# Insertion sort worst case running time

Why in the worst case running time complexty of insertion sort is it n(n-1)/2 ~ n^2? highlighting the division by 2?

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1. The run time is not `n(n-1)/2`, each step requires more then 1 machine OP (in all machine I am aware of). This is why we usually use big O notation and "ignoring" constants in algorithms analysis - we want to make our analysis generic and platform independent.

2. Insertion sort is analyzed as `n(n-1)/2 = O(n^2)` because it is sum of arithmetic progression. The first iteration requires 1 step, the second 2 steps,.. the n'th requires n steps, so we get `1 + 2 + ... + n = n(n-1)/2` from sum of arithmetic progression.

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I understand the arithmetic progression part, but it's not clear to me where the division by 2 fits in? –  user1475421 Jun 23 '12 at 13:10
@user1475421 the first iteration iteration is 1 step, the 2nd is 2 steps, the 3rs is 3 steps, ... the nth is n steps, giving you total of `1 + 2 + 3 + ... + n` steps, which sums to `n(n-1)/2`. Are you asking why does `1 + 2 + ... + n` sums to `n(n-1)/2` ? –  amit Jun 23 '12 at 15:04
I understand n(n-1) part but can't understand where the /2 part fits in? –  user1475421 Jun 23 '12 at 16:46
@user1475421: This is simple math. have a look at: this article, it gives a close formula how to calculate the sum of the series `1 + 2 + ... +n` –  amit Jun 23 '12 at 16:58

Introduction to algorithms gives the details of insertion sort in chapter 2.1, which discuss the whole process of insertion sort.

The worst case is caused by the switch of subarray in reversed order.

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So, I've taken the time to read the chapter you've suggested.. I've even go so far as to purchase it. Definitely worth the money. Not to put a negative on it that chapter doesn't make it clear as to why the arithmetic progression is divided by 2? –  user1475421 Jun 23 '12 at 14:38
It's just a simple result of the sum of arithmetic progression which is famous when Gauss solved it as a kid. –  kid551 Jun 26 '12 at 11:33
We can deduce the expression like this: sum the first and the last as a pair, then sume the second and the last but one as a pair,etc. It is clearly that all the sum of pair equal. Define the sum as s1. So, in order to get the original sum, we can repeat n times s1 and divided by 2, because we repeat the original sum one more time. –  kid551 Jun 26 '12 at 14:55