# "Neurons #5" fractal, part of the Mandelbrot set. [Exact location in M-set: centre ...

April 14, 2010

"Neurons #5" fractal, part of the Mandelbrot set. [Exact location in M-set: centre 2.68254503e-1 + 3.62449166e-3i; max. iterations: 6,000; view radius 5.473821e-8.] As the image is enlarged--the picture going deeper and deeper into the region near the boundary of the Mandelbrot set itself (black bits)--we see infinitely many fabulous patterns, including miniature copies of the whole set, spidery filaments, pools and lagoons of color, devilish pitchforks and complicated spirals. This image was made using the KPT Fractal Explorer plug-in for Adobe Photoshop. The colors have been chosen to emphasize the structure and detail of the M-set, rather than to make an artistic statement.

More about Fractals Mathematician Benoit Mandelbrot introduced a set of equations in 1975, which impressed artists more than scientists. That's because his equations--called fractals--become amazing geometrical pictures. The Mandelbrot set is a fractal.

Fractals are self-similar structures, containing patterns within patterns. Fractal-like structures are found in nature in clouds, mountain ranges and coastlines. In fractals, the basic shape occurs infinitely many times in the set, an example of the self-similarity of fractals. If you were to magnify a fractal, it would reveal small scale details similar to the large scale characteristics. However, at magnified scales, the small scale details would not be identical to the whole. In fact, the Mandelbrot set is infinitely complex, yet the process of generating it is based on an extremely simple equation involving complex numbers.

The Mandelbrot set is a mathematical set, a collection of numbers. These numbers are different than the real numbers that you use in everyday life. They are complex numbers. Complex numbers have a real part plus an imaginary part. The real part is an ordinary number, for example -2. The imaginary part is a real number times a special number called i, for example 3i. An example of a complex number would be -2Â°+Â°3i.

More about Fractals Mathematician Benoit Mandelbrot introduced a set of equations in 1975, which impressed artists more than scientists. That's because his equations--called fractals--become amazing geometrical pictures. The Mandelbrot set is a fractal.

Fractals are self-similar structures, containing patterns within patterns. Fractal-like structures are found in nature in clouds, mountain ranges and coastlines. In fractals, the basic shape occurs infinitely many times in the set, an example of the self-similarity of fractals. If you were to magnify a fractal, it would reveal small scale details similar to the large scale characteristics. However, at magnified scales, the small scale details would not be identical to the whole. In fact, the Mandelbrot set is infinitely complex, yet the process of generating it is based on an extremely simple equation involving complex numbers.

The Mandelbrot set is a mathematical set, a collection of numbers. These numbers are different than the real numbers that you use in everyday life. They are complex numbers. Complex numbers have a real part plus an imaginary part. The real part is an ordinary number, for example -2. The imaginary part is a real number times a special number called i, for example 3i. An example of a complex number would be -2Â°+Â°3i.

**Topics:**Fractal, Fractals, Mathematics, Fractal lake, Tricorn, Complex number, Mandelbrot set, Self-similarity, Benoit Mandelbrot

comments powered by Disqus