# The inverse Fibonacci problem?

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There are dozens of ways of computing F(n) for an arbitrary n, many of which have great runtime and memory usage.

However, suppose I wanted to ask the opposite question:

Given F(n) for n > 2, what is n?

(The n > 2 restriction is in there since F(1) = F(2) = 1 and there's no unambiguous inverse).

What would be the most efficient way of solving this problem? It's easy to do this in linear time by enumerating the Fibonacci numbers and stopping when you hit the target number, but is there some way of doing this any faster than that?

EDIT: currently, the best solution posted here runs in O(log n) time using O(log n) memory, assuming that mathematical operations run in O(1) and that a machine word can hold any number in O(1) space. I'm curious if it's possible to drop the memory requirements, since you can compute Fibonacci numbers using O(1) space.

Thanks, and I hope you think this is as cool as I do. :-)

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You can find some useful discussion in the math.exchange related question: [checking-if-a-number-is-a-fibonacci-or-not]: math.stackexchange.com/questions/9999/… – ypercube Mar 2 '11 at 23:34
I might call this the fibonacci logarithm – GregS Mar 4 '11 at 12:03

Since OP has asked about matrix solution not involving any floating point computations, here it is. We can achieve `O(logn)` complexity this way, assuming numeric operations have `O(1)` complexity.

Let's take 2x2 matrix `A` having following structure

``````1 1
1 0
``````

Now consider vector `(8, 5)`, storing two consecutive fibonacci numbers. If you multiply it by this matrix, you'll get `(8*1 + 5*1, 8*1 + 5*0) = (13, 8)` - the next fibonacci number.
If we generalize, `A^n * (1, 0) = (f(n), f(n - 1))`.

The actual algorithm takes two steps.

1. Calculate `A^2`, `A^4`, `A^8`, etc. until we pass desired number.
2. Do a binary search by `n`, using calculated powers of `A`.

On a side note, any sequence of the form `f(n) = k1*f(n-1) + k2*f(n-2) + k3*f(n-3) + .. + kt*f(n-t)` can be presented like this.

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I'm still a bit fuzzy on what in particular you do once you pass the desired number. How exactly do you recover the answer? – templatetypedef Mar 2 '11 at 3:57
@templatetypedef Imagine we passed `f` at `A^16`, therefore we do binary search in range `[0, 16]`. `mid` is 8, and we have `A^8` computed already. Let's say `f > A^8`, then the range is reduced to `[8, 16]`. Now `mid` is 12, but `A^12` is `A^8*A^4`. 8 is a current search border and 4 is a power of 2: therefore we have both computed and can calculate `A^12` in one multiplication. And so on. – Nikita Rybak Mar 2 '11 at 4:02
@templatetypedef Comparing matrixes with numbers (`f`) is a bit of simplification, but that should give the idea. – Nikita Rybak Mar 2 '11 at 4:03
@Nikita Rybak- Awesome. So this is silly, but I want to upvote your answer but for some reason I can't unless you make an edit; can you make some small change to the answer so I can +1 you? – templatetypedef Mar 2 '11 at 4:12
+1, Best answer so far. Fast and avoids using floating point. – MAK Mar 2 '11 at 6:40

Wikipedia gives the result as

``````n(F) = Floor[ Log(F Sqrt(5))/Log(Phi) + 1/2]
``````

where Phi is the golden ratio.

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This `n(F)` is the fastest way to compute `n` for a given `F(n)` (ignoring the fact that `n(1)` returns 2). However, it does not guarantee that `F` is actually a member of the Fibonacci sequence (given a large `F`, the numbers around `F` will give the same result). – Brandon Tilley Mar 2 '11 at 2:57
This can be computed in constant time, as there are functions in almost every language that perform log and sqrt in constant time. – Dan Mar 2 '11 at 2:59
@Dan I found this interesting: You can also check to see if `phi * n - (1.0 / n)` and `phi * n + (1.0 / n)` crosses a positive integer. E.g. for `n = 144` you get `232.9899` and `233.0038`, which crosses `233`. Using the same calculation on `n = 143` gives `231.3718` and `231.3858`, and so is not a Fibonacci number. – Brandon Tilley Mar 2 '11 at 3:07
@Dan: It's constant time only if you consider numbers with a fixed upper bound. – R. Martinho Fernandes Mar 2 '11 at 3:10
@Dan- I am skeptical that you can take a log in constant time unless you bound the precision of your numbers. This would be a practically good solution, but I'm more interested in something that scales as well as possible given just basic mathematical operations as primitives. – templatetypedef Mar 2 '11 at 3:34

Measuring memory usage by counting unbounded words is sort of silly, but as long as that's the model, there's an O(log n) time, O(1) word solution similar to Nikita Rybak's that in essence computes `n` via its Zeckendorf representation, which is based on the Fibonacci numbers (YO DAWG).

Define the matrix

``````      1  1
A  =       ,
1  0
``````

which satisfies

``````        F(m + 1)    F(m)
A^m  =                      .
F(m)    F(m - 1)
``````

Instead of the sequence `A^(2^k)`, we're going to use the sequence `A^F(k)`. The latter sequence has the property that we can move forward with a matrix multiply

``````A^F(k + 1) = A^F(k - 1) * A^F(k)
``````

and backward with a matrix inverse and multiplication

``````A^F(k - 1) = A^F(k + 1) (A^F(k))^-1,
``````

so we can build a bidirectional iterator with only eight six twelve words assuming we store everything as rationals (to avoid assuming the existence of a unit-cost divide). The rest is just adapting this O(1)-space algorithm for finding a Zeckendorf representation.

``````def zeck(n):
a, b = (0, 1)
while b < n:
a, b = (b, a + b)
yield a
n1 = a
while n1 < n:
a, b = (b - a, a)
if n1 + a <= n:
yield a
n1 += a
a, b = (b - a, a)
``````
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 From this it's obvious that the basic Fib eqn F(m + 1) = F(m-1) + F(m) is the log, base the matrix A, of the matrix multiply eqn A^F(m+1)=A^F(m)*A^F(m-1). Sweet mathy answer! – Reb.Cabin Feb 29 '12 at 12:49

If you can easily interpret F(n) in binary,

You may be suspicious of the constants 1.7 and 1.1. These work because d*1.44042009041 + C never gets very close to an integer.

I can post a derivation tomorrow if there is interest.

Here is a table with n = 2 through 91, which shows the formula result before flooring:

`````` n  formula w/o floor     F(n) F(n) in binary

2  2.540                    1 1
3  3.981                    2 10
4  4.581                    3 11
5  5.421                    5 101
6  6.862                    8 1000
7  7.462                   13 1101
8  8.302                   21 10101
9  9.743                   34 100010
10 10.343                   55 110111
11 11.183                   89 1011001
12 12.623                  144 10010000
13 13.223                  233 11101001
14 14.064                  377 101111001
15 15.504                  610 1001100010
16 16.104                  987 1111011011
17 17.545                 1597 11000111101
18 18.385                 2584 101000011000
19 19.825                 4181 1000001010101
20 20.425                 6765 1101001101101
21 21.266                10946 10101011000010
22 22.706                17711 100010100101111
23 23.306                28657 110111111110001
24 24.147                46368 1011010100100000
25 25.587                75025 10010010100010001
26 26.187               121393 11101101000110001
27 27.028               196418 101111111101000010
28 28.468               317811 1001101100101110011
29 29.068               514229 1111101100010110101
30 30.508               832040 11001011001000101000
31 31.349              1346269 101001000101011011101
32 32.789              2178309 1000010011110100000101
33 33.389              3524578 1101011100011111100010
34 34.230              5702887 10101110000010011100111
35 35.670              9227465 100011001100110011001001
36 36.270             14930352 111000111101000110110000
37 37.111             24157817 1011100001001111001111001
38 38.551             39088169 10010101000111000000101001
39 39.151             63245986 11110001010000111010100010
40 40.591            102334155 110000110010111111011001011
41 41.432            165580141 1001110111101000110101101101
42 42.032            267914296 1111111110000000110000111000
43 43.472            433494437 11001110101101001100110100101
44 44.313            701408733 101001110011101010010111011101
45 45.753           1134903170 1000011101001010011111110000010
46 46.353           1836311903 1101101011100111110010101011111
47 47.193           2971215073 10110001000110010010010011100001
48 48.634           4807526976 100011110100011010000101001000000
49 49.234           7778742049 111001111101001100010111100100001
50 50.074          12586269025 1011101110001100110011100101100001
51 51.515          20365011074 10010111101110110010110100010000010
52 52.115          32951280099 11110101100000011001010000111100011
53 53.555          53316291173 110001101001111001100000101001100101
54 54.396          86267571272 1010000010101111100101010110001001000
55 55.836         139583862445 10000001111111110110001011011010101101
56 56.436         225851433717 11010010010101110010110110001011110101
57 57.276         365435296162 101010100010101101001000001100110100010
58 58.717         591286729879 1000100110101011011011110111110010010111
59 59.317         956722026041 1101111011000001000100111001011000111001
60 60.157        1548008755920 10110100001101100100000110001001011010000
61 61.598        2504730781961 100100011100101101100101101010100100001001
62 62.198        4052739537881 111010111110011010000110011011101111011001
63 63.038        6557470319842 1011111011011000111101100000110010011100010
64 64.478       10610209857723 10011010011001100001110010100010000010111011
65 65.078       17167680177565 11111001110100101001011110101000010110011101
66 66.519       27777890035288 110010100001110001011010001001010011001011000
67 67.359       44945570212853 1010001110000010110100101111110010101111110101
68 68.800       72723460248141 10000100010010001000000000000111101001001001101
69 69.400      117669030460994 11010110000010011110100110000101111111001000010
70 70.240      190392490709135 101011010010100100110100110001101101000010001111
71 71.681      308061521170129 1000110000010111000101001100010011100111011010001
72 72.281      498454011879264 1110001010101011101011110010100001001111101100000
73 73.121      806515533049393 10110111011000010110000111110110100110111000110001
74 74.561     1304969544928657 100101000101101110011100110001010110000110110010001
75 75.161     2111485077978050 111100000000110001001101110000001010111101111000010
76 76.602     3416454622906707 1100001000110011111101010100001100001000100101010011
77 77.442     5527939700884757 10011101000111010000111000010001101100000010100010101
78 78.042     8944394323791464 11111110001101110000100010110011001101000111001101000
79 79.483    14472334024676221 110011011010101000001011011000100111001001001101111101
80 80.323    23416728348467685 1010011001100010110001111101111000000110010000111100101
81 81.764    37889062373143906 10000110100110111110011011000111100111111011010101100010
82 82.364    61305790721611591 11011001110011010100101010110110101000101101011101000111
83 83.204    99194853094755497 101100000011010010011000101111110010000101000110010101001
84 84.644   160500643816367088 1000111010001101100111110000110100111001010110001111110000
85 85.244   259695496911122585 1110011010100111111010110110110011001001111111000010011001
86 86.085   420196140727489673 10111010100110101100010100111101000000011010101010010001001
87 87.525   679891637638612258 100101101111011101011101011110011011001101010100010100100010
88 88.125  1100087778366101931 111101000100010011000000000110000011010000101001100110101011
89 89.566  1779979416004714189 1100010110011110000011101100100011110011101111101111011001101
90 90.406  2880067194370816120 10011111111000000011011101101010100001101110100111100001111000
91 91.846  4660046610375530309 100000010101011110011111011001111000000001100100101011101000101
``````

'

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 This answer is O(1) and an absolute triumph - @rcollyer's answer reduced to a very slick calculation. Given the original constraints of the problem (knowing the input certainly is Fibonacci), surely this can't be beat. – Chris Nash Mar 11 '11 at 21:40 I don't know why you bothered writing out an approximation of 1/log_2(phi), since you need lg d + O(1) bits of accuracy. This is most definitely not O(1). – userOVER9000 Mar 11 '11 at 22:54 @userOVER9000 So getting a better double approximation would be good enough to answer the question for an input that's 2^53 bits long? 1 pebibyte? – Chris Nash Mar 12 '11 at 1:33 Still not O(1). – userOVER9000 Mar 13 '11 at 17:45

It's been proven that the formula for a fib n is `fib(n) = ( (phi)^n - (-phi)^(-n) ) / sqrt(5)` where `phi = (1+sqrt(5)) / 2`, the golden section number. (see this link).

You could try to find a mathematical inverse to the fib function above, or otherwise do a binary search in 32/64 operations (depending on how big your searchable maximum is) to find the n that matches the number (try each n by computing fib(n) and splitting your sample space in two according to how fib(n) compares to the given fibonacci number).

Edit: @rcollyer's solution is faster, as mine is in O(lg n) and the one he found is in O(1) = constant time.

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Someone posted this proof (based on work he did in high school!) of the answer posted by @Dan.

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So I was thinking about this problem and I think that it's possible to do this in O(lg n) time with O(lg n) memory usage. This is based on the fact that

F(n) = (1 / √5) (Φn - φn)

Where Φ = (1 + √5)/2 and φ = 1 - Φ.

The first observation is that φn < 1 for any n > 1. This means that for any n > 2, we have that

F(n) = ⌊ Φn / √5 ⌋

Now, take n and write it in binary as bk-1bk-2...b1b0. This means that

n = 2k-1 bk-1 + 2k-2 bk-2 + ... + 21 b1 + 20 b0.

This means that

F(n) = ⌊ Φ2k-1 bk-1 + 2k-2 bk-2 + ... + 21 b1 + 20 b0 / √5 ⌋

F(n) = ⌊ Φ2k-1 bk-1Φ2k-2 bk-2 ... Φ21 b1Φ20 b0 / √5 ⌋

This suggests the following algorithm. First, start computing Φ2k for all k until you compute a number Φz such that ⌊ Φz / √5 ⌋ that's greater than your number F(n). Now, from there, iterate backwards across all of the powers of Φ you generated this way. If the current number is bigger than the indicated power of Φ, then divide it by that power of Φ and record that the number was divided by this value. This process essentially recovers one bit of n at a time by subtracting out the largest power of 2 that you can at a time. Consequently, once you're done, you'll have found n.

The runtime of this algorithm is O(lg n), since you can generate Φ2i by repeated squaring, and we only generate O(lg n) terms. The memory usage is O(lg n), since we store all of these values.

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 You can escape floating point computations if you use 2x2 matrixes instead. It should be faster and somewhat simpler. – Nikita Rybak Mar 2 '11 at 3:28 Don't agree with this. Compute phi^2^k itself is a problem. How precise? Then you need to take the floors etc. What is wrong with a simple binary search, computing Fibonacci using matrix multiplication? :-P – Aryabhatta Mar 2 '11 at 3:29 @Moron, @Nikita Rybak- I like the idea to use the matrix representation. However, I don't see how to recover individual bits out of those representations. Could you clarify that step? I definitely would like something numerically stable! – templatetypedef Mar 2 '11 at 3:31 @templatetypedef I've posted a description in a separate answer. – Nikita Rybak Mar 2 '11 at 3:56 @Moron Solution based on matrix multiplication will have the same problems, as `n` grows. Only here we need lots of signs after decimal point, and with matrix multiplication we need huge numbers. – Nikita Rybak Mar 2 '11 at 3:58

You can find n for any Fib(n) in O(1) time and O(1) space.

You can use a fixed-point CORDIC algorithm to compute ln() using only shift and add on integer data types.

If x = Fib(n), then n can be determined by

``````     n = int(2.0801 * ln(x) + 2.1408)
``````

CORDIC run-time is determined by the desired level of precision. The two floating-point values would be encoded as fixed-point values.

The only issue with this proposal is that it returns a value for numbers that are not in the Fibonacci sequence, but the original problem specifically stated that the input to the function would be Fib(n), which implies that only valid Fibonacci numbers would be used.

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EDIT: Never mind. The asker has stated in comments that exponentiation is definitely not constant time.

Is exponentiation one of the mathematical operations that you'll allow in constant time? If so, we can compute F(n) in constant time via the closed-form formula. Then, given some F, we can do the following:

1. Compute F(1), F(2), F(4), F(16), F(256), ... until F(2^k) <= F < F(2^{k+1})
2. Do a binary search for i between 2^k and 2^{k+1} until F(i) <= F < F(i+1)

If F = F(n), then first part takes k = O(log(n)) steps. The second part is a binary search over a range of size O(2^k), so it also takes k = O(log(n)). So, in total, we have O(log(n)) time in O(1) space if (and it's a big if) we have exponentiation in O(1) time.

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A closed form of the Fibonacci number formula is:

``````Fn = Round(φ^n / Sqrt(5))
``````

Where φ is the golden ratio.

If we ignore the rounding factor this is invertible and the inverse function is:

``````F(-1)n= log(n*Sqrt(5))/logφ
``````

Because we ignored the rounding factor there is an error in the formula which could be calculated. However if we consider that a number n is a Fibonacci number iff the interval [n*φ - 1/n, n*φ + 1/n] contains a natural number then:

A number is a Fibonacci number iff the interval [n*φ - 1/n, n*φ + 1/n] contains a natural number and that number's index in the Fibonacci sequence is given by rounding log(n*Sqrt(5))/logφ

This should be doable in (pseudo)-constant time depending on the algorithms used for calculating the log and square roots etc.

Edit: φ = (1+Sqrt(5))/2

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