AP Precalculus

AP Precalculus is an Advanced Placement (AP) course and corresponding exam administered by the College Board, launched in the fall of 2023 to equip high school students with essential mathematical tools for college-level studies in science, technology, engineering, and mathematics (STEM) fields.^[1] The course emphasizes the study of functions as models of dynamic phenomena, fostering skills in procedural fluency, multiple representations, and reasoned communication to bridge secondary and postsecondary mathematics.^[2] It serves as a capstone for students completing Geometry and Algebra 2 (or Integrated Math 3), providing a rigorous yet accessible pathway for those pursuing majors in mathematics, physics, biology, data science, or related disciplines without immediate advancement to AP Calculus.^[3] Equivalent to a first-semester college precalculus course, AP Precalculus integrates topics from college algebra and trigonometry while introducing advanced concepts like parameter-dependent functions and vector applications.^[2] The curriculum is structured around four units: Unit 1 on Polynomial and Rational Functions (15%–25% of exam weight), Unit 2 on Exponential and Logarithmic Functions (20%–28%), Unit 3 on Trigonometric and Polar Functions (25%–35%), and Unit 4 on Functions Involving Parameters, Vectors, and Matrices (not assessed on the exam but included for deeper exploration).^[4] Throughout, students develop three core mathematical practices: procedural and symbolic fluency for algebraic manipulation (39%–48% of exam emphasis), translation across graphical, numerical, analytical, and verbal representations (20%–27%), and precise communication with justifications (32%–39%).^[4] The AP Precalculus exam, first administered in May 2024, is a hybrid digital assessment lasting three hours, comprising 40 multiple-choice questions (two hours) and four free-response questions (one hour), with a graphing calculator required for specific parts (Sections I Part B and II Part A) and not permitted for others (Sections I Part A and II Part B).^[5] It evaluates mastery of Units 1–3 through problem-solving scenarios that require modeling real-world phenomena, such as population growth or periodic behaviors.^[5] Successful performance can earn college credit, advanced placement, or both at participating institutions, potentially accelerating students' progress and reducing postsecondary costs.^[6] Developed collaboratively by college faculty and experienced AP teachers, the course promotes equitable access to advanced mathematics, addressing barriers like inconsistent precalculus preparation in high schools.^[1]

Introduction

History and Development

The AP Precalculus course was announced by the College Board on May 17, 2022, as a new addition to the Advanced Placement Program designed to bridge gaps in high school mathematics preparation for students pursuing STEM fields.^[1] This initiative addressed the finding that approximately 40% of college students lack sufficient high school mathematics experience to succeed in entry-level college math courses, thereby hindering their progress toward graduation and access to STEM majors.^[1] The course was developed over multiple years by a team of College Board faculty, high school mathematics teachers, and university professors, including experts such as Michael Boardman from Pacific University and David Bressoud from Macalester College, who analyzed hundreds of college precalculus syllabi to ensure alignment with first-semester college-level standards.^[7] The development process involved iterative stages of review, revision, piloting, and analysis, with input from professional organizations like the National Council of Teachers of Mathematics (NCTM) and the Mathematical Association of America (MAA), culminating in the release of the course framework (Version 1.0) in 2023.^[7] This framework emphasizes conceptual understanding of functions and mathematical modeling—such as exploring covariation, rates of change, and real-world applications—over rote computation and memorization, distinguishing it from traditional high school precalculus offerings.^[7] The course was positioned as a capstone for students completing Algebra 2 or Integrated Math III, providing a rigorous yet accessible pathway that prepares learners for advanced topics without assuming prior exposure to precalculus concepts.^[7] However, implementation has faced some local controversies, such as schools mandating it in place of honors precalculus courses.^[8]^[9] Key milestones included the first implementation during the 2023-2024 school year, starting in fall 2023, followed by the inaugural AP Precalculus Exam administered in May 2024, with a second administration in May 2025.^[7] The course has seen rapid adoption, becoming the fastest-growing AP course as of 2025, with 76% of 2024 exam takers scoring 3 or higher.^[10] Unlike AP Calculus AB, which presupposes knowledge of precalculus topics like advanced functions and trigonometry, AP Precalculus fills a critical void for students in schools without dedicated advanced math tracks, enabling broader participation in AP-level mathematics and facilitating credit or placement at over 3,300 colleges and universities, as validated by the American Council on Education.^[7]^[1] This expansion aims to motivate a diverse range of students, including those starting high school with Algebra I, to persist in mathematics and pursue STEM pathways.^[1]

Purpose and Prerequisites

The AP Precalculus course aims to prepare high school students for entry into college-level mathematics and science courses, particularly calculus, by fostering a deep conceptual understanding of functions as tools for modeling real-world phenomena. It emphasizes the analysis of how quantities change and interact dynamically, building skills in problem-solving, quantitative reasoning, and mathematical modeling that are essential for success in STEM fields and beyond. Unlike traditional precalculus courses that may prioritize rote procedural skills, AP Precalculus shifts focus toward interpreting functions through multiple representations—graphical, numerical, analytical, and verbal—to develop fluency in constructing and validating models for diverse applications in natural and social sciences. This approach serves as a capstone for secondary mathematics education, equipping students with the foundational knowledge needed to tackle advanced topics like rates of change, limits, and extrema in subsequent coursework.^[7]^[3] Designed for students seeking college credit, advanced placement, or enhanced readiness, AP Precalculus targets high school juniors and seniors, especially those in schools lacking dedicated advanced precalculus options. It provides an accessible pathway to rigorous mathematics for a broad audience, including both STEM-aspiring students and those pursuing other majors, by increasing overall college preparedness through targeted practice in function-based reasoning. The course bridges the gap between high school and college curricula by prioritizing modeling over mechanical computation, encouraging the use of technology such as graphing calculators to explore real-world data and validate function behaviors. An optional extension in Unit 4 introduces parametric functions, vectors, and matrices to further enrich understanding for interested students, though this content is not required for exam preparation or core prerequisites.^[2]^[3] Successful participation requires proficiency in foundational topics from prior high school mathematics courses, ensuring students can engage with the course's emphasis on function analysis without prior calculus exposure. The table below outlines the key prerequisites:

Course	Required Proficiency
Algebra 1	Linear and quadratic equations, inequalities; basic manipulation of polynomials.
Geometry	Coordinate geometry; right-triangle trigonometry and basic properties.
Algebra 2	Polynomial operations (addition, multiplication, factoring, quadratic formula); exponential and logarithmic functions; radicals; complex numbers; piecewise functions; systems of 2–3 equations.

No calculus background is necessary, as the course builds directly on these prerequisites to introduce college-level function concepts.^[7]^[2]

Course Framework

Big Ideas and Enduring Understandings

The AP Precalculus course is organized around three foundational Big Ideas—Change, Patterns, and Equivalence—that unify the curriculum and emphasize the role of functions in modeling and analyzing mathematical relationships.^[7] The Big Idea of Change focuses on how functions represent dynamic relationships between quantities, including rates of change and transformations that describe variation over time or in response to inputs.^[7] Patterns highlight the recognizable structures in functions, such as periodicity, symmetry, and sequences, which allow for prediction and generalization of behavior.^[7] Equivalence underscores the interconnectedness of multiple representations—algebraic, graphical, numerical, and contextual—to interpret function properties and apply them to real-world scenarios.^[7] These Big Ideas are supported by Enduring Understandings, which articulate the core principles students retain for long-term conceptual mastery. Under Change, enduring understandings include that functions model how quantities vary together, rates of change provide insights into function behavior (such as average or instantaneous rates), and transformations predictably alter how functions represent dynamic processes.^[7] For Patterns, key principles are that functions exhibit identifiable patterns like linear growth, exponential decay, or cyclical repetition, enabling analysis and forecasting of outcomes.^[7] The Equivalence Big Idea yields understandings that equivalent representations reveal different aspects of the same relationship, models link function properties to practical contexts, and synthesizing diverse views accounts for limitations and uncertainties in predictions.^[7] The Big Ideas and Enduring Understandings integrate across the course's four units, fostering conceptual depth by linking topics like polynomial functions in Unit 1 to trigonometric patterns in Unit 3, rather than treating skills in isolation.^[7] This approach ensures students develop a cohesive framework for exploring function behaviors, from covariation in exponential models to periodic connections in polar representations.^[7] In the course design, these elements guide all learning objectives, promoting transferable knowledge for advanced mathematics and STEM fields by prioritizing multirepresentational thinking, modeling applications, and interpretive problem-solving over rote procedures.^[7] This structure prepares students for college-level calculus and beyond, emphasizing enduring principles that reveal the power of functions in describing change and patterns in diverse contexts.^[7]

Mathematical Practices and Skills

The AP Precalculus course emphasizes three interconnected mathematical practices that students develop throughout the curriculum to build proficiency in precalculus concepts. These practices—procedural and symbolic fluency, multiple representations, and communication and reasoning—guide students in manipulating mathematical objects, connecting ideas across forms, and articulating their thinking precisely.^[7] By engaging with these practices, students gain the tools to explore functions and models effectively, aligning with broader course goals such as understanding change and patterns.^[7] Procedural and Symbolic Fluency involves algebraically manipulating functions, equations, and expressions using definitions and theorems to solve problems and justify solutions. Students practice this by solving equations and inequalities analytically, expressing functions in equivalent forms for specific contexts, and constructing new functions through transformations, compositions, inverses, or regressions.^[7] Multiple Representations requires translating information between graphical, numerical, analytical, and verbal forms to identify key features and construct equivalent representations. This practice enables students to answer questions from one representation and build models by connecting others, fostering a comprehensive view of functions.^[7] Communication and Reasoning focuses on using precise language to describe function characteristics, apply numerical results in contexts, and support conclusions with logical rationales or data. Students learn to implement algebraic and computational processes while explaining their choices clearly.^[7] These practices are operationalized through eight specific skills that progress from foundational tasks to more sophisticated applications. Early skills emphasize basic operations, such as solving equations analytically (Skill 1.A) or identifying information from graphs and tables (Skill 2.A), allowing students to determine function values or simple properties.^[7] As the course advances, skills build toward complex reasoning, including constructing equivalent representations for modeling (Skill 2.B), describing detailed function behaviors like asymptotes or extrema (Skill 3.A), and justifying model selections with evidence (Skill 3.C). This scaffolded progression—from routine computation to interpretive analysis—ensures students can compare models, evaluate end behaviors, and approximate limits through multiple lenses.^[7] Technology integration enhances these practices, particularly through graphing calculators, which students use for visualizing functions, performing regressions to fit models, and conducting operations like matrix computations when applicable. Calculators support exploration without replacing symbolic fluency; for instance, they aid in graphing transformations or analyzing residuals, but students must also demonstrate hand-calculated manipulations.^[7] On the AP Exam, these skills are assessed via a mix of calculator-allowed and no-calculator sections, with criterion-referenced scoring that evaluates procedural accuracy, representational connections, and reasoned explanations rather than isolated computations. Multiple-choice and free-response items test fluency in solving, translating representations, and communicating insights, contributing to overall exam weighting of 38%–49% for procedural skills, 20%–26% for representations, and 32%–40% for reasoning.^[7]

Curriculum

Unit 1: Polynomial and Rational Functions

Unit 1 introduces students to the analysis of polynomial and rational functions, emphasizing their algebraic properties, graphical behaviors, and applications in modeling real-world scenarios. This unit builds on prerequisites such as polynomial manipulation from Algebra 2, with brief reviews as needed to ensure foundational skills. It constitutes 30–40% of the AP Precalculus exam, focusing on students' ability to interpret function behaviors through rates of change, zeros, asymptotes, and transformations.^[7] A core emphasis is on change in tandem, or covariation, where students examine how two quantities vary together within functions, such as the coordinated movement of input and output values in polynomial expressions. This leads into rates of change, including average rates calculated as \frac{f(b) - f(a)}{b - a} over an interval and instantaneous rates approximated by the slope of secant lines approaching the tangent. For linear functions, rates of change remain constant, while in quadratic functions, they vary linearly, providing insight into accelerating or decelerating behaviors. Polynomial functions extend this by incorporating higher degrees, where the rate of change depends on the interval and the function's degree, with leading coefficients influencing the steepness.^[7] Polynomial functions are defined as p(x) = a_n x^n + a_{n-1} x^{n-1} + \cdots + a_1 x + a_0, where n is the degree and a_n \neq 0. The degree determines the number of possible real zeros (up to n) and the end behavior: for even degrees, both ends rise or fall together based on the sign of a_n; for odd degrees, one end rises while the other falls. Zeros are found via factoring, applying the Factor Theorem (if p(c) = 0, then x - c is a factor) and Remainder Theorem (dividing by x - c yields remainder p(c)). Polynomial division, including synthetic division for linear factors, enables factorization and analysis of roots, including complex zeros guaranteed by the Fundamental Theorem of Algebra. End behavior is analyzed using limits as x \to \pm \infty, revealing whether the graph approaches positive or negative infinity.^[7] Rational functions take the form r(x) = \frac{p(x)}{q(x)}, where p(x) and q(x) are polynomials with no common factors, and the domain excludes values where q(x) = 0. Simplification involves canceling shared factors, which may create holes (removable discontinuities) at those points. Vertical asymptotes occur at zeros of q(x) that are not zeros of p(x), indicating undefined behavior and infinite limits. Horizontal asymptotes are determined by degree comparison: if \deg(p) < \deg(q), the asymptote is y = 0; if equal, y = \frac{a_n}{b_m}; if \deg(p) = \deg(q) + 1, a slant asymptote exists via polynomial division. Limits at infinity assess end behavior, contrasting with polynomial growth by approaching constant values. Zeros of rational functions are the zeros of p(x), provided they are in the domain.^[7] Transformations of these functions include shifts (f(x - h) + k for horizontal shift by h and vertical by k), stretches or compressions (a f(x) for vertical scaling by |a|, f(bx) for horizontal), and reflections (over the x-axis via -f(x), y-axis via f(-x)). These modify parent graphs, affecting zeros, asymptotes, and rates of change while preserving overall shape. Equivalent representations—graphical, numerical, and analytical—allow students to connect these transformations across formats.^[7] In modeling applications, polynomials suit scenarios with quadratic or cubic growth, such as projectile motion or area optimization, where multiple constraints define the function. Rational functions model inverse relationships or asymptotic approaches, like average fuel efficiency decreasing with speed or resource depletion nearing a limit. Students select models based on context, construct them using data and regression tools, and evaluate fit through residuals, prioritizing conceptual alignment over exhaustive computation. This unit typically spans 30–40 class periods, integrating technology for graphing and analysis to reinforce these skills.^[7]

Unit 2: Exponential and Logarithmic Functions

Unit 2 of the AP Precalculus curriculum introduces students to exponential and logarithmic functions as tools for modeling dynamic phenomena involving proportional change, such as growth and decay processes. Building on the polynomial and rational functions from Unit 1, which describe algebraic variation with polynomial rates, this unit shifts focus to continuous, non-periodic quantitative changes characterized by constant relative rates. Exponential functions model scenarios where the rate of change is proportional to the current value, while logarithmic functions serve as their inverses, enabling the analysis of scales that compress wide ranges of data. The unit encompasses sequences, function manipulation, equation solving, and data modeling, with an emphasis on multiple representations—graphical, numerical, analytical, and verbal—to foster deep conceptual understanding. Allocated 30–45 class periods, this unit accounts for 27–40% of the AP Exam weighting.^[7] Sequences provide a discrete foundation for understanding exponential behavior, distinguishing arithmetic sequences, which exhibit constant differences, from geometric sequences, which feature constant ratios. An arithmetic sequence is defined by the formula a_n = a_0 + d n, where a_0 is the initial term and d is the common difference, modeling linear change over discrete intervals. In contrast, a geometric sequence follows g_n = g_0 r^n, with g_0 as the initial term and r as the common ratio; for example, if r > 1, the terms grow exponentially, paralleling continuous exponential functions. These sequences illustrate covariation: arithmetic ones show additive growth, while geometric ones demonstrate multiplicative scaling, essential for transitioning to continuous models in real-world contexts like population projections over discrete time steps.^[7] Exponential functions formalize continuous growth and decay, expressed in the general form f(x) = a b^x, where a represents the initial value and b is the base or growth factor. If b > 1, the function models exponential growth, such as population increase where each increment is proportional to the existing population; conversely, $0 < b < 1 indicates decay, as in radioactive half-life scenarios. The domain is all real numbers, with a horizontal asymptote at y = 0 for a > 0, contrasting the unbounded end behavior of polynomials from Unit 1. Properties of exponents allow manipulation, such as b^{x+y} = b^x b^y and (b^x)^y = b^{xy}, facilitating the rewriting of expressions for simplification. In applications like compound interest, the model A(t) = P (1 + r/n)^{nt} approximates continuous growth as n increases, converging to A(t) = P e^{rt} using the natural base e \approx 2.718. Students construct these models from bivariate data via exponential regression and validate them using residual plots to assess fit.^[7] Logarithmic functions emerge as the inverses of exponential functions, defined such that if y = b^x, then x = \log_b y, or equivalently, \log_b c = d where b^d = c. The standard form is f(x) = a \log_b x, with domain restricted to x > 0 and range all real numbers, featuring a vertical asymptote at x = 0. Logarithms enable solving for exponents in equations and modeling compressed scales, such as the Richter scale for earthquake magnitude, where each unit increase represents a tenfold amplification in amplitude, or pH levels in chemistry, quantifying acidity via \mathrm{pH} = -\log_{10} [\mathrm{H}^+]. Key properties include the product rule \log_b (xy) = \log_b x + \log_b y, quotient rule \log_b (x/y) = \log_b x - \log_b y, and power rule \log_b (x^n) = n \log_b x, which mirror exponent rules and aid in expression manipulation. The change of base formula, \log_b a = \frac{\ln a}{\ln b}, allows computation using natural or common logarithms, broadening applicability.^[7] Function composition and inverses connect exponentials and logarithms conceptually: the composition \log_b (b^x) = x yields the identity function, underscoring their inverse relationship. Students evaluate compositions like f(g(x)) and determine inverses analytically or graphically, reinforcing that logarithmic inputs correspond to exponential outputs. In data modeling, semi-log plots linearize exponential relationships by plotting logarithms of one variable against the other, simplifying regression analysis for phenomena like sound intensity decay. Validation involves comparing competing models—e.g., exponential versus linear—for contexts like bacterial growth, using residuals to quantify deviations and ensure the model's proportionality captures the data's dynamic nature.^[7] Solving exponential and logarithmic equations and inequalities integrates these concepts, often requiring isolation and application of inverse operations. For an exponential equation like a b^x = c, taking the logarithm yields x = \log_b (c/a); similarly, \log_b x = y rewrites as x = b^y. Inequalities follow analogous steps, considering domain restrictions and base values (e.g., for b > 1, \log_b x > y implies x > b^y). Technology supports numerical solutions, but analytical methods emphasize properties to avoid extraneous roots. These skills culminate in modeling tasks, such as fitting logarithmic regressions to data on viral spread or economic scaling, prioritizing conceptual insight into proportional change over rote computation.^[7]

Unit 3: Trigonometric and Polar Functions

Unit 3 of the AP Precalculus curriculum introduces trigonometric and polar functions as tools for modeling periodic phenomena and circular motion, extending the function analysis from Units 1 and 2 by incorporating periodicity and angular representations. This unit emphasizes the sine and cosine functions defined via the unit circle, transformations of sinusoidal models, key trigonometric identities, solutions to trigonometric equations, and the polar coordinate system for graphing curves like roses and limaçon. Allocated 30–35% of the exam weight, the unit is designed for 35–50 class periods of instruction, allowing students to develop proficiency in representing cyclical behaviors such as oscillations and rotations.^[7] Periodic phenomena, such as repeating cycles in nature or technology, are central to this unit and are modeled using trigonometric functions that exhibit inherent periodicity. The basic sine and cosine functions have a period of $2\pi, meaning their values repeat every $2\pi radians, which captures the repetitive nature of events like daily temperature fluctuations or mechanical vibrations. Students explore how these functions arise from the unit circle, a circle of radius 1 centered at the origin in the coordinate plane, where for an angle \theta measured counterclockwise from the positive x-axis, \cos \theta is the x-coordinate of the point on the circle and \sin \theta is the y-coordinate. This geometric definition extends the right-triangle ratios from basic trigonometry to all angles, enabling the evaluation of trigonometric values for any \theta.^[7]^[11] Sinusoidal functions generalize sine and cosine to model real-world periodic data through transformations that adjust amplitude, period, phase shift, and midline. The standard form is y = A \sin(B(x - C)) + D, where A represents the amplitude (half the range of the function), the period is \frac{2\pi}{B} (controlling the horizontal stretch or compression), C is the phase shift (horizontal translation), and D is the midline (vertical shift, often the average value of the oscillation). For example, the height of a pendulum bob undergoing simple harmonic motion can be approximated by such a model for small angles, where the amplitude reflects the maximum displacement and the period depends on the pendulum's length, illustrating rates of change like velocity as the derivative of the position function. Similarly, sound waves are modeled as sinusoidal pressure variations over time, with frequency related to the period. These models build conceptual understanding by fitting data to identify parameters, such as estimating amplitude and phase from scatterplots of periodic observations.^[7]/07%3A_Trigonometric_Identities_and_Equations/7.06%3A_Modeling_with_Trigonometric_Equations) Key trigonometric identities facilitate simplification and verification in modeling and equation solving. The Pythagorean identities, \sin^2 \theta + \cos^2 \theta = 1, \tan^2 \theta + 1 = \sec^2 \theta, and $1 + \cot^2 \theta = \csc^2 \theta, stem directly from the unit circle definitions and right-triangle relationships. Angle addition formulas, such as \sin(\alpha + \beta) = \sin \alpha \cos \beta + \cos \alpha \sin \beta and \cos(\alpha + \beta) = \cos \alpha \cos \beta - \sin \alpha \sin \beta, allow expansion of composite angles, useful for deriving other identities or analyzing phase shifts in models. These identities are applied to rewrite expressions, prove equivalences, and solve problems involving multiple angles.^[7]^[12] Solving trigonometric equations requires accounting for the periodic nature of the functions, yielding infinitely many solutions within each cycle. For instance, to solve \sin x = k where -1 \leq k \leq 1, students use the inverse sine function to find the principal value \theta = \arcsin k in [-\pi/2, \pi/2], then add multiples of the period $2\pi and consider the cosine-reflected solution \pi - \theta for the full set of solutions in one period. Similar approaches apply to cosine and tangent equations, often involving identities to isolate the trigonometric term. Graphical and algebraic methods reinforce understanding, such as identifying intersections of y = \sin x and horizontal lines on the unit circle or transformed graphs.^[7] Polar coordinates provide an alternative system to rectangular coordinates, using a radius r (distance from the origin) and angle \theta (from the positive x-axis) to locate points, represented as (r, \theta). Conversions between systems are given by x = r \cos \theta and y = r \sin \theta, with the reverse r = \sqrt{x^2 + y^2} and \theta = \arctan(y/x) (adjusting for quadrant). Polar functions of the form r = f(\theta) generate graphs by plotting points for \theta from 0 to $2\pi (or more for full curves), revealing symmetric patterns suited to rotational symmetry. Common graphs include roses, r = a \sin(n\theta) or r = a \cos(n\theta), which produce petal-like shapes with n petals if n is odd or $2n if even, and limaçon, r = a + b \cos \theta or r = a + b \sin \theta, which form cardioid (when a = b) or looped/convex curves depending on the ratio a/b. These are modeled for contexts like planetary orbits approximated in polar form or cardioids representing certain reflective paths. Rates of change in polar settings, such as angular speed, extend analysis of periodic motion.^[7]

Unit 4: Functions Involving Parameters, Vectors, and Matrices

Unit 4 of the AP Precalculus curriculum explores advanced mathematical tools for modeling complex relationships and transformations in multiple dimensions, building on the foundational functions from earlier units. This unit introduces parametric functions, vectors, and matrices as extensions of concepts like polar coordinates covered in Unit 3, allowing students to represent paths, directions, and linear mappings that traditional single-variable functions cannot capture. With an allocated instructional time of approximately 35 class periods, the content is designed for post-exam flexibility and is not assessed on the AP Precalculus exam.^[7] Parametric functions provide a method to describe relationships between variables using a parameter, typically time or another independent variable, enabling the modeling of curves and paths that may not be expressible as simple y = f(x) relations. In two dimensions, a parametric function is defined by equations of the form x = f(t) and y = g(t), where t varies over an interval, producing a graph that traces a path in the plane. Graphs of parametric functions do not necessarily pass the vertical line test, distinguishing them from standard functions, and they are particularly useful for representing motion or cyclical patterns. For instance, conic sections can be parametrized, such as an ellipse given by x = a \cos t and y = b \sin t for $0 \leq t < 2\pi, which generates the curve without solving for one variable in terms of the other.^[7] One key application of parametric functions is in modeling planar motion, such as projectile trajectories under gravity. In this context, the horizontal position might be x(t) = v_0 \cos \theta \cdot t, where v_0 is initial velocity and \theta is the launch angle, while the vertical position is y(t) = v_0 \sin \theta \cdot t - \frac{1}{2} g t^2, with g as gravitational acceleration; this pair of equations captures the parabolic path over time t. Students analyze rates of change in parametric forms, such as velocity components derived from derivatives with respect to t, to understand acceleration and direction. Parametrizations extend to lines and circles as well, for example, a circle of radius r centered at the origin via x = r \cos t and y = r \sin t, facilitating the study of periodic or rotational behaviors.^[7] Vectors extend scalar quantities by incorporating both magnitude and direction, essential for representing physical quantities like displacement or force in two or three dimensions. A vector in 2D is denoted as \vec{v} = \langle v_x, v_y \rangle, where v_x and v_y are its components along the axes, and its magnitude is calculated as |\vec{v}| = \sqrt{v_x^2 + v_y^2}. Basic operations include vector addition, performed component-wise as \vec{u} + \vec{v} = \langle u_x + v_x, u_y + v_y \rangle, and scalar multiplication, which scales the vector by a constant k to yield k \vec{v} = \langle k v_x, k v_y \rangle. The dot product, defined as \vec{u} \cdot \vec{v} = u_x v_x + u_y v_y, measures the alignment between vectors and equals the product of their magnitudes times the cosine of the angle between them, useful for projections and work calculations. In 3D, vectors take the form \vec{v} = \langle v_x, v_y, v_z \rangle with analogous operations and magnitude |\vec{v}| = \sqrt{v_x^2 + v_y^2 + v_z^2}. Vector-valued functions, such as \vec{r}(t) = \langle x(t), y(t) \rangle, combine parametric equations to model paths in space.^[7] Matrices serve as tools for linear transformations and systems modeling, representing functions that map input vectors to output vectors in a structured way. A matrix A of size m \times n acts on a vector \vec{x} via multiplication A \vec{x}, producing a transformed vector; for example, a 2x2 matrix can encode rotations or scalings. A rotation by angle \theta counterclockwise is given by the matrix \begin{pmatrix} \cos \theta & -\sin \theta \\ \sin \theta & \cos \theta \end{pmatrix}, which applied to a point \begin{pmatrix} x \\ y \end{pmatrix} yields the rotated coordinates. Scaling by factors a and b uses \begin{pmatrix} a & 0 \\ 0 & b \end{pmatrix}, stretching the plane non-uniformly. The determinant of a 2x2 matrix \begin{pmatrix} a & b \\ c & d \end{pmatrix} is ad - bc, indicating whether the transformation preserves orientation or scales area, while the inverse matrix A^{-1}, if it exists (determinant nonzero), undoes the transformation such that A^{-1} A = I, the identity matrix. Matrix multiplication follows row-by-column rules, enabling composition of transformations.^[7] These concepts converge in modeling applications across disciplines. Parametric equations and vectors model dynamic systems like projectile motion or orbital paths, while matrices apply to computer graphics for rendering transformations and to economics for input-output analysis, such as Leontief models where a matrix represents production coefficients across sectors. For example, in graphics, successive matrix multiplications simulate combined rotations and scalings to manipulate 2D images efficiently. This unit emphasizes conceptual understanding through graphs, tables, and contextual problems, preparing students for multivariable calculus or linear algebra without requiring exhaustive computations.^[7]

Examination

Exam Format and Content

The AP Precalculus Exam is a 3-hour assessment administered annually in May, consisting of two main sections that together evaluate students' mastery of the course's core concepts and skills from Units 1 through 3.^[7] Section I features 40 multiple-choice questions, accounting for 62.5% of the exam score, while Section II includes 4 free-response questions, weighted at 37.5%.^[7] The multiple-choice section is divided into Part A (28 questions, 80 minutes, no calculator permitted) and Part B (12 questions, 40 minutes, graphing calculator required), designed to test quick conceptual understanding and application.^[5] Free-response questions are similarly split, with Part A (2 questions, 30 minutes, graphing calculator required) and Part B (2 questions, 30 minutes, no calculator permitted), each worth 6 points for a total of 24 points in this section.^[7] Content coverage on the exam focuses exclusively on Units 1 (Polynomial and Rational Functions, 30–40%), 2 (Exponential and Logarithmic Functions, 27–40%), and 3 (Trigonometric and Polar Functions, 30–35%), emphasizing mathematical modeling, function analysis, and key skills such as identifying function types, interpreting rates of change, and solving equations in contextual scenarios.^[7] Multiple-choice questions typically assess foundational concepts through single- or multiple-select formats, often requiring students to select the correct asymptote for a rational function or evaluate a logarithmic expression's behavior.^[14] In contrast, free-response questions demand extended reasoning and justification, such as constructing a polynomial model for real-world data and explaining its limitations, or deriving trigonometric identities to solve periodic problems, aligning with the course's mathematical practices for precise communication and representation translation.^[7] Graphing calculators are required for designated sections (Parts B of both multiple-choice and free-response) to support tasks like graphing functions, performing regressions, and analyzing data tables, but devices with internet access, such as cell phones or tablets, are prohibited to maintain exam integrity.^[15] The exam is administered in a hybrid digital format starting in 2025, using the Bluebook app for viewing questions and paper booklets for free-response answers, with accommodations available through the College Board's Services for Students with Disabilities (SSD) program for eligible students.^[16] For the 2026 administration, it is scheduled for May 12 at 8 a.m. local time.^[5]

Section	Part	Questions	Time	Calculator Policy	Exam Weight
Multiple-Choice (Section I)	A	28	80 minutes	Not permitted	62.5% total (43.75% for Part A)
	B	12	40 minutes	Graphing calculator required	62.5% total (18.75% for Part B)
Free-Response (Section II)	A	2	30 minutes	Graphing calculator required	37.5% total (18.75% for Part A)
	B	2	30 minutes	Not permitted	37.5% total (18.75% for Part B)

Scoring and Performance Data

The AP Precalculus exam is scored on a 1 to 5 scale, a criterion-referenced system that measures student performance against predefined standards rather than curving scores relative to other test-takers.^[17] A score of 5 indicates extremely well qualified performance, equivalent to an A or A+ in a college course; 4 is very well qualified, akin to an A- to B; 3 is qualified, corresponding to a B- to C; 2 is possibly qualified; and 1 offers no recommendation for college credit or placement.^[17] The composite score is derived from the multiple-choice section, which accounts for 62.5% of the total (40 questions, each worth approximately 1 raw point with no penalty for incorrect answers), and the free-response section, which contributes 37.5% (4 questions, each scored from 0 to 6 points based on rubric criteria).^[5] Raw scores are scaled through equating processes to ensure consistency across exam versions, resulting in the final 1-5 score.^[5] Performance data for the AP Precalculus exam, introduced in 2023 with its first administration in 2024, show steady improvement in student outcomes. In 2024, the exam's debut year, 75.6% of students achieved a score of 3 or higher, reflecting initial challenges associated with the course's novelty and limited prior teaching experience. By 2025, the pass rate (scores of 3 or above) rose to 80.8%, with increased participation—approximately 70,000 more students than in 2024—indicating broader access and enhanced preparation through resources like AP Classroom modules and practice exams.^[18]^[19] The exam's emphasis on conceptual understanding and mathematical modeling, rather than rote computation, influences these scores, as students must demonstrate skills in interpreting functions and solving contextual problems.^[5]

Year	Score 5 (%)	Score 4 (%)	Score 3 (%)	Score 2 (%)	Score 1 (%)	Mean Score	Total Test-Takers
2024	25.9	23.9	25.9	14.6	9.8	3.42	184,394
2025	28.1	25.8	26.8	11.2	8.0	3.55	253,596

Source: College Board AP Score Distributions^[18] College credit policies for AP Precalculus vary by institution, but a score of 3 or higher generally qualifies students for credit equivalent to a college precalculus course at many universities, potentially fulfilling prerequisites for calculus or granting elective credits.^[20] For example, selective policies at institutions like the University of California system may not award credit for this exam, emphasizing its role more as preparation than direct equivalency.^[21] Students should consult specific college policies via the College Board's credit search tool to confirm eligibility.^[20]