul 8 '12 at 19:48

There is a closed formula for any linear recurrence relation (which this is).

It involves solving the characteristic polynomial, which in this case is:

``````t^2 - 2*t - 2 = 0   (since F(n) - 2 * F(n-1) - 2 * F(n-2) = 0)
``````

If t1 and t2 are the (complex) solutions of this quadratic equation, then the formula is:

``````F(n) = a * t1^n + b * t2^n
``````

where a and b are constants, which can be found from the initial conditions (i.e. the values of F(0) and F(1) in this case). I.e.

``````F(0) = a + b
F(1) = a * t1 + b * t2
``````

Solving for a and b:

``````a = ( t2 * F(0) - F(1) ) / ( t2 - t1 )
b = ( t1 * F(0) - F(1) ) / ( t1 - t2 )
``````

In this particular case the roots of the characteristic polynomial are:

``````t1 = 1 + sqrt(3)
t2 = 1 - sqrt(3)
``````
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+1 Use math when you can. (Also: nice background and explanation, giving the tools for readers how to develop these equations when possible) –  amit Jul 8 '12 at 19:45
An important tnote: a closed form solution does not imply a fast O(1) or O(lg n) solution. The precision required for `t1` and `t2` to calculate the n-th term grows with `n`. –  tskuzzy Jul 8 '12 at 20:21
@tskuzzy: Not if you're cunning. `(a + b.sqrt(3)) * (c + d.sqrt(3)) == (e + f.sqrt(3))`, where `e == (a.c + b.d)`, `f == (a.d + b.c)`. In other words, it can all be done with integer maths. –  Oliver Charlesworth Jul 8 '12 at 20:27
@OliCharlesworth: Wait what, I did not follow that. Where did those equations come from and what do they mean? –  tskuzzy Jul 8 '12 at 20:30
@tskuzzy: Your original comment was implying that the irrational/fractional nature of sqrt(3) would be a problem, due to precision limitations. My comment is pointing out that it's not a problem. The equations I gave are just an example; they illustrate that it's possible to handle algebra on sqrt(3) with integer arithmetic only. –  Oliver Charlesworth Jul 8 '12 at 20:33

In your solution, you also used O(n) memory.

You can use simple loop to calculate the n-th Fibonacci element:

The only thing you need to save is the 3 (a1,a2,a3) last elements, in each iteration you update a1 to be a2, update a2 to be a3, and update a3 to be old(a1) + old(a2) (you can use 2 temp vars for this purpose).

So we get simple algorithm with run-time O(n) only O(1) memory.

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The OP is asking about improving the time complexity, not the space complexity... –  Oliver Charlesworth Jul 8 '12 at 20:43