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I have an algorithm i'm trying to implement. I've been asked to determine a function that describes its worst case running time. As input, it takes an array of some length (lets call it n). Then what it does is as follows:

if (n==0){ return 0;}
else if(n==1){return A[0];}
else{
     return f(n-1)+f(n-2)
}

Sorry if I'm a tad sparse on the implementation details, but in a sense, its rather similar to something like the fibbanoci sequence. I'm thinking the worst case running time of this algorithm is t(n)=2^n, because if n is large, it will decompose into 2 separate calculations, which in turn will split into 2 more and so on. I'm just not sure how to formally justify this

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See stackoverflow.com/questions/4326634/… –  jrajav Sep 29 '12 at 18:52
    
Thank you. However, I'm sorta looking for a bit of an explanation of how exactly you determine these things. I've looked around, but people just seem to start throwing notation and answers around without a good explanation. I'm kinda new to this whole thing –  user979616 Sep 29 '12 at 18:56
1  
There's no quick answer. You need to understand recurrence relations in the context of algorithmic complexity in order to prove your result. The accepted answer on the question I linked links to a page that explains it: cs.duke.edu/~ola/ap/recurrence.html (See heading "The Recurrence Relation" and beyond) –  jrajav Sep 29 '12 at 19:01
    
With what you show from the code, there is no worst case, you only use A[0] whatever the value of n ... show us more –  Kwariz Sep 29 '12 at 19:36

1 Answer 1

up vote 5 down vote accepted

Let's first get a recursion for the running time.

T(0) = T(1) = 1

since both just return a number (one is an array-lookup, but that's constant time too). And for n > 1 we have

T(n) = T(n-1) + T(n-2) + 1

since you evaluate f(n-1) and f(n-2) and add the two results. That's almost the same recurrence as the Fibonacci sequence itself, F(n) = F(n-1) + F(n-2), and the result is closely related.

 n | T(n) | F(n)
----------------
 0 |   1  |   0
 1 |   1  |   1
 2 |   3  |   1
 3 |   5  |   2
 4 |   9  |   3
 5 |  15  |   5
 6 |  25  |   8
 7 |  41  |  13
 8 |  67  |  21
 9 | 109  |  34
10 | 177  |  55
11 | 287  |  89

If you look at the values, you see that

T(n) = F(n+2) + F(n-1) - 1

and can prove that with induction, if you need to.

Since the terms of the Fibonacci sequence are given by F(n) = (φ^n - (1-φ)^n)/√5, where φ = (1 + √5)/2, you see that the complexity of your f is also Θ(φ^n), like that of the Fibonacci sequence. That's better than Θ(2^n), but still exponential, so calculation using this way is only feasible for small n.

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if A[0] == 1 isn't the OP definition exactly the definition of Fibonacci sequence? Fibonacci calculation too adds the two sub-cases. So why there should be any difference? –  Will Ness Sep 29 '12 at 19:59
    
The exact code in the last return is slightly different, but is of the same level of complexity. Its just a comparison with some other array element. –  user979616 Sep 29 '12 at 20:02
    
@WillNess Whatever A[0] is, the sequence will be A[0]*F(n), so the complexity of computing it the naive way is exactly that of computing F(n) the naive way. The cost of computing F(n) the naive way is usually called nfib(n), which can be expressed like above by Fibonacci numbers. –  Daniel Fischer Sep 29 '12 at 20:07
    
Thanks, Daniel; I've edited to clarify the sentence, with apologies for intrusion. :) –  Will Ness Sep 29 '12 at 20:10
    
@WillNess Yeah, I guess that's clearer for people not being able to read my mind, thanks. –  Daniel Fischer Sep 29 '12 at 20:14

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