Date |
Sections |
Topics |
Prerequisite Skills |
Student Learning Outcomes
|
Week 1
|
5.1
|
Continuous Functions
|
|
- The definition of a continuous function
- Sequential criterion for continuity
- Discontinuity criterion
|
Week 1/2
|
5.2
|
Combinations of Continuous Functions
|
|
- Sums, differences, products and quotients of continuous functions on the same domain
- Composition of continuous functions
|
Week 2
|
5.3
|
Continuous Functions on Intervals
|
|
- Bounded Functions
- The boundedness theorem on closed and bounded intervals
- Definitions of absolute maximum and absolute minimum of a function
- The maximum-minimum theorem
|
Week 2/3
|
5.3
|
The Intermediate Value Theorem
|
|
- The Location of Roots theorem
- The Intermediate Value Theorem
- The image of a continuous functions on a closed and bounded interval is a closed and bounded interval
|
|
Week 3
|
5.4
|
Uniform Continuity
|
|
- The definition of uniform continuity
- Nonuniform continuity criteria
- Uniform continuity theorem
|
|
Week 3/4
|
5.4
|
Lipschitz Functions
|
|
- Definition of a Lipschitz function
- If a function is Lipschtiz, then it is uniformly continuous
|
|
Week 4
|
5.4
|
The Continuous Extension Theorem
|
|
- Uniform continuity and Cauchy sequences
- The Continuous Extension Theorem
|
|
Week 4/5
|
5.4
|
Approximations of Continuous Functions
|
|
- Definition of a step function
- On closed and bounded intervals, continuous functions can be approximated by piecewise linear functions
- Weierstrass approximation theorem
|
|
Week 5
|
5.5
|
Continuity and Gauges
|
|
- Definition of a partition of an interval
- Definition of a tagged partition of an interval
- Definition of a gauge of an interval
- The existence of delta-fine partitions
|
|
Week 5/6
|
5.6
|
Monotone Functions
|
|
- Monotone functions
- The left and right hand limits for interior points of monotone functions
- Defining the jump pf a function at a point
- For a monotone function on an interval, the set of points at which the function is discontinuous is countable
|
|
Week 6
|
5.6
|
Inverse Functions
|
|
- The continuous inverse theorem
- The nth root function
|
Week 6/7
|
6.1
|
The Derivative
|
|
- Definition of the derivative of a function at a point
- Continuity is required for a function to be differentiable
- The constant, sum, product and quotient rules for derivatives
- Caratheodory's theorem
- The chain rule
|
Week 7
|
6.1
|
Derivatives of Functions with Inverses
|
|
- Relation between continuous, strictly monotone functions and their inverses
|
Week 7/8
|
6.2
|
The Mean Value Theorem
|
|
- Relative maximum and relative minimum of a function
- Interior extremum theorem
- Rolle's Theorem
- The Mean Value theorem
|
Week 8
|
6.2
|
Extrema of a Function
|
|
- Increasing and Decreasing functions
- First Derivative test for extrema
- Applications of the Mean Value Theorem
- The Intermediate Value Property of Derivatives
|
Week 8/9
|
6.3
|
L'Hospital's Rules
|
|
- Intermediate forms
- The Cauchy mean value theorem
- L'Hospital's Rule for limits of the 0/0 form
- L'Hospital's Rule for limits with infinity in the denominator
|
Week 9
|
2.3
|
Taylor's Theorem
|
|
- Taylor's Theorem
- Applications of Taylor's theorem
|
Week 9/10
|
6.4
|
Relative Extrema and Convex Functions
|
|
- Using higher order derivatives to determine where a function has a relative maximum or minimum
- Definition of a convex function
- Determining whether a function is convex using the second derivative
|
Week 10
|
6.4
|
Newton's Method
|
|
- Description of Newton's Method
- Examples of Newton's Method
|
Week 10/11
|
3.1
|
Sequences and Their Limits
|
|
- Definition of the limit of a sequence
- The uniqueness of limits in the real numbers
- Tails of sequences
- Examples of common sequences
|
Week 4
|
3.2
|
The Limit Laws for Sequences
|
|
- Bounded Sequences
- Summation, difference, products, and quotients of sequences
- The squeeze theorem for sequences
- Divergent Sequences
|
Week 4/5
|
3.3
|
Monotone Sequences
|
|
- Increasing and Decreasing sequences
- The Monotone Convergence theorem
- Inductively defined sequences
- The existence of Euler's Number
|
Week 5
|
3.4
|
Subsequences
|
|
- Definition of a Subsequence
- If a sequence converges to limit L, then every subsequence of that sequence also converges to L.
- Definition of a divergent Sequence
- Divergence criteria of a sequence
- Monotone subsequence theorem
|
Week 5
|
3.4
|
The Bolzano Weierstrass Theorem
|
|
- The Bolzano Weierstrass Theorem
- Examples using the Bolzano Weierstrass Theorem
|
Week 5/6
|
3.4
|
The Limit Superior and Limit Inferior
|
|
- Definition of the limit superior and limit inferior
- Equivalent statements defining the limit superior and limit inferior
- A bounded sequence converges if and only if its limit superior equals its limit inferior
|
Week 6
|
3.5
|
The Cauchy Criterion for Convergence
|
|
- Definition of a Cauchy sequence
- A sequence converges if and only if it is a Cauchy sequence
- Contractive sequences
|
Week 6
|
3.6
|
Properly Divergent Sequences
|
|
- Limits that tend to infinity
- Properly divergent sequences
|
Week 6/7
|
3.7
|
Introduction to Infinite Series
|
|
- Sequences of partial sums
- If a series converges, then the sequence of coefficients for that series must converge to zero.
- Examples of common series
- Comparison tests for series
|
Week 12
|
4.1
|
Cluster Points
|
|
- Definition of a cluster point
- The cluster point as the limit of a sequence
|
Week 12
|
4.1
|
The Definition of the Limit of a Function
|
|
- The definition of the limit of a function at a point
- The uniqueness of limits at cluster points
- Examples of limits of functions
|
Week 12/13
|
4.1
|
The Sequential Criterion and Divergence Criteria
|
|
- The sequential criterion for limits of functions at a point
- Divergence criteria for limits
- The signum function
|
Week 13
|
4.2
|
The Limit Theorems for Functions
|
|
- Functions bounded on a neighborhood of a cluster point
- Sums, differences, products, and quotients of limits
- The squeeze theorem for limits of functions
- Examples of Limits using the limit theorems
|
Week 14
|
4.3
|
One Sided Limits
|
|
- The definition of the right and left hand limits of a function at a point
- The sequential criterion for the left and right hand limits
- The limit of a function at a point exists if and only if its left and right hand limits are equal
|
Week 14/15
|
4.3
|
Infinite Limits and Limits at Infinity
|
|
- The definition of an infinite limit
- If the function f is less than the function g on a specified domain and f tends to infinity, then g tends to infinity on this domain as well.
- The definition of a limit has its independent variable approaches infinity
- The sequential criterion for limits at infinity
|