Need a little help! This is what I have so far using backward substitution:

```
T(n) = 2T(n/2) + sqrt(n), where T(1) = 1, and n = 2^k
T(n) = 2[2T(n/4) + sqrt(n/2)] + sqrt(n) = 2^2T(n/4) + 2sqrt(n/2) + sqrt(n)
T(n) = 2^2[2T(n/8) + sqrt(n/4)] + 2sqrt(n/2) + sqrt(n)
= 2^3T(n/8) + 2^2sqrt(n/4) + 2sqrt(n/2) + sqrt(n)
```

In general

```
T(n) = 2^kT(1) + 2^(k-1) x sqrt(2^1) + 2^(k-2) x sqrt(2^2) + ... + 2^1 x sqrt(2^(k-1)) + sqrt(2^k)
```

Is this right so far? If it is, I can not figure out how to simplify it and reduce it down to a general formula.

I'm guessing something like this? Combining the terms

```
= 1 + 2^(k-(1/2)) + 2^(k-(2/2)) + 2^(k-(3/2)) + ... + 2^((k-1)/2) + 2^(k/2)
```

And this is where I'm stuck. Maybe a way to factor out a 2^k? Any help would be great, thanks!

`n`

with`2^k`

, at each iteration you get first`2^(k-1)`

, then`2^(k-2)`

and eventually`2^0`

. You have`k`

calls,`k`

being`log2(n)`

... thus complexity of`T(n)`

is`O(log(n))`

. – ring0 Apr 28 '13 at 5:04