Group 5

IB Math AA HL Past Papers

Full-length papers matching IB format, timing, and mark allocation — scoped to the current syllabus with criterion-referenced feedback.

Official source: IB mathematics curriculum

How it works

1
Choose your paper type and topic weighting
2
Complete the paper under timed conditions
3
Get AI marking against the mark scheme

Start practicing Math AA HL

Start free

More Math AA HL tools

Practice Papers

Target your weak spots

Custom papers focused on specific topics. Pick the outcomes you want to drill, set the marks, and generate exactly what you need.

Syllabus

See where you stand

Every syllabus outcome mapped visually. Track which topics are solid, which need work, and how ready you are for mocks.

Paper 3

HL Paper 3 practice

Extended-response questions in Paper 3 format. HL-only component with deeper problem-solving.

Syllabus viewer

Topic and outcome data shown here comes from Edvana's local syllabus data for this subject, filtered by listed level.

Math AA HL

5 topics83 outcomesLocal syllabus version: 2021

Number and Algebra

16 outcomes

Open

SL 1.1Operations with numbers in the form a × 10^k where 1 ≤ a < 10 and k is an integer (scientific notation); calculator notation is not acceptable
SL 1.2Arithmetic sequences and series: formulae for the nth term and the sum of the first n terms; use of sigma notation; applications
SL 1.3Geometric sequences and series: formulae for the nth term and the sum of the first n terms; use of sigma notation; applications
SL 1.4Financial applications of geometric sequences and series: compound interest and annual depreciation; calculating the real value of an investment with interest and inflation
SL 1.5Laws of exponents with integer exponents; introduction to logarithms with base 10 and e; awareness that a^x = b is equivalent to log_a(b) = x; numerical evaluation of logarithms using technology
SL 1.6Simple deductive proof, numerical and algebraic; how to lay out a left-hand side to right-hand side (LHS to RHS) proof; symbols and notation for equality and identity
SL 1.7Laws of exponents with rational exponents; laws of logarithms (product, quotient, power rules); change of base of a logarithm; solving exponential equations including using logarithms
SL 1.8Sum of infinite convergent geometric sequences; use of |r| < 1 and modulus notation
SL 1.9The binomial theorem: expansion of (a + b)^n for n ∈ ℕ; use of Pascal's triangle and nCr; finding specific terms
AHL 1.10Counting principles including permutations and combinations; extension of the binomial theorem to fractional and negative indices: (a + b)^n for n ∈ ℚ HL only
AHL 1.11Partial fractions: maximum of two distinct linear terms in the denominator, degree of numerator less than degree of denominator HL only
AHL 1.12Complex numbers: the number i where i² = −1; Cartesian form z = a + bi; real part, imaginary part, conjugate, modulus and argument; the complex plane (Argand diagram) HL only
AHL 1.13Modulus–argument (polar) form z = r(cosθ + i sinθ) = r cisθ; Euler form z = re^{iθ}; sums, products and quotients in Cartesian, polar or Euler forms and their geometric interpretation HL only
AHL 1.14Complex conjugate roots of quadratic and polynomial equations with real coefficients; De Moivre's theorem and its extension to rational exponents; powers and roots of complex numbers HL only
AHL 1.15Proof by mathematical induction; proof by contradiction; use of a counterexample to show a statement is not always true HL only
AHL 1.16Solutions of systems of linear equations (maximum of three equations in three unknowns) using algebraic and matrix/row-reduction methods; unique solution, infinite solutions, or no solution (inconsistent) HL only

Functions

16 outcomes

Open

SL 2.1Different forms of the equation of a straight line: gradient-intercept (y = mx + c), general (ax + by + d = 0), point-gradient form; gradient; intercepts; parallel lines (m1 = m2) and perpendicular lines (m1 × m2 = −1)
SL 2.2Concept of a function, domain, range and graph; function notation f(x), v(t), C(n); the concept of a function as a mathematical model; informal concept of inverse function; inverse notation f⁻¹(x); reflection in y = x
SL 2.3The graph of a function y = f(x); creating a sketch from information given or a context; using technology to graph functions including sums and differences; all axes and key features labelled
SL 2.4Key features of graphs: maximum and minimum values, intercepts, symmetry, vertex, zeros/roots, vertical and horizontal asymptotes using technology; finding the point of intersection of two curves or lines
SL 2.5Composite functions (f ∘ g)(x) = f(g(x)); identity function; finding the inverse function f⁻¹(x); existence of an inverse for one-to-one functions
SL 2.6The quadratic function f(x) = ax² + bx + c: graph, y-intercept, axis of symmetry; factored form f(x) = a(x−p)(x−q) with x-intercepts; vertex form f(x) = a(x−h)² + k with vertex (h, k)
SL 2.7Solution of quadratic equations and inequalities using factorization, completing the square, and the quadratic formula; the discriminant Δ = b² − 4ac and the nature of the roots (two distinct real, two equal real, no real roots)
SL 2.8The reciprocal function f(x) = 1/x and its self-inverse nature; rational functions f(x) = (ax + b)/(cx + d) and their graphs; equations of vertical and horizontal asymptotes
SL 2.9Exponential functions f(x) = a^x, f(x) = e^x and their graphs; logarithmic functions f(x) = log_a x, f(x) = ln x and their graphs; exponential and logarithmic functions as inverses of each other
SL 2.10Solving equations both graphically and analytically; use of technology to solve equations where there is no appropriate analytic approach; applications to real-life situations
SL 2.11Transformations of graphs: translations y = f(x) + b and y = f(x − a); reflections in both axes y = −f(x) and y = f(−x); vertical stretch y = p f(x); horizontal stretch y = f(qx); composite transformations
AHL 2.12Polynomial functions: graphs, equations, zeros, roots and factors; the factor and remainder theorems; sum and product of the roots of polynomial equations HL only
AHL 2.13Rational functions of the form f(x) = (ax + b)/(cx² + dx + e) and f(x) = (ax² + bx + c)/(dx + e); graphs including all asymptotes (horizontal, vertical and oblique) and intercepts HL only
AHL 2.14Odd and even functions; finding the inverse function f⁻¹(x) including domain restriction; self-inverse functions; periodic functions HL only
AHL 2.15Solutions of g(x) ≥ f(x) both graphically and analytically; graphical or algebraic methods for simple polynomials up to degree 3, technology for others HL only
AHL 2.16The graphs of y = |f(x)|, y = f(|x|), y = 1/f(x), y = f(ax + b), y = [f(x)]²; solution of modulus equations and inequalities HL only

Geometry and Trigonometry

18 outcomes

Open

SL 3.1Distance between two points in three-dimensional space and their midpoint; volume and surface area of 3D solids including right pyramid, right cone, sphere, hemisphere and combinations; angle between two intersecting lines or between a line and a plane
SL 3.2Use of sine, cosine and tangent ratios in right-angled triangles; the sine rule a/sinA = b/sinB = c/sinC; the cosine rule c² = a² + b² − 2ab cosC; area of a triangle as (1/2)ab sinC
SL 3.3Applications of right and non-right-angled trigonometry including Pythagoras's theorem; angles of elevation and depression; construction of labelled diagrams from written statements; contexts may include bearings
SL 3.4The circle: radian measure of angles; length of an arc; area of a sector
SL 3.5Definition of cosθ and sinθ in terms of the unit circle; definition of tanθ as sinθ/cosθ; exact values of trig ratios of 0, π/6, π/4, π/3, π/2 and their multiples; extension of the sine rule to the ambiguous case
SL 3.6The Pythagorean identity cos²θ + sin²θ = 1; double angle identities for sine and cosine; relationship between trigonometric ratios
SL 3.7The circular functions sinx, cosx and tanx: amplitude, periodic nature and graphs; composite functions of the form f(x) = a sin(b(x + c)) + d; transformations; real-life contexts such as tide height or Ferris wheel motion
SL 3.8Solving trigonometric equations in a finite interval both graphically and analytically; equations leading to quadratic equations in sinx, cosx or tanx
AHL 3.9Definition of the reciprocal trigonometric ratios secθ, cosecθ and cotθ; Pythagorean identities 1 + tan²θ = sec²θ and 1 + cot²θ = cosec²θ; inverse trig functions arcsin, arccos, arctan: domains, ranges and graphs HL only
AHL 3.10Compound angle identities for sin(A ± B), cos(A ± B), tan(A ± B); derivation of double angle identities from compound angle identities; double angle identity for tan HL only
AHL 3.11Relationships between trigonometric functions and the symmetry properties of their graphs, e.g. sin(π − θ) = sinθ, cos(π − θ) = −cosθ, tan(π − θ) = −tanθ HL only
AHL 3.12Concept of a vector; position vectors; displacement vectors; representation using directed line segments; base vectors i, j, k; components; algebraic and geometric approaches to sum/difference, zero vector, scalar multiplication, magnitude and unit vectors HL only
AHL 3.13The scalar (dot) product of two vectors: definition, properties, angle between two vectors v · w = |v||w|cosθ; perpendicular vectors (v · w = 0); parallel vectors (|v · w| = |v||w|) HL only
AHL 3.14Vector equation of a line in two and three dimensions r = a + λb; parametric form and Cartesian form; the angle between two lines; simple applications to kinematics HL only
AHL 3.15Coincident, parallel, intersecting and skew lines in 3D; distinguishing between these cases; points of intersection HL only
AHL 3.16The vector product v × w of two vectors: definition, properties; geometric interpretation |v × w| as area of parallelogram (and hence triangle) HL only
AHL 3.17Vector equations of a plane: r = a + λb + μc; r · n = a · n; Cartesian equation ax + by + cz = d HL only
AHL 3.18Intersections of: a line with a plane; two planes; three planes; finding intersections by solving equations; geometrical interpretation of solutions; angle between a line and a plane and between two planes HL only

Statistics and Probability

14 outcomes

Open

SL 4.1Concepts of population, sample, random sample, discrete and continuous data; reliability of data sources and bias in sampling; interpretation of outliers (data more than 1.5 × IQR from nearest quartile); sampling techniques: simple random, convenience, systematic, quota, stratified
SL 4.2Presentation of data: frequency distributions and tables; histograms; cumulative frequency graphs; use of cumulative frequency to find median, quartiles, percentiles, range and IQR; box-and-whisker diagrams; comparing two distributions
SL 4.3Measures of central tendency: mean, median and mode; estimation of mean from grouped data; modal class; measures of dispersion: IQR, standard deviation and variance; effect of constant changes on original data
SL 4.4Pearson's product-moment correlation coefficient r; linear correlation of bivariate data; scatter diagrams; positive, zero, negative; strong, weak, no correlation; equation of the regression line of y on x; use for prediction; distinguish correlation from causation
SL 4.5Concepts of trial, outcome, equally likely outcomes, relative frequency, sample space and event; probability of an event P(A) = n(A)/n(U); complementary events A and A′; expected number of occurrences
SL 4.6Use of Venn diagrams, tree diagrams, sample space diagrams and tables of outcomes; combined events P(A ∪ B) = P(A) + P(B) − P(A ∩ B); mutually exclusive events; conditional probability P(A|B) = P(A ∩ B)/P(B); independent events P(A ∩ B) = P(A)P(B)
SL 4.7Concept of discrete random variables and their probability distributions; expected value (mean) E(X) for discrete data; applications including fair games
SL 4.8Binomial distribution B(n, p): situations where it is an appropriate model; mean and variance of the binomial distribution; probabilities found using technology
SL 4.9The normal distribution and curve; properties of the normal distribution; diagrammatic representation; normal probability calculations using technology; inverse normal calculations
SL 4.10Equation of the regression line of x on y; use for prediction; awareness that a y-on-x line cannot always be used to predict x from a given y value
SL 4.11Formal definition and use of the conditional probability formula P(A|B) = P(A ∩ B)/P(B); testing for independence: P(A|B) = P(A) = P(A|B′) for independent events
SL 4.12Standardization of normal variables (z-values): z = (x − μ)/σ; the standardized value gives the number of standard deviations from the mean; inverse normal calculations where mean and standard deviation are unknown using z-values
AHL 4.13Use of Bayes' theorem for a maximum of three events HL only
AHL 4.14Variance of a discrete random variable; continuous random variables and their probability density functions; mode and median of continuous random variables; mean, variance and standard deviation of discrete and continuous random variables; effect of linear transformations E(aX + b) = aE(X) + b, Var(aX + b) = a²Var(X) HL only

Calculus

19 outcomes

Open

SL 5.1Introduction to the concept of a limit; derivative interpreted as gradient function and as rate of change; informal understanding of the gradient of a curve as a limit; derivative notation dy/dx, f′(x)
SL 5.2Increasing and decreasing functions; graphical interpretation of f′(x) > 0 (increasing), f′(x) = 0 (stationary), f′(x) < 0 (decreasing)
SL 5.3Derivative of f(x) = ax^n is f′(x) = anx^{n−1} for n ∈ ℤ; derivative of functions of the form f(x) = ax^n + bx^{n−1} + … with integer exponents
SL 5.4Tangents and normals at a given point and their equations; use of both analytic approaches and technology
SL 5.5Introduction to integration as anti-differentiation of f(x) = ax^n + bx^{n−1} + … for n ∈ ℤ, n ≠ −1; anti-differentiation with boundary condition to find the constant term; definite integrals using technology; area under a curve y = f(x) where f(x) > 0
SL 5.6Derivative of x^n (n ∈ ℚ), sinx, cosx, e^x and lnx; differentiation of a sum and a multiple of these functions; the chain rule for composite functions; the product and quotient rules
SL 5.7The second derivative f″(x) / d²y/dx²; graphical behaviour of functions including the relationship between the graphs of f, f′ and f″
SL 5.8Local maximum and minimum points; testing using change of sign of f′ or sign of f″; optimization; points of inflexion with zero and non-zero gradients; concave-up (f″ > 0) and concave-down (f″ < 0)
SL 5.9Kinematic problems involving displacement s, velocity v = ds/dt, acceleration a = dv/dt = d²s/dt²; total distance travelled; displacement and distance as definite integrals of velocity
SL 5.10Indefinite integrals of x^n (n ∈ ℚ), sinx, cosx, 1/x and e^x; composites of any of these with linear function ax + b; integration by inspection (reverse chain rule) or by substitution for ∫k g′(x) f(g(x)) dx
SL 5.11Definite integrals using analytical approach ∫_a^b g′(x) dx = g(b) − g(a); areas of a region enclosed by y = f(x) and the x-axis where f(x) can be positive or negative; areas between curves
AHL 5.12Informal understanding of continuity and differentiability at a point; understanding of limits (convergence and divergence); definition of derivative from first principles f′(x) = lim_{h→0} [f(x+h) − f(x)]/h; higher derivatives d^n y/dx^n and f^{(n)}(x) HL only
AHL 5.13Evaluation of limits of indeterminate forms 0/0 and ∞/∞ using l'Hôpital's rule or Maclaurin series; repeated use of l'Hôpital's rule HL only
AHL 5.14Implicit differentiation; related rates of change; optimisation problems including cases where the optimum is at an endpoint HL only
AHL 5.15Derivatives of tanx, secx, cosecx, cotx, a^x, log_a x, arcsinx, arccosx, arctanx; corresponding indefinite integrals; composites with a linear function; use of partial fractions to rearrange the integrand HL only
AHL 5.16Integration by substitution (substitution provided if not of form ∫k g′(x) f(g(x)) dx); integration by parts ∫u dv = uv − ∫v du; repeated integration by parts HL only
AHL 5.17Area of the region enclosed by a curve and the y-axis in a given interval; volumes of revolution about the x-axis or y-axis HL only
AHL 5.18First order differential equations: numerical solution using Euler's method; variables separable; homogeneous differential equations using substitution y = vx; solution of y′ + P(x)y = Q(x) using the integrating factor HL only
AHL 5.19Maclaurin series to obtain expansions for e^x, sinx, cosx, ln(1+x), (1+x)^p for p ∈ ℚ; use of substitution, products, integration and differentiation to obtain other series HL only