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12. Modelling non-linear relationships

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1 12. Modelling non-linear relationships
Cambridge University Press  G K Powers 2013 Study guide Chapter 12

2 Quadratic functions Quadratic function has the equation:
To graph a quadratic function: Construct a table of values. Draw a number plane. Plot the points. Join the points to make a curve in the shape of a parabola. HSC Hint – Problems involving quadratic functions may involve maximum or minimum values. Look for the maximum or minimum y value (vertical). Cambridge University Press  G K Powers 2013

3 Cubic functions A cubic function has the equation:
To graph a cubic function: Construct a table of values. Draw a number plane. Plot the points. Join the points to make a curve. HSC Hint – It is often convenient to use a different scale for the x and y axes. Cambridge University Press  G K Powers 2013

4 Exponential functions
An exponential function has the equation: To graph a exponential function: Construct a table of values. Draw a number plane. Plot the points. Join the points to make a curve. HSC Hint – When a > 1 it represents exponential growth. When a < 1 it represents exponential decay. Cambridge University Press  G K Powers 2013

5 Hyperbolic functions An hyperbolic function has the equation:
To graph a hyperbolic function: Construct a table of values. Draw a number plane. Plot the points. Join the points to make a curve. HSC Hint – A hyperbolic function has two branches (or parts) as division by 0 (x = 0) is undefined. Cambridge University Press  G K Powers 2013

6 Algebraic modelling Algebraic modelling occurs when a practical situation is described mathematically using an algebraic function. For example, the speed of a car (s, in km/h) and time taken (t, in hours) is shown below. A hyperbolic model describes this situation: HSC Hint – Algebraic models may have limitations that restrict their use. Cambridge University Press  G K Powers 2013

7 Direct variation Write an equation relating the two variables.
y is directly proportional to x then y = kx. y is directly proportional to square of x then y = kx2. y is directly proportional to cube of x then y = kx3. y is directly proportional to square root of x then Solve the equation for k by substituting values for x and y. Write the equation with the solution for k (step 2) and solve the problem by substituting a value for either x or y. HSC Hint – Questions containing the words ‘directly proportional’ or ‘varies directly’ are an indication of a direct variation problem. Cambridge University Press  G K Powers 2013

8 Inverse variation Write an equation relating the two variables.
y is inversely proportional to x so the equation is Solve the equation for k by substituting values for x and y. Write the equation with the solution for k (step 2) and solve the problem by substituting a value for either x or y. HSC Hint – The constant of variation (k) for inverse variation problems is the product of two variables: x and y. Cambridge University Press  G K Powers 2013

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