Hausdorff dimension: Difference between revisions

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In mathematics, the Hausdorff dimension is a way of defining a fractional area for all dimensional figures such that the dimension describes partially the way that an area moves in the space around it.  For example, a [[plane (geometry)|plane]] would have a Hausdorff dimension of 2.  However, it wouldn't make sense to give the [[Sierpinski triangle]] [[fractal]] a dimension of 2, since it doesn't fully occupy the 2-dimensional realm.  Therefore, its Hausdorff dimension describes it mathematically, creating a relationship between the number of new self-similar sections and their scale.
In mathematics, the Hausdorff dimension is a way of defining a fractional area for all dimensional figures such that the dimension describes partially the way that an area moves in the space around it.  For example, a [[plane (geometry)|plane]] would have a Hausdorff dimension of 2.  However, it wouldn't make sense to give the [[Sierpinski triangle]] [[fractal]] a dimension of 2, since it doesn't fully occupy the 2-dimensional realm.  Therefore, its Hausdorff dimension describes it mathematically, creating a relationship between the number of new self-similar sections and their scale.
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Revision as of 03:12, 31 October 2007

In mathematics, the Hausdorff dimension is a way of defining a fractional area for all dimensional figures such that the dimension describes partially the way that an area moves in the space around it. For example, a plane would have a Hausdorff dimension of 2. However, it wouldn't make sense to give the Sierpinski triangle fractal a dimension of 2, since it doesn't fully occupy the 2-dimensional realm. Therefore, its Hausdorff dimension describes it mathematically, creating a relationship between the number of new self-similar sections and their scale.