100 10097
120 Calculus (AP) 500
130 
140 
150 11-12
160 
170 
180 
210 25.1 Mathematics - Alg Reasoning: Patterns & Functs
211 1.9.1
212 1.9.2
213 1.9.3
214 1.9.11
215 2.9.3
216 2.9.5
220 25.1 Mathematics - Alg Reasoning: Patterns & Functs
221 2.9.7
222 3.9.2
223 1.0.3
224 1.1.1
225 1.1.4
226 1.3.2
230 25.1 Mathematics - Alg Reasoning: Patterns & Functs
231 1.4.2
232 1.4.3
233 1.5.1
234 1.5.2
235 1.6.1
236 1.9.11
240 25.2 Mathematics - Numerical & Prop Reasoning
241 2.9.1
242 2.9.3
243 
244 
245 
246 
250 25.3 Mathematics - Geom & Measuremt
251 1.9.2
252 2.9.2
253 2.9.4
254 2.9.5
255 
256 
300 1)  What are limits? How are they analyzed? Why are they important to the study of calculus?
300 
300 2)  What is a derivative? What techniques are used to find derivatives? How is a derivative related to a tangent line? How can the derivative concept be applied to real world problems?
300 
300 3)   What is integration, and how does it relate to differentiation? What are techniques used to find an anti-derivative, and what does the answer represent? How can the integral concept be applied to real world problems?
300 
300 4)  What is the stylistic focus of the AP exam when dealing with limits, derivatives, and integrals?
400 This course focuses on the following concepts:
400 Analysis of Graphs
400 Limits of Functions  
400 Asymptotic and Unbounded Behavior
400 Continuity as a Property of Functions
400 Concept of Derivative
400 Derivative at a Point
400 Derivative as a Function
400 Higher Order Derivatives
400 Techniques of Differentiation
400 Applications of Derivatives 
400 Interpretations and Properties of Definite Integrals
400 Applications of Integrals
400 Fundamental Theorem of Calculus
400 Techniques of Antidifferentiation
400 Applications of Antidifferentiation
400 Numerical Approximations to Definite Integrals
400 Introduction to Sequences
400 Introduction to Series
500 Students will develop the ability to:
500 
500 -- Determine the relationship between the geometric and analytic representations of functions and how to use calculus to explain and predict both local and global behavior, 
500 -- Explain the limiting process, 
500 -- Calculate limits using algebra, 
500 -- Estimate limits from graphs or tables of data, 
500 -- Explain asymptotes in terms of graphical behavior, 
500 -- Describe asymptotic behavior in terms of limits involving infinity, 
500 -- Compare relative magnitudes of functions and their rates of change, 
500 -- Explain what makes a function continuous or discontinuous, 
500 -- Relate continuity to limits, 
500 -- Present the derivative graphically, numerically, and analytically, 
500 -- Relate the derivative to instantaneous rate of change, 
500 -- Use the definition of the derivative to find the derivative, 
500 -- Explain the relationship between differentiability and continuity, 
500 -- Find the derivative at a point, 
500 -- Identify where there are vertical tangents and removable discontinuities, 
500 -- Approximate rate of change from graphs and tables, 
500 -- Relate the graph of a function to the graph of its derivative, 
500 -- Translate verbal descriptions into equations involving derivatives and vice versa, 
500 -- Relate the graph of a function to its second derivative graph, 
500 -- Identify points of inflection, 
500 -- Analyze curves in terms of increasing and decreasing intervals and concavity, 
500 -- Find maximums and minimums through equation analysis, 
500 -- Model rates of change including related rate problems, 
500 -- Differentiate implicitly, 
500 -- Differentiate power, exponential, logarithmic, trigonometric, and inverse trigonometric functions, 
500 -- Differentiate sums, products, and quotients of functions, 
500 -- Differentiate using the chain rule, 
500 -- Compute Riemann sums using left, right, and midpoint evaluation points, 
500 -- Explain the definite integral as a limit of Riemann sums over equal subdivisions, 
500 -- Explain the definite integral as the change of the quantity over the interval, 
500 -- Explain the properties of definite integrals, 
500 -- Solve application problems that involve the area of a region, the volume of solids of revolution using the disk and shell methods, the volume of a solid with known cross sections, the average value of a function, and the distance covered by a particle along a line, 
500 -- Use the Fundamental Theorem of Calculus to represent and evaluate definite integrals, 
500 -- Solve separable differential equations and use them in modeling, 
500 -- Use Riemann and trapezoidal sums to approximate definite integrals of functions represented algebraically, graphically, and by tables of values,
500 -- Use derivatives of basic functions to antidifferentiate, 
500 -- Use u-substitution of variables to antidifferentiate,
500 -- Use integration by parts to integrate,
500 -- Use properties of trigonometric powers to integrate,
500 -- Use trigonometric substitution to integrate,
500 -- Use partial fractions to integrate,
500 -- Analyze the behavior of sequences and series.
600 All students will:
600 
600 -- Have daily exposure to mechanical, theoretical, and application-based AP-style questions,
600 -- Utilize the graphing calculator extensively to supplement pencil and paper techniques.
600 
700 Students will be assessed by:
700 
700 1.  Daily homework assignments, which will acount for 10% of their final grade 
700 
700 2.  In-class pop quizzes, one per week
700 
700 3.  Take-home quizzes, six questions per week
700 
700 4.  Unit tests (comprised of 50% multiple choice and 50% free response) designed from released AP exam questions and graded in a manner identical to the AP exam every one to two weeks
700 
700 5.  Projects that are 100% application-based
700 
700 6.  Final exam that covers an entire semester's material.  This final exam will account for 20% of their final grade.
800 Projects that involve hands-on experience with differentation and integration (e.g.related rates, optimization, area, or volume) and research into areas not specifically covered by the curriculum (e.g. math history).
820 1. Course Materials: unit packets made from available released AP exam questions  (used in place of a traditional text from January - May)
820 
820 2.  Course Text - Calculus with Analytic Geometry - 6th Edition - Larson & Hostetler (used in May and June)
820 
820 3.  Supplementary texts
820 
820 4.  Graphing calculator
820 
820 5.  Graphing calculator projector