Advanced Placement
Calculus
I think that calculus
defines more unequivocally than anything else, the inception of modern
mathematics; and the system of mathematical analysis still constitutes the
greatest technical advance in exact thinking.
-
John von Newman
Textbooks: 1. CALCULUS Concepts and Applications, Paul A. Forester.
2. CALCULUS, Finney, Thomas, Demana & Waits.
Instructor: Judson Swets
676-6481 x5220
jswets@bham.wednet.edu
Course Overview:
Welcome to Advanced Placement Calculus.
Calculus is the reformulation of elementary mathematics through the use of the limit. Of course, you have yet to learn about the limit, so this explanation may be less than illuminating. However, to give you a sense of the power of calculus, I will contrast it with the mathematics that you already know.
|
Without Calculus |
With Calculus |
|
You can find the slope of a line. |
You can find the slope at any point on a curve. |
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You can find the equation of a secant line. |
You can find the equation of a tangent line. |
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You can calculate average speed. |
You can calculate instantaneous speed. |
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You can find the height of f(x) when x = c. |
You can find the maximum or minimum height of f(x) on a given interval. |
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You can describe the direction of motion along a straight line. |
You can describe the direction of motion along a curve. |
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You can find the area of a rectangle. |
You can find the area of a curved region. |
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You can calculate work done by a constant force. Work = Force x Distance |
You can calculate work done by a variable force. (i.e. friction) |
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You can find the length of a line segment. |
You can find the length of a curved segment. |
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You can find the surface area of a cylinder. |
You can find the surface area of a solid of revolution. |
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You can find the mass of a solid with constant density. |
You can find the mass of a solid with variable density. |
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You can find the volume of a rectangular solid. |
You can find the volume of a region under a surface. |
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You can find the sum of a finite number of terms. |
You can find the sum of an infinite number of terms. |
Almost every professional field uses calculus in some way. Economists use calculus to forecast global market trends. Meteorologists use calculus to describe the flow of air in the upper atmosphere. Biologists use calculus to forecast population size. Medical researchers use calculus to design ultrasound and x-ray equipment for scanning the internal organs of the body. Astrophysicists use calculus to study distant objects and to contemplate the nature of time. Hydraulic engineers use calculus to find safe closure patterns for valves in pipelines. Large companies use calculus to determine profitable inventory levels. Timber companies use calculus to decide the most profitable time to harvest.
Now, it is true that you will be hard pressed to find any engineer, scientist, or economist that does any calculus by hand. Nope. They use computers, and why not? They understand the ideas of changing rates of change, and they are not troubled by the idea of a sum of an infinite number of infinitely small quantities. These ideas are still new to you, and we must become comfortable with them. Remember that it will be you that poses the question to the computer and not the other way around. It’s not an equal relationship. You can be buddies with your calculator, but only one of you will understand what’s going on. Kinda sad, isn’t it? I always end up feeling bad for the calculator. Smart, but clueless.
First Semester Grading:
0% Homework
Homework will be given daily.
It is imperative that you work the problems out completely. You cannot learn calculus by simply watching
it done or reading about it. The
homework will give you the experiences you need to be successful.
20% Formal Sets
Formal Sets are
assignments or handouts that will be graded for correctness. You will receive about one Formal Set per
week.
20% Quizzes
You will have a quiz
on most Fridays. Quizzes can be made up
for excused absences and your lowest two quizzes will be dropped.
20% Test I
Test I will be given at midterm. It will be a comprehensive multi-chapter test. If unavoidable circumstances will cause you to miss the test, you must notify me in advance. If you are out of school, use e-mail or the telephone.
20% Test II
Test II will be given in early
December. It will be a comprehensive
multi-chapter test. If unavoidable
circumstances will cause you to miss the test, you must notify me in advance. If you are out of school, use e-mail or the
telephone.
20% Semester Exam
A cumulative exam will be given during Finals schedule.
The AP Exam:
Every student is strongly encouraged to take the AP Calculus exam in May. The exam will require that you learn the coursework in depth, develop your analytical reasoning skills, and form disciplined study habits. Some of the rewards for putting forth your best efforts are
1.
College credit for as
much as one semester or two quarters depending on your score
2. A demonstration of college readiness that will prepare you for continued success at the college level
3. A selection advantage for the student who wishes to attend a highly competitive college.
Students who take the AP Exam are among the most academically able students of the college-bound group. The exam is challenging, but you will be well prepared.
www.collegeboard.org/ap/calculus/
A.P. Calculus
Checklist
Course
Content:
I. Functions, Graphs, and Limits
A.
Graph Analysis: With
the aid of technology, graphs of functions are often easy to produce. 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.
B.
Limits of Functions
(including one-sided limits).
1.
An intuitive
understanding of the limiting process.
2.
Calculating limits
using algebra.
3.
Estimating limits
from graphs or tables of data.
C.
Asymptotic and
unbounded behavior
1.
Understanding
asymptotes in terms of graphical behavior.
2.
Describing asymptotic
behavior in terms of limits involving infinity.
3.
Comparing relative magnitudes
of functions and their rates of change.
(For example, contrasting exponential growth, polynomial growth, and
logarithmic growth.)
D.
Continuity as a
property of functions
1.
An intuitive
understanding of continuity (Close
values of the domain lead to close values of the range.)
2.
Understanding
continuity in terms of limits
3.
A geometric
understanding of the graphs of continuous functions (Intermediate Value Theorem and Extreme Value Theorem.)
II.
Derivatives
A.
Concept of the
derivative
1.
Derivative presented
geometrically, numerically, and analytically
2.
Derivative
interpreted as an instantaneous rate of change
3.
Derivative defined as
the limit of a quotient
4.
Relationship between
differentiability and continuity
B.
Derivative at a point
1.
Slope of a curve at a
point (Examples include points at which
there are vertical tangents and points at which there are no tangents.)
2.
Tangent line to a
curve at a point and local linear approximation
3.
Instantaneous rates
of change as the limit of average rates of change
4.
Approximate rate of
change from graphs and tables of values
C.
Derivative as a
function
1.
Corresponding
characteristics of graphs of f and f’
2.
Relationship between
the increasing and decreasing behavior of f
and the sign of f’
3.
The Mean Value
Theorem and its geometric consequences
4.
Equations involving
derivatives: Verbal descriptions are translated into equations involving
derivatives and vice versa.
D.
Second derivatives
1.
Corresponding
characteristics of the graphs of f, f’ and f”
2.
Relationship between
the concavity of f and the sign of f”
3.
Points of inflection
as places where concavity changes
E.
Applications of
derivatives
1.
Analysis of curves,
including the notions of monotonicity and concavity
2.
Optimization of
absolute and relative extrema
3.
Modeling rates of
change (Related rate problems)
4.
Use of implicit
differentiation to find the derivative of an inverse function
5.
Interpretation of the
derivative as a rate of change in varied applied contexts, including velocity,
speed and acceleration
F.
Computation of
derivatives
1.
Knowledge of
derivatives of basic functions, including power, exponential, logarithmic,
trigonometric, and inverse trigonometric functions
2.
Basic rules for the
derivative of sums, products, and quotients of functions
3.
Chain rule and
implicit differentiation
III. Integrals
A.
Interpretations and
properties of definite integrals
1.
Computation of
Riemann sums using left, right, and midpoint evaluation points
2.
Definite integral as
a limit of Riemann sums over equal subdivisions
3.
Definite integral of the rate of change
of a quantity over an interval interpreted as the change of the quantity over
the interval:
4.
Basic properties of
definite integrals, including additivity and linearity
B.
Applications of
integrals: The integral will be used in applications to find an accumulated
change or to approximate the limit of a Riemann sum. To provide a foundation, students should be familiar with
applications such as finding the area of a region under a curve, the volume of
a solid with known cross sections, the average value of a function, and the
distance traveled by a particle along a line.
C. Fundamental Theorem of Calculus
1.
Use of the
Fundamental Theorem to evaluate definite integrals
2.
Use of the
Fundamental Theorem to represent a particular antiderivative, and the
analytical and graphical analysis of functions so defined
D.
Techniques of
antidifferentiation
1.
Antiderivatives
following directly from derivatives of basic functions
2.
Antiderivatives by
substitution of variables (including change of limits for definite
integrals)
E.
Applications of
antidifferentiation
1.
Finding specific
antiderivatives using initial conditions, including applications to motion
along a line
2.
Solving separable
differential equations and using them in modeling, including the study of y’=ky and exponential growth
F.
Numerical
approximations for definite integrals: Use Riemann and trapezoidal sums to
approximate definite integrals of functions represented algebraically,
geometrically, and by tables of values.