Calculus
Curriculum
Calculus
When taught in high school, calculus should be presented with the same level of
depth and rigor as are entry-level college and university calculus courses. These
standards outline a complete college curriculum in one variable calculus. Many high
school programs may have insufficient time to cover all of the following content in a
typical academic year. For example, some districts may treat differential equations
lightly and spend substantial time on infinite sequences and series. Others may do
the opposite. Consideration of the College Board syllabi for the Calculus AB and
Calculus BC sections of the Advanced Placement Examination in Mathematics may
be helpful in making curricular decisions. Calculus is a widely applied area of
mathematics and involves a beautiful intrinsic theory. Students mastering this content
will be exposed to both aspects of the subject.
1.0 Students demonstrate knowledge of both the formal definition and the graphical
interpretation of limit of values of functions. This knowledge includes one-sided
limits, infinite limits, and limits at infinity. Students know the definition of
convergence and divergence of a function as the domain variable approaches either
a number or infinity:
1.1 Students prove and use theorems evaluating the limits of sums, products,
quotients, and composition of functions.
1.2 Students use graphical calculators to verify and estimate limits.
1.3 Students prove and use special limits, such as the limits of (sin(x))/x and
(1-cos(x))/x as x tends to 0.
2.0 Students demonstrate knowledge of both the formal definition and the graphical
interpretation of continuity of a function.
3.0 Students demonstrate an understanding and the application of the intermediate
value theorem and the extreme value theorem.
4.0 Students demonstrate an understanding of the formal definition of the derivative
of a function at a point and the notion of differentiability:
4.1 Students demonstrate an understanding of the derivative of a function as the slope
of the tangent line to the graph of the function.
4.2 Students demonstrate an understanding of the interpretation of the derivative as an
instantaneous rate of change. Students can use derivatives to solve a variety of
problems from physics, chemistry, economics, and so forth that involve the rate of
change of a function.
4.3 Students understand the relation between differentiability and continuity.
4.4 Students derive derivative formulas and use them to find the derivatives of
algebraic, trigonometric, inverse trigonometric, exponential, and logarithmic functions.
5.0 Students know the chain rule and its proof and applications to the calculation of
the derivative of a variety of composite functions.
6.0 Students find the derivatives of parametrically defined functions and use implicit
differentiation in a wide variety of problems in physics, chemistry, economics,
and so forth.
7.0 Students compute derivatives of higher orders.
8.0 Students know and can apply Rolle’s theorem, the mean value theorem, and
L’Hôpital’s rule.
9.0 Students use differentiation to sketch, by hand, graphs of functions. They can
identify maxima, minima, inflection points, and intervals in which the function is
increasing and decreasing.
10.0 Students know Newton’s method for approximating the zeros of a function.
11.0 Students use differentiation to solve optimization (maximum-minimum problems)
in a variety of pure and applied contexts.
12.0 Students use differentiation to solve related rate problems in a variety of pure
and applied contexts.
13.0 Students know the definition of the definite integral by using Riemann sums.
They use this definition to approximate integrals.
14.0 Students apply the definition of the integral to model problems in physics, eco
nomics, and so forth, obtaining results in terms of integrals.
15.0 Students demonstrate knowledge and proof of the fundamental theorem of
calculus and use it to interpret integrals as antiderivatives.
16.0 Students use definite integrals in problems involving area, velocity, acceleration,
volume of a solid, area of a surface of revolution, length of a curve, and work.
17.0 Students compute, by hand, the integrals of a wide variety of functions by using
techniques of integration, such as substitution, integration by parts, and trigonometric
substitution. They can also combine these techniques when appropriate.
18.0 Students know the definitions and properties of inverse trigonometric functions
and the expression of these functions as indefinite integrals.
19.0 Students compute, by hand, the integrals of rational functions by combining the
techniques in standard 17.0 with the algebraic techniques of partial fractions and
completing the square.
20.0 Students compute the integrals of trigonometric functions by using the
techniques noted above.
21.0 Students understand the algorithms involved in Simpson’s rule and Newton’s
method. They use calculators or computers or both to approximate integrals
numerically.
22.0 Students understand improper integrals as limits of definite integrals.
23.0 Students demonstrate an understanding of the definitions of convergence and
divergence of sequences and series of real numbers. By using such tests as the
comparison test, ratio test, and alternate series test, they can determine whether a
series converges.
24.0 Students understand and can compute the radius (interval) of the convergence of
power series.
25.0 Students differentiate and integrate the terms of a power series in order to form
new series from known ones.
26.0 Students calculate Taylor polynomials and Taylor series of basic functions,
including the remainder term.
27.0 Students know the techniques of solution of selected elementary differential
equations and their applications to a wide variety of situations, including
growth-and-decay problems.