From 9d5eca17c629fa00fa433cf205152202db02865a Mon Sep 17 00:00:00 2001 From: Divay Prakash Date: Sat, 12 Mar 2016 16:58:00 +0530 Subject: [PATCH] Fixed typos and content exceeding beyond 80 chars --- asymptotic-notation.html.markdown | 145 ++++++++++++++++++------------ 1 file changed, 89 insertions(+), 56 deletions(-) diff --git a/asymptotic-notation.html.markdown b/asymptotic-notation.html.markdown index d7dbb960..a23ef1c8 100644 --- a/asymptotic-notation.html.markdown +++ b/asymptotic-notation.html.markdown @@ -10,35 +10,45 @@ contributors: ## What are they? -Asymptotic Notations are languages that allow us to analyze an algorithm's running time by -identifying its behavior as the input size for the algorithm increases. This is also known as -an algorithm's growth rate. Does the algorithm suddenly become incredibly slow when the input -size grows? Does it mostly maintain its quick run time as the input size increases? -Asymptotic Notation gives us the ability to answer these questions. +Asymptotic Notations are languages that allow us to analyze an algorithm's +running time by identifying its behavior as the input size for the algorithm +increases. This is also known as an algorithm's growth rate. Does the +algorithm suddenly become incredibly slow when the input size grows? Does it +mostly maintain its quick run time as the input size increases? Asymptotic +Notation gives us the ability to answer these questions. ## Are there alternatives to answering these questions? -One way would be to count the number of primitive operations at different input sizes. -Though this is a valid solution, the amount of work this takes for even simple algorithms -does not justify its use. +One way would be to count the number of primitive operations at different +input sizes. Though this is a valid solution, the amount of work this takes +for even simple algorithms does not justify its use. -Another way is to physically measure the amount of time an algorithm takes to complete -given different input sizes. However, the accuracy and relativity (times obtained would -only be relative to the machine they were computed on) of this method is bound to -environmental variables such as computer hardware specifications, processing power, etc. +Another way is to physically measure the amount of time an algorithm takes to +complete given different input sizes. However, the accuracy and relativity +(times obtained would only be relative to the machine they were computed on) +of this method is bound to environmental variables such as computer hardware +specifications, processing power, etc. ## Types of Asymptotic Notation -In the first section of this doc we described how an Asymptotic Notation identifies the -behavior of an algorithm as the input size changes. Let us imagine an algorithm as a function -f, n as the input size, and f(n) being the running time. So for a given algorithm f, with input -size n you get some resultant run time f(n). This results in a graph where the Y axis is the -runtime, X axis is the input size, and plot points are the resultants of the amount of time -for a given input size. +In the first section of this doc we described how an Asymptotic Notation +identifies the behavior of an algorithm as the input size changes. Let us +imagine an algorithm as a function f, n as the input size, and f(n) being +the running time. So for a given algorithm f, with input size n you get +some resultant run time f(n). This results in a graph where the Y axis is the +runtime, X axis is the input size, and plot points are the resultants of the +amount of time for a given input size. -You can label a function, or algorithm, with an Asymptotic Notation in many different ways. -Some examples are, you can describe an algorithm by its best case, worse case, or equivalent case. -The most common is to analyze an algorithm by its worst case. You typically don't evaluate by best case because those conditions aren't what you're planning for. A very good example of this is sorting algorithms; specifically, adding elements to a tree structure. Best case for most algorithms could be as low as a single operation. However, in most cases, the element you're adding will need to be sorted appropriately through the tree, which could mean examining an entire branch. This is the worst case, and this is what we plan for. +You can label a function, or algorithm, with an Asymptotic Notation in many +different ways. Some examples are, you can describe an algorithm by its best +case, worse case, or equivalent case. The most common is to analyze an +algorithm by its worst case. You typically don't evaluate by best case because +those conditions aren't what you're planning for. A very good example of this +is sorting algorithms; specifically, adding elements to a tree structure. Best +case for most algorithms could be as low as a single operation. However, in +most cases, the element you're adding will need to be sorted appropriately +through the tree, which could mean examining an entire branch. This is the +worst case, and this is what we plan for. ### Types of functions, limits, and simplification @@ -46,16 +56,25 @@ The most common is to analyze an algorithm by its worst case. You typically don' Logarithmic Function - log n Linear Function - an + b Quadratic Function - an^2 + bn + c -Polynomial Function - an^z + . . . + an^2 + a*n^1 + a*n^0, where z is some constant +Polynomial Function - an^z + . . . + an^2 + a*n^1 + a*n^0, where z is some +constant Exponential Function - a^n, where a is some constant ``` -These are some basic function growth classifications used in various notations. The list starts at the slowest growing function (logarithmic, fastest execution time) and goes on to the fastest growing (exponential, slowest execution time). Notice that as 'n', or the input, increases in each of those functions, the result clearly increases much quicker in quadratic, polynomial, and exponential, compared to logarithmic and linear. +These are some basic function growth classifications used in various +notations. The list starts at the slowest growing function (logarithmic, +fastest execution time) and goes on to the fastest growing (exponential, +slowest execution time). Notice that as 'n', or the input, increases in each +of those functions, the result clearly increases much quicker in quadratic, +polynomial, and exponential, compared to logarithmic and linear. -One extremely important note is that for the notations about to be discussed you should do your best to use simplest terms. This means to disregard constants, and lower order terms, because as the input size (or n in our f(n) -example) increases to infinity (mathematical limits), the lower order terms and constants are of little -to no importance. That being said, if you have constants that are 2^9001, or some other ridiculous, -unimaginable amount, realize that simplifying will skew your notation accuracy. +One extremely important note is that for the notations about to be discussed +you should do your best to use simplest terms. This means to disregard +constants, and lower order terms, because as the input size (or n in our f(n) +example) increases to infinity (mathematical limits), the lower order terms +and constants are of little to no importance. That being said, if you have +constants that are 2^9001, or some other ridiculous, unimaginable amount, +realize that simplifying will skew your notation accuracy. Since we want simplest form, lets modify our table a bit... @@ -68,11 +87,13 @@ Exponential - a^n, where a is some constant ``` ### Big-O -Big-O, commonly written as **O**, is an Asymptotic Notation for the worst case, or ceiling of growth -for a given function. It provides us with an _**asymptotic uppper bound**_ for the growth rate of runtime of an algorithm. -Say `f(n)` is your algorithm runtime, and `g(n)` is an arbitrary time complexity -you are trying to relate to your algorithm. `f(n)` is O(g(n)), if for some real constant c (c > 0), -`f(n)` <= `c g(n)` for every input size n (n > 0). +Big-O, commonly written as **O**, is an Asymptotic Notation for the worst +case, or ceiling of growth for a given function. It provides us with an +_**asymptotic upper bound**_ for the growth rate of runtime of an algorithm. +Say `f(n)` is your algorithm runtime, and `g(n)` is an arbitrary time +complexity you are trying to relate to your algorithm. `f(n)` is O(g(n)), if +for some real constant c (c > 0), `f(n)` <= `c g(n)` for every input size +n (n > 0). *Example 1* @@ -116,50 +137,62 @@ Is there some constant c that satisfies this for all n? No, there isn't. `f(n)` is NOT O(g(n)). ### Big-Omega -Big-Omega, commonly written as **Ω**, is an Asymptotic Notation for the best case, or a floor growth rate -for a given function. It provides us with an _**asymptotic lower bound**_ for the growth rate of runtime of an algorithm. +Big-Omega, commonly written as **Ω**, is an Asymptotic Notation for the best +case, or a floor growth rate for a given function. It provides us with an +_**asymptotic lower bound**_ for the growth rate of runtime of an algorithm. -`f(n)` is Ω(g(n)), if for some real constant c (c > 0), `f(n)` is >= `c g(n)` for every input size n (n > 0). +`f(n)` is Ω(g(n)), if for some real constant c (c > 0), `f(n)` is >= `c g(n)` +for every input size n (n > 0). ### Note -The asymptotic growth rates provided by big-O and big-omega notation may or may not be asymptotically tight. -Thus we use small-o and small-omega notation to denote bounds that are not asymptotically tight. +The asymptotic growth rates provided by big-O and big-omega notation may or +may not be asymptotically tight. Thus we use small-o and small-omega notation +to denote bounds that are not asymptotically tight. ### Small-o -Small-o, commanly written as **o**, is an Asymptotic Notation to denote the upper bound (that is not asmptotically tight) -on the growth rate of runtime of an algorithm. +Small-o, commonly written as **o**, is an Asymptotic Notation to denote the +upper bound (that is not asymptotically tight) on the growth rate of runtime +of an algorithm. -`f(n)` is o(g(n)), if for any real constant c (c > 0), `f(n)` is < `c g(n)` for every input size n (n > 0). +`f(n)` is o(g(n)), if for any real constant c (c > 0), `f(n)` is < `c g(n)` +for every input size n (n > 0). -The definitions of O-notation and o-notation are similar. The main difference is that in f(n) = O(g(n)), the bound f(n) <= g(n) -holds for _**some**_ constant c > 0, but in f(n) = o(g(n)), the bound f(n) < c g(n) holds for _**all**_ constants c > 0. +The definitions of O-notation and o-notation are similar. The main difference +is that in f(n) = O(g(n)), the bound f(n) <= g(n) holds for _**some**_ +constant c > 0, but in f(n) = o(g(n)), the bound f(n) < c g(n) holds for +_**all**_ constants c > 0. ### Small-omega -Small-omega, commanly written as **ω**, is an Asymptotic Notation to denote the lower bound (that is not asmptotically tight) -on the growth rate of runtime of an algorithm. +Small-omega, commonly written as **ω**, is an Asymptotic Notation to denote +the lower bound (that is not asymptotically tight) on the growth rate of +runtime of an algorithm. -`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). +`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). -The definitions of Ω-notation and ω-notation are similar. The main difference is that in f(n) = Ω(g(n)), the bound f(n) >= g(n) -holds for _**some**_ constant c > 0, but in f(n) = ω(g(n)), the bound f(n) > c g(n) holds for _**all**_ constants c > 0. +The definitions of Ω-notation and ω-notation are similar. The main difference +is that in f(n) = Ω(g(n)), the bound f(n) >= g(n) holds for _**some**_ +constant c > 0, but in f(n) = ω(g(n)), the bound f(n) > c g(n) holds for +_**all**_ constants c > 0. ### Theta -Theta, commonly written as **Θ**, is an Asymptotic Notation to denote the _**asmptotically tight bound**_ on the growth rate -of runtime of an algorithm. +Theta, commonly written as **Θ**, is an Asymptotic Notation to denote the +_**asymptotically tight bound**_ on the growth rate of runtime of an algorithm. -`f(n)` is Θ(g(n)), if for some real constants c1, c2 (c1 > 0, c2 > 0), `c1 g(n)` is < `f(n)` is < `c2 g(n)` for every input size n (n > 0). +`f(n)` is Θ(g(n)), if for some real constants c1, c2 (c1 > 0, c2 > 0), +`c1 g(n)` is < `f(n)` is < `c2 g(n)` for every input size n (n > 0). ∴ `f(n)` is Θ(g(n)) implies `f(n)` is O(g(n)) as well as `f(n)` is Ω(g(n)). -Feel free to head over to additional resources for examples on this. Big-O is the primary notation used -for general algorithm time complexity. +Feel free to head over to additional resources for examples on this. Big-O +is the primary notation use for general algorithm time complexity. ### Ending Notes -It's hard to keep this kind of topic short, and you should definitely go through the books and online -resources listed. They go into much greater depth with definitions and examples. -More where x='Algorithms & Data Structures' is on its way; we'll have a doc up on analyzing actual -code examples soon. +It's hard to keep this kind of topic short, and you should definitely go +through the books and online resources listed. They go into much greater depth +with definitions and examples. More where x='Algorithms & Data Structures' is +on its way; we'll have a doc up on analyzing actual code examples soon. ## Books