I'm trying to figure out how to give a worst case time complexity. I'm not sure about my analysis. I have read nested `for`

loops big O is `n^2`

; is this correct for a `for`

loop with a `while`

loop inside?

```
// A is an array of real numbers.
// The size of A is n. i,j are of type int, key is
// of type real.
Procedure IS(A)
for j = 2 to length[A]
{
key = A[ j ]
i = j-1
while i>0 and A[i]>key
{
A[i+1] = A[i]
i=i-1
}
A[i+1] = key
}
```

so far I have:

```
j=2 (+1 op)
i>0 (+n ops)
A[i] > key (+n ops)
so T(n) = 2n+1?
```

But I'm not sure if I have to go inside of the `while`

and `for`

loops to analyze a worse case time complexity...

Now I have to prove that it is tightly bound, that is Big theta.

I've read that nested `for`

loops have Big O of `n^2`

. Is this also true for Big Theta? If not how would I go about finding Big Theta?!

**C1= C sub 1, C2= C sub 2, and no= n naught all are elements of positive real numbers

To find the `T(n)`

I looked at the values of `j`

and looked at how many times the while loop executed:

```
values of J: 2, 3, 4, ... n
Loop executes: 1, 2, 3, ... n
```

Analysis:

Take the summation of the while loop executions and recognize that it is `(n(n+1))/2`

I will assign this as my `T(n)`

and prove it is tightly bounded by `n^2`

.
That is `n(n+1)/2= θ(n^2)`

Scratch Work:

```
Find C1, C2, no є R+ such that 0 ≤ C1(n^2) ≤ (n(n+1))/2 ≤ C2(n^2)for all n ≥ no
To make 0 ≤ C1(n) true, C1, no, can be any positive reals
To make C1(n^2) ≤ (n(n+1))/2, C1 must be ≤ 1
To make (n(n+1))/2 ≤ C2(n^2), C2 must be ≥ 1
```

PF:

```
Find C1, C2, no є R+ such that 0 ≤ C1(n^2) ≤ (n(n+1))/2 ≤ C2(n^2) for all n ≥ no
Let C1= 1/2, C2= 1 and no = 1.
```

show that 0 ≤ C1(n^2) is true C1(n^2)= n^2/2

n^2/2≥ no^2/2

⇒no^2/2≥ 0

1/2 > 0

Therefore C1(n^2) ≥ 0 is proven true!show that C1(n^2) ≤ (n(n+1))/2 is true C1(n^2) ≤ (n(n+1))/2

n^2/2 ≤ (n(n+1))/2 n^2 ≤ n(n+1)

n^2 ≤ n^2+n

0 ≤ nThis we know is true since n ≥ no = 1

Therefore C1(n^2) ≤ (n(n+1))/2 is proven true!Show that (n(n+1))/2 ≤ C2(n^2) is true (n(n+1))/2 ≤ C2(n^2)

(n+1)/2 ≤ C2(n)

n+1 ≤ 2 C2(n)

n+1 ≤ 2(n)

1 ≤ 2n-n

1 ≤ n(2-1) = n

1≤ n

Also, we know this to be true since n ≥ no = 1Hence by 1, 2 and 3, θ(n^2 )= (n(n+1))/2 is true since

0 ≤ C1(n^2) ≤ (n(n+1))/2 ≤ C2(n^2) for all n ≥ no

Tell me what you thing guys... I'm trying to understand this material and would like y'alls input!

anyway you could have included that content in the actual question itself?? – bedwyr Mar 18 '09 at 2:24