Difference between revisions of "Polygon"

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A '''polygon''' is a closed [[planar figure]] consisting of straight [[line segment]]s. There are two types of polygons: [[convex polygon|convex]] and [[concave polygon|concave]].
 
A '''polygon''' is a closed [[planar figure]] consisting of straight [[line segment]]s. There are two types of polygons: [[convex polygon|convex]] and [[concave polygon|concave]].
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A polygon can be [[regular polygon| regular]] or irregular. A polygon is regular if all sides are the same length and all angles are [[congruent]].
  
 
In their most general form, polygons are an ordered [[set]] of [[vertex|vertices]], <math>\{A_1, A_2, \ldots, A_n\}</math>, <math>n \geq 3</math>,  with [[edge]]s <math>\{\overline{A_1A_2}, \overline{A_2A_3}, \ldots, \overline{A_nA_1}\}</math> joining consecutive vertices.  Most frequently, one deals with ''simple polygons'' in which no two edges are allowed to intersect.  (In fact, the adjective "simple" is almost always omitted, so the term "polygon" should be understood to mean "simple polygon" unless otherwise noted.)   
 
In their most general form, polygons are an ordered [[set]] of [[vertex|vertices]], <math>\{A_1, A_2, \ldots, A_n\}</math>, <math>n \geq 3</math>,  with [[edge]]s <math>\{\overline{A_1A_2}, \overline{A_2A_3}, \ldots, \overline{A_nA_1}\}</math> joining consecutive vertices.  Most frequently, one deals with ''simple polygons'' in which no two edges are allowed to intersect.  (In fact, the adjective "simple" is almost always omitted, so the term "polygon" should be understood to mean "simple polygon" unless otherwise noted.)   
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== Angles in Regular Polygons ==
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== Angles in Polygons ==
 
===Exterior===
 
===Exterior===
In any regular polygon, the sum of the [[exterior angle]] is equal to <math>360^\circ</math>.
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In any simple convex polygon, the sum of the [[exterior angle|exterior angles]] is equal to <math>360^\circ</math>.
  
 
===Interior===
 
===Interior===
The sum of interior angles can be given by the formula <math>180(n-2)^\circ</math>, where<math> n</math> is the number of sides. Thus any angle is <math>\frac{180(n-2)}{n}^\circ</math>.
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The sum of interior angles can be given by the formula <math>180(n-2)^\circ</math>, where <math>n</math> is the number of sides. Thus in regular polygons, any angle is <math>\frac{180(n-2)}{n}^\circ</math>.
 
{| class="wikitable"
 
{| class="wikitable"
 
|-
 
|-
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! Individual angle measure in regular polygon
 
! Individual angle measure in regular polygon
 
|-
 
|-
| [[Triangle 3]]
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| [[Triangle|3]]
 
| <math>180^\circ</math>
 
| <math>180^\circ</math>
 
| <math>60^\circ</math>
 
| <math>60^\circ</math>
 
|-
 
|-
| [[quadrilateral 4]]
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| [[quadrilateral|4]]
 
| <math>360^\circ</math>
 
| <math>360^\circ</math>
 
| <math>90^\circ</math>
 
| <math>90^\circ</math>
 
|-
 
|-
|[[pentagon 5]]
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|[[pentagon|5]]
 
|<math>540^\circ</math>
 
|<math>540^\circ</math>
 
|<math>108^\circ</math>
 
|<math>108^\circ</math>

Latest revision as of 18:04, 30 May 2015

A polygon is a closed planar figure consisting of straight line segments. There are two types of polygons: convex and concave.

A polygon can be regular or irregular. A polygon is regular if all sides are the same length and all angles are congruent.

In their most general form, polygons are an ordered set of vertices, $\{A_1, A_2, \ldots, A_n\}$, $n \geq 3$, with edges $\{\overline{A_1A_2}, \overline{A_2A_3}, \ldots, \overline{A_nA_1}\}$ joining consecutive vertices. Most frequently, one deals with simple polygons in which no two edges are allowed to intersect. (In fact, the adjective "simple" is almost always omitted, so the term "polygon" should be understood to mean "simple polygon" unless otherwise noted.)

A degenerate polygon is one in which some vertex lies on an edge joining two other vertices. This can happen in one of two ways: either the vertices $A_{i - 1},A_i$ and $A_{i+1}$ can be colinear or the vertices $A_i$ and $A_{i + 1}$ can overlap (fail to be distinct). In either of these cases, our polygon of $n$ vertices will appear to have $n - 1$ or fewer -- it will have "degenerated" from an $n$-gon to an $(n - 1)$-gon. (In the case of triangles, this will result in either a line segment or a point.)


Angles in Polygons

Exterior

In any simple convex polygon, the sum of the exterior angles is equal to $360^\circ$.

Interior

The sum of interior angles can be given by the formula $180(n-2)^\circ$, where $n$ is the number of sides. Thus in regular polygons, any angle is $\frac{180(n-2)}{n}^\circ$.

Number of Sides Sum of Interior angles Individual angle measure in regular polygon
3 $180^\circ$ $60^\circ$
4 $360^\circ$ $90^\circ$
5 $540^\circ$ $108^\circ$
6 $720^\circ$ $120^\circ$
8 $1080^\circ$ $135^\circ$

See also

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