In median-of-medians algorithm, we need to divide the array into chunks of size 5. I am wondering how did the inventors of the algorithms came up with the magic number '5' and not, may be, 7, or 9 or something else?


I think that if you'll check "Proof of O(n) running time" section of wiki page for medians-of-medians algorithm:

The median-calculating recursive call does not exceed worst-case linear behavior because the list of medians is 20% of the size of the list, while the other recursive call recurses on at most 70% of the list, making the running time


The O(n) term c n is for the partitioning work (we visited each element a constant number of times, in order to form them into n/5 groups and take each median in O(1) time). From this, using induction, one can easily show that


That should help you to understand, why.

  • 3
    This proves the O(n) running time of using 20%, it doesn't disprove the O(n) running time of some other percentage (if some other percentage was also O(n), it doesn't justify the choice of 20% above the other). – Dukeling Aug 7 '13 at 8:14

The number has to be larger than 3 (and an odd number, obviously) for the algorithm. 5 is the smallest odd number larger than 3. So 5 was chosen.

  • It doesn't have to be larger tan 3 (and odd), see my answer below. – Ecir Hana Sep 2 '16 at 9:20
  • Yes, but that is a different algorithm. It's only a slight variation of the algorithm OP was asking about - but it's still a different algorithm. OP asked "why in this specific algorithm do we need to use blocks of 5", and not "is there a variant on this algorithm where we could use smaller blocks". They were trying to understand how something was calculated rather than trying to find if there's something different that can do it better. – rabensky Sep 2 '16 at 13:12

You can also use blocks of size 3 or 4, as shown in the paper Select with groups of 3 or 4 by K. Chen and A. Dumitrescu (2015). The idea is to use the "median of medians" algorithm twice and partition only after that. This lowers the quality of the pivot but is faster.

So instead of:

T(n) <= T(n/3) + T(2n/3) + O(n)
T(n) = O(nlogn)

one gets:

T(n) <= T(n/9) + T(7n/9) + O(n)
T(n) = Theta(n)

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