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AP Calculus AB

Course Description:

Advanced Placement Calculus AB is primarily concerned with developing the students’ understanding

of the concepts of calculus and providing experiences with its methods and applications. The four major

topics of this course are limits, differential calculus, integral calculus, and their applications. All

students will be required to analyze problems graphically, numerically, analytically and verbally in this

course. The course content will follow the outlines set forth by the College Board and the state. All

students will be required to use a TI-89 series graphing calculator for this course.

Course Prerequisites:

All students enrolling in AP Calculus AB should successfully complete Pre-Calculus. By successfully

completing Pre-Calculus all students should have a working understanding of linear, polynomial,

rational, exponential, logarithmic, trigonometric, inverse trigonometric, and piecewise defined functions.

Students must also be familiar with the properties of functions, the algebra of functions, the graphs of

functions, the language of functions (domain, range, odd, even, periodic, symmetry, zeros, intercepts,

etc.) and understand the concept of the unit circle.

Textbook:

AP Review Supplemental Workbook:

Lederman, David. Multiple-Choice & Free-Response Questions in Preparation for the AP Calculus

Student Evaluation:

1st, 2nd & 3rd Nine Weeks: Exams 65%

Quizzes 15%

Daily Warm-ups 10%

Assignments 10%

4th Nine Weeks Exam 40%

AP Free-Response 25%

AP Multiple Choice 25%

Assignments 10%

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Student Assessments:

Exams will be given at the completion of a unit (typically at the end of a chapter). Most exams will span

over a 57 minute class period. The majority of the exam will be without the use of a calculator and the

remainder of the exam will require the use of a TI-89 series graphing calculator.

Quizzes will be given during the coverage of the chapter, usually covering 2 – 4 sections of textbook

material. These quizzes will be completed during one class period and some will be with the use of a

graphing calculator and others will be without.

Daily warm-ups are calculus problems given at the beginning of each class to assess the students’

understanding of concepts taught a few days earlier. Daily warm-up problems are collected and graded

each day.

Assignments are graded works which assess the students understanding of the basic calculus concepts.

Assignments are given daily.

AP Review Problems will be assigned daily beginning with the fourth nine weeks. These problems are

past AP Free Response and AP Multiple Choice questions. All AP free response questions will be

assigned to students to complete from the past five examination cycles. AP Multiple Choice will be

review assignments from the D&S Marketing review workbook. Students will practice the multiple

choice questions in these workbooks to help them prepare for the AP examination.

Old AP questions will be given throughout the year as appropriate on quizzes and exams, as well as

homework assignments.

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AP Calculus AB: Course Outline

The 2007-2008 school year begins on August 20, 2007 in Orange County Florida. The AP Calculus

Exam will be administered on May 7, 2008. This gives OrangeCounty students 158 in session school

days to learn calculus and prepare for the AP Calculus exam. All of the days listed below are an

approximation. This is a typical schedule, but it does change slightly from year to year with the number

of days spent on each topic.

First Semester:

Chapter 1: Limits and Their Properties 15 days

Section 1.1: A Preview of Calculus 1 day

Section 1.2: Finding Limits Graphically and Numerically 1 day

Section 1.3: Evaluating Limits Analytically 3 days

Section 1.4: Continuity and One-Sided Limits 3 days

Review (Sections 1.1 – 1.4) 1 day

Quiz (Sections 1.1 – 1.4) 1 day

Section 1.5: Infinite Limits 2 days

Section 3.5: Limits at Infinity 1 day

Review (Chapter 1) 1 day

Exam (Chapter 1) 1 day

Chapter 2: Differentiation 29 days

Section 2.1: The Derivative and the Tangent Line Problem 2 days

Section 2.2: Basic Differentiation Rules and Rates of Change 2 days

Section 2.3: The Product and Quotient Rules and Higher-Order Derivatives 2 days

Section 2.4: The Chain Rule 3 days

Review (Sections 2.1 – 2.4) 1 day

Quiz (Sections 2.1 – 2.4) 1 day

Section 2.5: Implicit Differentiation 3 days

Section 2.A: Supplemental Unit: Particle Motion 5 days

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Review (Section 2.5 & Particle Motion) 1 day

Quiz (Section 2.5 & Particle Motion) 1 day

Section 2.6: Related Rates 5 days

Supplemental Worksheet on Related Rates 1 day

Review (Chapter 2) 1 day

Exam (Chapter 2) 1 day

Chapter 3: Applications of Differentiation 27 days

Section 3.1: Extrema on an Interval 2 days

Section 3.2: Rolle’s Theorem and the Mean Value Theorem 2 days

Section 3.3: Increasing and Decreasing Functions and the First Derivative Test 2 days

Section 3.4: Concavity and the Second Derivative Test 2 days

Section 3.6: A Summary of Curve Sketching 2 days

Supplemental worksheets on Sketching Functions 2 days

Review (Sections 3.1 – 3.6) 1 day

Test (Sections 3.1 – 3.6) 1 day

Section 3.7: Optimization Problems 3 days

Supplemental Worksheet on Optimization Problems 1 day

Section 3.8: Newton’s Method 2 days

Section 3.9: Differentials 2 days

Review (Sections 3.7 – 3.9) 1 day

Quiz (Sections 3.7 – 3.9) 1 day

Section 3.10: Business and Economic Applications 1 day

Review (Chapter 3) 1 day

Exam (Chapter 3) 1 day

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Second Semester:

Chapter 4: Integration 23 days

Section 4.1: Antiderivatives and Indefinite Integration 2 days

Section 4.2: Area 4 days

Section 4.3: Riemann Sums and Definite Integrals 2 days

Review (Sections 4.1 – 4.3) 1 day

Quiz (Sections 4.1 – 4.3) 1 day

Section 4.4: The Fundamental Theorem of Calculus 3 days

Section 4.5: Integration by Substitution 3 days

Review (Sections 4.4 – 4.5) 1 day

Quiz (Sections 4.4 – 4.5) 1 day

Section 4.6: Numerical Integration (Trapezoidal Rule and

Simpson’s Rule) 2 days

Review (Chapter 4) 2 days

Exam (Chapter 4) 1 days

Chapter 5: Logarithmic, Exponential, and Other Transcendental Functions 27 days

Section 5.1: The Natural Logarithmic Function: Differentiation 2 days

Section 5.2: The Natural Logarithmic Function: Integration 2 days

Section 5.3: Inverse Functions 2 day

Section 5.4: Exponential Functions: Differentiation and Integration 2 days

Section 5.5: Bases Other than e and Applications 3 days

Review (Sections 5.1 – 5.5) 1 day

Quiz (Sections 5.1 – 5.5) 1 day

Section 5.6: Differential Equations: Growth and Decay 1 days

Section 5.7: Differential Equations: Separation of Variables 2 days

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Section 5.A Supplemental Unit on Slope Fields 1 day

Supplemental worksheet on Slope Fields & Differential Equations 1 day

Section 5.8: Inverse Trigonometric Functions: Differentiation 2 days

Section 5.9: Inverse Trigonometric Functions: Integration 2 days

Review (Sections 5.6 – 5.9, 5.A) 1 day

Quiz (Sections 5.6 – 5.9, 5.A) 1 day

Section 7.1: Basic Integration Rules 1 day

Review (Chapter 5) 1 day

Exam (Chapter 5 and Section 7.1) 1 day

Chapter 6: Applications of Integration 9 days

Section 6.1: Area of a Region Between Two Curves 1 day

Section 6.2: Volume: The Disk Method 3 days

Section 6.3: Volume: Shell Method 2 days

Section 7.7: Indeterminate Forms and L’Hôpital’s Rule 1 day

Review (Sections 6.1 6.3, 7.7) 1 day

Exam (Sections 6.1 6.3, 7.7) 1 day

Review: Review for AP Examination 20 days

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AP Calculus AB: College Board’s Topic Outline & Correlation to Textbook

The sections listed next to each topic, lists a section (or supplemental unit) of the textbook which

corresponds to each topic. Although several of these topics appear throughout a calculus course, the

section where it is first introduced is included for reference.

TOPIC TEXTBOOK SECTION

I. Functions, Graphs, and Limits

Analysis of Graphs

With the aid of technology, graphs of functions are often easy to produce. (1.2, 1.3)

The emphasis is on the interplay between the geometric and analytic

information and on the use of Calculus both to predict and to

explain the observed local and global behavior of a function.

Limits of Functions (Including one-sided limits)

An intuitive understanding of the limiting process (1.2)

Calculating limits using algebra (1.3)

Estimating limits from graphs or tables of data (1.2)

Asymptotic and Unbounded Behavior

Understanding asymptotes in terms of graphical behavior (1,4, 1.5, 3.5)

Describing asymptotic behavior in terms of limits involving infinity (3.5)

Comparing relative magnitudes of functions and their rates of change (5.6)

(for example, contrasting exponential growth, polynomial growth, and

logarithmic growth)

Continuity as a Property of Functions

An intuitive understanding of continuity. (The function values can be made (1.4)

as close as desired by taking sufficiently close values of the domain.)

Understanding continuity in terms of limits (1.4)

Geometric understanding of graphs of continuous functions (Intermediate (1.4)

Value Theorem and Extreme Value Theorem)

II. Derivatives

Concept of the Derivative

Derivative presented graphically, numerically, and analytically (2.1, 2.2)

Derivative interpreted as an instantaneous rate of change (2.2, 2.A)

Derivative defined as the limit of the difference quotient (2.1)

Relationship between differentiability and continuity (2.1)

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Derivative at a Point

Slope of a curve at a point. Examples are emphasized, including points (2.1)

at which there are vertical tangents and points at which there are

no tangents.

Tangent line to a curve at a point and local linear approximation (2.1)

Instantaneous rate of change as the limit of average rate of change (2.2)

Approximate rate of change from graphs and tables of values (2.2)

Derivative as a Function

Corresponding characteristics of graphs of f and f (3.3)

Relationship between the increasing and decreasing behavior of f and the (3.3)

sign of f

The Mean Value Theorem and its geometric consequences (3.2)

Equations involving derivatives. Verbal descriptions are translated into (5.6)

equations involving derivatives or vice versa.

Second Derivatives

Corresponding characteristics of the graphs of f, f , f (3.3, 3.4, 3.6)

Relationship between the concavity of f and the sign of f (3.4, 3.6)

Points of inflection as places where concavity changes (3.4, 3.6)

Applications of Derivatives

Analysis of curves, including the notations of monotonicity and concavity (3.6)

Optimization, both absolute (global) and relative (local) extrema (3.1, 3.7)

Modeling rates of change, including related rates problems (2.6)

Use of implicit differentiation to find the derivative of an inverse function (5.3)

Interpretation of the derivate as a rate of change in varied applied contexts, (2.2, 4.4, 2.A)

including velocity, speed, and acceleration

Geometric interpretation of differential equations via slope fields and the (5.A)

Relationship between slope fields and solution curves for differential

equations

Computation of Derivatives

Knowledge of derivatives of basic functions, including power, exponential (2.2, 2.3, 5.1

logarithmic, trigonometric, and inverse trigonometric functions 5.3, 5.4, 5.8, 5.9)

Basic rules for the derivative of sums, products, and quotients of functions (2.2, 2.3)

Chain rule and implicit differentiation (2.4, 2.5)

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III. Integrals

Interpretation and Properties of Definite Integrals

Definite integral as a limit of Riemann sums (4.2)

Definite integral of the rate of change of a quantity over an interval (4.4)

interpreted as the change of the quantity over the interval:

f x dx f b f a

Basic properties of definite integrals (examples include additivity and (4.4)

linearity)

Applications of Integrals

Appropriate integrals are used in a variety of application to model physical, (3.10, 4.1, 4.2,

biological, or economic situations. Although only a sampling of applications 4.3, 4.4, 6.1,

can be included in any specific course, students should be able to adapt 6.2, 6.3)

their knowledge and techniques to solve other similar application problems.

Whatever applications are chosen, the emphasis is on using the method of

setting up an approximating Riemann sum and representing its limit as a

definite integral. To provide a common foundation, specific applications

should include using the integral of a rate of change to give accumulated

change, finding the area of a region, the volume of solid with known

cross sections, the average value of a function, and the distance traveled

by a particle along a line.

Fundamental Theorem of Calculus

Use of the Fundamental Theorem to evaluate definite intergrals (4.4)

Use of the Fundamental Theorem to represent a particular antiderivative, (4.4)

and the analytical and graphical analysis of functions so defined

Techniques of Antidifferentiation

Antiderivatives following directly from derivatives of basic functions (4.1)

Antiderivatives by substitution of variables (including change of (4.5)

limits for definite integrals)

Applications of Antidifferentiation

Finding specific antiderivatives using initial conditions, including (4.5)

applications to motion along a line

Solving separable differential equations and using them in modeling (5.6, 5.7)

(in particular, studying the equation y ky and exponential growth)

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Numerical Approximations to Definite Integrals

Use of Riemann sums (using left, right, and midpoint evaluation points) (4.2, 4.6)

and trapezoidal sums to approximate definite integrals of functions

represented algebraically, graphically, and by tables of values.

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AP Calculus AB: Evidence of Curricular Requirements

Curricular Requirement #1:

The course teaches all topics associated with Functions, Graphs, and Limits; Derivatives; and Integrals

as delineated in the Calculus AB Topic Outline in the AP Calculus Course Description.

This curricular requirement is met and on the four previous pages the entire Calculus AB topic outline

was reproduced and the section or supplemental unit where it is covered is denoted. In addition, some

topics that are not in the Calculus AB Topic Outline are also covered in this course. Examples of these

topics include Simpson’s Rule, L’Hôpital’s Rule, and Volume: Shell Method.

Curricular Requirement #2

This course provides students with the opportunity to work with functions represented in a variety of

ways – graphically, numerically, analytically, and verbally – and emphasizes the connections among

these representations.

Example #1:

Students are first introduced to limits numerically, then graphically, then analytically. Students will

construct tables of values, then graph the function to see if the two answers agree. During the next class

the analytical method is introduced and the three methods are compared. Students are encouraged to

verbalize their explanations and answers in class on a daily basis.

Example #2:

To find the area under the curve the students are exposed to several approximation techniques prior to

learning how to evaluate the definite integral algebraically.

Examples of this would include problems of the following nature:

Problem #1: (Numerical)

Suppose a volcano is erupting and readings of the rate r t at which solid materials are spewed into the

atmosphere are given in the table. The time t is measured in seconds and the units for r t are tones

(metric tons) per second.

t 0 1 2 3 4 5 6

r t 2 10 24 36 46 54 60

Use the Trapezoidal Rule with 3 subdivisions of equal length to approximate

r t dt .

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0.5 1 1.5 2 2.5

Problem #2: (Graphical)

Use the midpoint rule to approximate the area of the region bounded by the graph of the function and the

x-axis over the indicated interval. Use n 4 subintervals.

2 f x x 3 ; 0,2

Problem #3: (Analytical)

A particle moves along the x-axis so that its acceleration at any time t is given by a t 6t 18. At

time t 0 the velocity of the particle v 0 24 , and at time t 1 its position is x 1 20.

(A) Write an expression for the velocity v t of the particle at any time t.

(B) For what value(s) of t is the particle at rest?

(D) Write an expression for the position x t of the particle at any time t.

At the conclusion of this students can present their finding to class by writing their solutions on the

board and verbally explaining the steps to their classmates.

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Curricular Requirement #3

The course teaches students how to communicate mathematics and explain solutions to problems both

verbally and in written sentences.

Students are encouraged to verbally express their suggestions on solving problems in class on a daily

basis. Students will also come to the board and demonstrate their solutions to the class.

Examples of questions that have been used on examinations for students to express the mathematics in

written sentences appear below.

Example #1:

If oil leaks from a tank at a rate of r t gallons per minute at time t, what does

120

r t dt represent?

Example #2:

During the first 40 seconds of a flight, the rocket is propelled straight up so that in t seconds it reaches a

height of 3 s 5t feet.

It can be shown that 2 15

Interpret

in the context of the problem.

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Curricular Requirement #4

The course teaches students how to use graphing calculators to help solve problems, experiment,

interpret results, and support conclusions.

Example for Solving Problems:

Each student enrolled in this course will have a TI-89 series graphing calculator to use. The students are

expected to bring their graphing calculators to class with them each day. The calculators are used

frequently in class to explore, discover and reinforce the concepts that we are learning.

Example for Experiment:

When introducing the limit definition of a derivative, the students will sketch a function using their

graphing calculator and graph various secant lines to the curve which pass through a specific point

x, f x on the curve. Students will calculate the slope of their secant lines. To graph the other secant

lines students will choose a second point on the curve closer to fixed point of x, f x . They will

continue this pattern until they pick a point very close to the fixed point x, f x .

Example of Interpretation of Results:

Using the example above, students will notice that our secant line is very close to slope of the curve at

the fixed point x, f x . They will explore this further by “zooming in” on their original function

close to the fixed point and noticing that it appears almost linear over a small fixed interval.

Example of Supporting Conclusions:

The first function students experiment with is usually a quadratic. I continue this experimentation with

polynomial, exponential and logarithmic functions.