Quantitative reasoning and logical structures across arithmetic, geometry, and advanced analysis. Builds problem-solving skills through pattern recognition and modeling.
One-to-one correspondence and cardinality skills through counting discrete objects in various arrangements. Strengthens number recognition and the understanding of quantity.
Identification and spelling of number words from zero through millions. Connects numerical symbols to their written linguistic representations to strengthen mathematical literacy.
Mathematical symbols including greater than (>), less than (<), and equal to (=) to evaluate numerical relationships. Builds fluency in ordering sets and comparing quantities from single digits to multi-digit integers.
Proportional relationships, unit rates, and constant of proportionality. Develops strategies for solving multi-step problems involving scale, percentages, and equivalent ratios.
Analysis of equivalent ratios and the constant of proportionality across tables, graphs, and equations. Connects unit rates to linear relationships and real-world scaling applications.
Calculation and comparison of rates where the second quantity is one unit. Applies division strategies to solve real-world problems involving constant speed, unit pricing, and measurement conversions.
Numerical representation of parts of a whole and location on number lines. Develops understanding of fraction magnitude, equivalence, and the relationship between numerators and denominators.
Part-whole relationships, unit fractions, and numerator-denominator identification. Develops foundational understanding through visual area models, sets, and number line representations.
Visual models, common denominators, and benchmark fractions to compare and order values. Develops methods for identifying equivalent fractions and placing fractional numbers on a number line.
Calculation methods for fractions with like and unlike denominators using least common multiples. Covers regrouping with mixed numbers and simplifying final sums and differences.
Algorithmic procedures for multiplying and dividing proper, improper, and mixed fractions. Connects visual area models to standard calculations and the use of reciprocals.
Reciprocal operations, visual modeling, and the standard algorithm for dividing proper fractions and mixed numbers. Connects inverse operations to real-world division scenarios and word problems.
Equivalency between fractions with denominators of 10 or 100 and their decimal representations. Targets place value understanding, number line positioning, and basic operations with tenths and hundredths.
Standard algorithms for multi-digit multiplication and long division alongside prime factorization, GCF, and LCM. Strengthens computational fluency with decimal operations across all four basic functions.
Arithmetic operations including addition, subtraction, multiplication, and division of positive and negative fractions and decimals. Integrates strategies for common denominators, reciprocal multiplication, and precise decimal alignment.
Classification and representation of integers, fractions, and terminating or repeating decimals on the number line. Examines the relationships between subsets of real numbers and techniques for comparing and ordering rational values.
Identifies irrational numbers such as non-repeating decimals and square roots of non-perfect squares. Develops skills for estimating these values and positioning them accurately on a number line.
Fundamental concepts of limits, including one-sided and infinite limits, to analyze function behavior. Establishes formal criteria for continuity at points and across intervals as the basis for differentiation.
Instantaneous rates of change, slopes of tangent lines, and the formal limit definition. Introduces Leibniz and Lagrange notation for representing derivatives across different mathematical contexts.
Power, product, quotient, and chain rules for differentiating algebraic and transcendental functions. Strengthens skills in implicit differentiation and trigonometric derivatives for modeling rates of change.
Optimization, related rates, and curve sketching via first and second derivatives. Addresses real-world scenarios in physics and economics using the Mean Value Theorem and L'Hôpital's Rule.
Application of derivatives to identify absolute extrema within constrained systems. Addresses problems in surface area maximization, cost minimization, and physical efficiency.
Differentiation of interdependent variables with respect to time using the chain rule. Connects geometric formulas with algebraic manipulation to solve problems involving moving objects, fluid flow, and changing dimensions.
Analysis of function behavior using first and second derivatives to identify extrema, concavity, and points of inflection. Integrates limits, asymptotes, and intercepts to accurately visualize complex algebraic expressions graphically.
Fundamental principles of definite and indefinite integrals, Riemann sums, and the Fundamental Theorem of Calculus. Establishes proficiency in standard integration notation and area calculations under curves.
Fundamental techniques for reversing differentiation using the power rule, substitution, and basic transcendental functions. Emphasizes the relationship between derivatives and indefinite integrals including the constant of integration.
Evaluates the Fundamental Theorem of Calculus to determine the exact area under a curve and between multiple functions. Connects accumulation concepts to Riemann sums and definite integration techniques.
Formal connection between differentiation and integration through the evaluation of definite integrals using antiderivatives. Addresses both parts of the theorem to solve area problems and calculate rates of change.
Substitution, integration by parts, partial fractions, and trigonometric substitution methods for evaluating complex integrals. Connects foundational calculus concepts to advanced applications in area, volume, and physics.
Calculation of area between curves and volumes of solids using disk, washer, and shell methods. Connects integral calculus to physical applications like work, arc length, and centroids.
Examines first-order and higher-order linear equations using techniques like separation of variables, Laplace transforms, and power series. Connects mathematical models to physical systems such as population growth, fluid dynamics, and electrical circuits.
Arithmetic and geometric progressions, summation notation, and convergence tests for infinite series. Connects patterns in numbers to limits and foundational calculus concepts.
Differentiation and integration techniques for curves defined by independent parameters and polar coordinates. Targets area calculations, arc length, and coordinate conversions for non-Cartesian systems.
Maps scalar inputs to vectors to define curves in two and three-dimensional space. Calculates derivatives and integrals to analyze velocity, acceleration, arc length, and curvature.
Vector addition, scalar multiplication, and matrix operations including multiplication and determinants. Introduces linear transformations and system modeling through matrix equations.
Mathematical and physical quantities defined by both magnitude and direction. Emphasizes vector addition, component resolution, and applications in force and motion.
Calculation of vector sums, differences, and products in two and three dimensions. Examines magnitude, direction, and the application of dot and cross products to solve geometric and physical problems.
Addition, subtraction, and multiplication of matrices alongside techniques for calculating determinants and inverses. Supports solving systems of linear equations and modeling multi-dimensional data transformations.
Visual recognition and naming of two-dimensional and three-dimensional geometric figures. Builds classification skills based on properties such as sides, vertices, and curves.
Properties of two-dimensional and three-dimensional geometric figures, focusing on sides, angles, and vertices. Strengthens spatial awareness through classification and construction activities.
Identification of properties including sides, vertices, and angles in two-dimensional and three-dimensional shapes. Classifies and sorts objects based on shared attributes to build foundational geometric reasoning.
Identification of 2D and 3D shapes alongside their defining attributes like sides, angles, and vertices. Builds spatial reasoning by composing simple shapes into complex figures and decomposing larger objects into constituent parts.
Categorizes polygons based on side lengths, angle measures, and the presence of parallel or perpendicular lines. Distinguishes between subcategories of quadrilaterals and triangles using hierarchical relationships.
Properties of 2D and 3D shapes, including symmetry, congruence, and similarity. Develops spatial reasoning through the study of angles, lines, and coordinate transformations.
Geometric foundations including parallel and perpendicular lines, angle classification, and the properties of two-dimensional polygons. Strengthens spatial reasoning through the identification of vertices, edges, and symmetry.
Geometric properties including angle measurement, area of polygons, and volume of three-dimensional solids. Applies formulas and theorems to solve spatial reasoning problems.
Area, perimeter, and volume calculations for two- and three-dimensional figures. Develops spatial reasoning through the application of measurement formulas and unit conversions.
Formulas and calculations for determining the capacity of prisms, pyramids, cylinders, cones, and spheres. Develops spatial reasoning through applications involving cubic units and composite solids.
Quadrant navigation, distance calculations between points, and area determinations for polygons. Applies coordinate geometry to mapping, reflections, and data visualization.
Translations, rotations, reflections, and dilations within the coordinate system. Examines congruence and similarity through geometric mapping and algebraic rules.
Rigid transformations, scale factors, and proportional reasoning for identifying identical or scaled figures. Addresses triangle congruence criteria and similarity theorems for polygons.
Translations, rotations, and reflections define geometric congruence through the exact mapping of figures. Examines how rigid motions preserve distance and angle measure to establish structural equality.
Dilations and scale factors define similarity through proportional relationships and preserved angle measures. Examines sequences of rigid motions combined with resizing to map figures onto one another.
Geometric proofs using AA, SAS, and SSS criteria to establish triangle similarity. Applies proportional reasoning to solve for unknown side lengths and verify the Pythagorean theorem through similar sub-triangles.
Relationship between the sides of right triangles using the formula a² + b² = c². Guides students through solving for missing side lengths and applying the theorem to real-world geometric problems.
Law of Sines and Law of Cosines applications for solving non-right triangles. Includes area formulas for oblique triangles and techniques for finding unknown side lengths and angles.
Compass and straightedge techniques for bisecting angles, segments, and constructing perpendicular lines. Develops precision through the creation of parallel lines and inscribed regular polygons.
Logical deduction and formal proof methods applied to lines, angles, and polygons. Builds mastery of axioms and postulates while establishing properties of congruence and similarity.
Relationships between chords, secants, tangents, and inscribed angles. Establishes proofs for arc measures, segment lengths, and angle properties within circular geometry.
Calculation of arc lengths and sector areas using central angles and radius measurements. Applies proportional reasoning to circular geometry in both degrees and radians.
Geometric calculations for three-dimensional shapes including prisms, cylinders, pyramids, cones, and spheres. Develops skills for solving missing dimensions and real-world capacity problems.
Cross-sections of three-dimensional solids and the generation of solids of revolution from two-dimensional shapes. Connects planar geometry to spatial visualization through nets and surface area calculations.
Coordinate geometry techniques, including the distance, midpoint, and slope formulas, verify properties of polygons. Establishes formal proofs for parallel and perpendicular lines within a coordinate plane.
Derivation of algebraic equations from geometric definitions including foci, directrices, and vertices. Connects visual properties of parabolas, ellipses, circles, and hyperbolas to their standard coordinate forms.
Translates physical scenarios into geometric representations to solve optimization and design problems. Employs area, volume, and density calculations to analyze real-world objects and structures.
Function notation, domain, and range across algebraic, graphical, and tabular representations. Evaluates expressions for specific inputs and distinguishes between functions and relations using the vertical line test.
Distinguishes between linear and non-linear functions using tables, graphs, and algebraic representations. Compares rates of change and initial values across different mathematical models.
Relates mathematical functions to real-world scenarios through the analysis of key features like intercepts, intervals of increase, and relative extrema. Builds proficiency in translating verbal descriptions into algebraic and graphical representations.
Translates between graphs, tables, and symbolic equations to determine domain, range, and rate of change. Evaluates how transformations and properties manifest across diverse mathematical models.
Mathematical modeling techniques representing variable dependencies through tables, graphs, and algebraic expressions. Analyzes functional behavior to predict outcomes and solve real-world contextual problems.
Distinguishes between additive and multiplicative patterns in tables, graphs, and real-world contexts. Examines constant rates of change versus constant percentage growth to identify function types.
Comparative analysis of linear, quadratic, exponential, and absolute value functions using graphs, tables, and algebraic representations. Evaluates constant rates of change versus varying growth patterns to identify and classify specific function families.
Analyzes differences between linear, quadratic, and exponential functions as inputs increase. Equips learners to identify dominance and relative rates of change using tables, graphs, and algebraic limits.
Analysis of terms and coefficients within algebraic expressions to assign contextual meaning to variables and constants. Targets the translation of mathematical relationships into practical, real-world scenarios.
Explicit and recursive formulas derived from arithmetic and geometric sequences. Connects contextual scenarios to linear, exponential, and quadratic models through algebraic notation.
Construction of linear, quadratic, and exponential functions based on contextual data or geometric patterns. Interprets key features and parameters to solve applied problems.
Horizontal and vertical translations, reflections, and dilations of parent functions. Includes function arithmetic and composition to create complex mathematical models.
Cross-validation, AIC, and BIC metrics for evaluating predictive performance and model complexity. Balances bias and variance to select the most generalizable model for a given dataset.
Logarithmic transformations and base-matching strategies to isolate variables in exponent positions. Develops proficiency in solving growth and decay models.
Sequential number naming and cardinal counting principles for early learners. Develops fluency in forward and backward sequences while introducing skip-counting patterns.
Numeral recognition, counting, and cardinality for integers zero through ten. Strengthens one-to-one correspondence and basic number sense through visual sets and tracing.
Positional notation and relationships between digits in the base-ten system. Strengthens skills in regrouping, estimation, and comparing magnitudes of whole numbers and decimals.
Addition and subtraction strategies for numbers up to 20, including regrouping and word problem applications. Strengthens mental math skills and builds fluency with basic facts.
Mental math strategies, regrouping techniques, and the inverse relationship between operations. Builds computational fluency through visual models, number lines, and real-world word problems.
Solving single-step equations using inverse operations to isolate variables. Connects basic arithmetic to algebraic reasoning through balanced equations and word problem applications.
One- and two-step word problems involving joining, separating, and comparing quantities. Develops strategies for modeling operations and understanding the inverse relationship between addition and subtraction.
Equal groups, repeated addition, and array structures for early learners. Connects skip counting to multiplication concepts through visual models and concrete examples.
Commutative, associative, and distributive properties alongside the inverse relationship between multiplication and division. Builds mental math fluency and prepares students for algebraic manipulation.
Multiplication and division fluency within 100 using arrays, equal groups, and number lines. Connects inverse operations and properties of arithmetic to solve one- and two-step word problems.
Multi-step word problems involving equal groups, arrays, and area models. Strengthens computational fluency and the ability to interpret remainders in real-world contexts.
Prime and composite numbers, divisibility rules, and the relationship between multiplication and division. Strengthens skills in identifying greatest common factors and least common multiples for fraction operations.
Commutative, associative, and distributive properties for addition and multiplication. Develops mental math strategies and provides the foundation for algebraic manipulation.
Identification, extension, and creation of repeating and growing patterns using shapes, colors, and numbers. Develops algebraic thinking by analyzing sequences and defining functional relationships between variables.
Numerical and geometric sequence identification using explicit rules. Builds algebraic reasoning through the analysis of term-to-term relationships and coordinate plane representations.
Addition, subtraction, multiplication, and division involving multi-digit integers and decimals. Strengthens proficiency in place value, regrouping, and standard algorithms.
Multi-digit arithmetic strategies using base-ten blocks, area models, and regrouping. Connects concrete representations to standard algorithms for addition, subtraction, multiplication, and division.
Standard algorithms for multi-digit addition, subtraction, multiplication, and division. Applies place value logic to decimal calculations, including regrouping and precise point placement.
Evaluates multi-step mathematical statements using the order of operations. Includes the use of parentheses, brackets, and braces to structure calculations and represent relationships between numbers.
Multi-digit addition, subtraction, multiplication, and division strategies paired with identifying numerical patterns. Strengthens algebraic thinking through analysis of sequence rules and arithmetic relationships.
Addition, subtraction, multiplication, and division applications within complex word problems. Strengthens the ability to translate scenarios into mathematical equations and execute multi-step solutions.