What is a plain English explanation of Big O? With as little formal definition as possible and simple mathematics.
Quick note, this is almost certainly confusing Big O notation (which is an upper bound) with Theta notation (which is a twoside bound). In my experience this is actually typical of discussions in nonacademic settings. Apologies for any confusion caused. Big O complexity can be visualized with this graph: The simplest definition I can give for BigO notation is this: BigO notation is a relative representation of the complexity of an algorithm. There are some important and deliberately chosen words in that sentence:
Come back and reread the above when you've read the rest. The best example of BigO I can think of is doing arithmetic. Take two numbers (123456 and 789012). The basic arithmetic operations we learnt in school were:
Each of these is an operation or a problem. A method of solving these is called an algorithm. Addition is the simplest. You line the numbers up (to the right) and add the digits in a column writing the last number of that addition in the result. The 'tens' part of that number is carried over to the next column. Let's assume that the addition of these numbers is the most expensive operation in this algorithm. It stands to reason that to add these two numbers together we have to add together 6 digits (and possibly carry a 7th). If we add two 100 digit numbers together we have to do 100 additions. If we add two 10,000 digit numbers we have to do 10,000 additions. See the pattern? The complexity (being the number of operations) is directly proportional to the number of digits n in the larger number. We call this O(n) or linear complexity. Subtraction is similar (except you may need to borrow instead of carry). Multiplication is different. You line the numbers up, take the first digit in the bottom number and multiply it in turn against each digit in the top number and so on through each digit. So to multiply our two 6 digit numbers we must do 36 multiplications. We may need to do as many as 10 or 11 column adds to get the end result too. If we have two 100digit numbers we need to do 10,000 multiplications and 200 adds. For two one million digit numbers we need to do one trillion (10^{12}) multiplications and two million adds. As the algorithm scales with nsquared, this is O(n^{2}) or quadratic complexity. This is a good time to introduce another important concept: We only care about the most significant portion of complexity. The astute may have realized that we could express the number of operations as: n^{2} + 2n. But as you saw from our example with two numbers of a million digits apiece, the second term (2n) becomes insignificant (accounting for 0.0002% of the total operations by that stage). One can notice that we've assumed the worst case scenario here. While multiplying 6 digit numbers if one of them is 4 digit and the other one is 6 digit, then we only have 24 multiplications. Still we calculate the worst case scenario for that 'n', i.e when both are 6 digit numbers. Hence BigO notation is about the Worstcase scenario of an algorithm The Telephone BookThe next best example I can think of is the telephone book, normally called the White Pages or similar but it'll vary from country to country. But I'm talking about the one that lists people by surname and then initials or first name, possibly address and then telephone numbers. Now if you were instructing a computer to look up the phone number for "John Smith" in a telephone book that contains 1,000,000 names, what would you do? Ignoring the fact that you could guess how far in the S's started (let's assume you can't), what would you do? A typical implementation might be to open up to the middle, take the 500,000^{th} and compare it to "Smith". If it happens to be "Smith, John", we just got real lucky. Far more likely is that "John Smith" will be before or after that name. If it's after we then divide the last half of the phone book in half and repeat. If it's before then we divide the first half of the phone book in half and repeat. And so on. This is called a binary search and is used every day in programming whether you realize it or not. So if you want to find a name in a phone book of a million names you can actually find any name by doing this at most 20 times. In comparing search algorithms we decide that this comparison is our 'n'.
That is staggeringly good isn't it? In BigO terms this is O(log n) or logarithmic complexity. Now the logarithm in question could be ln (base e), log_{10}, log_{2} or some other base. It doesn't matter it's still O(log n) just like O(2n^{2}) and O(100n^{2}) are still both O(n^{2}). It's worthwhile at this point to explain that Big O can be used to determine three cases with an algorithm:
Normally we don't care about the best case. We're interested in the expected and worst case. Sometimes one or the other of these will be more important. Back to the telephone book. What if you have a phone number and want to find a name? The police have a reverse phone book but such lookups are denied to the general public. Or are they? Technically you can reverse lookup a number in an ordinary phone book. How? You start at the first name and compare the number. If it's a match, great, if not, you move on to the next. You have to do it this way because the phone book is unordered (by phone number anyway). So to find a name given the phone number (reverse lookup):
The Travelling SalesmanThis is quite a famous problem in computer science and deserves a mention. In this problem you have N towns. Each of those towns is linked to 1 or more other towns by a road of a certain distance. The Travelling Salesman problem is to find the shortest tour that visits every town. Sounds simple? Think again. If you have 3 towns A, B and C with roads between all pairs then you could go:
Well actually there's less than that because some of these are equivalent (A → B → C and C → B → A are equivalent, for example, because they use the same roads, just in reverse). In actuality there are 3 possibilities.
This is a function of a mathematical operation called a factorial. Basically:
So the BigO of the Travelling Salesman problem is O(n!) or factorial or combinatorial complexity. By the time you get to 200 towns there isn't enough time left in the universe to solve the problem with traditional computers. Something to think about. Polynomial TimeAnother point I wanted to make quick mention of is that any algorithm that has a complexity of O(n^{a}) is said to have polynomial complexity or is solvable in polynomial time. O(n), O(n^{2}) etc are all polynomial time. Some problems cannot be solved in polynomial time. Certain things are used in the world because of this. Public Key Cryptography is a prime example. It is computationally hard to find two prime factors of a very large number. If it wasn't, we couldn't use the public key systems we use. Anyway, that's it for my (hopefully plain English) explanation of Big O (revised). 


It shows how an algorithm scales. O(n^{2}): known as Quadratic complexity
Notice that the number of items increases by a factor of 10, but the time increases by a factor of 10^{2}. Basically, n=10 and so O(n^{2}) gives us the scaling factor n^{2} which is 10^{2}. O(n): known as Linear complexity
This time the number of items increases by a factor of 10, and so does the time. n=10 and so O(n)'s scaling factor is 10. O(1): known as Constant complexity
The number of items is still increasing by a factor of 10, but the scaling factor of O(1) is always 1. O(log n): known as Logarithmic complexity
The number of computations is only increased by a log of the input value. So in this case, assuming each computation takes 1 second, the log of the input That's the gist of it. They reduce the maths down so it might not be exactly n^{2} or whatever they say it is, but that'll be the dominating factor in the scaling. 


EDIT: Quick note, this is almost certainly confusing Big O notation (which is an upper bound) with Theta notation (which is both an upper and lower bound). In my experience this is actually typical of discussions in nonacademic settings. Apologies for any confusion caused. In one sentence: As the size of your job goes up, how much longer does it take to complete it? Obviously that's only using "size" as the input and "time taken" as the output — the same idea applies if you want to talk about memory usage etc. Here's an example where we have N Tshirts which we want to dry. We'll assume it's incredibly quick to get them in the drying position (i.e. the human interaction is negligible). That's not the case in real life, of course...
One important aspect of "big O" notation is that it doesn't say which algorithm will be faster for a given size. Take a hashtable (string key, integer value) vs an array of pairs (string, integer). Is it faster to find a key in the hashtable or an element in the array, based on a string? (i.e. for the array, "find the first element where the string part matches the given key.") Hashtables are generally amortised (~= "on average") O(1) — once they're set up, it should take about the same time to find an entry in a 100 entry table as in a 1,000,000 entry table. Finding an element in an array (based on content rather than index) is linear, i.e. O(N) — on average, you're going to have to look at half the entries. Does this make a hashtable faster than an array for lookups? Not necessarily. If you've got a very small collection of entries, an array may well be faster — you may be able to check all the strings in the time that it takes to just calculate the hashcode of the one you're looking at. As the data set grows larger, however, the hashtable will eventually beat the array. 


BigO notation (also called "asymptotic growth" notation) is what functions "look like" when you ignore constant factors and stuff near the origin. We use it to talk about how thing scale. Basics for "sufficiently" large inputs...
bigO notation doesn't care about constant factors: the function Why would you want to ignore the smaller parts of the equation? Because they become completely dwarfed by the big parts of the equation as you consider larger and larger scales; their contribution becomes dwarfed and irrelevant. (See example section.) Put another way, it's all about the ratio. If you divide the actual time it takes by the
... this means that for "large enough" problem sizes N (if we ignore stuff near the origin), there exists some constant (e.g. 2.5, completely made up) such that:
There are many choices of constant; often the "best" choice is known as the "constant factor" of the algorithm... but we often ignore it like we ignore nonlargest terms (see Constant Factors section for why they don't usually matter). You can also think of the above equation as a bound, saying "In the worstcase scenario, the time it takes will never be worse than roughly In general, Intuition This lets us make statements like...
(with credit to http://stackoverflow.com/a/487292/711085 ) Applications As a purely mathematical construct, bigO notation is not limited to talking about processing time and memory. You can use it to discuss the asymptotics of anything where scaling is meaningful, such as:
Example For the handshake example,
If you wanted to prove this to yourself, you could perform some simple algebra on the ratio to split it up into multiple terms (
Constant factors Usually we don't care what the specific constant factors are, because they don't affect the way the function grows. For example, two algorithm may both take Some asymptotically superior algorithms (e.g. a noncomparison Why O(N) is sometimes the best you can do, i.e. why we need datastructures
The same can be said for the very act of writing. For example, all algorithms which print out all permutations of a number N are This motivates the use of data structures: a data structure requires reading the data only once (usually For example, say you had the latitude and longitude coordinates of millions of roads segments, and wanted to find all street intersections.
The moral of the story: a data structure lets us speed up operations. Even more advanced data structures can let you combine, delay, or even ignore operations in incredibly clever ways, like leaving the equivalent of "todo" notes at junctions in a tree. Amortized and averagecase complexity There is also the concept of "amortized" and/or "average case" (note that these are different). Average Case: This is no more than using bigO notation for the expected value of a function, rather than the function itself. In the usual case where you consider all inputs to be equally likely, the average case is just the average of the running time. For example with quicksort, even though the worstcase is Amortized WorstCase: Some data structures may have a worstcase complexity that is large, but guarantee that if you do many of these operations, the average amount of work you do will be better than worstcase. For example you may have a data structure that normally takes constant
Comparison between averagecase and amortized worstcase:
(See Difference between average case and amortized analysis if interested on this subtopic.) Multidimensional bigO Most of the time, people don't realize that there's more than one variable at work. For example, in a stringsearch algorithm, your algorithm may take time The whole story Keep in mind that bigO is not the whole story. You can drastically speed up some algorithms by using caching, making them cacheoblivious, avoiding bottlenecks by working with RAM instead of disk, using parallelization, or doing work ahead of time  these techniques are often independent of the orderofgrowth "bigO" notation, though you will often see the number of cores in the bigO notation of parallel algorithms. Also keep in mind that due to hidden constraints of your program, you might not really care about asymptotic behavior. You may be working with a bounded number of values, for example:
In practice, even among algorithms which have the same or similar asymptotic performance, their relative merit may actually be driven by other things, such as: other performance factors (quicksort and mergesort are both Many things can implicitly contribute to the running time's constant factor, such as whether you run your algorithm on a 500MHz computer vs 2GHz computer, whether your programming language is interpreted or using a JIT compiler, whether you are doing a constant amount of extra work in a critical section of code, etc. The effect may be small (e.g. 0.9x speed) or large (e.g. 0.01x speed) compared to a different implementation and/or environment. Do you switch languages to eke out that little extra constant factor of work? That literally depends on a hundred other reasons (necessity, skills, coworkers, programmer productivity, the monetary value of your time, familiarity, workarounds, why not assembly or GPU, etc...), which may be more important than performance. The above issues, like programming language, are almost never considered as part of the constant factor (nor should they be); yet one should be aware of them, because sometimes (though rarely) they may not be constant. For example in cpython, the native priority queue implementation is asymptotically nonoptimal ( Math addenda For completeness, the precise definition of bigO notation is as follows: People will often use 


Big O describes an upper limit on the growth behaviour of a function, for example the runtime of a program, when inputs become large. Examples:
The input size is usually the space in bits needed to represent the input. 


Big O notation is most commonly used by programmers as an approximate measure of how long a computation (algorithm) will take to complete expressed as a function of the size of the input set. Big O is useful to compare how well two algorithms will scale up as the number of inputs is increased. More precisely Big O notation is used to express the asymptotic behavior of a function. That means how the function behaves as it approaches infinity. In many cases the "O" of an algorithm will fall into one of the following cases:
Big O ignores factors that do not contribute in a meaningful way to the growth curve of a function as the input size increases towards infinity. This means that constants that are added to or multiplied by the function are simply ignored. 


Big O is just a way to "Express" yourself in a common way, "How much time / space does it take to run my code?". You may often see O(n), O(n^{2}), O(nlogn) and so forth, all these are just ways to show; How does an algorithm change? O(n) means Big O is n, and now you might think, "What is n!?" Well "n" is the amount of elements. Imaging you want to search for an Item in an Array. You would have to look on Each element and as "Are you the correct element/item?" in the worst case, the item is at the last index, which means that it took as much time as there are items in the list, so to be generic, we say "oh hey, n is a fair given amount of values!". So then you might understand what "n^{2}" means, but to be even more specific, play with the thought you have a simple, the simpliest of the sorting algorithms; bubblesort. This algorithm needs to look through the whole list, for each item. My list
The flow here would be:
This is O n^{2} because, you need to look at all items in the list there are "n" items. For each item, you look at all items once more, for comparing, this is also "n", so for every item, you look "n" times meaning n*n = n^{2} I hope this is as simple as you want it. But remember, Big O is just a way to experss yourself in the manner of time and space. 


Big O describes the fundamental scaling nature of an algorithm. There is a lot of information that Big O does not tell you about a given algorithm. It cuts to the bone and gives only information about the scaling nature of an algorithm, specifically how the resource use (think time or memory) of an algorithm scales in response to the "input size". Consider the difference between a steam engine and a rocket. They are not merely different varieties of the same thing (as, say, a Prius engine vs. a Lamborghini engine) but they are dramatically different kinds of propulsion systems, at their core. A steam engine may be faster than a toy rocket, but no steam piston engine will be able to achieve the speeds of an orbital launch vehicle. This is because these systems have different scaling characteristics with regards to the relation of fuel required ("resource usage") to reach a given speed ("input size"). Why is this so important? Because software deals with problems that may differ in size by factors up to a trillion. Consider that for a moment. The ratio between the speed necessary to travel to the Moon and human walking speed is less than 10,000:1, and that is absolutely tiny compared to the range in input sizes software may face. And because software may face an astronomical range in input sizes there is the potential for the Big O complexity of an algorithm, it's fundamental scaling nature, to trump any implementation details. Consider the canonical sorting example. Bubblesort is O(n^{2}) while mergesort is O(n log n). Let's say you have two sorting applications, application A which uses bubblesort and application B which uses mergesort, and let's say that for input sizes of around 30 elements application A is 1,000x faster than application B at sorting. If you never have to sort much more than 30 elements then it's obvious that you should prefer application A, as it is much faster at these input sizes. However, if you find that you may have to sort ten million items then what you'd expect is that application B actually ends up being thousands of times faster than application A in this case, entirely due to the way each algorithm scales. 


It is very difficult to measure the speed of software programs, and when we try, the answers can be very complex and filled with exceptions and special cases. This is a big problem, because all those exceptions and special cases are distracting and unhelpful when we want to compare two different programs with one another to find out which is "fastest". As a result of all this unhelpful complexity, people try to describe the speed of software programs using the smallest and least complex (mathematical) expressions possible. These expressions are very very crude approximations: Although, with a bit of luck, they will capture the "essence" of whether a piece of software is fast or slow. Because they are approximations, we use the letter "O" (Big Oh) in the expression, as a convention to signal to the reader that we are making a gross oversimplification. (And to make sure that nobody mistakenly thinks that the expression is in any way accurate). If you read the "Oh" as meaning "on the order of" or "approximately" you will not go too far wrong. (I think the choice of the BigOh might have been an attempt at humour). The only thing that these "BigOh" expressions try to do is to describe how much the software slows down as we increase the amount of data that the software has to process. If we double the amount of data that needs to be processed, does the software need twice as long to finish it's work? Ten times as long? In practice, there are a very limited number of bigOh expressions that you will encounter and need to worry about: The good:
The bad:
... and the ugly:



A Plain English Explanation of the Need for BigO Notation: When we program, we are trying to solve a problem. What we code is called an algorithm. Big O notation allows us to compare the worse case performance of our algorithms in a standardized way. Hardware specs vary over time and improvements in hardware can reduce the time it takes an algorithms to run. But replacing the hardware does not mean our algorithm is any better or improved over time, as our algorithm is still the same. So in order to allow us to compare different algorithms, to determine if one is better or not, we use Big O notation. A Plain English Explanation of What Big O Notation is: Not all algorithms run in the same amount of time, and can vary based on the number of items in the input, which we'll call n. Based on this, we consider the worse case analysis, or an upperbound of the runtime as n get larger and larger. We must be aware of what n is, because many of the Big O notations reference it. 


Big O is a measure of how much time/space an algorithm uses relative to the size of its input. If an algorithm is O(n) then the time/space will increase at the same rate as its input. If an algorithm is O(n^{2}) then the time/space increase at the rate of its input squared. and so on. 


Here is the plain English bestiary I tend to use when explaining the common varieties of BigO In all cases, prefer algorithms higher up on the list to those lower on the list. However, the cost of moving to a more expensive complexity class varies significantly. O(1): No growth. Regardless of how big as the problem is, you can solve it in the same amount of time. This is somewhat analogous to broadcasting where it takes the same amount of energy to broadcast over a given distance, regardless of the number of people that lie within the broadcast range. O(log n): This complexity is the same as O(1) except that it's just a little bit worse. For all practical purposes, you can consider this as a very large constant scaling. The difference in work between processing 1 thousand and 1 billion items is only a factor six. O(n): The cost of solving the problem is proportional to the size of the problem. If your problem doubles in size, then the cost of the solution doubles. Since most problems have to be scanned into the computer in some way, as data entry, disk reads, or network traffic, this is generally an affordable scaling factor. O(n log n): This complexity is very similar to O(n). For all practical purposes, the two are equivalent. This level of complexity would generally still be considered scalable. By tweaking assumptions some O(n log n) algorithms can be transformed into O(n) algorithms. For example, bounding the size of keys reduces sorting from O(n log n) to O(n). O(n^{2}): Grows as a square, where n is the length of the side of a square. This is the same growth rate as the "network effect", where everyone in a network might know everyone else in the network. Growth is expensive. Most scalable solutions cannot use algorithms with this level of complexity without doing significant gymnastics. This generally applies to all other polynomial complexities  O(n^{k})  as well. O(2^{n}): Does not scale. You have no hope of solving any nontrivially sized problem. Useful for knowing what to avoid, and for experts to find approximate algorithms which are in O(n^{k}). 


Ok, my 2cents. BigO, is rate of increase of resource consumed by program, w.r.t. probleminstancesize Resource : Could be totalCPU time, could be maximum RAM space. By default refers to CPU time. Say the problem is "Find the sum",
probleminstance= {5,10,15} ==> probleminstancesize = 3, iterationsinloop= 3 probleminstance= {5,10,15,20,25} ==> probleminstancesize = 5 iterationsinloop = 5 For input of size "n" the program is growing at speed of "n" iterations in array. Hence BigO is N expressed as O(n) Say the problem is "Find the Combination",
probleminstance= {5,10,15} ==> probleminstancesize = 3, totaliterations = 3*3 = 9 probleminstance= {5,10,15,20,25} ==> probleminstancesize = 5, totaliterations= 5*5 =25 For input of size "n" the program is growing at speed of "n*n" iterations in array. Hence BigO is N^{2} expressed as O(n^{2}) 

Big O notation is a way of describing the upper bound of an algorithm in terms of space or running time. The n is the number of elements in the the problem (i.e size of an array, number of nodes in a tree, etc.) We are interested in describing the running time as n gets big. When we say some algorithm is O(f(n)) we are saying that the running time (or space required) by that algorithm is always lower than some constant times f(n). To say that binary search has a running time of O(logn) is to say that there exists some constant c which you can multiply log(n) by that will always be larger than the running time of binary search. In this case you will always have some constant factor of log(n) comparisons. In other words where g(n) is the running time of your algorithm, we say that g(n) = O(f(n)) when g(n) <= c*f(n) when n > k, where c and k are some constants. 


A simple straightforward answer can be: Big O represents the worst possible time/space for that algorithm. The algorithm will never take more space/time above that limit. Big O represents time/space complexity in the extreme case. 


Such a beautifully simple and short question seems at least to deserve an equally short answer, like a student might receive during tutoring.
( *in a wonderful, unitfree sense of time!) Well, what's so wonderful about Big O notation if that's what it does?



Not sure I'm further contributing to the subject but still thought I'd share: I once found this blog post to have some quite helpful (though very basic) explanations & examples on Big O: Via examples, this helped get the bare basics into my tortoiseshelllike skull, so I think it's a pretty descent 10minute read to get you headed in the right direction. 


Algorithm example (Java):
Algorithm description:
BigO notation represent the upperbound on the Complexity (Time, Space, ..) To find The BigO on Time Complexity:
There's also BigOmega, which represent complexity of the BestCase:



Big O f(x) = O(g(x)) when x goes to a (for example, a = +∞) means that there is a function k such that:
In other words, in plain English: f(x) = O(g(x)), x → a, means that in a neighborhood of a, f decomposes into the product of g and some bounded function. Small o By the way, here is for comparison the definition of small o. f(x) = o(g(x)) when x goes to a means that there is a function k such that:
Examples
Attention! The notation with the equal sign "=" uses a "fake equality": it is true that o(g(x)) = O(g(x)), but false that O(g(x)) = o(g(x)). Similarly, it is ok to write "ln(x) = o(x) when x → +∞", but the formula "o(x) = ln(x)" would make no sense. More examples
Here is the Wikipedia article: https://en.wikipedia.org/wiki/Big_O_notation 


Big O notation is a way of describing how quickly an algorithm will run given an arbitrary number of input parameters, which we'll call "n". It is useful in computer science because different machines operate at different speeds, and simply saying that an algorithm takes 5 seconds doesn't tell you much because while you may be running a system with a 4.5 Ghz octocore processor, I may be running a 15 year old, 800 Mhz system, which would take longer regardless of the algorithm. So instead of specifying how fast an algorithm runs in terms of time, we say how fast it runs in terms of number of input parameters, or "n". By describing algorithms in this way, we are able to compare the speeds of algorithms without having to take into account the speed of the computer itself. 


Assume we're talking about an algorithm A, which should do something with a dataset of size n. Then
As it happens, there are certain functions (think of them as implementations of X(n)) that tend to occur quite often. These are well known and easily compared (Examples: By comparing these when talking about A and other algorithms, it is easy to rank the algorithms according to the number of operations they may (worstcase) require to complete. In general, our goal will be to find or structure an algorithm A in such a way that it will have a function 


I've more simpler way to understand the time complexity he most common metric for calculating time complexity is Big O notation. This removes all constant factors so that the running time can be estimated in relation to N as N approaches infinity. In general you can think of it like this:
Is constant. The running time of the statement will not change in relation to N
Is linear. The running time of the loop is directly proportional to N. When N doubles, so does the running time.
Is quadratic. The running time of the two loops is proportional to the square of N. When N doubles, the running time increases by N * N.
Is logarithmic. The running time of the algorithm is proportional to the number of times N can be divided by 2. This is because the algorithm divides the working area in half with each iteration.
Is N * log ( N ). The running time consists of N loops (iterative or recursive) that are logarithmic, thus the algorithm is a combination of linear and logarithmic. In general, doing something with every item in one dimension is linear, doing something with every item in two dimensions is quadratic, and dividing the working area in half is logarithmic. There are other Big O measures such as cubic, exponential, and square root, but they're not nearly as common. Big O notation is described as O ( ) where is the measure. The quicksort algorithm would be described as O ( N * log ( N ) ). Note: None of this has taken into account best, average, and worst case measures. Each would have its own Big O notation. Also note that this is a VERY simplistic explanation. Big O is the most common, but it's also more complex that I've shown. There are also other notations such as big omega, little o, and big theta. You probably won't encounter them outside of an algorithm analysis course. 


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BigO notation explained by a selftaught programmer
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