Difference between revisions of "Single Transformations of Functions"
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==Introduction== | ==Introduction== | ||
− | + | ||
− | + | <div class="floatright"> | |
− | + | <gallery perrow="2" widths="300px" heights="200px"> | |
− | + | File:Vertical shift.png|Vertical shift: <math> f(x) = x^2 </math> (red) and <math> g(x) = x^2 + 4 </math> (blue) | |
+ | File:Horizontal shift.png|Horizontal shift: <math> f(x) = sin(x) </math> (red) and <math> g(x) = sin(x + \frac{\pi}{2}) </math> (blue) | ||
+ | File:Vertical reflection.png|Vertical reflection: <math> f(x) = \sqrt{x} </math> (red) and <math> g(x) = -\sqrt{x} </math> (blue) | ||
+ | File:Horizontal reflection.png|Horizontal reflection: <math> f(x) = e^x </math> (red) and <math> g(x) = e^{-x} </math> (blue) | ||
+ | File:Vertical stretch compression.png|Vertical stretch/compression: <math> f(x) = x^2 </math> (red), <math> g(x) = \frac{1}{2}x^2 </math> (blue, vert. compression), <math> h(x) = 2x^2 </math> (green, vert. stretch), and <math> j(x) = -2x^2 </math> (black, vert. stretch and vert. reflection) | ||
+ | File:Horizontal stretch compression.png|Horizontal stretch/compression: <math> f(x) = \sqrt{x} </math> (red), <math> g(x) = \sqrt{2x} </math> (blue, horiz. compression), <math> h(x) = \sqrt{\frac{1}{2}x} </math> (green, horiz. stretch), and <math> j(x) = \sqrt{-2x} </math> (black, horiz. compression and horiz. reflection) | ||
+ | </gallery> | ||
+ | </div> | ||
+ | |||
===Translations=== | ===Translations=== | ||
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* If <math> b > 1 </math>, then the graph will be horizontally compressed by a factor of <math> \frac{1}{b} </math>. | * If <math> b > 1 </math>, then the graph will be horizontally compressed by a factor of <math> \frac{1}{b} </math>. | ||
* If <math> 0 < b < 1 </math>, then the graph will be horizontally stretched by a factor of <math> \frac{1}{b} </math>. | * If <math> 0 < b < 1 </math>, then the graph will be horizontally stretched by a factor of <math> \frac{1}{b} </math>. | ||
− | * If b < 0, then there will be a horizontal stretch or compression of a factor of <math> |\frac{1}{b}| </math>, along with a vertical reflection. | + | * If b < 0, then there will be a horizontal stretch or compression of a factor of <math> \Big|\frac{1}{b} \Big| </math>, along with a vertical reflection. |
==Resources== | ==Resources== | ||
* [https://courses.lumenlearning.com/wmopen-collegealgebra/chapter/introduction-transformations-of-functions/ Intro to Transformations of Functions], Lumen Learning | * [https://courses.lumenlearning.com/wmopen-collegealgebra/chapter/introduction-transformations-of-functions/ Intro to Transformations of Functions], Lumen Learning | ||
− | * | + | |
+ | == Licensing == | ||
+ | Content obtained and/or adapted from: | ||
+ | * [https://courses.lumenlearning.com/wmopen-collegealgebra/chapter/introduction-transformations-of-functions/ Transformations of Functions, Lumen Learning College Algebra] under a CC BY-SA license |
Latest revision as of 12:39, 15 January 2022
Contents
Introduction
Translations
One kind of transformation involves shifting the entire graph of a function up, down, right, or left. The simplest shift is a vertical shift, moving the graph up or down, because this transformation involves adding a positive or negative constant to the function. In other words, we add the same constant to the output value of the function regardless of the input. For a function , the function is shifted vertically k units. For example, is the function shifted up by 4 units. is the function shifted down by 7.7 units.
Given a function f, a new function , where h is a constant, is a horizontal shift of the function f. If h is positive, the graph will shift h units to the right. If h is negative, the graph will shift h units to the left. For example, is the graph of shifted 3 units to the right. is the function shifted units to the left.
Reflections
Given a function , a new function is a vertical reflection of the function , sometimes called a reflection about (or over, or through) the x-axis. For example, is a vertical reflection of the function .
Given a function , a new function is a horizontal reflection of the function , sometimes called a reflection about the y-axis. For example, is a horizontal reflection of the function .
Even and Odd Functions
A function f is even if for all values of x, ; that is, a function is even if its horizontal reflection is identical to itself. For example, is an even function since .
A function f is odd if for all values of x, ; that is, a function is odd if a horizontal reflection and vertical reflection of the function results in the same function. For example, is an odd function since .
If a function satisfies neither of these conditions, then it is neither even nor odd. For example, is neither even nor odd because , which is not equal to , and , which is also not equal to .
Compressions and Stretches
Given a function , a new function , where is a constant, is a vertical stretch or vertical compression of the function .
- If , then the graph will be stretched.
- If , then the graph will be compressed.
- If a < 0, then there will be a vertical stretch or compression of a factor of , along with a vertical reflection.
Given a function , a new function , where is a constant, is a horizontal stretch or horizontal compression of the function .
- If , then the graph will be horizontally compressed by a factor of .
- If , then the graph will be horizontally stretched by a factor of .
- If b < 0, then there will be a horizontal stretch or compression of a factor of , along with a vertical reflection.
Resources
- Intro to Transformations of Functions, Lumen Learning
Licensing
Content obtained and/or adapted from:
- Transformations of Functions, Lumen Learning College Algebra under a CC BY-SA license