Algebraic Reasoning and Functions

MYP Unit Framework

Key Concept: RELATIONSHIPS Related Concepts: Generalization. Patterns. Representation. Global Context: Scientific and Technical Innovation (How can algebraic models help us understand, predict, and optimise complex systems?) Statement of Inquiry: Algebraic functions model relationships between variables, enabling prediction, optimisation, and understanding of change.


Inquiry Questions

TypeQuestion
FactualWhat is a function? What is the difference between linear, quadratic, and exponential functions? How do you find the vertex of a parabola? What is a transformation of a function?
ConceptualHow can a mathematical EQUATION REPRESENT a real-world relationship? What makes a model 'good enough' for prediction?
DebatableCan mathematical models EVER capture the full complexity of real-world systems — or do they always DISTORT reality in dangerous ways? Should we base policy decisions (e.g., interest rates, climate targets) on mathematical models?

1. Functions — The Fundamental Idea

What Is a Function?

'A function is a RELATIONSHIP between two sets — the INPUT (domain) and the OUTPUT (range) — where EACH input has EXACTLY ONE output. A function is like a MACHINE: you put something in, and the machine transforms it into something else according to a fixed RULE.'

f(x) notation: 'f(x) is read as "f of x." It means "the value of the function f when the input is x." If f(x) = 2x + 3, then f(4) = 2(4) + 3 = 11.'

Domain and Range

  • Domain: The set of all POSSIBLE inputs. 'For f(x) = 1/x, the domain is ALL REAL NUMBERS EXCEPT 0 — because division by zero is UNDEFINED.'
  • Range: The set of all POSSIBLE outputs. 'For f(x) = x², the range is ALL NON-NEGATIVE real numbers — because a square can NEVER be negative.'

Function Families

'Functions can be organised into FAMILIES based on their GENERAL FORM. Each family has DISTINCTIVE properties — shape, behaviour, key features.'


2. Linear Functions — Constant Rate of Change

The Form: f(x) = mx + c

'm' is the GRADIENT (slope) — the RATE OF CHANGE. 'c' is the Y-INTERCEPT — the value of f(x) when x = 0.

Rate of Change

'The gradient tells you how MUCH y changes for EVERY ONE UNIT increase in x. m = Δy/Δx = (y₂ − y₁)/(x₂ − x₁). A POSITIVE gradient means y INCREASES as x increases. A NEGATIVE gradient means y DECREASES as x increases.'

Real-World Applications

'Linear functions model CONSTANT RATE OF CHANGE. Examples: Distance = speed × time (if speed is constant). Cost = fixed cost + (variable cost × quantity). Converting between Celsius and Fahrenheit: F = 1.8C + 32.'


3. Quadratic Functions — Curved Change

The Form: f(x) = ax² + bx + c

'The graph of a quadratic function is a PARABOLA — a symmetric U-shape (or upside-down U-shape).'

Key features:

  • Vertex: The TURNING POINT — maximum or minimum. 'The vertex is at x = −b/(2a). The y-coordinate of the vertex is f(−b/(2a)).'
  • Axis of symmetry: The vertical line through the vertex: x = −b/(2a).
  • Y-intercept: The point where the parabola crosses the y-axis: (0, c).
  • X-intercepts (roots): The solutions to ax² + bx + c = 0. Found using FACTORISATION, the QUADRATIC FORMULA: x = [−b ± √(b² − 4ac)]/(2a), or COMPLETING THE SQUARE.

The Discriminant: D = b² − 4ac

'The discriminant tells you how MANY real roots the quadratic has:

  • D > 0: TWO distinct real roots. The parabola crosses the x-axis TWICE.
  • D = 0: ONE repeated real root. The parabola TOUCHES the x-axis at one point.
  • D < 0: NO real roots. The parabola NEVER crosses the x-axis.'

Real-World Applications

'Quadratic functions model ACCELERATION. The height of a projectile: h(t) = −4.9t² + v₀t + h₀ (on Earth). Profit = −ax² + bx + c (finding the price that MAXIMISES profit). Area optimisation: what dimensions give the MAXIMUM area for a given perimeter?'


4. Exponential Functions — Growth and Decay

The Form: f(x) = a · bˣ

'a' is the INITIAL VALUE (when x = 0). 'b' is the GROWTH (b > 1) or DECAY (0 < b < 1) factor.

Key Difference from Linear and Quadratic

'Linear functions change by a CONSTANT AMOUNT. Quadratic functions change by a CONSTANTly CHANGING amount. EXPONENTIAL functions change by a CONSTANT PERCENTAGE. This is the MOST POWERFUL pattern in mathematics — because it produces EXPLOSIVE growth or RAPID decay.

Example: 'A population of 100 bacteria, doubling every hour: f(t) = 100 × 2ᵗ. After 1 hour: 200. After 2 hours: 400. After 10 hours: 102,400. After 24 hours: 1.6 BILLION.'

Real-World Applications

  • Population growth: f(t) = P₀ × eʳᵗ
  • Compound interest: A = P(1 + r/n)ⁿᵗ
  • Radioactive decay: N(t) = N₀ × e^(−λt)
  • Viral spread: Early stages of a pandemic follow exponential growth

5. Transformations of Functions

Moving and Stretching Graphs

'Understanding transformations allows you to sketch ANY function by starting from a BASIC parent function and applying SHIFTS, REFLECTIONS, and STRETCHES.'

TransformationEffect on graphFormula
Vertical shiftMoves the graph UP or DOWNf(x) + k
Horizontal shiftMoves the graph LEFT or RIGHTf(x − h)
Reflection in x-axisFlips the graph VERTICALLY−f(x)
Reflection in y-axisFlips the graph HORIZONTALLYf(−x)
Vertical stretch/compressionMakes graph TALLER or SHORTERa·f(x)
Horizontal stretch/compressionMakes graph WIDER or NARROWERf(b·x)

Composite Transformations

'When MULTIPLE transformations are applied, the ORDER MATTERS. The general transformed function is: y = a·f(b(x − h)) + k.'


6. Modelling with Functions

The Modelling Cycle

  1. Identify the problem and the variables.
  2. Choose an appropriate function family based on the pattern of change.
  3. Use DATA to find the PARAMETERS of the function.
  4. Verify the model — does it fit the data REASONABLY well?
  5. Use the model to PREDICT or OPTIMISE.
  6. Evaluate the model's LIMITATIONS.

Choosing the Right Model

'Look at the PATTERN of change: Constant difference → LINEAR. Constant second difference → QUADRATIC. Constant ratio → EXPONENTIAL.

'But real-world data is MESSY. No model is PERFECT. The question is not "Is the model TRUE?" — it is "Is the model USEFUL?"'


Your Summative Assessment — The Modelling Project

Task: Choose a REAL-WORLD PHENOMENON that can be modelled by a linear, quadratic, or exponential function. Collect or obtain DATA. Find the equation of the BEST-FITTING function using algebraic methods. Use your model to make a PREDICTION. Analyse: How WELL does your model fit the data? What are the LIMITATIONS of your model? What are the IMPLICATIONS of using your model to make decisions? Write a STRUCTURED REPORT (1000–1200 words) with an introduction, methodology, results, discussion, and conclusion.

'This project MIRRORS the IB DP Mathematics Internal Assessment (IA). Developing these skills NOW will give you a SIGNIFICANT advantage in the Diploma Programme.'


ATL Skills

SkillFocus
Critical ThinkingEvaluating model validity. Distinguishing between correlation and causation.
ResearchCollecting and analysing real-world data.
CommunicationWriting a structured mathematical report with clear explanations.
Information LiteracyUsing technology (graphing calculators, spreadsheets) to analyse data.

Formative Assessments

AssessmentFocus
Function identificationGiven a table of values, identify the function family and find the equation.
Graph sketchingSketch the graphs of f(x), f(x) + 3, f(x − 2), and 2f(x) for a given function.
Quadratic problem setSolve a set of problems involving finding roots, vertex, and y-intercept.
Exponential applicationsCalculate compound interest, population growth, and radioactive decay problems.

Interdisciplinary Connections

  • Physics: Kinematics (quadratic), radioactive decay (exponential).
  • Economics: Supply and demand, compound interest, profit optimisation.
  • Biology: Population growth models, bacterial growth, drug concentration.
  • TOK: Can a mathematical model be 'true'? What is the relationship between mathematics and reality?

Service as Action

  • Tutoring: Tutor younger students in algebraic concepts.
  • Data analysis for a local NGO: Help a community organisation analyse their data (e.g., donor trends, service usage).
  • Financial literacy workshop: Design and deliver a workshop on compound interest and saving for fellow students.

IB Learner Profile Attributes

AttributeHow This Unit Develops It
ThinkersStudents analyse problems, identify patterns, and construct mathematical models.
InquirersStudents explore real-world phenomena through mathematical investigation.
KnowledgeableStudents build deep understanding of function families and their properties.
ReflectiveStudents evaluate the strengths and limitations of their models.

Self-Test Questions

  1. What is a function? Explain the difference between domain and range.

  2. A line passes through (2, 5) and (6, 13). Find the equation of the line.

  3. For f(x) = 2x² − 8x + 6, find: the vertex, the axis of symmetry, and the roots.

  4. The population of a town grows from 10,000 to 12,100 in two years. Assuming exponential growth, find the annual growth rate and predict the population after 5 years.

  5. Explain how the graph of f(x) = x² is transformed to g(x) = −(x − 3)² + 4.

  6. Describe the MODELLING CYCLE and apply it to a real-world example of your choice.

  7. 'A model is never right, but sometimes it is useful.' Explain what this statement means and give an example.

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