# Complexity of algo whose runtime is expressed by T(n) = T(n-1) + T(n-2) + C

[This is not a homework question. I'm out of college about 5 years ago :) ]

I want to understand how to arrive at the complexity of the below recurrence relation.

T(n) = T(n-1) + T(n-2) + C Given T(1) = C and T(2) = 2C;

Generally for equations like T(n) = 2T(n/2) + C (Given T(1) = C), I use the following method.

T(n) = 2T(n/2) + C => T(n) = 4T(n/4) + 3C => T(n) = 8T(n/8) + 7C => ... => T(n) = 2^k T (n/2^k) + (2^k - 1) c

Now when n/2^k = 1 => K = log (n) (to the base 2)

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

But, I'm not able to come up with similar approach for the problem I have in question. Please correct me if my approach is incorrect.

Thanks, Gopal

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The complexity is related to input-size, where each call produce a binary-tree of calls

Where `T(n)` make `2``n` calls in total ..

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

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

`O(2``n``)`

In the same fashion, you can generalize your recursive function, as a Fibonacci number

`T(n) = F(n) + ( C * 2``n``)`

Next you can use a direct formula instead of recursive way

Using a complex method known as Binet's Formula

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Is "worse than exponential" accurate enough for your purposes? The special case C=0 defines http://en.wikipedia.org/wiki/Fibonacci_number, which you can see from the article is exponential. Assuming C is positive, your series will be growing faster than this. In fact, your series will lie between the Fibonacci series and a variant of the Fibonacci series in which the golden ratio is replaced by something very slightly larger.

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@mcdowella..thanks for the quick response! –  Gopal Jul 18 '13 at 7:13

You can use this general approach described here.Please ask if you have more questions.

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@Aravind..The link you provided was of great help! –  Gopal Jul 18 '13 at 7:13

If you were also interested in finding an explicit formula for `T(n)` this may help.

We know that `T(1) = c` and `T(2) = 2c` and `T(n) = T(n-1) + T(n-2) + c`.

So just write `T(n)` and start expanding...

``````T(n) = T(n-1) + T(n-2) + c
T(n) = 2*T(n-2) + T(n-m) + 2c
T(n) = 3*T(n-3) + 2*T(n-4) + 4c
T(n) = 5*T(n-4) + 3*T(n-5) + 7c
etc ...
``````

You see the coefficients are Fibonacci numbers themselves!

Call `F(n)` the `nth` Fibonacci number. `F(n) = (phi^n + psi^n)/sqrt(5)` where `phi = (1+sqrt(5))/2` and `psi = -1/phi`, then we have:

``````T(n) = F(n)*2c + F(n-1)*c + (F(n+1)-1)*c
``````

Here is some quick code to demonstrate:

``````def fib_gen(n):
"""generates fib numbers to avoid rounding errors"""
fibs=[1,1]
for i in xrange(n-2):
fibs.append(fibs[i]+fibs[i+1])
return fibs

F = fib_gen(50) #just an example.
c=1

def T(n):
"""the recursive definiton"""
if n == 1:
return c
if n == 2:
return 2*c
return T(n-1) + T(n-2) + c

def our_T(n):
n=n-2 #just because your intials were T(1) and T(2), sorry this is ugly!
"""our found relation"""
return F[n]*2*c + F[n-1]*c + (F[n+1]-1)*c
``````

and

``````>>> T(24)
121392
>>> our_T(24)
121392
``````
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