OCG - Calculus

Limits and Continuity

The student will:
C.LC.1 Understand the concept of a limit graphically, numerically, analytically, and
contextually.
a. Estimate and verify limits using tables, graphs of functions, and technology.
b. Calculate limits, including onesided
limits, algebraically using direct substitution,
simplification, rationalization , and the limit laws for constant multiples, sums,
differences, products, and quotients.
c. Calculate infinite limits and limits at infinity. Understand that infinite limits and
limits at infinity provide information regarding the asymptotes of certain functions,
including rational, exponential and logarithmic functions .
C.LC.2 Understand the definition and graphical interpretation of continuity of a function.
a. Apply the definition of continuity of a function at a point to solve problems.
b. Classify discontinuities as removable, jump, or infinite. Justify that
classification using the definition of continuity.
c. Understand the Intermediate Value Theorem and apply the theorem to prove the
existence of solutions of equations arising in mathematical and realworld
problems.
Derivatives

The student will:
C.D.1 Understand the concept of the derivative of a function geometrically, numerically,
analytically, and verbally.
a. Interpret the value of the derivative of a function as the slope of the
corresponding tangent line.
b. Interpret the value of the derivative as an instantaneous rate of change in a
variety of realworld
contexts such as velocity and population growth .
c. Approximate the derivative graphically by finding the slope of the tangent line
drawn to a curve at a given point and numerically by using the difference
quotient.
d. Understand and explain graphically and analytically the relationship
between differentiability and continuity.
e. Explain graphically and analytically the relationship between the average rate
of change and the instantaneous rate of change.
f. Understand the definition of the derivative and use this definition to
determine the derivatives of various functions.
C.D.2 Apply the rules of differentiation to functions.
a. Know and apply the derivatives of constant, power, trigonometric, inverse
trigonometric , exponential , and logarithmic functions .
b. Use the constant multiple, sum, difference, product, quotient, and chain
rules to find the derivatives of functions.
c. Understand and apply the methods of implicit and logarithmic
differentiation .
C.D.3 Apply theorems and rules of differentiation to solve mathematical and realworld
problems.
a. Explain geometrically and verbally the mathematical and realworld
meanings
of the Extreme Value Theorem and the Mean Value Theorem.
b. Write an equation of a line tangent to the graph of a function at a point.
c. Explain the relationship between the increasing/decreasing behavior of f and the
signs of f ′. Use the relationship to generate a graph of f given the graph of f ′, and
vice versa, and to identify relative and absolute extrema of f .
d. Explain the relationships among the concavity of the graph of f , the
increasing/decreasing behavior of f ′ and the signs of f ′′. Use those relationships to
generate graphs of f, f ′, and f ′′ given any one of them and identify the points of
inflection of f .
e. Solve a variety of realworld
problems involving related rates, optimization, linear
approximation , and rates of change.
Integrals
The student will:
C.I.1 Understand the concept of the integral of a function geometrically, numerically,
analytically, and contextually.
a. Explain how the definite integral is used to solve area problems.
b. Approximate definite integrals by calculating Riemann sums using left, right,
and midpoint evaluations, and using trapezoidal sums.
c. Interpret the definite integral as a limit of Riemann sums.
d. Explain the relationship between the integral and derivative as expressed in both
parts of the Fundamental Theorem of Calculus. Interpret the relationship in terms
of rates of change.
C.I.2 Apply theorems and rules of integration to solve mathematical and realworld
problems.
a. Apply the Fundamental Theorems of Calculus to solve mathematical and
realworld
problems.
b. Explain graphically and verbally the properties of the definite integral. Apply
these properties to evaluate basic definite integrals.
c. Evaluate integrals using substitution.

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Mathematics