 Fun arithmetic with the number nine. |  Fun arithmetic with the number seven. |  A magic square. All rows, columns, and diagonals have the same sum. |
 The ratio of the circumference of a circle to its diameter is pi. Pi is transcendental, i.e., irrational and non-algebraic. |  Area and volume formulas. Archimedes solved the sphere. |  Pi, expressed as an infinite series and an infinite product. |
 The sum of the numbers from 1 to n. |  The product of the numbers from 1 to n is n factorial. |  Stirling's approximation of n factorial. Euler's gamma function gives factorials for integers but has surprising values for fractions. |
 A prime number is divisible only by one and itself. The sieve of Eratosthenes finds primes. |  The prime number theorem of Gauss and Legendre approximates the number of primes less than x. |  The zeta function of Euler and Riemann, expressed as an infinite series and a curious product over all primes. |
 The binomial theorem expands powers of sums. The binomial coefficient is the number of ways to choose k objects from a set of n objects, regardless of order. |  Pascal's triangle shows the binomial coefficients. |  Proof that the square root of two is irrational. |
 The quadratic equation defines a parabola. |  The Pythagorean theorem. A proof by rearrangement. |  The trigonometric functions. Another form of the Pythagorean theorem. |
 The golden ratio, phi. The ratio of a whole to its larger part equals the ratio of the larger part to the smaller. phi is irrational and algebraic. |  The golden rectangle, a classical aesthetic ideal. Cutting off a square leaves another golden rectangle. A logarithmic spiral is inscribed. |  The pentagram contains many pairs of line segments that have the golden ratio. |
 The golden ratio, expressed as a continued fraction. |  Each Fibonacci number is the sum of the previous two. The number of spirals in a sunflower or a pinecone is a Fibonacci number. |  The ratio of successive Fibonacci numbers approaches the golden ratio. An exact formula for the nth Fibonacci number. |
 Napier's constant, e, is the base of natural logarithms and exponentials. e is transcendental. |  Calculus, developed by Newton and Leibniz, is based on derivatives (slopes) and integrals (areas) of curves. The derivative of ex is ex. The integral of ex is ex. |  e, expressed as a limit and an infinite series. |
 Euler's formula relating exponentials to sine waves. A special case relating the numbers pi, e, and the imaginary square root of -1. |  The Gaussian or normal probability distribution is a bell-shaped curve. |  Gibbs's vector cross product. Del operates on scalar and vector fields in 3D, quad in 4D. |
 The five regular polyhedra. Euler's formula for the number of vertices, edges, and faces of any polyhedron. |  The hypercube. Schläfli's formula for vertices, edges, faces, and cells of any 4-dimensional polytope. |  The Möbius strip has only one side. The Klein bottle's inside is its outside. |
 Fractals of Mandelbrot, Koch, and Sierpinski have infinite levels of detail. |  Cantor's proof that the infinity of real numbers is greater than the infinity of integers. |  Gödel proved that if arithmetic is consistent, it must be incomplete, i.e., it has true propositions that can never be proved. |
Keith Enevoldsen's Think Zone
No comments:
Post a Comment