Course Overview: In these lectures we define Riemann integration and study its properties, including a proof of the Fundamental Theorem of Calculus. This gives us the tools to justify term-by-term differentiation of power series and deduce the elementary properties of the trigonometric functions.
Learning Outcomes: At the end of the course students will be familiar with the construction of an integral from fundamental principles, including important theorems. They will know when it is possible to integrate or differentiate term-by-term and be able to apply this to, for example, trigonometric series.
Course Synopsis: Step functions, their integral, basic properties. Minorants and majorants of bounded functions on bounded intervals. Definition of Riemann integral. Elementary properties of Riemann integrals: positivity, linearity, subdivision of the interval.
The application of uniform continuity to show that continuous functions are Riemann integrable on closed bounded intervals; bounded continuous functions are Riemann integrable on bounded intervals.
The Mean Value Theorem for Integrals. The Fundamental theorem of Calculus; integration by parts and by substitution.
The interchange of integral and limit for a uniform limit of integrable functions on a bounded interval. Term-by-term integration and differentiation of a (real) power series (interchanging limit and derivative for a series of functions where the derivatives converge uniformly).