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11X1 t10 01 graphing quadratics (2011)

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Nigel Simmons
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The Quadratic Polynomial and the Parabola
The Quadratic Polynomial and the Parabola Quadratic polynomial –
The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c
The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function –
The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c
The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation –
The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0
The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients –
The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c
The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c Indeterminate –
The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c Indeterminate – x
The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c Indeterminate – x Roots –
The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c Indeterminate – x Roots – Solutions to the quadratic equation
The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c Indeterminate – x Roots – Solutions to the quadratic equation Zeroes –
The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c Indeterminate – x Roots – Solutions to the quadratic equation Zeroes – x intercepts of the quadratic function
The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c Indeterminate – x Roots – Solutions to the quadratic equation Zeroes – x intercepts of the quadratic function e.g. Find the roots of x 2  1  0
The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c Indeterminate – x Roots – Solutions to the quadratic equation Zeroes – x intercepts of the quadratic function e.g. Find the roots of x 2  1  0 x2 1  0 x2  1
The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c Indeterminate – x Roots – Solutions to the quadratic equation Zeroes – x intercepts of the quadratic function e.g. Find the roots of x 2  1  0 x2 1  0 x2  1 x  1
The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c Indeterminate – x Roots – Solutions to the quadratic equation Zeroes – x intercepts of the quadratic function e.g. Find the roots of x 2  1  0 x2 1  0 x2  1 x  1  the roots are x  1 and x  1
Graphing Quadratics
Graphing Quadratics The graph of a quadratic function is a parabola.
Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c
Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c a
Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y a x
Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y a x a0
Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y a x a0 concave up
Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 concave up
Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up
Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down
Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c
Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c = y intercept
Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c = y intercept zeroes (roots)
Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c = y intercept zeroes (roots) = x intercepts
Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c = y intercept zeroes (roots) = x intercepts b x 2a
Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c = y intercept zeroes (roots) = x intercepts b x = axis of symmetry 2a
Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c = y intercept zeroes (roots) = x intercepts b x = axis of symmetry Note: AOS is the average of the zeroes 2a
Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c = y intercept zeroes (roots) = x intercepts b x = axis of symmetry Note: AOS is the average of the zeroes 2a vertex
Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c = y intercept zeroes (roots) = x intercepts b x = axis of symmetry Note: AOS is the average of the zeroes 2a vertex x value is the AOS
Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c = y intercept zeroes (roots) = x intercepts b x = axis of symmetry Note: AOS is the average of the zeroes 2a vertex x value is the AOS y value is found by substituting AOS into the function.
Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c = y intercept zeroes (roots) = x intercepts b x = axis of symmetry Note: AOS is the average of the zeroes 2a vertex x value is the AOS y value is found by substituting AOS into the function. (It is the maximum/minimum value of the function)
e.g. Graph y  x 2  8 x  12
e.g. Graph y  x 2  8 x  12 a=1>0 y x
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up y x
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12 y y  x 2  8 x  12 x
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  y x
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  y 12 x
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes y 12 x
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12 12 x
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2 x
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  x
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  –6 –2 x
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS –6 –2 x
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b 2a –6 –2 x
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b 2a 8  2 –6 –2 x  4
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b OR x  6  2 2a 2 8  2 –6 –2 x  4
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b OR x  6  2 2a 2 8  4  2 –6 –2 x  4
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b OR x  6  2 2a 2 8  4  2 –6 –2 x  4
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b OR x  6  2 2a 2 8  4  2 –6 –2 x  4 vertex
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b OR x  6  2 2a 2 8  4  2 –6 –2 x  4 y   4   8  4   12 2 vertex
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b OR x  6  2 2a 2 8  4  2 –6 –2 x  4 y   4   8  4   12 2 vertex  4
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b OR x  6  2 2a 2 8  4  2 –6 –2 x  4 y   4   8  4   12 2 vertex  4  vertex is  4, 4 
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b OR x  6  2 2a 2 8  4  2 –6 –2 x  4 y   4   8  4   12 2 vertex (–4, –4)  4  vertex is  4, 4 
e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b OR x  6  2 2a 2 8  4  2 –6 –2 x  4 y   4   8  4   12 2 vertex (–4, –4)  4  vertex is  4, 4 
(ii) Find the quadratic with; a) roots 3 and 6
(ii) Find the quadratic with; a) roots 3 and 6 y  a  x 2  9 x  18 
(ii) Find the quadratic with; a) roots 3 and 6 y  a  x 2  9 x  18    6  3 63
(ii) Find the quadratic with; a) roots 3 and 6 b) monic roots 3  2 and 3  2 y  a  x 2  9 x  18    6  3 63
(ii) Find the quadratic with; a) roots 3 and 6 b) monic roots 3  2 and 3  2 y  a  x 2  9 x  18  y  x2  6x  7   6  3 63 c) roots 2 and 8 and vertex (5,3) y  a  x 2  10 x  16   5,3 : 3  a  52  10  5   16  3  9a 1 a 3  y    x  10 x  16  1 2 3
(ii) Find the quadratic with; a) roots 3 and 6 b) monic roots 3  2 and 3  2 y  a  x 2  9 x  18  y  x2  6x  7   6  3 63   3 2 3 2  3  2 3  2 
(ii) Find the quadratic with; a) roots 3 and 6 b) monic roots 3  2 and 3  2 y  a  x 2  9 x  18  y  x2  6x  7   6  3 63   3 2 3 2  3  2 3  2  c) roots 2 and 8 and vertex (5,3)
(ii) Find the quadratic with; a) roots 3 and 6 b) monic roots 3  2 and 3  2 y  a  x 2  9 x  18  y  x2  6x  7   6  3 63   3 2 3 2  3  2 3  2  c) roots 2 and 8 and vertex (5,3) y  a  x 2  10 x  16 
(ii) Find the quadratic with; a) roots 3 and 6 b) monic roots 3  2 and 3  2 y  a  x 2  9 x  18  y  x2  6x  7   6  3 63   3 2 3 2  3  2 3  2  c) roots 2 and 8 and vertex (5,3) y  a  x 2  10 x  16   5,3 : 3  a  52  10  5   16 
(ii) Find the quadratic with; a) roots 3 and 6 b) monic roots 3  2 and 3  2 y  a  x 2  9 x  18  y  x2  6x  7   6  3 63   3 2 3 2  3  2 3  2  c) roots 2 and 8 and vertex (5,3) y  a  x 2  10 x  16   5,3 : 3  a  52  10  5   16  3  9a 1 a 3
(ii) Find the quadratic with; a) roots 3 and 6 b) monic roots 3  2 and 3  2 y  a  x 2  9 x  18  y  x2  6x  7   6  3 63   3 2 3 2  3  2 3  2  c) roots 2 and 8 and vertex (5,3) y  a  x 2  10 x  16   5,3 : 3  a  52  10  5   16  3  9a 1 a 3  y    x  10 x  16  1 2 3
(iii) Solve; a) x 2  5 x  6  0
(iii) Solve; a) x 2  5 x  6  0  x  2  x  3  0
(iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 –3 –2 x
(iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 –3 –2 x
(iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 –3 –2 x Q: for what values of x is the parabola above the x axis?
(iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 –3 –2 x Q: for what values of x is the parabola above the x axis?
(iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 x  3 or x  2 –3 –2 x Q: for what values of x is the parabola above the x axis?
(iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 x  3 or x  2 –3 –2 x Q: for what values of x is the parabola above the x axis? b)  x 2  3 x  4
(iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 x  3 or x  2 –3 –2 x Q: for what values of x is the parabola above the x axis? b)  x 2  3 x  4 x 2  3x  4  0
(iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 x  3 or x  2 –3 –2 x Q: for what values of x is the parabola above the x axis? b)  x 2  3 x  4 x 2  3x  4  0  x  4  x  1  0
(iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 x  3 or x  2 –3 –2 x Q: for what values of x is the parabola above the x axis? b)  x 2  3 x  4 y x 2  3x  4  0  x  4  x  1  0 –4 1 x
(iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 x  3 or x  2 –3 –2 x Q: for what values of x is the parabola above the x axis? b)  x 2  3 x  4 y x 2  3x  4  0  x  4  x  1  0 –4 1 x
(iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 x  3 or x  2 –3 –2 x Q: for what values of x is the parabola above the x axis? b)  x 2  3 x  4 y x 2  3x  4  0  x  4  x  1  0 –4 1 x Q: for what values of x is the parabola below the x axis?
(iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 x  3 or x  2 –3 –2 x Q: for what values of x is the parabola above the x axis? b)  x 2  3 x  4 y x 2  3x  4  0  x  4  x  1  0 –4 1 x Q: for what values of x is the parabola below the x axis?
(iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 x  3 or x  2 –3 –2 x Q: for what values of x is the parabola above the x axis? b)  x 2  3 x  4 y x 2  3x  4  0  x  4  x  1  0 4  x  1 –4 1 x Q: for what values of x is the parabola below the x axis?
Exercise 8A; 1adf, 2adf, 3bd, 4bd, 5c, 6ade, 7d, 9ace, 12c, 13b, 14a

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X2 t02 04 forming polynomials (2013)
X2 t02 04 forming polynomials (2013)X2 t02 04 forming polynomials (2013)
X2 t02 04 forming polynomials (2013)
 
X2 t02 03 roots & coefficients (2013)
X2 t02 03 roots & coefficients (2013)X2 t02 03 roots & coefficients (2013)
X2 t02 03 roots & coefficients (2013)
 
X2 t02 02 multiple roots (2013)
X2 t02 02 multiple roots (2013)X2 t02 02 multiple roots (2013)
X2 t02 02 multiple roots (2013)
 
X2 t02 01 factorising complex expressions (2013)
X2 t02 01 factorising complex expressions (2013)X2 t02 01 factorising complex expressions (2013)
X2 t02 01 factorising complex expressions (2013)
 
11 x1 t16 07 approximations (2013)
11 x1 t16 07 approximations (2013)11 x1 t16 07 approximations (2013)
11 x1 t16 07 approximations (2013)
 
11 x1 t16 06 derivative times function (2013)
11 x1 t16 06 derivative times function (2013)11 x1 t16 06 derivative times function (2013)
11 x1 t16 06 derivative times function (2013)
 
11 x1 t16 05 volumes (2013)
11 x1 t16 05 volumes (2013)11 x1 t16 05 volumes (2013)
11 x1 t16 05 volumes (2013)
 
11 x1 t16 04 areas (2013)
11 x1 t16 04 areas (2013)11 x1 t16 04 areas (2013)
11 x1 t16 04 areas (2013)
 
11 x1 t16 03 indefinite integral (2013)
11 x1 t16 03 indefinite integral (2013)11 x1 t16 03 indefinite integral (2013)
11 x1 t16 03 indefinite integral (2013)
 
11 x1 t16 02 definite integral (2013)
11 x1 t16 02 definite integral (2013)11 x1 t16 02 definite integral (2013)
11 x1 t16 02 definite integral (2013)
 
11 x1 t16 01 area under curve (2013)
11 x1 t16 01 area under curve (2013)11 x1 t16 01 area under curve (2013)
11 x1 t16 01 area under curve (2013)
 

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11X1 t10 01 graphing quadratics (2011)

  • 1. The Quadratic Polynomial and the Parabola
  • 2. The Quadratic Polynomial and the Parabola Quadratic polynomial –
  • 3. The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c
  • 4. The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function –
  • 5. The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c
  • 6. The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation –
  • 7. The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0
  • 8. The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients –
  • 9. The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c
  • 10. The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c Indeterminate –
  • 11. The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c Indeterminate – x
  • 12. The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c Indeterminate – x Roots –
  • 13. The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c Indeterminate – x Roots – Solutions to the quadratic equation
  • 14. The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c Indeterminate – x Roots – Solutions to the quadratic equation Zeroes –
  • 15. The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c Indeterminate – x Roots – Solutions to the quadratic equation Zeroes – x intercepts of the quadratic function
  • 16. The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c Indeterminate – x Roots – Solutions to the quadratic equation Zeroes – x intercepts of the quadratic function e.g. Find the roots of x 2  1  0
  • 17. The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c Indeterminate – x Roots – Solutions to the quadratic equation Zeroes – x intercepts of the quadratic function e.g. Find the roots of x 2  1  0 x2 1  0 x2  1
  • 18. The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c Indeterminate – x Roots – Solutions to the quadratic equation Zeroes – x intercepts of the quadratic function e.g. Find the roots of x 2  1  0 x2 1  0 x2  1 x  1
  • 19. The Quadratic Polynomial and the Parabola Quadratic polynomial – ax 2  bx  c Quadratic function – y  ax 2  bx  c Quadratic equation – ax 2  bx  c  0 Coefficients – a, b, c Indeterminate – x Roots – Solutions to the quadratic equation Zeroes – x intercepts of the quadratic function e.g. Find the roots of x 2  1  0 x2 1  0 x2  1 x  1  the roots are x  1 and x  1
  • 21. Graphing Quadratics The graph of a quadratic function is a parabola.
  • 22. Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c
  • 23. Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c a
  • 24. Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y a x
  • 25. Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y a x a0
  • 26. Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y a x a0 concave up
  • 27. Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 concave up
  • 28. Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up
  • 29. Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down
  • 30. Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c
  • 31. Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c = y intercept
  • 32. Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c = y intercept zeroes (roots)
  • 33. Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c = y intercept zeroes (roots) = x intercepts
  • 34. Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c = y intercept zeroes (roots) = x intercepts b x 2a
  • 35. Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c = y intercept zeroes (roots) = x intercepts b x = axis of symmetry 2a
  • 36. Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c = y intercept zeroes (roots) = x intercepts b x = axis of symmetry Note: AOS is the average of the zeroes 2a
  • 37. Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c = y intercept zeroes (roots) = x intercepts b x = axis of symmetry Note: AOS is the average of the zeroes 2a vertex
  • 38. Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c = y intercept zeroes (roots) = x intercepts b x = axis of symmetry Note: AOS is the average of the zeroes 2a vertex x value is the AOS
  • 39. Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c = y intercept zeroes (roots) = x intercepts b x = axis of symmetry Note: AOS is the average of the zeroes 2a vertex x value is the AOS y value is found by substituting AOS into the function.
  • 40. Graphing Quadratics The graph of a quadratic function is a parabola. y  ax 2  bx  c y y a x x a0 a0 concave up concave down c = y intercept zeroes (roots) = x intercepts b x = axis of symmetry Note: AOS is the average of the zeroes 2a vertex x value is the AOS y value is found by substituting AOS into the function. (It is the maximum/minimum value of the function)
  • 41. e.g. Graph y  x 2  8 x  12
  • 42. e.g. Graph y  x 2  8 x  12 a=1>0 y x
  • 43. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up y x
  • 44. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12 y y  x 2  8 x  12 x
  • 45. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  y x
  • 46. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  y 12 x
  • 47. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes y 12 x
  • 48. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12 12 x
  • 49. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x
  • 50. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2 x
  • 51. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  x
  • 52. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  –6 –2 x
  • 53. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS –6 –2 x
  • 54. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b 2a –6 –2 x
  • 55. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b 2a 8  2 –6 –2 x  4
  • 56. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b OR x  6  2 2a 2 8  2 –6 –2 x  4
  • 57. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b OR x  6  2 2a 2 8  4  2 –6 –2 x  4
  • 58. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b OR x  6  2 2a 2 8  4  2 –6 –2 x  4
  • 59. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b OR x  6  2 2a 2 8  4  2 –6 –2 x  4 vertex
  • 60. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b OR x  6  2 2a 2 8  4  2 –6 –2 x  4 y   4   8  4   12 2 vertex
  • 61. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b OR x  6  2 2a 2 8  4  2 –6 –2 x  4 y   4   8  4   12 2 vertex  4
  • 62. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b OR x  6  2 2a 2 8  4  2 –6 –2 x  4 y   4   8  4   12 2 vertex  4  vertex is  4, 4 
  • 63. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b OR x  6  2 2a 2 8  4  2 –6 –2 x  4 y   4   8  4   12 2 vertex (–4, –4)  4  vertex is  4, 4 
  • 64. e.g. Graph y  x 2  8 x  12 a = 1 > 0  concave up c = 12  y intercept is  0,12  zeroes x 2  8 x  12  0 y y  x 2  8 x  12  x  6  x  2   0 12 x  6 or x  2  x intercepts are  6,0  and  2,0  AOS x  b OR x  6  2 2a 2 8  4  2 –6 –2 x  4 y   4   8  4   12 2 vertex (–4, –4)  4  vertex is  4, 4 
  • 65. (ii) Find the quadratic with; a) roots 3 and 6
  • 66. (ii) Find the quadratic with; a) roots 3 and 6 y  a  x 2  9 x  18 
  • 67. (ii) Find the quadratic with; a) roots 3 and 6 y  a  x 2  9 x  18    6  3 63
  • 68. (ii) Find the quadratic with; a) roots 3 and 6 b) monic roots 3  2 and 3  2 y  a  x 2  9 x  18    6  3 63
  • 69. (ii) Find the quadratic with; a) roots 3 and 6 b) monic roots 3  2 and 3  2 y  a  x 2  9 x  18  y  x2  6x  7   6  3 63 c) roots 2 and 8 and vertex (5,3) y  a  x 2  10 x  16   5,3 : 3  a  52  10  5   16  3  9a 1 a 3  y    x  10 x  16  1 2 3
  • 70. (ii) Find the quadratic with; a) roots 3 and 6 b) monic roots 3  2 and 3  2 y  a  x 2  9 x  18  y  x2  6x  7   6  3 63   3 2 3 2  3  2 3  2 
  • 71. (ii) Find the quadratic with; a) roots 3 and 6 b) monic roots 3  2 and 3  2 y  a  x 2  9 x  18  y  x2  6x  7   6  3 63   3 2 3 2  3  2 3  2  c) roots 2 and 8 and vertex (5,3)
  • 72. (ii) Find the quadratic with; a) roots 3 and 6 b) monic roots 3  2 and 3  2 y  a  x 2  9 x  18  y  x2  6x  7   6  3 63   3 2 3 2  3  2 3  2  c) roots 2 and 8 and vertex (5,3) y  a  x 2  10 x  16 
  • 73. (ii) Find the quadratic with; a) roots 3 and 6 b) monic roots 3  2 and 3  2 y  a  x 2  9 x  18  y  x2  6x  7   6  3 63   3 2 3 2  3  2 3  2  c) roots 2 and 8 and vertex (5,3) y  a  x 2  10 x  16   5,3 : 3  a  52  10  5   16 
  • 74. (ii) Find the quadratic with; a) roots 3 and 6 b) monic roots 3  2 and 3  2 y  a  x 2  9 x  18  y  x2  6x  7   6  3 63   3 2 3 2  3  2 3  2  c) roots 2 and 8 and vertex (5,3) y  a  x 2  10 x  16   5,3 : 3  a  52  10  5   16  3  9a 1 a 3
  • 75. (ii) Find the quadratic with; a) roots 3 and 6 b) monic roots 3  2 and 3  2 y  a  x 2  9 x  18  y  x2  6x  7   6  3 63   3 2 3 2  3  2 3  2  c) roots 2 and 8 and vertex (5,3) y  a  x 2  10 x  16   5,3 : 3  a  52  10  5   16  3  9a 1 a 3  y    x  10 x  16  1 2 3
  • 76. (iii) Solve; a) x 2  5 x  6  0
  • 77. (iii) Solve; a) x 2  5 x  6  0  x  2  x  3  0
  • 78. (iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 –3 –2 x
  • 79. (iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 –3 –2 x
  • 80. (iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 –3 –2 x Q: for what values of x is the parabola above the x axis?
  • 81. (iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 –3 –2 x Q: for what values of x is the parabola above the x axis?
  • 82. (iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 x  3 or x  2 –3 –2 x Q: for what values of x is the parabola above the x axis?
  • 83. (iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 x  3 or x  2 –3 –2 x Q: for what values of x is the parabola above the x axis? b)  x 2  3 x  4
  • 84. (iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 x  3 or x  2 –3 –2 x Q: for what values of x is the parabola above the x axis? b)  x 2  3 x  4 x 2  3x  4  0
  • 85. (iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 x  3 or x  2 –3 –2 x Q: for what values of x is the parabola above the x axis? b)  x 2  3 x  4 x 2  3x  4  0  x  4  x  1  0
  • 86. (iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 x  3 or x  2 –3 –2 x Q: for what values of x is the parabola above the x axis? b)  x 2  3 x  4 y x 2  3x  4  0  x  4  x  1  0 –4 1 x
  • 87. (iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 x  3 or x  2 –3 –2 x Q: for what values of x is the parabola above the x axis? b)  x 2  3 x  4 y x 2  3x  4  0  x  4  x  1  0 –4 1 x
  • 88. (iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 x  3 or x  2 –3 –2 x Q: for what values of x is the parabola above the x axis? b)  x 2  3 x  4 y x 2  3x  4  0  x  4  x  1  0 –4 1 x Q: for what values of x is the parabola below the x axis?
  • 89. (iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 x  3 or x  2 –3 –2 x Q: for what values of x is the parabola above the x axis? b)  x 2  3 x  4 y x 2  3x  4  0  x  4  x  1  0 –4 1 x Q: for what values of x is the parabola below the x axis?
  • 90. (iii) Solve; a) x 2  5 x  6  0 y  x  2  x  3  0 x  3 or x  2 –3 –2 x Q: for what values of x is the parabola above the x axis? b)  x 2  3 x  4 y x 2  3x  4  0  x  4  x  1  0 4  x  1 –4 1 x Q: for what values of x is the parabola below the x axis?
  • 91. Exercise 8A; 1adf, 2adf, 3bd, 4bd, 5c, 6ade, 7d, 9ace, 12c, 13b, 14a