Presentation is loading. Please wait.

Presentation is loading. Please wait.

Replacing f(x) with k f(x) and f(k x) Adapted from Walch Education.

Published byMeagan Watts Modified over 9 years ago

Similar presentations

Presentation on theme: "Replacing f(x) with k f(x) and f(k x) Adapted from Walch Education."— Presentation transcript:

1

2 Replacing f(x) with k f(x) and f(k x) Adapted from Walch Education

3 Graphing and Points of Interest In the graph of a function, there are key points of interest that define the graph and represent the characteristics of the function. When a function is transformed, the key points of the graph define the transformation. The key points in the graph of a quadratic equation are the vertex and the roots, or x- intercepts. 5.8.2: Replacing f(x) with k f(x) and f(k x)2

4 Multiplying the Dependent Variable by a Constant, k: k f(x) In general, multiplying a function by a constant will stretch or shrink (compress) the graph of f vertically. If k > 1, the graph of f(x) will stretch vertically by a factor of k (so the parabola will appear narrower). A vertical stretch pulls the parabola and stretches it away from the x-axis. If 0 < k < 1, the graph of f(x) will shrink or compress vertically by a factor of k (so the parabola will appear wider). 5.8.2: Replacing f(x) with k f(x) and f(k x)3

5 Key Concepts, continued. A vertical compression squeezes the parabola toward the x-axis. If k < 0, the parabola will be first stretched or compressed and then reflected over the x- axis. The x-intercepts (roots) will remain the same, as will the x-coordinate of the vertex (the axis of symmetry). While k f(x) = f(k x) can be true, generally k f(x) ≠ f(k x). 5.8.2: Replacing f(x) with k f(x) and f(k x)4

6 Vertical Stretches 5.8.2: Replacing f(x) with k f(x) and f(k x)5 Vertical stretches: when k > 1 in k f(x) The graph is stretched vertically by a factor of k. The x-coordinate of the vertex remains the same. The y-coordinate of the vertex changes. The x-intercepts remain the same.

7 Vertical Compressions 5.8.2: Replacing f(x) with k f(x) and f(k x)6 Vertical compressions: when 0 < k < 1 in k f(x) The graph is compressed vertically by a factor of k. The x-coordinate of the vertex remains the same. The y-coordinate of the vertex changes. The x-intercepts remain the same.

8 Reflections over the x-axis 5.8.2: Replacing f(x) with k f(x) and f(k x)7 Reflections over the x-axis: when k = –1 in k f(x) The parabola is reflected over the x-axis. The x-coordinate of the vertex remains the same. The y-coordinate of the vertex changes. The x-intercepts remain the same. When k < 0, first perform the vertical stretch or compression, and then reflect the function over the x-axis.

9 Multiplying the Independent Variable by a Constant, k: f(k x) In general, multiplying the independent variable in a function by a constant will stretch or shrink the graph of f horizontally. If k > 1, the graph of f(x) will shrink or compress horizontally by a factor of (so the parabola will appear narrower). A horizontal compression squeezes the parabola toward the y-axis. 5.8.2: Replacing f(x) with k f(x) and f(k x)8

10 Key Concepts, continued. If 0 < k < 1, the graph of f(x) will stretch horizontally by a factor of (so the parabola will appear wider). A horizontal stretch pulls the parabola and stretches it away from the y-axis. If k < 0, the graph is first horizontally stretched or compressed and then reflected over the y-axis. The y-intercept remains the same, as does the y-coordinate of the vertex. 5.8.2: Replacing f(x) with k f(x) and f(k x)9

11 Key Concepts, continued. When a constant k is multiplied by the variable x of a function f(x), the interval of the intercepts of the function is increased or decreased depending on the value of k. The roots of the equation ax 2 + bx + c = 0 are given by the quadratic formula, Remember that in the standard form of an equation, ax 2 + bx + c, the only variable is x; a, b, and c represent constants. 5.8.2: Replacing f(x) with k f(x) and f(k x)10

12 Key Concepts, continued. If we were to multiply x in the equation ax 2 + bx + c by a constant k, we would arrive at the following: Use the quadratic formula to find the roots of 5.8.2: Replacing f(x) with k f(x) and f(k x)11

13 Horizontal Compressions 5.8.2: Replacing f(x) with k f(x) and f(k x)12 Horizontal compressions: when k > 1 in f(k x) The graph is compressed horizontally by a factor of The y-coordinate of the vertex remains the same. The x-coordinate of the vertex changes.

14 Horizontal Stretches 5.8.2: Replacing f(x) with k f(x) and f(k x)13 Horizontal stretches: when 0 < k < 1 in f(k x) The graph is stretched horizontally by a factor of The y-coordinate of the vertex remains the same. The x-coordinate of the vertex changes.

15 Reflections over the y-axis 5.8.2: Replacing f(x) with k f(x) and f(k x)14 Reflections over the y-axis: when k = –1 in f(k x) The parabola is reflected over the y-axis. The y-coordinate of the vertex remains the same. The x-coordinate of the vertex changes. The y-intercept remains the same. When k < 0, first perform the horizontal compression or stretch, and then reflect the function over the y-axis.

16 Practice # 1 Consider the function f(x) = x 2, its graph, and the constant k = 2. What is k f(x)? How are the graphs of f(x) and k f(x) different? How are they the same? 5.8.2: Replacing f(x) with k f(x) and f(k x)15

17 Substitute the value of k into the function. If f(x) = x 2 and k = 2, then k f(x) = 2 f(x) = 2x 2. Use a table of values to graph the functions. 5.8.2: Replacing f(x) with k f(x) and f(k x)16 xf(x)f(x)k f(x) –248 –112 000 112 248

18 Graph f(x) = x 2 and k f(x) = 2 f(x) = 2x 2 5.8.2: Replacing f(x) with k f(x) and f(k x)17

19 Compare the graphs. Notice the position of the vertex has not changed in the transformation of f(x). Therefore, both equations have same root, x = 0. However, notice the inner graph, 2x 2, is more narrow than x 2 because the value of 2 f(x) is increasing twice as fast as the value of f(x). Since k > 1, the graph of f(x) will stretch vertically by a factor of 2. The parabola appears narrower. 5.8.2: Replacing f(x) with k f(x) and f(k x)18

20 THANKS FOR WATCHING! Ms. Dambreville

Download ppt "Replacing f(x) with k f(x) and f(k x) Adapted from Walch Education."

Similar presentations

y = ⅔f(x) Vertical Stretches about an Axis.

y = ⅔f(x) Vertical Stretches about an Axis.
THE GRAPH OF A QUADRATIC FUNCTION

THE GRAPH OF A QUADRATIC FUNCTION
Mathematical Studies for the IB Diploma Second Edition © Hodder & Stoughton Ltd 2012 6.3 The quadratic function.

Mathematical Studies for the IB Diploma Second Edition © Hodder & Stoughton Ltd The quadratic function.
Quadratic Functions, Quadratic Expressions, Quadratic Equations

Quadratic Functions, Quadratic Expressions, Quadratic Equations
Gold Day – 2/24/2015 Blue Day – 2/25/2015.  Unit 5 – Linear functions and Applications  Review – slope, slope intercept form  Standard Form  Finding.

Gold Day – 2/24/2015 Blue Day – 2/25/2015.  Unit 5 – Linear functions and Applications  Review – slope, slope intercept form  Standard Form  Finding.
Quadratic Functions Review / Warm up. f(x) = ax^2 + bx + c. In this form when: a>0 graph opens up a 0 Graph has 2 x-intercepts.

Quadratic Functions Review / Warm up. f(x) = ax^2 + bx + c. In this form when: a>0 graph opens up a 0 Graph has 2 x-intercepts.
The vertex of the parabola is at (h, k).

The vertex of the parabola is at (h, k).
Adapted from Walch Education  The standard form of a quadratic function is f ( x ) = ax 2 + bx + c, where a is the coefficient of the quadratic term,

Adapted from Walch Education  The standard form of a quadratic function is f ( x ) = ax 2 + bx + c, where a is the coefficient of the quadratic term,
Graphing Quadratic Functions

Graphing Quadratic Functions
3.2 Intercepts. Intercepts X-intercept is the x- coordinate of a point when the graph cuts the x-axis Y-intercept is the y- coordinate of a point when.

3.2 Intercepts. Intercepts X-intercept is the x- coordinate of a point when the graph cuts the x-axis Y-intercept is the y- coordinate of a point when.
Chapter 16 Quadratic Equations.

Chapter 16 Quadratic Equations.
+ Translating Parabolas §5.3. + By the end of today, you should be able to… 1. Use the vertex form of a quadratic function to graph a parabola. 2. Convert.

+ Translating Parabolas § By the end of today, you should be able to… 1. Use the vertex form of a quadratic function to graph a parabola. 2. Convert.
Warm-Up: you should be able to answer the following without the use of a calculator 2) Graph the following function and state the domain, range and axis.

Warm-Up: you should be able to answer the following without the use of a calculator 2) Graph the following function and state the domain, range and axis.
9.2 Key Features of a Parabola

9.2 Key Features of a Parabola
Copyright © 2014, 2010, 2007 Pearson Education, Inc. 1 1 Chapter 9 Quadratic Equations and Functions.

Copyright © 2014, 2010, 2007 Pearson Education, Inc. 1 1 Chapter 9 Quadratic Equations and Functions.
Copyright © 2011 Pearson Education, Inc. Quadratic Functions and Inequalities Section 3.1 Polynomial and Rational Functions.

Copyright © 2011 Pearson Education, Inc. Quadratic Functions and Inequalities Section 3.1 Polynomial and Rational Functions.
The General Quadratic Function Students will be able to graph functions defined by the general quadratic equation.

The General Quadratic Function Students will be able to graph functions defined by the general quadratic equation.
Warm Up  .

Warm Up  .
Graphing Quadratic Functions 11.4 1.Graph quadratic functions of the form f ( x ) = ax 2. 2.Graph quadratic functions of the form f ( x ) = ax 2 + k. 3.Graph.

Graphing Quadratic Functions Graph quadratic functions of the form f ( x ) = ax 2. 2.Graph quadratic functions of the form f ( x ) = ax 2 + k. 3.Graph.
Definitions 4/23/2017 Quadratic Equation in standard form is viewed as, ax2 + bx + c = 0, where a ≠ 0 Parabola is a u-shaped graph.

Definitions 4/23/2017 Quadratic Equation in standard form is viewed as, ax2 + bx + c = 0, where a ≠ 0 Parabola is a u-shaped graph.

Similar presentations

Ads by Google