# Recurrence Relations [closed]

How to calculate tribonacci number for very large n ( say 10^14 ) in best complexity. Tribonacci numbers are defined as `F(n)=F(n-1)+F(n-2)+F(n-3)` with `F0=1, F1=2, F2=4`.

Or recurrence defined as `F(n)=aF(n-1)+bF(n-2)+cF(n-3)` with `F0=1, F1=2, F2=4`.

I want to Calculate nth term in log(n) just like nth Fibonacci number.

How can I generate the Base Matrix for using matrix exponentiation to calulate the nth term?

Previously I was trying to implement it using DP but as we cannot take array of such large size its not working fine. Similarly Recursion didn't work here due to stack overflow for very large numbers of order of 10^14.

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## closed as not a real question by templatetypedef, Eitan T, j0k, Monolo, dgwSep 2 '12 at 10:34

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Well `f(n) = 1.1374515722826291096 * 1.8392867552141611326^n - 0.73735270576032767520^n * (0.24704361526838014667 sin(2.17623354549187039845 n) + 0.13745157228262910956 cos(2.17623354549187039845 n))` :p –  kennytm Sep 2 '12 at 7:19
write the program using MPI and become famous for releasing the largest tribonacci number to the world! –  pyCthon Sep 2 '12 at 7:21
By "very large n", do you mean that the value will be ~10^14, or do you want the 10^14th term in the tribonacci sequence, i.e. F(10^14)? That latter number will be absurdly large. –  DSM Sep 2 '12 at 7:22
There's a formula for the general term of the Tribonacci sequence (or any extension to the Fibonacci sequence, for that matter). I suggest you use that. –  Eitan T Sep 2 '12 at 7:28
@EitanT, that suffers from numerical inaccuracy for large n. –  huon-dbaupp Sep 2 '12 at 7:30

The best asymptotic complexity for tribonacci numbers will be using a matrix exponentiation method like the one for Fibonacci numbers. Specifically, written correctly, this is O(log n) integer operations, rather than O(n) (like the dynamic programming method) or O(3n) (like the naive solution).

The matrix of interest is

``````    [1, 1, 1]
M = [1, 0, 0]
[0, 1, 0]
``````

and the nth tribonacci number is in the upper left corner of Mn. The matrix exponentiation must be computed by squaring to achieve log(n) complexity.

(for `F(n+3) = a F(n+2) + b F(n+1) + c F(n)`, the matrix is:

``````    [a, b, c]
M = [1, 0, 0]
[0, 1, 0]
``````

and the result is {Fn+2,Fn+1,Fn} = Mn {F2,F1,F0}, also see here.)

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I don't like the statement `The best complexiy`. You can find the number using a close formula, as shown by @KennyTM in comments, this will be `O(f(answer))`, where `f(answer)` is the complexity of your power function of the resulting number. There are other close formulas in this page. Other then the first statement - I like this answer. –  amit Sep 2 '12 at 7:36
@amit, the complexity of that is still O(log n), since there is an exponentiation by n required, and that can't be done faster than O(log n), I believe. –  huon-dbaupp Sep 2 '12 at 7:38
Best asymptotic complexity != best complexity. [I sinned in using the asymptotic notation in the comment as well]. –  amit Sep 2 '12 at 7:39
@amit, is that better? :) –  huon-dbaupp Sep 2 '12 at 7:40
Yes. But your previous comment made me think of a different issue. Both are `O(logn)` assuming `O(1)` integer ops. However - this assumption is unrealistic for large numbers as the OP is after, since the number (answer) itself is `O(3^n)`, so you need `O(n)` bits to represent it - resulting in integer arithmetics to be `O(n)` itself - thus DP will be `O(n^2)`, and close formula/matrix will be `O(nlogn)`. Don't you agree? –  amit Sep 2 '12 at 7:44

A Dynamic programming solution does NOT require 10^14 elements array. It only requires 3.

Note that each step is only using previous 3 elements, so for `F(1000)`, you really do not need `F(5)`.

You can simply override elements that are no longer needed, and regard them as a new number.

The `%` operator is your friend for this purpose.

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its taking too much time too compute using O(n) I want algorithm which can compute in O(logn ) time .. –  Rahul Kumar Dubey Sep 2 '12 at 7:40
@RahulKumarDubey: Then use a close formula or dbaupp suggestion. I was just answering your question, I thought DP is what you are after. –  amit Sep 2 '12 at 7:47
thanks for the reply –  Rahul Kumar Dubey Sep 2 '12 at 7:51