# Tagged Questions

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**1**answer

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### Big Theta asymptotic analysis

Given that f(n) ∈ Ѳ(g(n)); how can you prove that 2^(f(n)) ∈ Ѳ(2^(g(n)))?
I have tried using limits of big theta and using first principles, no luck. Please help

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**3**answers

920 views

### Using worst/avg/best case for asymptotic analysis [closed]

I understand the worst/avg/best case are used to determine the complexity time of an algorithm into a function but how is that used in asymptotic analysis? I understand the upper/tight/lower bound(big ...

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**1**answer

137 views

### Prove max(O(f(n)), O(g(n)))=O(max(f(n), g(n))

Prove max(O(f(n)), O(g(n)))=O(max(f(n), g(n))
It does make sense, but so far I don't have any idea how to actually prove it.
Any input would be appreciated.

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**2**answers

552 views

### Different upper bounds and lower bounds of same algorithm

So I just started learning about Asymptotic bounds for an algorithm
Question:
What can we say about theta of a function if for the algorithm we find different lower and upper bounds?? (say omega(n) ...

**4**

votes

**2**answers

354 views

### How to add Big O and Big omega

If an algorithm has two sub algorithm, when it is best case for sub algorithm A1 to the given input, it is the worst case for sub algorithm A2. How could I find the overall algorithm complexity?
...

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**2**answers

427 views

### Merge sort time complexity vs my algorithm. Big O

Here is an algorithm I am trying to analyse (see below). I do not understand why this has a O(n) time complexity when the merge sorts has O(n logn), they both seems to be doing the same thing.
then ...

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**4**answers

315 views

### Question about big O and big Omega

I think this is probably a beginner question about big-O notation. Say, for example, I have an algorithm that breaks apart an entire list recursively(O(n)) and then puts it back together (O(n)). I ...

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**1**answer

1k views

### In Asymptotic Analysis, Show That :- O( f(n) + g(n) ) = O( max{ f(n) , g(n) } ) [closed]

O represents Big-O.
O(g) : { f| f is non negative function
there exists c,m where c and m are any constants
...