A Proof of Thebault's Theorem
by R. Shail
In the 1938 volume of the MONTHLY the prolific French geometer Victor Thébault posed a problem in Euclidean geometry concerning the collinearity of the incentre of a triangle and the centres of two circles drawn to touch a line through a vertex of the triangle, the opposite side, and the circumcircle. It was not until some 45 years later that an elaborate proof was given. We provide an elementary proof using the methods of Cartesian coordinate geometry. Computer algebra is used to assist with some of the calculations, but no advanced algebraic methods are employed.
The Convergence of an Euler Approximation of an Initial Value Problem is not Always Obvious
by Samer S. Habre, John H. Hubbard, and Beverly H. West
We consider the initial value problem dx / dt = (|x|)1/2 with x (-2) = -1. Uniqueness of solutions fails when x = 0, and there is a continuum of solutions u(t) with u (-2) = -1, for which u (2) takes all the values between 0 and 1. But what about numerical approximations to solutions? Do they converge to a limit as ? No, contrary to the expectation even of many a professional mathematician. We show that as , the Euler approximations approach all the solutions, and how, as , the value uh(2) oscillates between cusp values at 0 and maxima >1.
The Missing Spectral Basis in Algebra and Number Theory
by Garret Sobczyk
The fundamental concept of a spectral basis is missing in elementary mathematics! Beginning with one of the oldest and most venerated theorems in mathematics, the Euclidean Algorithm, we define the spectral basis of the modular numbers, and the spectral basis of the modular polynomials. Using a spectral basis simplifies proofs of elementary results in number theory, in factor rings of polynomials, and in linear algebra, and it gives the classical Lagrange and Hermite interpolation polynomials. While all of our results are well known in advanced mathematics, the concept of a spectral basis makes it possible to teach these ideas at an elementary level. The article is based on the author's experience in teaching this concept to undergraduate students in courses in linear algebra, modern algebra, and finite mathematics at the Universidad de las Américas-Puebla, Mexico.
The Mathematics of Musical Instruments
by Rachel W. Hall and Kresimir Josic
This article highlights several applications of mathematics to the design of musical instruments. In particular, we consider the physical properties of a Norwegian folk instrument called the willow flute. The willow flute relies on harmonics, rather than finger holes, to produce a scale that is related to a major scale. The pitches correspond to fundamental solutions of the one-dimensional wave equation. This "natural" scale is the jumping--off point for a discussion of several systems of scale construction-just, Pythagorean, and equal temperament--that have connections to number theory and dynamical systems and are crucial in the design of keyboard instruments. The willow flute example also provides a nice introduction to the spectral theory of partial differential equations, which explains the differences between the sounds of wind or stringed instruments and drums.
A Simple Slide Rule for Finite Fields
by Holger Schellwat
A General Method for Establishing Geometric Inequalities in a Triangle
by Razvan Alin Satnoianu
A Theorem of D. J. Newman on Euler's Function and Arithmetic Progressions
by J.M. Aldaz, A. Bravo, S. Guitiérrez, and A. Ubis
A Counterexample for the Two-Dimensional Density Function
by Liu Wen
The Remarkable Tetron
by N.S. Astapov and N.C. Noland
PROBLEMS AND SOLUTIONS
The Universal History of Numbers: From Prehistory to the Invention of the Computer.
By Georges Ifrah
Reviewed by Eli Maor
Mathematics: Frontiers and Perspectives.
Edited by V. Arnold, M. Atiyah, P. Lax, and B. Mazur
Reviewed by Harsh V. Pittie