Chapter 0: The Language of Mathematics

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Page ID: 146868

Roy Simpson
Cosumnes River College

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The development of mathematics from the ground up is an astounding feat that is still unfinished and will never be. There is more that goes into creating the concepts and structures of the subject than most people could ever fathom. To complicate matters, the historical and conceptual development of mathematics have followed completely different paths.

The historical development of mathematics is full of odd leaps in knowledge and vast lengths of time with little development. Some very advanced mathematical concepts came about long before some elementary ones. For example, Calculus, arguably a very challenging field of study relying on mastery of Arithmetic, Algebra, and Trigonometry, was developed during the 17^th century. However, this was nearly 200 years before the development of the complex number system and almost 300 years before the modern multiplication symbol, \( \times \), was created (1902).

This nonlinear development is because mathematics has historically been driven by application and necessity rather than philosophy. This ebb and flow of mathematical concepts throughout time makes writing a textbook based upon when an idea was discovered impossible.

The conceptual development of mathematics is how we will approach learning Trigonometry. We will develop mathematics at a pace and in such a way that concepts will naturally lead to the next set of consequences. Upon this framework, we will place the usefulness of our concepts. That is, we will apply our knowledge to real-world problems.

It will seem, at times, that Trigonometry is full of definitions and theorems;¹ however, the definitions will be used enough to become part of our natural language, and we will concentrate on understanding why mathematics works the way it does so that theorems become "obvious" results rather than obscure mysteries. We will not allow ourselves to become intimidated by what many believe to be a "cold, lifeless subject." Instead, we will embrace how we can use this knowledge to open ourselves to a better, more robust understanding of our world. I hope this textbook enhances your worldview and enables you to apply critical thinking and analysis to many facets of your life.

With all that said, let us put on our thinking caps and prepare to become philosophers. We are going to figure out what makes mathematics so beautiful and true. This exercise will require brain power and creativity.

Footnotes

¹ We will talk about what theorems and definitions are momentarily.

0.1: Definitions
This section introduces the student to the foundational concept of a definition. While simple in concept, mathematics (and language) would not exist without such a crucial structure.
0.2: Axioms, Theorems, and Proofs
0.3: Operations
0.4: Simplifying
0.5: Theory versus Application
0.6: The Mathematical Mantra

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