# Find the theta notation of the following recursive method

I have the homework question:

Let T(n) denote the number of times the statement x = x + 1 is executed in the algorithm

``````example (n)
{
if (n == 1)
{
return
}
for i = 1 to n
{
x = x + 1
}
example (n/2)
}
``````

Find the theta notation for the number of times x = x + 1 is executed. (10 points).

## here is what I have done:

we have the following amount of work done: - A constant amount of work for the base case check - O(n) work to count up the number - The work required for a recursive call to something half the size

We can express this as a recurrence relation: T(1) = 1 T(n) = n + T(n/2)

Let’s see what this looks like. We can start expanding this out by noting that

``````T(n)=n+T(n/2)
=n+(n/2+T(n/4))
=n+n/2+T(n/4)
=n+n/2+(n/4+T(n/8))
=n+n/2+n/4+T(n/8)
``````

We can start to see a pattern here. If we expand out the T(n/2) bit k times, we get: T(n)=n+n/2+n/4+⋯+n/2^k +T(n/2^k )

Eventually, this stops when `n/2^k =1` when this happens, we have: T(n)=n+n/2+n/4+n/8+⋯+1

What does this evaluate to? Interestingly, this sum is equal to 2n+1 because the sum `n+ n/2 + n/4 + n/8 +…. = 2n.` Consequently this first function is O(n)

Know I am confused with the theta notation. will the answer be the same? I know that the theta notation is supposed to bound the function with a lower and upper limit. that means I need to functions?

-

You can easily use the same tools to prove `T(n) = Omega(n)`.
After proving `T(n)` is both `O(n)` [upper asymptotic bound] and `Omega(n)` [lower asymptotic bound], you know it is also `Theta(n)` [tight asymptotic bound]
In your example, it is easy to show that `T(n) >= n` - since it is homework, it is up to you to understand why.