5.3 Graphing Quadratics in Vertex Form Every quadratic relation
Transcription
5.3 Graphing Quadratics in Vertex Form Every quadratic relation
Kerr MPM2D Applying Quadratic Models 5.3 Graphing Quadratics in Vertex Form Every quadratic relation begins as y = x2. This is your basic parabola. Notice the vertex is on the origin of the coordinate plane. Today we will examine how all four transformations can change the shape of the parabola and the location of the vertex. The transformations are applied in the following order: Transformation Examine the value of … If … a a < -1 or a > 1 a -1 < a < 1 a a = -1 h h<0 h h>0 k k<0 k k>0 1. vertical stretch or vertical compression 2. reflection in the x-axis 3. horizontal translation 4. vertical translation What changes? Parabola vertical becomes stretch more narrow Parabola vertical becomes compression more wide reflection Direction in the xof opening axis translate right Location of translate vertex left moves translate down translate up Then … The vertex form of a quadratic relation is: 1. vertical stretch (more narrow) or vertical compression (more wide) 2. reflection in xaxis if negative 3. moves vertex left (+) or right (-) y = a(x - h)2 + k 4. moves vertex up (+) or down (-) Kerr MPM2D Applying Quadratic Models This is called "vertex" form is because we can very easily identify the vertex of the quadratic relation. The vertex is (h, k), which means x = h is the axis of symmetry and y = k is the optimum value. If the parabola opens up (a > 0), the optimum value is a minimum. If the parabola opens down (a < 0), the optimum value is a maximum. Examples 1. In order, describe the transformations you would apply to the graph of y = x2 to create the graph of each relation. Then sketch the graph. a) y = 5x2 – 4 ______________________________ ______________________________ This parabola opens __________. The axis of symmetry is x = _____. The vertex is __________. b) y = - (x + 8)2 5 4 ______________________________ ______________________________ ______________________________ This parabola opens __________. The axis of symmetry is x = _____. The vertex is __________. Kerr MPM2D Applying Quadratic Models c) y = (x – 1)2 - 2 ______________________________ ______________________________ This parabola opens __________. The axis of symmetry is x = _____. The vertex is __________. d) y=- 15 (x + 14)2 + 18 17 ______________________________ ______________________________ ______________________________ ______________________________ This parabola opens __________. The axis of symmetry is x = _____. The vertex is __________. Kerr MPM2D Applying Quadratic Models 2. Complete the table below. Quadratic Relation y= Vertical Stretch or Vertical Compression Factor Reflection in the x-axis Translations (horizontal & vertical) Optimum Value (max or min) Axis of Symmetry 3 (x - 3)2 - 1 4 y = -7(x + 6)2 None No HT 2 left VT 4 down y = -4 (min) x = -2 None Yes HT 9 left y=0 (max) x = -9 y = -2x2 + 6 y = -3(x + 2)2 – 7 3. Write the equation of the parabola that matches each description. a) The graph of y = x2 is compressed by a factor of about the x-axis and translated 3 units right. 1 , reflected 3 b) _________________________ The graph of y = x2 is stretch by a factor of 7 and translated 6 units up. c) _________________________ The graph of y = x2 is reflected about the x-axis, translated 2 units right and 3 units up. _________________________ Kerr MPM2D Applying Quadratic Models The vertex form of quadratic relation is very helpful when solving word problems because we can immediately identify the optimum value. x-coordinate of the vertex & axis of symmetry if a is positive, parabola opens up optimum value is a minimum y = a(x - h)2 + k if a is negative, parabola opens down optimum value is a maximum y-coordinate of the vertex & optimum value 4. A football is kicked into the air. Its height, in meters, after t seconds is given by h = -4.9(t - 2.4)2 + 29. a) b) c) d) What is the maximum height of the football. At what time did the football reach its maximum height. Sketch a graph that represents the height of the football. When did the football reach a height of 10 m? Round your answer to the nearest hundredth. the axis of symmetry is x = _____ Solution: h = -4.9(t - 2.4)2 + 29 the parabola opens ______ so the optimum value is a _____________ a) b) c) vertex (_____, _____) the maximum height is y = _____ The maximum height of the football is __________. The football reached its maximum height after __________. Kerr MPM2D Applying Quadratic Models d) Translation: When h = 10, what is t? h = -4.9(t - 2.4)2 + 29 Substitute h = 10 into the original equation to isolate and solve for t. Don’t forget BEDMAS! Therefore the football reached a height of 10 m after ________________________________________________. How can you go from one form of a quadratic relation to another? factored form factored form Expand and simplify. Set the factors equal to zero. Solve for the zeros. Solve for axis of symmetry. (add and ÷ 2) Substitute the axis of symmetry back into the original equation to solve for the y-value of the vertex. Insert the given value of a, h(x) and k(y) into vertex form. standard form vertex form Kerr MPM2D Applying Quadratic Models 5. Express the quadratic relation y =3(x + 5)(x - 7) in standard form and vertex form. Standard Form y =3(x + 5)(x - 7) Vertex Form y =3(x + 5)(x - 7) Hints for the homework: Question #15 is just like example #4. Question #17 is just like example #5. Homework: Page 269 #1-4, 6, 7def, 8, 9, 11, 12cd, 13, 15, 17