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Length of coast : ウィキペディア英語版
How Long Is the Coast of Britain? Statistical Self-Similarity and Fractional Dimension

"How Long Is the Coast of Britain? Statistical Self-Similarity and Fractional Dimension" is a paper by mathematician Benoît Mandelbrot, first published in ''Science'' in 1967.〔Benoît Mandelbrot (1967). "How Long Is the Coast of Britain? Statistical Self-Similarity and Fractional Dimension", ''Science,'' New Series, Vol. 156, No. 3775. (May 5, 1967), pp. 636-638. 〕 In this paper Mandelbrot discusses self-similar curves that have Hausdorff dimension between 1 and 2. These curves are examples of ''fractals'', although Mandelbrot does not use this term in the paper, as he did not coin it until 1975. The paper is one of Mandelbrot's first publications on the topic of fractals.〔"Dr. Mandelbrot traced his work on fractals to a question he first encountered as a young researcher: how long is the coast of Britain?": Benoit Mandelbrot (1967). "(Benoît Mandelbrot, Novel Mathematician, Dies at 85 )", ''The New York Times''.〕
==Overview==
The paper examines the coastline paradox: the property that the measured length of a stretch of coastline depends on the scale of measurement. Empirical evidence suggests that the smaller the increment of measurement, the longer the measured length becomes. If one were to measure a stretch of coastline with a yardstick, one would get a shorter result than if the same stretch were measured with a one-foot (30cm) ruler. This is because one would be laying the ruler along a more curvilinear route than that followed by the yardstick. The empirical evidence suggests a rule which, if extrapolated, shows that the measured length increases without limit as the measurement scale decreases towards zero.
This discussion implies that it is meaningless to talk about the length of a coastline; some other means of quantifying coastlines are needed. Mandelbrot discusses an empirical law discovered by Lewis Fry Richardson, who observed that the measured length ''L''(''G'') of various geographic borders was a function of the measurement scale ''G''. Collecting data from several different examples, Richardson conjectured that ''L''(''G'') could be closely approximated by a function of the form
:L(G)=MG^
where ''M'' is a positive constant and ''D'' is a constant, called the dimension, greater than or equal to 1. Intuitively, if a coastline looks smooth it should have dimension close to 1; and the more irregular the coastline looks the closer its dimension should be to 2. The examples in Richardson's research have dimensions ranging from 1.02 for the coastline of South Africa to 1.25 for the West coast of Britain.
Mandelbrot then describes various mathematical curves, related to the Koch snowflake, which are defined in such a way that they are strictly self-similar. Mandelbrot shows how to calculate the Hausdorff dimension of each of these curves, each of which has a dimension ''D'' between 1 and 2 (he also mentions but does not give a construction for the space-filling Peano curve, which has a dimension exactly 2). He notes that the approximation of these curves with segments of length ''G'' have lengths of the form G^. The resemblance with Richardson's law is striking. Note that the paper does not claim that any coastline or geographic border actually ''has'' fractional dimension. Instead, he notes that Richardson's empirical law is compatible with the idea that geographic curves, such as coastlines, can be modelled by random self-similar figures of fractional dimension.
Near the end of the paper Mandelbrot briefly discusses how one might approach the study of fractal-like objects in nature that look random rather than regular. For this he defines statistically self-similar figures and says that these are encountered in nature.
The paper is important because it is a "turning point" in Mandelbrot's early thinking on fractals.〔"What is the essence of a coastline, for example ? Mandelbrot asked this question in a paper that became a turning point for his thinking: 'How Long Is the Coast of Britain'": James Gleick (1988) ''Chaos: Making a New Science'', p.94. ISBN 978-0747404132.〕 It is an example of the linking of mathematical objects with natural forms that was a theme of much of his later work.

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