# Can someone help solve this recurrence relation?

``````T(n) = 2T(n/2) + 0(1)

T(n) = T(sqrt(n)) + 0(1)
``````

In the first one I use substitution method for n, logn, etc; all gave me wrong answers.
Recurrence trees: I don't know if I can apply as the root will be a constant.

Can some one help?

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Let's look at the first one. First of all, you need to know T(base case). You mentioned that it's a constant, but when you do the problem it's important that you write it down. Usually it's something like T(1) = 1. I'll use that, but you can generalize to whatever it is.

Next, find out how many times you recur (that is, the height of the recursion tree). `n` is your problem size, so how many times can we repeatedly divide n by 2? Mathematically speaking, what's i when `n/(2^i) = 1`? Figure it out, hold onto it for later.

Next, do a few substitutions, until you start to notice a pattern.

`T(n) = 2(2(2T(n/2*2*2) + θ(1)) + θ(1)) + θ(1)`

Ok, the pattern is that we multiply T() by 2 a bunch of times, and divide n by 2 a bunch of times. How many times? `i` times.

`T(n) = (2^i)*T(n/(2^i)) + ...`

For the big-θ terms at the end, we use a cute trick. Look above where we have a few substitutions, and ignore the T() part. We want the sum of the θ terms. Notice that they add up to `(1 + 2 + 4 + ... + 2^i) * θ(1)`. Can you find a closed form for `1 + 2 + 4 + ... + 2^i`? I'll give you that one; it's `(2^i - 1)`. It's a good one to just memorize, but here's how you'd figure it out.

Anyway, all in all we get

`T(n) = (2^i) * T(n/(2^i)) + (2^i - 1) * θ(1)`

If you solved for `i` earlier, then you know that `i = log_2(n)`. Plug that in, do some algebra, and you get down to

`T(n) = n*T(1) + (n - 1)*θ(1)`. `T(1) = 1`. So `T(n) = n + (n - 1)*θ(1)`. Which is n times a constant, plus a constant, plus n. We drop lower order terms and constants, so it's θ(n).

Prasoon Saurav is right about using the master method, but it's important that you know what the recurrence relation is saying. The things to ask are, how much work do I do at each step, and what is the number of steps for an input of size `n`?

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Use `Master Theorem` to solve such recurrence relations.

Let a be an integer greater than or equal to 1 and b be a real number greater than 1. Let c be a positive real number and d a nonnegative real number. Given a recurrence of the form

• T (n) = a T(n/b) + nc .. if n > 1

• T(n) = d .. if n = 1

then for n a power of b,

1. if logb a < c, T (n) = Θ(nc),
2. if logb a = c, T (n) = Θ(nc log n),
3. if logb a > c, T (n) = Θ(nlogb a).

1) `T(n) = 2T(n/2) + 0(1)`

In this case

a = b = 2;
logb a = 1; c = 0 (since nc =1 => c= 0)

So Case (3) is applicable. So `T(n) = Θ(n)` :)

2) `T(n) = T(sqrt(n)) + 0(1)`

Let m = log2 n;

=> T(2m) = T( 2m / 2 ) + `0(1)`

Now renaming K(m) = T(2m) => K(m) = K(m/2) + `0(1)`

Apply Case (2).

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Can I apply masters theorem even if f(n) is a constant, such as in this case 0(1) What about second problem? –  rda3mon Oct 18 '10 at 3:44
@Ringo : Yes you can. Check out the edit. –  Prasoon Saurav Oct 18 '10 at 3:48
Part 2 is incorrect. If `2^m = t`, then `2^(m/2)` is again `sqrt(t)`. Or rather, `2^m = 2^log n = n`, so the substitution achieved nothing. –  casablanca Oct 18 '10 at 3:50
@casablanca : Thanks!! Corrected. –  Prasoon Saurav Oct 18 '10 at 3:55
Thanks a lot. But, in second case, how did you end up choosing m=lg(n)? I mean how to make a guess? –  rda3mon Oct 18 '10 at 4:39
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For part 1, you can use Master Theorem as @Prasoon Saurav suggested.

For part 2, just expand the recurrence:

``````T(n) = T(n ^ 1/2) + O(1)         // sqrt(n) = n ^ 1/2
= T(n ^ 1/4) + O(1) + O(1)  // sqrt(sqrt(n)) = n ^ 1/4
etc.
``````

The series will continue to `k` terms until `n ^ 1/(2^k) <= 1`, i.e. `2^k = log n` or `k = log log n`. That gives `T(n) = k * O(1) = O(log log n)`.

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how did 2^k = log n lead to k = log log n? –  Irwin Nov 25 '12 at 21:41
@casablanca, Can you please explain how did <= 1 come ? –  TechCrunch Sep 10 '13 at 3:44