Quadratics
Quadratics
Quadratics
what you'll learn
Lesson details
Units 1 & 2 (Quadratic Functions & Equations)
Focus on the structure, behavior, and algebra of quadratic functions. Explore factorization, solving techniques (including completing the square and the quadratic formula), and graphical interpretation (axis of symmetry, vertex, and intercepts). Emphasis is placed on the application of quadratics in modelling and problem solving.
Unit 2 (Algebraic Manipulation & Graphical Connections)
Develop fluency in manipulating quadratic expressions, solving equations analytically and graphically, and interpreting transformations of the basic parabola y=x2y = x^2y=x2. Reinforce connections between algebraic and graphical representations to support modelling contexts and real-world applications.
Unit 1: Foundations of Quadratic Algebra and Graphs
1.1 Structure of Quadratic Expressions
Standard Form: ax2+bx+cax^2 + bx + cax2+bx+c; vertex form and factored form
Terminology: leading coefficient, axis of symmetry, discriminant
Quadratic Arithmetic
Expanding binomials and perfect squares
Factorization techniques:
Common factor extraction
Simple trinomials (e.g. x2+bx+cx^2 + bx + cx2+bx+c)
Hard trinomials (e.g. ax2+bx+cax^2 + bx + cax2+bx+c, where a≠1a \neq 1a=1)
Completing the square
1.2 Solving Quadratic Equations
By Factorisation
By Completing the Square
By Quadratic Formula: derivation from completing the square
Discriminant Analysis: nature of roots (real, repeated, complex)
1.3 Graphing Quadratic Functions
Key Features: vertex, y-intercept, x-intercepts, axis of symmetry
Graph Shape: concavity based on sign of leading coefficient
Graphing from Different Forms: standard, vertex, and factored
Use of Technology: plotting with TI-Nspire/Casio, confirming algebraic work
1.4 Transformations of Quadratic Graphs
Vertical & Horizontal Translations
Reflections in x-axis and y-axis
Vertical Stretches/Compressions
Application in Modelling: e.g. projectile motion, revenue maximization
Unit 2: Further Techniques and Applications
2.1 Applications of Quadratics in Context
Worded Problems: motion under gravity, area and optimisation scenarios
Modelling with Parabolas: fitting equations to real data
2.2 Graphical and Numerical Solutions
Using Graphs to Estimate Roots
Understanding Parabolas that Don’t Intersect the x-axis
Vertex Form for Maximum/Minimum Values in Applications
2.3 Systems Involving Quadratics
Simultaneous Equations: linear-quadratic systems
Graphical Interpretation: points of intersection
Algebraic Solutions: substitution and elimination
2.4 Exploring Rates of Change (Prelude to Calculus)
Average Rate over an Interval on a Quadratic Curve
Concept of Gradient of a Chord
Estimating Instantaneous Rate: leading into the idea of derivatives
Units 1 & 2 (Quadratic Functions & Equations)
Focus on the structure, behavior, and algebra of quadratic functions. Explore factorization, solving techniques (including completing the square and the quadratic formula), and graphical interpretation (axis of symmetry, vertex, and intercepts). Emphasis is placed on the application of quadratics in modelling and problem solving.
Unit 2 (Algebraic Manipulation & Graphical Connections)
Develop fluency in manipulating quadratic expressions, solving equations analytically and graphically, and interpreting transformations of the basic parabola y=x2y = x^2y=x2. Reinforce connections between algebraic and graphical representations to support modelling contexts and real-world applications.
Unit 1: Foundations of Quadratic Algebra and Graphs
1.1 Structure of Quadratic Expressions
Standard Form: ax2+bx+cax^2 + bx + cax2+bx+c; vertex form and factored form
Terminology: leading coefficient, axis of symmetry, discriminant
Quadratic Arithmetic
Expanding binomials and perfect squares
Factorization techniques:
Common factor extraction
Simple trinomials (e.g. x2+bx+cx^2 + bx + cx2+bx+c)
Hard trinomials (e.g. ax2+bx+cax^2 + bx + cax2+bx+c, where a≠1a \neq 1a=1)
Completing the square
1.2 Solving Quadratic Equations
By Factorisation
By Completing the Square
By Quadratic Formula: derivation from completing the square
Discriminant Analysis: nature of roots (real, repeated, complex)
1.3 Graphing Quadratic Functions
Key Features: vertex, y-intercept, x-intercepts, axis of symmetry
Graph Shape: concavity based on sign of leading coefficient
Graphing from Different Forms: standard, vertex, and factored
Use of Technology: plotting with TI-Nspire/Casio, confirming algebraic work
1.4 Transformations of Quadratic Graphs
Vertical & Horizontal Translations
Reflections in x-axis and y-axis
Vertical Stretches/Compressions
Application in Modelling: e.g. projectile motion, revenue maximization
Unit 2: Further Techniques and Applications
2.1 Applications of Quadratics in Context
Worded Problems: motion under gravity, area and optimisation scenarios
Modelling with Parabolas: fitting equations to real data
2.2 Graphical and Numerical Solutions
Using Graphs to Estimate Roots
Understanding Parabolas that Don’t Intersect the x-axis
Vertex Form for Maximum/Minimum Values in Applications
2.3 Systems Involving Quadratics
Simultaneous Equations: linear-quadratic systems
Graphical Interpretation: points of intersection
Algebraic Solutions: substitution and elimination
2.4 Exploring Rates of Change (Prelude to Calculus)
Average Rate over an Interval on a Quadratic Curve
Concept of Gradient of a Chord
Estimating Instantaneous Rate: leading into the idea of derivatives
Units 1 & 2 (Quadratic Functions & Equations)
Focus on the structure, behavior, and algebra of quadratic functions. Explore factorization, solving techniques (including completing the square and the quadratic formula), and graphical interpretation (axis of symmetry, vertex, and intercepts). Emphasis is placed on the application of quadratics in modelling and problem solving.
Unit 2 (Algebraic Manipulation & Graphical Connections)
Develop fluency in manipulating quadratic expressions, solving equations analytically and graphically, and interpreting transformations of the basic parabola y=x2y = x^2y=x2. Reinforce connections between algebraic and graphical representations to support modelling contexts and real-world applications.
Unit 1: Foundations of Quadratic Algebra and Graphs
1.1 Structure of Quadratic Expressions
Standard Form: ax2+bx+cax^2 + bx + cax2+bx+c; vertex form and factored form
Terminology: leading coefficient, axis of symmetry, discriminant
Quadratic Arithmetic
Expanding binomials and perfect squares
Factorization techniques:
Common factor extraction
Simple trinomials (e.g. x2+bx+cx^2 + bx + cx2+bx+c)
Hard trinomials (e.g. ax2+bx+cax^2 + bx + cax2+bx+c, where a≠1a \neq 1a=1)
Completing the square
1.2 Solving Quadratic Equations
By Factorisation
By Completing the Square
By Quadratic Formula: derivation from completing the square
Discriminant Analysis: nature of roots (real, repeated, complex)
1.3 Graphing Quadratic Functions
Key Features: vertex, y-intercept, x-intercepts, axis of symmetry
Graph Shape: concavity based on sign of leading coefficient
Graphing from Different Forms: standard, vertex, and factored
Use of Technology: plotting with TI-Nspire/Casio, confirming algebraic work
1.4 Transformations of Quadratic Graphs
Vertical & Horizontal Translations
Reflections in x-axis and y-axis
Vertical Stretches/Compressions
Application in Modelling: e.g. projectile motion, revenue maximization
Unit 2: Further Techniques and Applications
2.1 Applications of Quadratics in Context
Worded Problems: motion under gravity, area and optimisation scenarios
Modelling with Parabolas: fitting equations to real data
2.2 Graphical and Numerical Solutions
Using Graphs to Estimate Roots
Understanding Parabolas that Don’t Intersect the x-axis
Vertex Form for Maximum/Minimum Values in Applications
2.3 Systems Involving Quadratics
Simultaneous Equations: linear-quadratic systems
Graphical Interpretation: points of intersection
Algebraic Solutions: substitution and elimination
2.4 Exploring Rates of Change (Prelude to Calculus)
Average Rate over an Interval on a Quadratic Curve
Concept of Gradient of a Chord
Estimating Instantaneous Rate: leading into the idea of derivatives
About Author
Samit believes fitness isn’t just about working out—it’s about taking care of your body. His classes focus on deep stretching, muscle recovery, and stress relief techniques to help students move better and feel their best every day.
Samit believes fitness isn’t just about working out—it’s about taking care of your body. His classes focus on deep stretching, muscle recovery, and stress relief techniques to help students move better and feel their best every day.
Samit believes fitness isn’t just about working out—it’s about taking care of your body. His classes focus on deep stretching, muscle recovery, and stress relief techniques to help students move better and feel their best every day.
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