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I've got an unusual (I think) problem. For a given number F_n (I don't know the value of n), I have to find numbers F_0, F_1 such that F_{n}=F_{n-1}+F_{n-2}. The additional difficulty is that this sequence should be as long as possible (value n for F_n should be the highest) and if there exist more then one solution I must take this with the smallest F_0. In short I must generate my "own" Fibonacci sequence. Some examples:

in: F_n = 10; out: F_0 = 0; F_1 = 2;

in: F_n = 17; out: F_0 = 1; F_1 = 5;

in: F_n = 4181; out: F_0 = 0; F_1 = 1;

What I observed for every sequence (with "Fibonacci rule") F_n there is:

F_n = Fib_n * F_1 + Fib_{n-1} * F_0

Where Fib_n is the n-th Fibonacci number. It is true especially for Fibonacci sequence. But I do not know whether this observation is worth anything. We don't know n and our task is to find F_1, F_0 so I think we have gained nothing. Any ideas?

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How about F_1 = F_n and F_0 = 0? You get the smallest possible F_0! – Shahbaz Apr 14 '12 at 14:33
@Shahbaz: but not the longest sequence. – Gareth Rees Apr 14 '12 at 14:34
Do F_0 and F_1 have to be nonnegative? – oldboy Apr 14 '12 at 14:37
@oldboy, yes, I should have written this – xan Apr 14 '12 at 14:39
and integers... – Karoly Horvath Apr 14 '12 at 14:41

4 Answers 4

up vote 2 down vote accepted

Your equation

F_n = Fib_n * F_1 + Fib_{n-1} * F_0

is a linear Diophantine equation in two variables F_1 and F_0. The link presents an efficient algorithm to compute a description of the solution set that allows you to find a solution, if one exists, with F_1 >= 0 and F_0 >= 0 and F_0 minimum. You can then attempt to guess n = 0, 1, ... until you find that there's no solution. This approach is polynomial in log(F_n).

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Bonus: you can use Cassini's identity to avoid implementing extended Euclidean GCD. – oldboy Apr 14 '12 at 14:54
It's very hard to code, but I think the best approach, at least I like it the most. – xan Apr 14 '12 at 22:40

Fn-1 = round(Fn/φ)

where φ=(√5+1)/2.

Proof is left as an exercise for the reader ;^P

Update This is incorrect, back to the drawing board.

Update 2 Let's compute backwards from Fn and Fn-1.

Fn-2 = Fn - Fn-1
Fn-3 = Fn-1 - Fn-2 = Fn-1 - (Fn - Fn-1) = 2Fn-1 - Fn
Fn-4 = Fn-2 - Fn-3 = (Fn - Fn-1) - (2Fn-1 - Fn) = 2Fn - 3Fn-1
Fn-5 = Fn-3 - Fn-4 = (2Fn-1 - Fn) - (2Fn - 3Fn-1) = 5Fn-1 - 3Fn
Fn-6 = Fn-4 - Fn-5 = (2Fn - 3Fn-1) - (5Fn-1 - 3Fn) = 5Fn - 8Fn-1

Notice the pattern? It is easy to compute any member of the sequence out of the real Fibonacci sequence and the last two members. But we only know the last member, how can we know the one before last?

Let's write down the requirement Fi>0 in terms of Fn-1.

Fn-2 = Fn - Fn-1 > 0 ⇒ Fn-1 < Fn
Fn-3 = 2Fn-1 - Fn > 0 ⇒ Fn-1 > Fn/2
Fn-4 = 2Fn - 3Fn-1 ⇒ Fn-1 < 2Fn/3
Fn-5 = 5Fn-1 - 3Fn ⇒ Fn-1 > 3Fn/5

So we have a sequence of bounds on Fn-1 in written terms of the real Fibonacci sequence, each one tighter than the previous. The very last bound that is still satisfiable determines Fn-1 that corresponds to the longest sequence. If there's more than one number that satisfies the last bound, use either the smallest or the largest one , depending on whether the sequence has even or odd length.

For instance, if Fn=101, then
101*5/8 < Fn-1 < 101*8/13 ⇒ Fn-1 = 63

The previous (incorrect) solution would imply Fn-1 = 62, which is close but no cigar.

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not true at all. eg: F_0 = 1, F_1 = 100. F_2 = 101 – Karoly Horvath Apr 14 '12 at 16:45
@Karoly Horvath: this is not the longest Fibonacci-like sequence that ends in 101. – n.m. Apr 14 '12 at 17:05
Proof is left as an exercise for the reader Don't say this if you're just guessing, and you are, because [11, 1, 12, 13, 25, 38, 63, 101] is better than [9, 7, 16, 23, 39, 62, 101]. It creates a never-ending headache for those of us knowledgeable enough to use it responsibly. – oldboy Apr 14 '12 at 17:05
@oldboy You are right, I thoight I have a proof but apparently it's full of holes. – n.m. Apr 14 '12 at 17:16
It is on the other hand a very good approximation - I tested all the numbers from 10 to 1000 and it was never more than 1.5 away from the best second last element. – Neil Apr 14 '12 at 23:31

I'm not sure what you are looking for. The recursive series you mention is defined as:

Fn = F{n-1} + F{n-2}

Clearly, if the staring values can be anything, we can arbirarlily choose F{n-1}, which will give F{n-2} ( = Fn=F{n-1}). Knowing that F{n-1} = F{n-2} + F{n-3}, follows that F{n-3} can be computed from F{n-1} and F{n-2}. This means that you can trace the numbers back to infinity, thus there is no "longest" sequence and there are infinitely many valid sequences.

In a way you are calculating an inverse Fibonacci sequence with initial values F{n} and F{n-1} where F{i} = F{i+2}-F{i+1}, i forever decreasing

UPDATE: If you are looking to constrain the solutionspace to results where all F{i} are non-negative integers, you will get only a handful (most of the time singleton) solutions.

If you calculate the original Fibonacci numbers (Fib{i}), soon you get F{n} < Fib{i-1}; clearly you do not need to go any further. Then you can try all possible combinations of F{0} and F{1} such that F{n} <= Fib{i} * F{1}+ Fib{i-1} * F{0} -- there are only a finite amount of possibilities for non-negative F{0} and F{1} (you can obviously rule out F{0}=F{1}=0). Then see which i(s) is(are) highest amongst the ones that satisfy equality -- you get F{0} and F{1} as well

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I'm terribly sorry, I simply did not sleep too well and didn't wrote strctly.. "The longest sequence" I mean the sequence end at given F_n. Simply, value n (which we do not know, I introduced it for better understanding) must be the highest. – xan Apr 14 '12 at 14:37
altough he didn't mention it I'm sure he is looking for non-negative integers – Karoly Horvath Apr 14 '12 at 14:38
Yes, so you go "backwards" from n, and you find there is no "highest" n, such that the sequence stop. – Attila Apr 14 '12 at 14:38
It's an easy guess that this would be defined over the whole numbers, so 0 < F(0) <= F(1). And by adding the constraint that the sequence be as long as possible, the difference between F(0) and F(1) should be minimized, subject to the final result coming out. And F(0) should be as small as possible. Given all that there is a longest sequence (possibly more than one); and there are not infinitely many valid sequences. – DRVic Apr 14 '12 at 14:39
@DRVic, exactly.. And if there exist more than one sequence we must take this with the smallest F_0. F_n are non-negative integers.. – xan Apr 14 '12 at 14:45

F_n = Fib_n * F_1 + Fib_{n-1} * F_0

Where Fib_n is the n-th Fibonacci number. It is true especially for Fibonacci sequence. But I do not know whether this observation is worth anything. We don't know n and our task is to find F_1, F_0 so I think we have gained nothing.

Well, you're looking for the longest sequence, this means you want to maximize n.

Create a lookup table for fibonacci numbers. Start with the biggest n such that Fib_n <= F_n, the previous entry in the table is fib_n{n-1}. Now the only variables are F_1 and F_0. Solve the linear Diophantine equation. If it has a solution, you finished. If not, decrease n by 1 and try again, till you find a solution.

Note: a solution always exists, since F_2 = 1 * F_1 + 0 * F_0 has the solution F_2 = F_1.

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