MA441 Learning Goals

Algebra and Geometry of Functions

F1: I can use function notations to describe functions.
F2: I can evaluate and graph functions.
F3: I can find domain, range and intercepts of a function.
F4: I can find the composition of functions and recognize a function as the composition of functions.
F5: I can perform mathematical operations on polynomials and factor polynomials.
F6: I can perform mathematical operations on rational expressions.
F7: I can perform mathematical operations on radical expressions and rationalize denominators or numerators.
F8: I can solve equations and inequalities.
F9: I can evaluate trigonometric functions and determine the measure of the angle from a special trigonometric equation.
F10: I can solve problems on right triangles using trigonometric identities.

Limits

L1: I can explain how the idea of a limit is involved in solving the the tangent problem.
L2: I can explain how the idea of a limit is involved in solving the area problem.
L3: I can explain the definition of the limit of a function using numerical, and graphical methods.
L4: I can provide an example that the numerical method fails.
L5: (CORE) I can find the limit of a function at a point using algebraic methods and limit laws.
L6: (CORE) I can explain the relationship between one-sided and two-sided limits.
L7: (CORE) I can evaluate the limit of a function by using the squeeze theorem.
L8: I can using correct notation, describe an infinite limit.
L9: (CORE) I can find the limit of a function at the infinity using algebraic methods.

Continuity

C1: I can explain the three conditions for continuity at a point.
C2: (CORE) I can describe three kinds of discontinuities and provide examples.
C3: (CORE) I can determine whether and when a function is continuous over a given interval using the definition of continuity.
C4: I can state the theorem for limits of composite functions.
C5: (CORE) I can use the theorem for limits of composite functions evaluate limits.
C6: I can state the intermediate value theorem and provide examples and counterexamples.
C7: (CORE) I can apply the intermediate value theorem to solve problems such as determine whether an equation has a solution over a given interval.

Derivatives

D1: (CORE) I can find the derivative of a function at a point and as a function using the definition.
D2: (CORE) I can state the connection between derivatives and continuity, and provide examples.
D3: I can determine whether or when a function is differentiable over an interval using the definition.
D4: (CORE) I can use derivative notations and calculate higher derivatives.
D5: (CORE) I can find the equation of the tangent line to a function at a point.
D6: I can correctly interpret a rate of change as a derivative in context and find the value.
D7: (CORE) I can find derivatives of power and trigonometric functions, and their linear combinations.
D8: (CORE) I can find derivatives of functions using the product rule and the quotient rule.
D9: (CORE) I can find derivatives of composite functions using the chain rule.
D10: (CORE) I can find derivatives by using multiple rules in combination.
D11: (CORE) I can find the derivative of an implicitly-defined function using implicit differentiation.
D12: I can find the slope of the tangent line to a curve defined by an implicit function.

Applications of Derivatives

A1: I can set up equations for relationships among derivatives in a related rates problems and find the rate of change of one quantity that depends on the rate of change of other quantities.
A2: I can find the linearization of a given function and use it to estimate the value of a function at a given point.
A3: I can use differential approximation to calculate the change in a quantity, the relative error, and percentage error.
A4: (CORE) I can find the critical values of a function.
A5: I can use the Extreme Value Theorem to find the absolute maximum and minimum values of a continuous function over a closed interval.
A6: I can demonstrate understanding of the Mean Value Theorem using examples and counterexamples.
A7: (CORE) I can state three important corollaries of the Mean Value Theorem.
A8: I can explain how the sign of the first derivative affects the shape of the graph of a function.
A9: (CORE) I can find intervals of increasing and decreasing of a function.
A10: (CORE) I can find local extrema of a function using the First and Second Derivative Tests.
A11: I can determine the intervals of concavity of a function and find all of its points of inflection.
A12: I can find horizontal, vertical and oblique (slanted) asymptotes of a function using rules of limits.
A13: I can sketch the graph of a function manually.
A14: (CORE) I can set up and use differential calculus to solve applied optimization problems.
A15: (CORE) I can find the general antiderivative of a given function.
A16: I can use anti-differentiation to solve initial-value problems.

Integrals and Applications

I1: I can use sigma (summation) notation to calculate sums of powers of integers.
I2: (CORE) I can approximate area between curves using Riemann sums, and interpret a definite integral as the limit of Riemann sums.
I3: I can evaluate integrals using geometry and the properties of definite integrals.
I4: I can explain the connection between the Mean Value Theorem and the Fundamental Theorem of Calculus part 1 (\(\frac{\operatorname{d}}{\operatorname{d} x}\int_a^xf(t)\operatorname{d}t=f(x)\)).
I5: (CORE) I can evaluate a definite integral using the Fundamental Theorem of Calculus.
I6: I can explain the relationship between differentiation and integration.
I7: I can describe the meaning of the mean value theorem for integrals.
I8: I can calculate the average value of a function.
I9: (CORE) I can evaluate a definite integral using integration rules.
I10: I can use the net change theorem to solve applied problems.
I11: (CORE) I can use substitution to evaluate indefinite integrals and definite integrals.
I12: (CORE) I can find the area of a region between two curves using definite integrals.