This paper introduces functional programming to the numerical methods community with the aim of popularizing this programming paradigm through a deeper appreciation for function as a mathematical concept and, at the same time, for its practical benefits. The functional language HASKELL is chosen amongst several choices because of its lazy evaluation strategy and high-performance compiler WinGHCi. We demonstrate the elegance and versatility of HASKELL by coding HASKELL programs to implement well-known numerical methods.

The concept of infinity pervades much of modern mathematics. Even elementary school students use the word infinity. However, what do we mean by infinity? While, for many infinity merely means either very large or not finite, in various contexts, the term infinity carries more information. Here we consider infinity in the contexts of cardinality (sizes of sets), ordinals (the order of numbers), and real numbers (a number system). Our aim is to introduce these various notions of infinity to interested mathematics students and whet their appetite for more. To accomplish this, we have included three online applets for readers to consider when teaching or learning about mappings from between natural and rational numbers.

This article explores the use of wikis to support student inquiry in large classes. The traditional tools of inquiry-based learning, such as group work and in-class presentations, are described and their applicability to large classes is assessed. Online learning management systems, and Wikis in particular, can help to address issues of scale and meet instructor needs. Wikis offer a unique collaborative space for writing, and this article surveys the uses and benefits of wikis. In particular, issues of anonymity, stereotype threat, and inclusivity are addressed. These observations were made while using MediaWiki to support student inquiry in a multivariable calculus course.

Although Vietnamese secondary students are quite good in solving problems with given mathematical models or partial modelling, but they feel difficult in creating their own mathematical models to solve non-routine realistic problems. Influenced by a focus on modelling with computer-based mathematical tools (CBMT), we will try to describe and give some situations that involved Vietnamese students in setting up and using models to solve real-world problems. We introduced the cycle of modelling with exponential and sinusoidal functions by using Microsoft Excel (2007) and GSP (version 5) as computer-based mathematical tools. In this article, we use Microsoft Excel as an automatically CBMT to set up exponential model, and the GSP as dynamically CBMT to make sinusoidal model. The results showed that setting up models with CBMT created an active learning environment in the mathematics classrooms and secondary students to construct a specific cycle with some concrete steps to solve real-life problems.

The special linear group $SL(2,\mathbb{R})$, the group of $2 × 2$ real matrices with determinant one, is one of the most important and fundamental mathematical objects not only in mathematics but also in physics. In this paper, we propose a three-dimensional model of $SL(2, \mathbb{R})$ in $\mathbb{R}^3,$ which is realized by embedding $SL(2,\mathbb{R})$ into the unit $3$-sphere. In this model, the set of symmetric matrices of $SL(2,\mathbb{Z})$ forms a hyperbolic pattern on the unit disk, like the islands floating on the sea named $SL(2,\mathbb{R}).$ The structure of this hyperbolic pattern is described in the upper half-plane $H.$ The upper half-plane $H$ also enables us to generate symmetric matrices of $SL(2,\mathbb{R})$ with three circles. Furthermore, the well-known fact $H = SL(2, \mathbb{R})/SO(2)$ is visualized as $S^1$ fibers of Hopf fibration in the unit $3$-sphere. With this three-dimensional model in $\mathbb{R}^3,$ we can have a concrete image of $SL(2,\mathbb{R})$ and its noncommutative group structure. This kind of visualization might bring great benefits for the readers who have background not only in mathematics, but also in all areas of science.

In this note we prove some elementary results of Cauchy’s mean value theorem. The main tools employed to get these are auxiliary functions.