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I am reading a algorithms book by S.DasGupta. Following is text snippet from the text regarding number of bits required for nth Fibonacci number.

It is reasonable to treat addition as a single computer step if small numbers are being added, 32-bit numbers say. But the nth Fibonacci number is about 0.694n bits long, and this can far exceed 32 as n grows. Arithmetic operations on arbitrarily large numbers cannot possibly be performed in a single, constant-time step.

My question is for eg, for Fibonacci number F1 = 1, F2 =1, F3=2, and so on. then substituting "n" in above formula i.e., 0.694n for F1 is approximately 1, F2 is approximately 2 bits, but for F3 and so on above formula fails. I think i didn't understand propely what author mean here, can any one please help me in understanding this?

Thanks

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7 Answers 7

up vote 4 down vote accepted

Well,

n              3    4     5     6     7     8
0.694n         2.08 2.78  3.47  4.16  4.86  5.55
F(n)           2    3     5     8     13    21
bits           2    2     3     4     4     5
log(F(n))      1    1.58  2.32  3     3.7   4.39

Bits required is the base-2 log rounded up, so this is close enough for me.

The value 0.694 comes from the fact that F(n) is the closest integer to (φn)/√5. So log(F(n)) is n * log(phi) - log(sqrt(5)), and log(phi) is 0.694. As n gets bigger, the log(sqrt(5)) and the rounding rapidly become insignificant.

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if you round it to integers it seems almost perfect –  n00b Mar 9 '11 at 15:52
    
what is phi here? is it 22/7 –  venkysmarty Mar 9 '11 at 16:08
1  
phi is the golden ratio, (1 + sqrt(5))/2, or 1.6180339887. See en.wikipedia.org/wiki/Golden_ratio. It becomes involved with Fibonacci numbers when you solve their recurrence relation. –  Steve Jessop Mar 9 '11 at 16:09
    
F(n) = (φ^n - φ'^n)/√5. (φ' = 1- φ) Could you please elaborate on saying F(n) is the closest integer to (φ^n)/√5 and ignoring the rest part of the formula. –  Gaurav yesterday
1  
@Gaurav: (φ'^n)/√5 < 1/2 for n>=0, and we know that the result is exactly an integer, therefore this small fractional part of the formula can be ignored by rounding the large other part. –  Steve Jessop yesterday

First of all, the word about is very important, as in the nth Fibonacci number is about 0.694n bits long. Second, I think the author means when n->infinity. Try some big number and check :)

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private static int nobFib(int n)  // number of bits Fib(n)  
{
    return n < 6 ? ++n/2 : (int)(0.69424191363061738 * n - 0.1609640474436813);
}  

Checked it for n from 0 to 500.000, n=500.000.000, n=1.000.000.000
It's based on Binet's formula.
Needed it for: Fibonacci Sequence Binary Plot.
See: http://bigintegers.blogspot.com/2012/09/fibonacci-sequence-binary-plot-edd-peg.html

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you cant have say half a bit... the amount of bits must be rounded

so it means

number of bits = Math.ceil(Math.max(0.694*n,32));

so its rounded up for n>32 and 32 for n<32

for 32bit systems that is

and the number may not be exact

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I think he's just using the Fibonacci numbers to illustrate his point that for large numbers (>32 bit) addition cannot be assumed to be constant anymore because it involves more than a singe instruction on the CPU.

Why does the formula fail? For F3=2 the binary representation needs 2bits (3 * 0.694 = 2.082) Take F50=12586269025, which can be represented using 33bits (50 * 0.694 = 35) which is still reasonably close to the true value.

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N    F(N)      0.694*N
1      0         1       
2      1         1
3      1         1
4      2         2
5      3         2
6      5         3
7      8         4
8     13         4

etc. That's my interpretation. But then, that means that you have to get to f(47) = 1,836,311,903 before you exceed 32 bits.

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The author is basically describing how large numbers affect the performance of the algorithm. To be overly simple, a processor can add numbers of the register size very quickly, if the numbers exceed the register size, more low level processor instructions need to be executed.

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