Benoit Mandelbrot died; mandelbrot set

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Xah's Top 10 Math Wonders

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Xah Lee, 2010-10-18

Benoît Mandelbrot, the mathematician who invented fractals, is dead. (1924-2010) He died of cancer. Aged 85.

Mandelset hires

the mandelbrot set.

The mandelbrot set is truely a amazing curiosity. I would rank it top 10 math curiosity in my book. If you only know highschool math, you can get a good explanation at Mandelbrot Set.

Let's see what other curiosity or such i consider in top 10 in my personal learnings of math in my life. In no particular order:


Fractals, Mandelbrot Set. The amazing part is how such system show self-similarity in such weird way and infinitely deep. Try to ask why.

Math Constants

golden ratio line

Golden Ratio

Mathematical constant. The nature of π, e, Golden ratio.

Ptolemy pentagon

Golden ratio in a pentagon.

These are simple to understand, occurs everywhere almost by magic, and their properties, as well as general nature, are elusive. Nobody really understand them. To understand them is like to understand the whole mysteries of math and philosophies of math. For example, on a non-tech aspect, one might say they are not special at all, or why isn't Sqrt[2] special too, or that they are simply arbitrary definitions in a logic system, that our perception of their curiosity, “coincidences”, complexity, are simply one particular aspect of how we perceive a simple system. But these entails the deepest philosophical questions about math.


Golden ration in icosahedron. Each rectangle has side length of golden ratio's a and b.

Cellular Automaton

Cellular Automaton (e.g. Conway's Game of Life, Langton's ant) and any such simple systems (tag system, recursive functions, ...). By Stephen Wolfram's A New Kind of Science, we learned that the properties of such system is basically unknown. This is especially interesting to pure mathematicians from symbolic logic and algorithmic (computer science) aspects. Great Software for Cellular Automata.

Dimensionality and Shape of Space

Dimensionality in math. e.g. Flatland. And also shape of space (n-manifold). It's quite amazing that you could have multi-dimensions. Instead of dealing with a single number, you deal with a array of numbers, and in this way, most math generalize to multi-dimensions. Then, many special concepts in higher dimensions arise (such as Orientability), and what happens to many theories in higher dimensions. I hardly understand this. I always wanted to know, a simple list of all such properties and concepts that does not exist in lower dimensions.

See also: Reading Notes on The Shapes of Space, and non-orientable surfaces and projective plane at: Gallery of Famous Surfaces.

Non-Euclidean Geometry

non-euclidean geometry. Not related, but also interesting is Gauss's Theorema Egregium and Euler characteristic (χ = V - E + F), and Gauss–Bonnet theorem, that connects metric aspects of a surface to the topological aspect. I don't really understand this.

Complex Number

Complex number. Perhaps best embodied in this Euler's identity “e^(i*pi) + 1 = 0” (but i much prefer E^(I*x) == Cos[x]+I*Sin[x]). Particularly interesting is the Sin function. And the subsequent so-called “complex analysis” or “functional analysis”, where, most real-functions are generalized to the complex number field. (See: Geometric Transformation on the Plane.) I always thought, complex numbers are fantastic because they are the algebraic closure, signifying certain ultimate perfection in generalization of real number. However, as i learned by tidbits over the years, complex number is rather just a special construction and isn't that important, useful, or general, in respect to the whole math (e.g. compared to dimensionality; symbolic logic, universal algebra, math constants, or linear algebra or calculus).

Group Theory and Universal Algebra, Symbolic Logic

The invention of group theory, and later modern algebra, Universal algebra, that studies structural aspects of numbers.

When i first learned group theory, i find it quite amazing how it captures the number 0 and 1. They are identities by different operations, are the 2 pillars of a number system. From which, you have inverses. Also, it is quite amazing that group theory in some sense, or by definiton, is simply a theory about symmetry! Symmetry is almost a non-descript, visual and perceptual phenomenon, of patterns, but amazingly, when you try to get the essence of it, it is symbols and permutations — group theory! (See: Introduction To Symmetry)

Then, group theory got expanded to modern algebra, of rings and fields. I never find anything attractive about rings and fields or other more complex structures. But i do find the direction of reduction fascinating. Monoids, semigroup, magma, and the whole systematic investigation of their system, e.g. universal algebra.

On the other hand, computation leads to studies of algorithms. Even groups and algorithms are both descrete, but they represent i think a deep question in math, not sure if there's a name. Namely: What Is vs How To. And much studies of logic invest these connections, even at philosophical level.

Cantor's Set Theory

Cantor's set theory, that infinite sets can be compared. When i first learned this, it sent a chill down my spine. Transfinite number. Algebraic numbers, and the fact that most real numbers are non-algebraic numbers.

Another item sent a chill down my spine is when i first learned is the Fundamental theorem of calculus.

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