Hi I am trying to understand what order of complexity in terms of Big O notation is. I have read many articles and am yet to find anything explaining exactly 'order of complexity', even on the useful descriptions of Big O on here.

What I already understand about big O

The part which I already understand. about Big O notation is that we are measuring the time and space complexity of an algorithm in terms of the growth of input size n. I also understand that certain sorting methods have best, worst and average scenarios for Big O such as O(n) ,O(n^2) etc and the n is input size (number of elements to be sorted).

Any simple definitions or examples would be greatly appreciated thanks.


Big O is about finding an upper limit for the growth of some function. See the formal definition on Wikipedia http://en.wikipedia.org/wiki/Big_O_notation

So if you've got an algorithm that sorts an array of size n and it requires only a constant amount of extra space and it takes (for example) 2 n² + n steps to complete, then you would say it's space complexity is O(n) or O(1) (depending on wether you count the size of the input array or not) and it's time complexity is O(n²).

Knowing only those O numbers, you could roughly determine how much more space and time is needed to go from n to n + 100 or 2 n or whatever you are interested in. That is how well an algorithm "scales".


Big O and complexity are really just two terms for the same thing. You can say "linear complexity" instead of O(n), quadratic complexity instead of O(n²), etc...

  • Thanks, I think I understand that part, I am trying to find out what exactly order of complexity means in terms of Big O – Luke Dec 19 '13 at 18:31

Big-O analysis is a form of runtime analysis that measures the efficiency of an algorithm in terms of the time it takes for the algorithm to run as a function of the input size. It’s not a formal bench- mark, just a simple way to classify algorithms by relative efficiency when dealing with very large input sizes.

Update: The fastest-possible running time for any runtime analysis is O(1), commonly referred to as constant running time.An algorithm with constant running time always takes the same amount of time to execute, regardless of the input size.This is the ideal run time for an algorithm, but it’s rarely achievable. The performance of most algorithms depends on n, the size of the input.The algorithms can be classified as follows from best-to-worse performance:

O(log n) — An algorithm is said to be logarithmic if its running time increases logarithmically in proportion to the input size.

O(n) — A linear algorithm’s running time increases in direct proportion to the input size.

O(n log n) — A superlinear algorithm is midway between a linear algorithm and a polynomial algorithm.

O(n^c) — A polynomial algorithm grows quickly based on the size of the input.

O(c^n) — An exponential algorithm grows even faster than a polynomial algorithm.

O(n!) — A factorial algorithm grows the fastest and becomes quickly unusable for even small values of n.

The run times of different orders of algorithms separate rapidly as n gets larger.Consider the run time for each of these algorithm classes with

   n = 10:
   log 10 = 1
   10 = 10
   10 log 10 = 10
   10^2 = 100
   2^10= 1,024
   10! = 3,628,800
   Now double it to n = 20:
   log 20 = 1.30
   20 = 20
   20 log 20= 26.02 
   20^2 = 400
   2^20 = 1,048,576 
   20! = 2.43×1018

Finding an algorithm that works in superlinear time or better can make a huge difference in how well an application performs.

  • 2
    The fastest running time for an algorithm is the one that runs fastest. It's possible for a O(1) algorithm to take more time than a O(n) algorithm. For example if O(1) always takes 10 minutes and O(n) finishes in less than 1 second for all pratical n than O(n) wins out. – Z boson Dec 19 '13 at 19:23

Say, f(n) in O(g(n)) if and only if there exists a C and n0 such that f(n) < C*g(n) for all n greater than n0.

Now that's a rather mathematical approach. So I'll give some examples. The simplest case is O(1). This means "constant". So no matter how large the input (n) of a program, it will take the same time to finish. An example of a constant program is one that takes a list of integers, and returns the first one. No matter how long the list is, you can just take the first and return it right away.

The next is linear, O(n). This means that if the input size of your program doubles, so will your execution time. An example of a linear program is the sum of a list of integers. You'll have to look at each integer once. So if the input is an list of size n, you'll have to look at n integers.

An intuitive definition could define the order of your program as the relation between the input size and the execution time.

  • Thanks for your answer, so does that mean that order of complexity means going from the simplest types to more complicate like this? O(1), O(log n), o(n), O(n log n), O(n^2) etc etc... A good source I have been using is leepoint.net/notes-java/algorithms/big-oh/bigoh.html I am thinking that the table on this ^ page describes order of complexity? – Luke Dec 19 '13 at 18:27
  • Good examples. That really helps the explanation. – bballdave025 May 14 at 23:40

Others have explained big O notation well here. I would like to point out that sometimes too much emphasis is given to big O notation.

Consider matrix multplication the naïve algorithm has O(n^3). Using the Strassen algoirthm it can be done as O(n^2.807). Now there are even algorithms that get O(n^2.3727).

One might be tempted to choose the algorithm with the lowest big O but it turns for all pratical purposes that the naïvely O(n^3) method wins out. This is because the constant for the dominating term is much larger for the other methods.

Therefore just looking at the dominating term in the complexity can be misleading. Sometimes one has to consider all terms.

  • 1
    You are entirely correct, and it's good someone mentions this. Thank you. I'm sorry I can't upvote because this was not asked, though. – Noctua Dec 19 '13 at 22:14
  • "For all practical purposes O(n^3) wins out". That rather depends on your practical purpose. If it is to multiply two 1000 x 1000 square matrices, then other algorithms would be more efficient then naïve multiplication. Big O notation doesn't tell you what algorithm is most efficient for a given n; it tells you what algorithm is most efficient for very large values of n. – Peter Webb Dec 22 '13 at 8:19
  • @PeterWebb, that's incorrect. The naïve multiplication still wins for large matricies. Big O tells you what is best at n goes to infinity but for all practical values of n in this case the naïve algorithm is still best. – Z boson Dec 29 '13 at 20:42

I see that you are commenting on several answers wanting to know the specific term of order as it relates to Big-O.

Suppose f(n) = O(n^2), we say that the order is n^2.


Be careful here, there are some subtleties. You stated "we are measuring the time and space complexity of an algorithm in terms of the growth of input size n," and that's how people often treat it, but it's not actually correct. Rather, with O(g(n)) we are determining that g(n), scaled suitably, is an upper bound for the time and space complexity of an algorithm for all input of size n bigger than some particular n'. Similarly, with Omega(h(n)) we are determining that h(n), scaled suitably, is a lower bound for the time and space complexity of an algorithm for all input of size n bigger than some particular n'. Finally, if both the lower and upper bound are the same complexity g(n), the complexity is Theta(g(n)). In other words, Theta represents the degree of complexity of the algorithm while big-O and big-Omega bound it above and below.

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