| Date |
Sections |
Topics |
Prerequisite Skills |
Student Learning Outcomes
|
| Week 1
|
1.1
|
Basic Terminology
|
|
- Subsets
- The definition of equality between two sets
- Commonly used sets
|
| Week 1
|
1.1
|
Set Operations
|
|
- Union, intersection and complements of sets
- De Morgans Laws for sets
- Infinite Unions and intersections of sets
|
| Week 1
|
1.1
|
Functions (The Cartesian product definition)
|
|
- The Cartesian Product
- Definition of a function
- Domain and Range in terms of the Cartesian product
- Transformations and Machines
|
| Week 1/2
|
1.1
|
Direct and Inverse Images
|
|
- Definition of the Direct Image
- Definition of the Inverse Image
|
|
| Week 1/2
|
1.1
|
Injective and Surjective Functions
|
|
- Injective functions
- Surjective functions
- Bijective functions
|
|
| Week 1/2
|
1.1
|
Inverse Functions
|
|
- Definition of Inverse functions
- Criteria for an Inverse of a function to exist
|
|
| Week 1/2
|
1.1
|
Composition of Functions
|
|
- Definition of a composition function
- When function composition is defined
|
|
| Week 1/2
|
1.1
|
Restrictions on Functions
|
|
- Define the restriction of a function
- Positive Square Root function
|
|
| Week 2
|
1.2
|
Mathematical Induction
|
|
- Well-ordering principal
- Principal of Mathematical induction
- The principal of Strong Induction
|
|
| Week 2
|
1.3
|
Finite and Infinite Sets
|
|
- Definition of finite and infinite sets
- Uniqueness Theorem
- If T is a subset of S and T is infinite, then S is also infinite.
|
|
| Week 2
|
1.3
|
Countable Sets
|
|
- Countable and Uncountable sets
- The set of rational numbers is countable
- Cantor's Theorem
|
| Week 6/7
|
3.8
|
Implicit Differentiation
|
|
- Assuming, for example, y is implicitly a function of x, find the derivative of y with respect to x.
- Assuming, for example, y is implicitly a function of x, and given an equation relating y to x, find the derivative of y with respect to x.
- Find the equation of a line tangent to an implicitly defined curve at a point.
|
| Week 7
|
3.9
|
Derivatives of Exponential and Logarithmic Functions
|
|
- Find the derivative of functions that involve exponential functions.
- Find the derivative of functions that involve logarithmic functions.
- Use logarithmic differentiation to find the derivative of functions containing combinations of powers, products, and quotients.
|
| Week 7/8
|
4.1
|
Related Rates
|
|
- Express changing quantities in terms of derivatives.
- Find relationships among the derivatives in a given problem.
- Use the chain rule to find the rate of change of one quantity that depends on the rate of change of other quantities.
|
| Week 8
|
4.2
|
Linear Approximations and Differentials
|
|
- Approximate the function value close to the center of the linear approximation using the linearization.
- Given an expression to be evaluated/approximated, come up with the function and its linearization
- Understand the formula for the differential; how it can be used to estimate the change in the dependent variable quantity, given the small change in the independent variable quantity.
- Use the information above to estimate potential relative (and percentage) error
|
| Week 8/9
|
4.3
|
Maxima and Minima
|
|
- Know the definitions of absolute and local extrema.
- Know what a critical point is and locate it (them).
- Use the Extreme Value Theorem to find the absolute extrema of a continuous function on a closed interval.
|
| Week 9
|
4.4
|
Mean Value Theorem
|
|
- Determine if the MVT applies given a function on an interval.
- Find c in the conclusion of the MVT (if algebraically feasible)
- Know the first 3 Corollaries of MVT (especially the 3rd)
|
| Week 9
|
4.5
|
Derivatives and the Shape of a Graph
|
|
- Use the First Derivative Test to find intervals on which the function is increasing and decreasing and the local extrema and their type
- Use the Concavity Test (aka the Second Derivative Test for Concavity) to find the intervals on which the function is concave up and down, and point(s) of inflection
- Understand the shape of the graph, given the signs of the first and second derivatives.
|
| Week 10
|
4.7
|
Applied Optimization Problems
|
|
- Set up a function to be optimized and find the value(s) of the independent variable which provide the optimal solution.
|
| Week 10
|
4.8
|
L’Hôpital’s Rule
|
|
- Identify indeterminate forms produced by quotients, products, subtractions, and powers, and apply L’Hôpital’s rule in each case.
- Recognize when to apply L’Hôpital’s rule.
|
| Week 11
|
4.10
|
Antiderivatives
|
|
- Find the general antiderivative of a given function.
- Explain the terms and notation used for an indefinite integral.
- State the power rule for integrals.
- Use anti-differentiation to solve simple initial-value problems.
|
| Week 11/12
|
5.1
|
Approximating Areas
|
|
- Calculate sums and powers of integers.
- Use the sum of rectangular areas to approximate the area under a curve.
- Use Riemann sums to approximate area.
|
| Week 12
|
5.2
|
The Definite Integral
|
|
- State the definition of the definite integral.
- Explain the terms integrand, limits of integration, and variable of integration.
- Explain when a function is integrable.
- Rules for the Definite Integral.
- Describe the relationship between the definite integral and net area.
- Use geometry and the properties of definite integrals to evaluate them.
- Calculate the average value of a function.
|
| Week 12/13
|
5.3
|
The Fundamental Theorem of Calculus
|
|
- Describe the meaning of the Mean Value Theorem for Integrals.
- State the meaning of the Fundamental Theorem of Calculus, Part 1.
- Use the Fundamental Theorem of Calculus, Part 1, to evaluate derivatives of integrals.
- State the meaning of the Fundamental Theorem of Calculus, Part 2.
- Use the Fundamental Theorem of Calculus, Part 2, to evaluate definite integrals.
- Explain the relationship between differentiation and integration.
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