# Asymptotic time complexity of inserting n elements to a binary heap already containing n elements

Suppose we have a binary heap of n elements and wish to insert n more elements(not necessarily one after other). What would be the total time required for this?

I think it's theta (n logn) as one insertion takes logn.

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I think the size of the existing heap should enter the result somehow. –  Kerrek SB Nov 4 '11 at 15:27

Assuming we are given:

• priority queue implemented by standard binary heap H (implemented on array)
• n current size of heap

We have following insertion properties:

• W(n) = WorstCase(n) = Θ(lg n) (Theta). -> W(n)=Ω(lg n) and W(n)=O(lg n)
• A(n) = AverageCase(n) = Θ(lg n) (Theta). -> W(n)=Ω(lg n) and W(n)=O(lg n)
• B(n) = BestCase(n) = Θ(1) (Theta). -> W(n)=Ω(1) and W(n)=O(1)

So for every case, we have

• T(n) = Ω(1) and T(n) = O(lg n)

WorstCase is when, we insert new minimal value, so up-heap has to travel whole branch.

BestCase is when, for minimal-heap (heap with minimal on top) we insert BIG (biggest on updated branch) value (so up-heap stops immediately).

You've asked about series of n operations on heap containing already n elements, it's size will grow

``````from n to 2*n
``````

what asymptotically is ...

``````n=Θ(n)
2*n=Θ(n)
``````

What simplifies our equations. (We don't have to worry about growth of n , as it's growth is by constant factor).

So, we have "for n insertions" of operation:

• Xi(n) = X_for_n_insertions(n)
• Wi(n) = Θ(n lg n)
• Ai(n) = Θ(n lg n)
• Bi(n) = Θ(n)
• it implies, for "all case":
• Ti(n) = Ω(n) and Ti(n) = O(n lg n)

P.S. For displaying Theta Θ , Omega Ω symbols, you need to have UTF-8 installed/be compatible.

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given : heap of n elements and n more elements to be inserted. So in the end there will be 2*n elements. since heap can be created in 2 ways 1. Successive insertion and 2. Build heap method. Amoung these build heap method takes O(n) time to construct heap which is explained in Build heap complexity. so total time required is O(2*n) which is same as O(n)

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its not theeta(nlogn)... its order(nlogn) since some of the insertions can take less then exact logn time... therefore for n insertions it will take time <=nlogn

=> time complexity=O(nlogn)

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