Henon Attractor
From Math Images
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[[Image:Henon2.jpg|right|thumb|Original Henon Attractor, a = 1.4, b = 0.3]] | [[Image:Henon2.jpg|right|thumb|Original Henon Attractor, a = 1.4, b = 0.3]] | ||
- | The Henon system can be described as [[Chaos|chaotic]] and random. However, the system does have structure in that its points settle very close to an underlying pattern called a | + | The Henon system can be described as [[Chaos|chaotic]] and random. However, the system does have structure in that its points settle very close to an underlying pattern called a <balloon title="In this chaotic system, points are in fact over time evolving towards a recognizable structure that is called the chaotic attractor."> chaotic attractor></balloon> or <balloon title="" basin of attraction></balloon>. The basic Henon Attractor can be described by the equations: |
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==Changing "a" and "b"== | ==Changing "a" and "b"== | ||
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- | Although the original Henon Attractor uses the values ''a'' = 1.4 and ''b'' = 0.3, we can alter those values within a range to produce various-looking Henon Attractors. As we can see below, | + | Although the original Henon Attractor uses the values ''a'' = 1.4 and ''b'' = 0.3, we can alter those values within a range to produce various-looking Henon Attractors. As we can see below, ''a'' and ''b'' are limited to the range of values outside of which the fractal ceases to resemble the Henon Attractor. |
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Image:Henon.jpg|a = 1; b = 0.542 | Image:Henon.jpg|a = 1; b = 0.542 | ||
Image:Henon_a1.2_b0.3.png|a = 1.2; b = 0.3 | Image:Henon_a1.2_b0.3.png|a = 1.2; b = 0.3 | ||
- | Image:Henon_a1.3_b0.3.png|a = 1.3; b = 0.3 (points | + | Image:Henon_a1.3_b0.3.png|a = 1.3; b = 0.3 (points need to be enlarged) |
Image:Henon_a1.4_b0.3.png|a = 1.4; b = 0.3 | Image:Henon_a1.4_b0.3.png|a = 1.4; b = 0.3 | ||
Image:Henon_a1.5_b0.2.png|a = 1.5; b = 0.2 | Image:Henon_a1.5_b0.2.png|a = 1.5; b = 0.2 |
Revision as of 13:57, 8 July 2009
- This image is a Henon Attractor (named after astronomer Michel Hénonn), which is a fractal in the division of the chaotic strange attractor. The Henon Attractor emerged from Hénon's attempt to model the orbits of celestial objects.
Henon Attractor |
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Contents |
Basic Description
The Henon Attractor is a special kind of fractal that belongs in a group called Strange Attractors.
A characteristic of this strange fractal is that it is drawn irregularly. The Henon Attractor is described by two equations. Let us say that we take a starting value (x,y) and apply the equations to the starting values and then the resulting outcome over and over (a process called iteration). If we plot every outcome from this iteration one at a time, we would observe that the points jump from one random location to another within the image. If you take a look at the animation, you can see the irregularity of a number of plotted points. Eventually, the individual points become so numerous that they appear to form lines and an image emerges.
This image results from an iterated function, meaning that the equations that describe it can be applied to itself an infinite amount of times. In fact, if you magnify this image, you would find that the lines (really many, many points) that appear to be single lines on the larger image are actually sets or bundles of lines, who, if magnified closer, are bundles of lines and so on. This property is called self-similarity, which means that even as you look closer and closer into the image, it continues to look the same. In other words, the larger view of the image is similar to a magnified part of the image.
A More Mathematical Explanation
- Note: understanding of this explanation requires: *Algebra
Fractal Properties
The Henon Attractor is often described as being similar to the Cantor Set. Let us zoom into the Henon Attractor near the doubled-tip of the fractal (as seen in the animation). We can see that as we continue to magnify the lines that form the structure of the Henon Attractor, these lines become layers of increasingly deteriorating lines that appear to resemble the Canter Set.
Chaotic System
Fixed Points
Looking at the system of equations that describe the fractal, the Henon Attractor uses only two variables (x and y) that are evaluated into themselves. This results in two equilibrium or fixed points for the attractor. Fixed points are such that if the system of equations are applied to the fixed points, the resulting output would be the same fixed points. Therefore, if the system ever plotted onto the fixed points, the fractal would become stagnant.
The two fixed points of the Henon Attractor must satisfy and .
Using the Henon Attractor's system of equations, the fixed points are (0.6314 , 0.1894) and (-1.1314 , -0.3394).
To solve the system of equations:
If and then
Using the quadratic equation
Using a = 1.4, b = 0.3:
Using y = bx:
Changing "a" and "b"
Here are some more examples of Henon Attractors with different a and b values.
Teaching Materials
- There are currently no teaching materials for this page. Add teaching materials.
About the Creator of this Image
The images created by this author were found on the author's (username SiMet) Picasa Web Album under the category "Computer Art".
References
Glenn Elert, The Chaos Hypertextbook Heinz-Otto Peitgen, Hartmut Jürgens, Dietmar Saupe, Chaos and fractals
Bill Casselman, Simple Chaos-The Hénon Map
www.ibiblio.org Henon Strange Attractors
Future Directions for this Page
A better, less vague description of how sections of the Henon Attractor resembles the Cantor Set
Leave a message on the discussion page by clicking the 'discussion' tab at the top of this image page.