Difference between revisions of "Cyclic quadrilateral"

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A '''cyclic quadrilateral''' is a [[quadrilateral]] that can be inscribed in a circle. They occur frequently on math contests/
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A '''cyclic quadrilateral''' is a [[quadrilateral]] that can be inscribed in a [[circle]]. While all [[triangles]] are cyclic, the same is not true of quadrilaterals. They have a number of interesting properties.
olmypiads due to their interesting properties.
 
  
 
<center>[[image:Cyclicquad2.png]]</center>
 
<center>[[image:Cyclicquad2.png]]</center>
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== Properties ==
 
== Properties ==
  
In cyclic quadrilateral <math>ABCD</math>:
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In a quadrilateral <math>ABCD</math>:
  
* <math>\angle A + \angle C = \angle B + \angle D = {180}^{o}</math>
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* <math>\angle A + \angle C = \angle B + \angle D = {180}^{o} </math> This property is both sufficient and necessary, and is often used to show that a quadrilateral is cyclic.
 
* <math>\angle ABD = \angle ACD</math>
 
* <math>\angle ABD = \angle ACD</math>
 
* <math>\angle BCA = \angle BDA</math>
 
* <math>\angle BCA = \angle BDA</math>
* <math>\angle BAC = \angle BDA</math>
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* <math>\angle BAC = \angle BDC</math>
 
* <math>\angle CAD = \angle CBD</math>
 
* <math>\angle CAD = \angle CBD</math>
 
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* All four [[perpendicular bisector|perpendicular bisectors]] are [[concurrent]]. The converse is also true. This intersection is the [[circumcenter]] of the quadrilateral.
  
 
== Applicable Theorems/Formulae ==
 
== Applicable Theorems/Formulae ==
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* [[Ptolemy's Theorem]]
 
* [[Ptolemy's Theorem]]
 
* [[Brahmagupta's formula]]
 
* [[Brahmagupta's formula]]
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[[Category:Definition]]
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[[Category:Geometry]]
  
 
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Revision as of 22:23, 17 May 2022

A cyclic quadrilateral is a quadrilateral that can be inscribed in a circle. While all triangles are cyclic, the same is not true of quadrilaterals. They have a number of interesting properties.

Cyclicquad2.png

Properties

In a quadrilateral $ABCD$:

  • $\angle A + \angle C = \angle B + \angle D = {180}^{o}$ This property is both sufficient and necessary, and is often used to show that a quadrilateral is cyclic.
  • $\angle ABD = \angle ACD$
  • $\angle BCA = \angle BDA$
  • $\angle BAC = \angle BDC$
  • $\angle CAD = \angle CBD$
  • All four perpendicular bisectors are concurrent. The converse is also true. This intersection is the circumcenter of the quadrilateral.

Applicable Theorems/Formulae

The following theorems and formulae apply to cyclic quadrilaterals:

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