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https://en.wikipedia.org/wiki/Conic_section '''Conic Sections''']
 
=====Description=====
 
A [https://en.wikipedia.org/wiki/Cone '''Cone'''] can be described as the '''[[Loci|Locus]]''' of all lines joining points on the circumference of a '''‘Base Circle’''' to a point, or '''‘Apex’''', above it.  If the Apex lies perpendicularly above the centre of the base circle it is known as a '''''‘right cone’''''' and if not, it is an '''''‘oblique cone’'''''.
 
 
A '''right circular cone''' is a [https://en.wikipedia.org/wiki/Solid_of_revolution '''Solid of Revolution'''] and can be produced by rotating a right angle triangle around one of the sides opposite its [https://en.wikipedia.org/wiki/Hypotenuse hypotenuse]. The hypotenuse generates the surface of a cone as it sweeps round the central '''‘Axis’'''. Any line joining the Apex to the Base Circle is known as a '''‘Generator’'''. Generators can continue through the Apex to produce a second cone opposite to the first, creating a '''‘Double Cone,’''' and each Cone could extend beyond he Base Circles to infinity.
 
 
A right circular cone can be sliced across in various ways to produce a number of [https://en.wikipedia.org/wiki/Conic_section '''Conic Sections''']. These are curves with particular mathematical properties and which are used in engineering design - e.g. [[Displacement Diagram|cam profiles]] and [[Arch Variations|arch bridge]] design.
 
 
=====Constructions=====
{|
|-
| '''[[Ellipse]]'''
| <span style="color:#B00000">
* The curve produced when a secton is taken across a right circular cone at an angle to the base circle, and intersecting the generators on both sides.
* Ellipses are a ''closed curve'' with a ''Major Axis'' and a ''Minor Axis''.
* An Ellipse is also the result of taking a section across a [https://en.wikipedia.org/wiki/Cylinder_%28geometry%29 '''Cylinder'''] at at angle to its base.
* Ellipses describe the orbits of planets and the curve has been used to design [https://en.wikipedia.org/wiki/Arch Arch Bridges].
* Ellipses can be drawn as '''[[Loci]]''' with an '''[[Conics|Eccentricity]]''' of less than 1 ''(i.e. the Locus of all points where the ratio of distances from its '''[[Conics|Focus]]''' and '''[[Conics|Directrix]]''' are a constant which is less than 1)''   
| [[File:Conics-ElipseTrans.png|300px|right]]
|-
| '''[[Parabola]]'''
| <span style="color:#B00000">
* The curve produced when a secton is taken through a right circular cone parallel to the generator.
* A Parabola describes the path taken by a object thrown into the air and the curve has been used to design [https://en.wikipedia.org/wiki/Arch Arch Bridges].
* Parabolas can be drawn as '''[[Loci]]''' with an '''[[Conics|Eccentricity]]''' equal to 1 ''(i.e. the Locus of all points where the ratio of distances from its '''[[Conics|Focus]]''' and '''[[Conics|Directrix]]''' are a constant which is equal to 1)''   
| [[File:Conics-ParabolaTrans.png |300px|right]]
|-
| [https://en.wikipedia.org/wiki/Hyperbola '''Hyperbola''']
| <span style="color:#B00000">
* The curve produced when a secton is taken which cuts both parts of a Double Cone but does not pass through the Apex ''(e.g. parallel to Axis as shown)'' - note that with a Double Cone, two Hyperbolae are created.
* Hyperbolae describe the paths taken by non-orbiting comets or the shadow cast on a sun dial for example.
* An Hyperbola can be drawn as a '''[[Loci|Locus]]''' with an '''[[Conics|Eccentricity]]''' greater than 1 ''(i.e. the Locus of all points where the ratio of distances from its '''[[Conics|Focus]]''' and '''[[Conics|Directrix]]''' are a constant which is greater than 1)''   
| [[File:Conics-HyperbolaTrans.png|300px|right]]
|-
| '''[[Circles|Circle]]'''
| <span style="color:#B00000">
* The curve produced when a secton is taken across a right circular cone parallel to the base circle.
* The circle can be considered as a fourth type of conic section  ''(as it was by [https://en.wikipedia.org/wiki/Apollonius_of_Perga '''Apollonius'''])'' or as a special case of ellipse.
* The part of a cone ''(or [https://en.wikipedia.org/wiki/Pyramid_%28geometry%29 '''Pyramid'''])'' lying between two parallel planes such as this is called the [https://en.wikipedia.org/wiki/Frustum '''Frustrum''']
| [[File:Conics-Circle.png |300px|right]]
|-
| [https://en.wikipedia.org/wiki/Triangle '''Triangle''']
| <span style="color:#B00000">
* Included for completeness, triangles are created when a section is taken through the Apex and across the Base Cicle diameter.
* Either an [https://en.wikipedia.org/wiki/Isosceles_triangle '''Isosceles'''] or [https://en.wikipedia.org/wiki/Equilateral_triangle '''Equilaterial Triangle'''] is revealed when a Right Cone is halved in this way. Other triangles would result from similar sectioning of an Oblique Cone. 
| [[File:Conics-TriangleTrans.png|300px|right]]
|}
 
 
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Latest revision as of 18:55, 2 June 2016

ConicSections.jpg


Description

A Cone can be described as the Locus of all lines joining points on the circumference of a ‘Base Circle’ to a point, or ‘Apex’, above it. If the Apex lies perpendicularly above the centre of the base circle it is known as a ‘right cone’ and if not, it is an ‘oblique cone’.


A right circular cone is a Solid of Revolution and can be produced by rotating a right angle triangle around one of the sides opposite its hypotenuse. The hypotenuse generates the surface of a cone as it sweeps round the central ‘Axis’. Any line joining the Apex to the Base Circle is known as a ‘Generator’. Generators can continue through the Apex to produce a second cone opposite to the first, creating a ‘Double Cone,’ and each Cone could extend beyond he Base Circles to infinity.


A right circular cone can be sliced across in various ways to produce a number of Conic Sections. These are curves with particular mathematical properties and which are used in engineering design - e.g. cam profiles and arch bridge design.


Constructions
Ellipse
  • The curve produced when a secton is taken across a right circular cone at an angle to the base circle, and intersecting the generators on both sides.
  • Ellipses are a closed curve with a Major Axis and a Minor Axis.
  • An Ellipse is also the result of taking a section across a Cylinder at at angle to its base.
  • Ellipses describe the orbits of planets and the curve has been used to design Arch Bridges.
  • Ellipses can be drawn as Loci with an Eccentricity of less than 1 (i.e. the Locus of all points where the ratio of distances from its Focus and Directrix are a constant which is less than 1)
Conics-ElipseTrans.png
Parabola
  • The curve produced when a secton is taken through a right circular cone parallel to the generator.
  • A Parabola describes the path taken by a object thrown into the air and the curve has been used to design Arch Bridges.
  • Parabolas can be drawn as Loci with an Eccentricity equal to 1 (i.e. the Locus of all points where the ratio of distances from its Focus and Directrix are a constant which is equal to 1)
Conics-ParabolaTrans.png
Hyperbola
  • The curve produced when a secton is taken which cuts both parts of a Double Cone but does not pass through the Apex (e.g. parallel to Axis as shown) - note that with a Double Cone, two Hyperbolae are created.
  • Hyperbolae describe the paths taken by non-orbiting comets or the shadow cast on a sun dial for example.
  • An Hyperbola can be drawn as a Locus with an Eccentricity greater than 1 (i.e. the Locus of all points where the ratio of distances from its Focus and Directrix are a constant which is greater than 1)
Conics-HyperbolaTrans.png
Circle
  • The curve produced when a secton is taken across a right circular cone parallel to the base circle.
  • The circle can be considered as a fourth type of conic section (as it was by Apollonius) or as a special case of ellipse.
  • The part of a cone (or Pyramid) lying between two parallel planes such as this is called the Frustrum
Conics-Circle.png
Triangle
  • Included for completeness, triangles are created when a section is taken through the Apex and across the Base Cicle diameter.
  • Either an Isosceles or Equilaterial Triangle is revealed when a Right Cone is halved in this way. Other triangles would result from similar sectioning of an Oblique Cone.
Conics-TriangleTrans.png


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