Daily Objectives

State the definitions of function, domain, and range.
Give and work with examples of functions, including functions that relate physical quantities, from all four perspectives - words, formulas, tables, graphs. (Most later objectives mean all of these perspectives whenever they refer to functions.)
Use function notation correctly and interpret function notation in an applied context.
Find and interpret vertical and horizontal intercepts.

Section 1.2

Determine whether a function is linear.
Find and interpret the slope, vertical intercept, input or output values for a linear function.
Construct a linear function if given a description in words, two points or a point and a slope, a graph, or a table.

Section 1.3

State the definitions of change and average rate of change and use correct units for each.
Find change and average rate of change, including average velocity, from two points given in words, in a table, on a graph, or by a formula.
Relate signs of average rate of change to the function increasing or decreasing.
Determine concavity from a graph or table.

Section 1.4

State definitions of and construct cost, revenue, and profit functions.
Use these functions to find break-even points and analyze how production levels affect profitability.
Interpret rates of change in cost, revenue, and profit as marginal cost, marginal revenue, and marginal profit.
Construct linear depreciation functions from supplied information.

Section 1.5

Construct exponential functions if given two points, or an initial value and a percent growth or decay rate.
Recognize when a formula or table represents exponential growth or decay.
Compare growth or decay of exponential and linear functions.

Section 1.6

State the definition of the natural logarithm and know its domain.
Correctly use the notation for and properties of the natural logarithm.
Solve equations using the natural logarithm and its properties.
Convert exponential equations between forms that show the percent rate of change and the continuous rate of change and read such information from them.

Section 1.7

State the definition of doubling time and half-life and understand why they do not depend on initial value or time.
Find doubling time and half-life and interpret them in applied problems.
Construct formulas for compound interest and compute related quantities.

Section 1.8

Given formulas for f(x) and g(x), find composite functions involving f(x) and g(x).
Given formulas, graphs, or tables for f(x) and g(x), find specific values of composite functions involving f(x) and g(x).
Given a composite function, break it apart into an inside function u and an outer function.
Apply stretches and shifts to graphs of functions.

Section 1.9

Identify power functions from formulas and quantities that are proportional from tables or given information.
Write formulas relating quantities that are proportional or inversely proportional and find the constant of proportionality.
Identify the degree and leading coefficient of polynomial functions and how they affect the shape of the graph (long term behavior and numbers of zeros and turning points).

Section 1.10

State the definitions of amplitude and period.
Find amplitude, period, and vertical shift for given functions involving sine and cosine and use this to graph them.
Construct functions involving sine and cosine given information about amplitude, period, and vertical shift.

Section 2.1

State the definition of instantaneous rate of change.
Correctly use the notation for and assign units to the derivative at a point.
Find or estimate instantaneous rates of change of functions given by formulas, tables, and graphs.
Interpret the instantaneous rate of change at a point as the slope of the tangent line to the graph at that point.

Section 2.2

Interpret the derivative as a function and sketch the graph of f '(x) if given the graph of f(x).
Find information about f(x) from information about f '(x).
Find approximate values for f '(x) from a table of values for f(x).

Section 2.3

Give units and interpret the meaning of the derivative in applications.
Describe what is known about a function from the sign of its derivative in applications.
Use the derivative to construct a local linear approximation that allows you to estimate nearby values of a function.

Section 2.4

State the definition of and correctly use notation for the second derivative.
Determine information about the second derivative from a graph of the function.
Determine information about a function from information about its second derivative.
Interpret the second derivative in terms of rates of change.

Section 2.5

Estimate marginal cost and marginal revenue from a graph, table, or values.
Estimate costs or revenue for nearby quantities using narginal cost or revenue in a local linear approximation.
Interpret marginal cost or revenue and related quantities in applications.

Chapter 3

Find formulas for derivatives of the given type(s) of functions.
Use derivative formulas or graphs to compute values of the derivative at a point.
Find the equation of the tangent line at a point using a value of the derivative.
Use the graph and concavity of the function to compare approximate values found using the tangent line with the actual value on the function.

Section 3.1 - powers of x, scalar multiples of functions, sums and differences of functions, hence any polynomial (including constant and linear functions)

Section 3.2 - f(x)=a^x, f(x)=ln(x)
Section 3.3 - composite functions
Section 3.4 - products and quotients of functions
Section 3.5 - periodic functions

Section 4.1

Find and classify all critical values of functions given by graphs or formulas as a local maximum, local minimum, or neither using the first or second derivative tests.
Find information about f(x) from information about zeros and signs of f '(x).

Section 4.2

Find inflection points for functions given by graphs or formulas.
Sketch a possible graph of f(x) given information about f '(x) and f ''(x).

Section 4.3

Use the first and second derivatives to determine global extreme values for a function given by a formula on a closed or open interval.
Find extreme values and the inputs that produce them in applications.
Sketch a possible graph of f(x) given information about its local and global extreme values.

Section 4.4

Apply principles from 4.1-4.3 to find maximum revenue and profit, minimum cost, and production levels where these occur.

Section 4.7

Know the formula for a logistic function and its properties, including the meaning of L and the point of diminishing returns.
Apply principles from calculus and algebra to answer questions about logistic models for populations and dose-response curves.

Section 4.8

Know the formula for drug concentration curves and the effect of changing parameters a and b in the family ate^(-bt).
Apply principles from calculus to answer questions about drug concentration curves.

Section 5.1

Estimate accumulated change in a function using a table of values or a graph for the rate of change of that function.
Determine whether an estimate is an overestimate or an underestimate based on whether the rate of change is increasing or decreasing and whether right or left endpoint values are used.

Section 5.2

Estimate a definite integral of a function using a table of values or graph of the function.
Determine the values of n, delta t, and f(t_i) used in estimating the definite integral of a function.
Use a calculator to estimate the definite integral of a function given by a formula.

Section 5.3

Interpret the definite integral of f(x) in terms of area when f(x) is positive and when f(x) is both positive and negative on the interval.
Estimate a definite integral using a graph of a function that is both positive and negative.
Determine the area between two functions (including the case where one function is 0 or the x=axis) using definite integrals.

Section 5.4

Estimate the total change in a quantity given information about its rate of change in a table, graph, or formula.
Estimate the value of a function if given its initial value and information about its rate of change.
Interpret the meaning of the definite integral in applications, including when the rate of change is positive and negative and when the function is a drug concentration curve.

Section 5.5

Interpret the First Fundamental Theorem of Calculus as relating the definite integral of a rate of change to total change.
Use the First Fundamental Theorem of Calculus to compute total cost if given fixed costs and information about the marginal cost.

Second Fundamental Theorem of Calculus

Interpret an integral with a variable in the upper limit as describing a function (that we will study again later in Chapter 7 as an antiderivative).
Interpret the First and Second Fundamental Theorem of Calculus as showing that differentiation and integration are opposite processes.

Section 6.1

Use definite integrals to find the average value of a function on an interval, including in applications.
Compare the average value of a function on an interval to the average of the values of the function at two inputs and describe how this depends on concavity.
Interpret the average value of a function on its graph.

Section 1.7

Compare options for amounts of money by computing present or future values of both options.

Section 6.3

Find present or future values of continuous income streams
Find the value of a constant continuous contribution to a bank account that will produce a desired future value.

Section 6.4

Find and interpret relative rates of change given in tables or graphs and compare to average rate of change.
Find percent change from a graph of relative rate of change using a definite integral and algebra
Analyze population change given a graph of relative birth rate and relative death rate.

Section 7.1

Find antiderivatives of common functions like x^n with n not -1, 1/x, e^(kx), cos(kx), sin(kx).
Use the sum, difference, and constant multiple rules to find antiderivatives.
Find a particular antiderivative when given further information about one of its values.

Section 7.2

Use substitution to find antiderivatives and use correct notation to describe the substitution.
Recognize when substitution is needed to find an antiderivative.

Section 7.3

Compute the exact value of a definite integral or the change in a function using antiderivatives and the Fundamental Theorem of Calculus.
Use correct notation when computing definite integrals by substitution.
Investigate convergence of improper integrals by numerical evidence.

Section 7.4

Find or approximate a value of a function when its rate of change and one value are known.
Graph a possible function given a graph of the derivative and graph a particular function if also given a point on the function.

Section 8.1

Sketch a density function representing a distribution described in words.
Use the properties in the definition of a density function to find fractions of populations satisfying certain conditions.

Section 8.2

Distinguish between a probability density function and a cumulative distribution function.
Find and interpret cumulative distribution functions and their values.

Section 8.3

Find median and mean values of density functions.

Previous Announcements

Carefully read the entire syllabus and suggestions on the homework web page. Also fill out the time management worksheet as a guide for yourself.
Please put homework in a single column on the paper and leave enough blank space for comments and marks from the grader.
Please use graph paper for all graphs on homework. Always mark scales on axes and draw graphs large and carefully.
In grading, a check mark means correct, a slash or x means incorrect.
Use the approximate sign rather than the equal sign whenever you round an answer. Include the full units (e.g. "years after 2000" rather than just "years"). Show steps for full credit. Be precise - try to avoid using the word "it". Write full words and complete sentences.
Remember that if a continuous rate is meant then the problem will say so (see comment just before Example 5 on p. 47).
Comments from the grader:
be careful not to round too far or too early,
please leave space for comments and for the score in the left margin,
use graph paper when drawing graphs,
draw only one graph on each set of axes.
Here is a solution to 1.7 #16. Solutions to the assigned problems in 1.8, 1.9, 1.10, 2.4, 3.5, 4.3, 5.4, 5.5 and all past quizzes and exams are available from me for you to check your own work.
Comments from the grader: Always be sure to include units and work on improving interpretations of answers in applied problems.
Good study strategies: working extra problems in sections and in the review sections, especially without the book or notes, going over mistakes on homework and quizzes, making summary outlines of important ideas in your own words, and reviewing sections.
Please double check the scores I have recorded on your slip (but note that the real Quiz 6 is on the back of Quiz 5 and that I mislabeled Quiz 7 as 6 by accident).
Comments from the grader on 5.4 & 5.5:
- To calculate total change in a function, integrate the rate of change of the function (e.g. in 5.4 #8, add the integral of r(t) from t=0 to t=10 to 90, not just r(10) and in 5.5 #12, add the integral of f '(t) from 0 to 10 to 40,000, not just f '(10)).
- Be careful about units - if t is in years since 1960, then to integrate on the interval of 1960 to 1990 use t=0 to t=30.
- Look closely at graphs and scales (e.g. on 5.4 #30d, include the squares under the scales and use that 10 minutes=1/6 hour).
- Be sure to indicate what you did to compute an answer, either by describing a calculator function or by stating that you counted squares and indicating how.
- Read carefully to make sure you answer all parts of every problem.
See the updated Useful Links page for some useful resources on test taking, mathematical, and general study strategies.