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I am trying to find the time complexity for selection sort which has the following equation
T(n)=T(n-1)+O(n)

First I supposed its T(n)=T(n-1)+n .. n is easier though..
Figured T(n-1) = T(n-2) + (n-1) and T(n-2) = T(n-3) + (n-2)

This makes T(n) = (T(n-3) + (n-2)) + (n-1) + n so its T(n) = T(n-3) + 3n - 3..

K instead of (3) .. T(n) = T(n-k) + kn - k

and because n-k >= 0 .. ==> n-k = 0 and n=k

Back to the eqaution its.. T(n) = T(0)// which is C + n*n - n

which makes it C + n^2 -n.. so its O(n^2).. is what I did ryt??

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Not quite. It's not T(n-k) + kn - k, but T(n-k) + kn - sum_{1 to k-1} j. – Daniel Fischer Mar 3 '13 at 17:08
    
Can't get why?? it keeps getting K not the sum :s – geekybedouin Mar 3 '13 at 17:52
    
T(n-k) + (n-(k-1)) + (n-(k-2)) + ... + (n-1) + n – Daniel Fischer Mar 3 '13 at 18:33
up vote 1 down vote accepted

Yes, your solution is correct. You are combining O(n) with O(n-1), O(n-2) ... and coming up with O(n^2). You can apply O(n) + O(n-1) = O(n), but only finitely. In a series it is different.

T(n) = (0 to n)Σ O(n - i)

Ignore i inside O(), your result is O(n^2)

The recurrence relationship you gave T(n)=T(n-1)+O(n) is true for Selection Sort, which has overall time complexity as O(n^2). Check this link to verify

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In selection sort:

In iteration i, we find the index min of smallest remaining entry. And then swap a[i] and a[min].

As such the selection sort uses

(n-1)+(n-2)+....+2+1+0 = (n-1)*(n-2)/2 = O(n*n) compares

and exactly n exchanges(swappings).

FROM ABOVE

And from the recurrence relation given above

=> T(n) = T(n-1)+ O(n)
=> T(n) = T(n-1)+ cn, where c is some positive constant
=> T(n) = cn + T(n-2) + c(n-1)
=> T(n) = cn + c(n-1) +T(n-3)+ c(n-2)

And this goes on and we finally get

=> T(n) = cn + c(n-1) + c(n-2) + ...... c (total no of n terms)
=> T(n) = c(n*(n-1)/2)
=> T(n) = O(n*n)

EDIT

Its always better to replace theta(n) as cn, where c is some constant. Helps in visualizing the equation more easily.

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