Difference between revisions of "Roulette"

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=== Hypotrochoid ===
 
=== Hypotrochoid ===
A '''[[hypotrochoid]]''' is any roulette in which both the rolling curve and the fixed curve are circles and the rolling circle is on the INSIDE of the fixed circle. The pole can be on the <balloon title="Hypocycloid" style="color:blue">
+
A '''[[hypotrochoid]]''' is any roulette in which both the rolling curve and the fixed curve are circles and the rolling circle is on the INSIDE of the fixed circle. The pole can be on the <balloon title="Hypocycloid" style="color:green">
 
edge
 
edge
</balloon>, <balloon title="Curtate Hypocycloid" style="color:blue">
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</balloon>, <balloon title="Curtate Hypocycloid" style="color:green">
 
inside
 
inside
</balloon>, or <balloon title="Prolate Hypocycloid" style="color:blue">
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</balloon>, or <balloon title="Prolate Hypocycloid" style="color:green">
 
outside
 
outside
 
</balloon> of the rolling circle.
 
</balloon> of the rolling circle.
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=== Epitrochoid ===
 
=== Epitrochoid ===
An '''epitrochoid''' is any roulette in which both the rolling and the fixed curve are circles and the rolling circle is on the OUTSIDE of the fixed circle. Like in the previous cases, the pole can be on the <balloon title="Epicycloid" style="color:blue">
+
An '''epitrochoid''' is any roulette in which both the rolling and the fixed curve are circles and the rolling circle is on the OUTSIDE of the fixed circle. Like in the previous cases, the pole can be on the <balloon title="Epicycloid" style="color:green">
 
edge
 
edge
</balloon>, <balloon title="Curtate Epiycloid" style="color:blue">
+
</balloon>, <balloon title="Curtate Epiycloid" style="color:green">
 
inside
 
inside
</balloon>, or <balloon title="Prolate Epicycloid" style="color:blue">
+
</balloon>, or <balloon title="Prolate Epicycloid" style="color:green">
 
outside
 
outside
 
</balloon> of the rolling circle.
 
</balloon> of the rolling circle.
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<br><br>
 
<br><br>
  
It is easy to imagine a nickel rolling on the floor, but how can we imagine a square rolling a on a bumpy road? Professor Stan Wagon of Macalester College created a square-wheeled tricycle and demonstrated that it is possible for square wheels to work. Below is a short video that shows how this tricycle works. For more information go to [[http://www.macalester.edu/mathcs/SquareWheelBike.html]]
+
It is easy to imagine a nickel rolling on the floor, but how can we imagine a square rolling a on a bumpy road? Professor Stan Wagon of Macalester College created a square-wheeled tricycle and demonstrated that it is possible for square wheels to work. Below is a short video that shows how this tricycle works. For more information go to [[http://www.macalester.edu/mathcs/SquareWheelBike.html| Macalester Math and Science]]
 
{{#ev:tubechop|jchrQqH6bT0&start=45&end=60|425|left}}  
 
{{#ev:tubechop|jchrQqH6bT0&start=45&end=60|425|left}}  
  

Revision as of 09:19, 1 June 2009


Roulette
Roulette.jpg
Field: Geometry
Image Created By: Wolfram MathWorld
Website: Wolfram MathWorld

Roulette

Four different roulettes formed by rolling four different shapes through one fixed point.


Basic Description

Suppose you see a nickel rolling on the sidewalk. Imagine a pen traced the path path of one fixed point on the coin as it rolled. A curve would be created. This curve is called a roulette. The example is depicted below:

Cycloid animated.gif      [[1]]

However, a roulette is not restricted to straight lines and circles. The rolling curve can range from a line to a parabola to a decagon. Similarly, the surface on which this curve rolls on does not have to be a line. It can be a parabola as well, or a circle, among many others. There are a few restrictions that apply:

  • The curve that is not rolling must remain fixed.
  • The point on the rolling curve must remain fixed.
  • Both curves must be differentiable.
  • The curves must be tangent at one point at all times.


There are numerous cases of different roulettes; the most common ones have been named. A few of these have been listed below:

Trochoid

A trochoid is any roulette in which the fixed curve is a line and the rolling curve is a circle.When the pole is on the edge of the rolling circle, then the roulette is called a cycloid. If the pole is inside the rolling circle, then the curve produced is called a curtate cycloid. If the pole is on the outside of the rolling circle, then the curve produced is called a prolate cycloid.

Example of a curtate cycloid

Curtatecycloid.gif
Cycloidc.gif


Hypotrochoid

A hypotrochoid is any roulette in which both the rolling curve and the fixed curve are circles and the rolling circle is on the INSIDE of the fixed circle. The pole can be on the edge , inside , or outside of the rolling circle.

Example of a hypocycloid

Hipoc.gif
Hypotrochoid2 2.gif


Epitrochoid

An epitrochoid is any roulette in which both the rolling and the fixed curve are circles and the rolling circle is on the OUTSIDE of the fixed circle. Like in the previous cases, the pole can be on the edge , inside , or outside of the rolling circle.

Example of an epicycloid

Epicycloid.gif
Epicycloid2.gif


Catenary

Explanation Pending

Involute

An involute is a more complicated roulette in which the rolling curve is a line, and the fixed curve is any curve. The pole, or fixed point on the rolling curve, can be anywhere on the line. In the case of the involute, the line acts as an imaginary string (ending at the pole) and as the line rolls, the string winds in around the curve. The pattern traced by the pole is the roulette.

Example of an involute with a circle as the fixed curve

Involute.gif

















Interesting Application of the Concept

The above roulettes are only a few of many different types of this curve. The main image of the page demonstrates that the fixed curve can be a catenary and the rolling curve does not need to be a circle but can be a polygon with sharp edges.

Below are a few examples of this concept:

Roll4gon.gif
Roll6gon.gif



It is easy to imagine a nickel rolling on the floor, but how can we imagine a square rolling a on a bumpy road? Professor Stan Wagon of Macalester College created a square-wheeled tricycle and demonstrated that it is possible for square wheels to work. Below is a short video that shows how this tricycle works. For more information go to [Macalester Math and Science]

EmbedVideo does not recognize the video service "tubechop".






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