# Understanding Big O: log(n), nlog(n), nlog(n^2) for calculating complexities in algorithm [closed]

I understand these algorithm functions for calculating complexities in algorithm:

n = input size
O(n) = linear

but I find it difficult to understand the logarithmic (lg) functions when it comes to using it in algorithms complexities. In fact I have read numerous posts in this forum concerning but almost all of them don't go into detail when it comes to the lg functions for the Big O in Computer Science. In the posts I read, they say anytime the size of a sorting function is divided into say half then it is lg function.

Concerns

1) For instance in the merge sort algorithm (eg: 2-way, 3-way), the input(eg: list) is divided into 2 or 3, which in turn the two(three) lists are divided into two(three) each. My concern is, is the input size still "n" during the various recursive calls? I want to be clear in this area so that I can calculate the time complexities sorting functions myself.

2) I know that lg function is for instance, to which number should a number(2, 10 etc.) be raised to get a certain number. When it comes to algorithms calculation in Computer science, I find it hard to calculate the complexities of sorting functions my self with the lg functions. I need a basic explanation with possibly some examples to be able to understand it well.

I need someone to help me understand these lg functions in relation to calculating algorithmic complexities. Probably some examples as if you are teaching a novice:

log(n), nlog(n), nlog(n^2)

I want to be able to compute algorithmic complexities myself so other general examples are also welcome.

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you want to know how these relate to CS? Right? Like Big O notation in complexity theory? Your post seems more like a math question and its getting off topic close votes. Try to rephrase the post relating to programming –  gideon Oct 31 '11 at 6:23

## closed as off topic by Mat, birryree, amit, DhruvPathak, GravitonNov 2 '11 at 8:40

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For a general example that is understandable: screw merge sort for now, look at binary search.

Pick a number between 1 and 1000. I guess 500. You say "higher". I guess 750. You say "lower." I choose 625... Clearly my search is not going to take 1000 guesses (order n). I chop my search domain in half each time and take 10 guesses or less (lg(1000) is about 10; 2^10 is 1024) Now, if you understand that, go back to merge sort.

Merge sort partitions its input set into 2 parts each call. Yes, the whole input set was still size n. But don't think of n as being redefined each call to merge sort. Let's imagine an ideal world where the list gets split evenly on each recursive call. The first call traverses the list of size n, and calls 2 functions with lists of size n/2 (see, I define the recursive function input in terms of the original program input size). Each of those functions will split their list n/2 came in, and 2 n/4 lists went into the recursive call. Effectively, here's what you get:

``````1 * n   - merge sort
2 * n/2 - 2 lists
4 * n/4 - which each get split into 2 lists
8 * n/8 - which each get split into 2 lists
...
``````

So, each row represents a recursion depth in the algorithm. There's one call of the whole list, two calls of half the list, 4 calls with a quarter of the list, etc. Each function call searches it's whole input list, so each set of calls is order n.

How deep does this go? Well, if I split the input in half each time, that's lg(n) in height. That's where the n lg(n) comes from. It's lg(n) depth times n.

Note: My assumption that the list was split evenly every time made things easier to illustrate, but it wouldn't be valid for worst-case analysis.

n log (n^2) : I don't have a good illustration of that, but since log (n^2) = 2 log n, n log (n^2) is still O(n log n).

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thanks for the reply –  Eddy Freeman Oct 31 '11 at 7:03

The classic example of an `O(log N)` algorithm is the binary chop.

Say you have a sorted array of 1024 numbers and you want to find a specific value.

First off, look at the middle one. If it's greater than what you're looking for, you can immediately throw away the upper half of your "search space" (the things left to check). If it's less than what you want, you throw away the lower half.

In either case, you've reduced the search space in half (finding it would result in immediate return but let's not worry about that for now - we'll assume we don't find it until the worst case). You now only have 512 elements to search.

Next time through, you choose the midpoint of those 512 and, again, either throw away the top or bottom half, leaving 256.

This means, at most, you'll need 10 iterations to find your value, since `210 = 1024` or, to put it another way, `log21024 = 10`.

The `N` in `log N` is always the initial `N`, the data set size at the start.

The base of the logarithm is not usually listed. You may have a selection process which, like the binary chop, throws away half the search space (`log2N`). If you can find a process which throws away 90% on each iteration, that would be `log10N`. However, that's never seen in complexity notation since the difference between the two is irrelevant compared to the difference between (for example) `log10N` and `N`).

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thanks for the reply –  Eddy Freeman Oct 31 '11 at 7:06