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126 lines
5.5 KiB
Markdown
126 lines
5.5 KiB
Markdown
---
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category: Algorithms & Data Structures
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contributors:
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- ["Jake Prather", "http://github.com/JakeHP"]
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---
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# Asymptotic Notations
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## What are they?
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Asymptotic Notations are languages that allows us to analyze an algorithm's running time by
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identifying its behavior as the input size for the algorithm increases. This is also known as
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an algorithm's growth rate. Does the algorithm suddenly become incredibly slow when the input
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size grows? Does it mostly maintain it's quick run time as the input size increases?
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Asymptotic Notation gives us the ability to answer these questions.
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## Are there alternatives to answering these questions?
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One way would be to count the number of primitive operations at different input sizes.
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Though this is a valid solution, the amount of work this takes for even simple algorithms
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does not justify its use.
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Another way is to physically measure the amount of time an algorithm takes to complete
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given different input sizes. However, the accuracy and relativity (times obtained would
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only be relative to the machine they were computed on) of this method is bound to
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environmental variables such as computer hardware specifications, processing power, etc.
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## Types of Asymptotic Notation
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In the first section of this doc we described how an Asymptotic Notation identifies the
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behavior of an algorithm as the input size changes. Let us imagine an algorithm as a function
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f, n as the input size, and f(n) being the running time. So for a given algorithm f, with input
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size n you get some resultant run time f(n). This results in a graph where the Y axis is the
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runtime, X axis is the input size, and plot points are the resultants of the amount of time
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for a given input size.
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You can label a function, or algorithm, with an Asymptotic Notation in many different ways.
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Some examples are, you can describe an algorithm by it's best case, worse case, or equivalent case.
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The most common is to analyze an algorithm by it's worst case. This is because if you determine an
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algorithm's run time or time complexity, by it's best case, what if it's best case is only obtained
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given at a low, unrealistic, input size? It is equivalent to having a 5 meter sprinting race.
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That isn't the best measurement.
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### Types of functions, limits, and simplification
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```
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Logarithmic Function - log n
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Linear Function - an + b
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Quadratic Function - an^2 + bn + c
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Polynomial Function - an^z + . . . + an^2 + a*n^1 + a*n^0, where z is some constant
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Exponential Function - a^n, where a is some constant
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```
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These are some basic function growth classifications used in various notations. The list starts at the least
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fast growing function (logarithmic) and goes on to the fastest growing (exponential). Notice that as 'n', or the input,
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increases in each of those functions, the result clearly increases much quicker in quadratic, polynomial, and
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exponential, compared to logarithmic and linear.
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One extremely important note is that for the notations about to be discussed you should do your best to use simplest terms.
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This means to disregard constants, and lower order terms, because as the input size (or n in our f(n)
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example) increases to infinity (mathematical limits), the lower order terms and constants are of little
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to no importance. That being said, if you have constants that are 2^9001, or some other ridiculous
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unimaginable amount, realize that simplifying will skew your notation accuracy.
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Since we want simplest form, lets modify our table a bit...
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```
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Logarithmic - log n
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Linear - n
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Quadratic - n^2
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Polynomial - n^z, where z is some constant
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Exponential - a^n, where a is some constant
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```
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### Big-Oh
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Big-Oh, commonly written as O, is an Asymptotic Notation for the worst case, or ceiling of growth
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for a given function. Say f(n) is your algorithm runtime, and g(n) is an arbitrary time complexity
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you are trying to relate to your algorithm. f(n) is O(g(n)), if for any real constant c (c>0),
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f(n) <= c g(n) for every input size n (n>0).
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Example 1
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f(n) = 3log n + 100
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g(n) = log n
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is f(n) O(g(n))?
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is 3 log n + 100 O(log n)?
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Let's look to the definition of Big-Oh.
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3log n + 100 <= c * log n
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Is there some constant c that satisfies this for all n?
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3log n + 100 <= 150 * log n, n > 2 (undefined at n = 1)
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Yes! The definition of Big-Oh has been met therefore f(n) is O(g(n)).
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Example 2
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f(n) = 3*n^2
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g(n) = n
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is f(n) O(g(n))?
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is 3*n^2 O(n)?
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Let's look at the definition of Big-Oh.
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3*n^2 <= c * n
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Is there some constant c that satisfies this for all n?
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No there isn't, f(n) is NOT O(g(n)).
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### Big-Omega
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Big-Omega, commonly written as Ω, is an Asymptotic Notation for the best case, or a floor growth rate
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for a given function.
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f(n) is Ω(g(n)), if for any real constant c (c>0), f(n) is >= c g(n) for every input size n (n>0).
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Feel free to head over to additional resources for examples on this. Big-Oh is the primary notation used
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for general algorithm time complexity.
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### Ending Notes
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It's hard to keep this kind of topic short, and you should definitely go through the books and online
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resources listed. They go into much greater depth with definitions and examples.
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More where x='Algorithms & Data Structures' is on it's way; we'll have a doc up on analyzing actual
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code examples soon.
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## Books
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* [Algorithms](http://www.amazon.com/Algorithms-4th-Robert-Sedgewick/dp/032157351X)
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* [Algorithm Design](http://www.amazon.com/Algorithm-Design-Foundations-Analysis-Internet/dp/0471383651)
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## Online Resources
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* [MIT](http://web.mit.edu/16.070/www/lecture/big_o.pdf)
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* [KhanAcademy](https://www.khanacademy.org/computing/computer-science/algorithms/asymptotic-notation/a/asymptotic-notation)
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