# What is a plain English explanation of “Big O” notation?

I'd prefer as little formal definition as possible and simple mathematics.

• Summary: The upper bound of the complexity of an algorithm. See also the similar question Big O, how do you calculate/approximate it? for a good explaination. – Kosi2801 Jan 28 '09 at 11:18
• The other answers are quite good, just one detail to understand it: O(log n) or similar means, that it depends on the "length" or "size" of the input, not on the value itself. This could be hard to understand, but is very important. For example, this happens when your algorithm is splitting things in two in each iteration. – Harald Schilly Jan 28 '09 at 11:23
• There is a lecture dedicated to complexity of the algorithms in the Lecture 8 of the MIT "Introduction to Computer Science and Programming" course youtube.com/watch?v=ewd7Lf2dr5Q It is not completely plain English, but gives nice explanation with examples that are easily understandable. – ivanjovanovic Jul 17 '10 at 20:57
• Big O is an estimate of the worst case performance of a function assuming the algorithm will perform the maximum number of iterations. – Paul Sweatte Aug 28 '12 at 0:16

Definition :- Big O notation is a notation which says how a algorithm performance will perform if the data input increases.

When we talk about algorithms there are 3 important pillars Input , Output and Processing of algorithm. Big O is symbolic notation which says if the data input is increased in what rate will the performance vary of the algorithm processing.

I would encourage you to see this youtube video which explains Big O Notation in depth with code examples. So for example assume that a algorithm takes 5 records and the time required for processing the same is 27 seconds. Now if we increase the records to 10 the algorithm takes 105 seconds.

In simple words the time taken is square of the number of records. We can denote this by O(n ^ 2). This symbolic representation is termed as Big O notation.

Now please note the units can be anything in inputs it can be bytes , bits number of records , the performance can be measured in any unit like second , minutes , days and so on. So its not the exact unit but rather the relationship. For example look at the below function "Function1" which takes a collection and does processing on the first record. Now for this function the performance will be same irrespective you put 1000 , 10000 or 100000 records. So we can denote it by O(1).

``````void Function1(List<string> data)
{
string str = data;
}
``````

Now see the below function "Function2()". In this case the processing time will increase with number of records. We can denote this algorithm performance using O(n).

``````void Function2(List<string> data)
{
foreach(string str in data)
{
if (str == "shiv")
{
return;
}
}
}
``````

When we see a Big O notation for any algorithm we can classify them in to three categories of performance :-

1. Log and constant category :- Any developer would love to see their algorithm performance in this category.
2. Linear :- Developer will not want to see algorithms in this category , until its the last option or the only option left.
3. Exponential :- This is where we do not want to see our algorithms and a rework is needed.

So by looking at Big O notation we categorize good and bad zones for algorithms. I would recommend you to watch this 10 minutes video which discusses Big O with sample code

Big O in plain english is like <= (less than or equal). When we say for two functions f and g, f = O(g) it means that f <= g.

However, this does not mean that for any n f(n) <= g(n). Actually what it means is that f is less than or equal g in terms of growth. It means that after a point f(n) <= c*g(n) if c is a constant. And after a point means than for all n >= n0 where n0 is another constant.

Big O is a means to represent the upper bounds of any function. We generally use it for expressing the upper bounds of a function that tells the running time of an Algorithm.

Ex : f(n) = 2(n^2) +3n be a function representing the running time of a hypothetical algorithm, Big-O notation essentially gives the upper limit for this function which is O(n^2)

This notation basically tells us that, for any input 'n' the running time won't be greater than the value expressed by Big-O notation.

Also, agree with all the above detailed answers. Hope this helps !!

Big O is describing a class of functions.

It describes how fast functions grow for big input values.

For a given function f, O(f) descibes all functions g(n) for which you can find an n0 and a constant c so that all values of g(n) with n >= n0 are less or equal to c*f(n)

In less mathematical words O(f) is a set of functions. Namely all functions, that from some value n0 onwards, are growing slower or as fast as f.

If f(n) = n then

g(n) = 3n is in O(f).Because constant factors do not matter h(n) = n+1000 is in O(f) because it might be bigger for all values smaler than 1000 but for big O only huge inputs matter.

However i(n) = n^2 is not in O(f) because a quadratic funcion grows faster than a linear one.

If I want to explain this to 6 years old child I will start to draw some functions f(x) = x and f(x) = x^2 for example and ask a child which function will be the upper function on the top of the page. Then we will proceed with drawing and see that x^2 wins. "Who wins" actually is the function which grows faster when x tends to infinity. So "function x is in Big O of x^2" means that x grows slower than x^2 when x tends to infinity. The same can be done when x tends to 0. If we draw these two function for x from 0 to 1 x will be an upper function, so "function x^2 is in Big O of x for x tends to 0". When the child will get older I add that really Big O can be a function which grows not faster but the same way as given function. Moreover constant is discarded. So 2x is in Big O of x.

It represents the speed of an algorithm in the long run.

To take a literal analogy, you don't care how fast a runner can sprint a 100m dash, or even a 5k run. You care more about marathoners, and preferably ultra marathoners (beyond which the analogy to running breaks down and you have to revert to the metaphorical meaning of "the long run").

You can safely stop reading here.

I'm adding this answer because I'm surprised how mathematical and technical the rest of the answers are. The notion of the "long run" in first sentence is related to the arbitrarily time-consuming computational tasks. Unlike running, which is limited by human capacity, computational tasks can take even more than millions of years for certain algorithms to complete.

What about all those mathematical logarithms and polynomials? It turns out that algorithms are intrinsically related to these mathematical terms. If you are measuring the heights of all the kids on the block, it will take you as much time as there are kids. This is intrinsically related to the notion of n^1 or just n where n is nothing more than the number of kids on the block. In the ultra-marathon case, you are measuring the heights of all the kids in your city, but you then have to ignore travel times and assume they are all available to you in a line (otherwise we jump ahead of the current explanation).

Suppose then you are trying to arrange the list that you made of of kids heights in order of shortest height to longest height. If it is just the kids in your neighborhood you might just eyeball it and come up with the ordered list. This is the "sprint" analogy, and we truly don't care about sprints in computer science because why use a computer when you can eyeball something?

But if you were arranging the list of the heights of all kids in your city, or better yet, your country, then you will find that how you do it is intrinsically tied to the mathematical log and n^2. Going through your list to find the shortest kid, writing his name in a separate notebook, and crossing it out from the original notebook is intrinsically tied to the mathematical n^2. If you think of arranging half your notebook, then the other half, and then combining the results, you will arrive at a method that is intrinsically tied to the logarithm.

Finally, suppose you first had to go to the store to buy a measuring tape. This is an example of an effort that is of consequence in short sprints, such as measuring the kids on the block, but when you are measuring all the kids in the city you can safely ignore this cost. This is the intrinsic connection to the mathematical dropping of say lower order polynomial terms.

I hope I have explained that the big-O notation is merely about the long run, that the mathematics is inherently connected to ways of computation, and that the dropping of mathematical terms and other simplifications are connected to the long run in a rather common sense way.

Once you realize this, you'll find the big-O is really super-easy because all the hard high school math just drops out easily. The only difficult part is analyzing an algorithm to identify the mathematical terms, but with some practice you can start dropping terms during the analysis itself and safely ignore chunks of the algorithm to focus only on the part that is relevant to the big-O. I. e. you should be able to eyeball most situations.

Happy big-O-ing, it was my favorite thing about Computer Science -- finding that something was way easier than I thought, and then being able to show off at Google interviews when the uninitiated would be intimidated, lol.

Big O - Economic Point of View.

My favourite English word to describe this concept is the price you pay for a task as it grows larger.

Think of it as recurring costs instead of fixed costs that you would pay at the beginning. The fixed costs become negligible in the big picture because costs only grow and they add up. We want to measure how fast they would grow and how soon they would add up with respect to the raw material we give to the set up - size of the problem.

However, if initial set up costs are high and you only produce a small amount of the product, you would want to look at these initial costs - they are also called the constants.

Since, these constants don't matter in the long run, this language allows us to discuss tasks beyond what kind of infrastructure we are running it on. So, the factories can be anywhere and the workers can be whoever - it's all gravy. But the size of the factory and the number of workers would be the things we could vary in the long run as your inputs and outputs grow.

Hence, this becomes a big picture approximation of how much you would have to spend to run something. Since time and space are the economic quantities (i.e. they are limited) here, they can both be expressed using this language.

Technical notes: Some examples of time complexity - O(n) generally means that if a problem is of size 'n', I at least have to see everything. O(log n) generally means that I halve the size of the problem and check and repeat until the task is done. O(n^2) means I need to look at pairs of things (like handshakes at a party between n people).

What is a plain English explanation of “Big O” notation?

I would like to stress that the driving motive for “Big O” notation is one thing, when an input size of algorithm gets too big some parts (i.e constants, coefficients, terms )of the equation describing the measure of the algorithm becomes so insignificant that we ignore them. The parts of equation that survives after ignoring some of its parts is termed as the “Big O” notation of the algorithm.

So if the input size is NOT too big the idea of “Big O” notation( upper bound ) will be unimportant.

Les say you want to quantify the performance of the following algorithm

``````int sumArray (int[] nums){
int sum=0;   // taking initialization and assignments n=1
for(int i=0;nums.length;i++){
sum += nums[i]; // taking initialization and assignments n=1
}
return sum;
}
``````

In above algorithm, lets say you find out `T(n)` as follows (time complexity):

``````T(n) = 2*n + 2
``````

To find its “Big O” notation, we need to consider very big input size:

``````n= 1,000,000   -> T(1,000,000) = 2,000,002
n=1,000,000,000  -> T(1,000,000,000) = 2,000,000,002
n=10,000,000,000  -> T(10,000,000,000) = 20,000,000,002
``````

Lets give this similar inputs for another function `F(n) = n`

``````n= 1,000,000   -> F(1,000,000) = 1,000,000
n=1,000,000,000  -> F(1,000,000,000) = 1,000,000,000
n=10,000,000,000  -> F(10,000,000,000) = 10,000,000,000
``````

As you can see as input size get too big the `T(n)` approximately equal to or getting closer to `F(n)`, so the constant `2` and the coefficient `2` are becoming too insignificant, now the idea of Big O” notation comes in,

``````O(T(n)) = F(n)
O(T(n)) = n
``````

We say the big O of `T(n)` is `n`, and the notation is `O(T(n)) = n`, it is the upper bound of `T(n)` as `n` gets too big. the same step applies for other algorithms.

There are some great answers already posted, but I would like to contribute in a different way. If you want to visualize what all is happening you can assume that a compiler can perform close to 10^8 operations in ~1sec. If the input is given in 10^8, you might want to design an algorithm that operates in a linear fashion(like an un-nested for-loop). below is the table that can help you to quickly figure out the type of algorithm you want to figure out ;) TLDR: Big O explains performance of an algorithm in mathematical terms.

Slower algorithms tend to run at n to the power of x or many, depending on depth of it, whereas faster ones like binary search run at O(log n), which makes it run faster as data set gets larger. Big O could be explained with other terms using n, or not even using n too (ie: O(1) ).

One can calculate Big O Looking at the most complex lines of the algorithm.

With small or unsorted datasets Big O can be surprising, as n log n complexity algorithms like binary search can be slow for smaller or unsorted sets, for a simple running example of linear search versus binary search, take a look at my JavaScript example:

https://codepen.io/serdarsenay/pen/XELWqN?editors=1011 (algorithms written below)

``````function lineerSearch() {
init();
var t = timer('lineerSearch benchmark');
var input = this.event.target.value;
for(var i = 0;i<unsortedhaystack.length - 1;i++) {
if (unsortedhaystack[i] === input) {
document.getElementById('result').innerHTML = 'result is... "' + unsortedhaystack[i] + '", on index: ' + i + ' of the unsorted array. Found' + ' within ' + i + ' iterations';
console.log(document.getElementById('result').innerHTML);
t.stop();
return unsortedhaystack[i];
}
}
}

function binarySearch () {
init();
sortHaystack();
var t = timer('binarySearch benchmark');
var firstIndex = 0;
var lastIndex = haystack.length-1;
var input = this.event.target.value;

//currently point in the half of the array
var currentIndex = (haystack.length-1)/2 | 0;
var iterations = 0;

while (firstIndex <= lastIndex) {
currentIndex = (firstIndex + lastIndex)/2 | 0;
iterations++;
if (haystack[currentIndex]  < input) {
firstIndex = currentIndex + 1;
//console.log(currentIndex + " added, fI:"+firstIndex+", lI: "+lastIndex);
} else if (haystack[currentIndex] > input) {
lastIndex = currentIndex - 1;
//console.log(currentIndex + " substracted, fI:"+firstIndex+", lI: "+lastIndex);
} else {
document.getElementById('result').innerHTML = 'result is... "' + haystack[currentIndex] + '", on index: ' + currentIndex + ' of the sorted array. Found' + ' within ' + iterations + ' iterations';
console.log(document.getElementById('result').innerHTML);
t.stop();
return true;
}
}
}
``````