Post on 18-May-2015
Transformations of Graphs
http://www.lahc.edu/math/precalculus/math_260a.html
Transformations of Graphs
Function Calisthenics (Origin Unknown)
Objective:
* Vertical stretches and compressions of graphs
* Vertical and horizontal translations of graphs
Transformations of Graphs
Using image manipulation software, we can drag and drop or stretch images.
Transformations of Graphs
Using image manipulation software, we can drag and drop or stretch images. For example, from the original image below,
Transformations of Graphs
y = f(x)
Using image manipulation software, we can drag and drop or stretch images. For example, from the original image below, we can elongate it,
stretch
Transformations of Graphs
y = f(x)
Using image manipulation software, we can drag and drop or stretch images. For example, from the original image below, we can elongate it, drag and lower it,
stretch
lower
Transformations of Graphs
y = f(x)
Using image manipulation software, we can drag and drop or stretch images. For example, from the original image below, we can elongate it, drag and lower it,
stretch
lower
vertically reflected
and reflect it vertically to create another pattern.
Transformations of Graphs
y = f(x)
Using image manipulation software, we can drag and drop or stretch images. For example, from the original image below, we can elongate it, drag and lower it,
stretch
lower
vertically reflected
and reflect it vertically to create another pattern.
If the original image is the graph of the function y = f(x), then these transformations can be tracked easily with the notation of functions.
Transformations of Graphs
y = f(x)
Given a function y = f(x) and P = (x, y = f(x)) a generic point on the graph as shown, the output f(x) = y represents the height of the point.
x
P = (x, f(x))
f(x) = ht y= f(x)
x
Vertical Translations
Given a function y = f(x) and P = (x, y = f(x)) a generic point on the graph as shown, the output f(x) = y represents the height of the point. Hence expressions in terms of f(x) may be translated precisely intothe corresponding manipulation of the graph.
x
P = (x, f(x))
f(x) = ht y= f(x)
x
Vertical Translations
Given a function y = f(x) and P = (x, y = f(x)) a generic point on the graph as shown, the output f(x) = y represents the height of the point. Hence expressions in terms of f(x) may be translated precisely intothe corresponding manipulation of the graph.Vertical Translations x
P = (x, f(x))
f(x) = ht y= f(x)
x
Vertical Translations
Given a function y = f(x) and P = (x, y = f(x)) a generic point on the graph as shown, the output f(x) = y represents the height of the point.
x
P = (x, f(x))
f(x) = ht y= f(x)
Hence expressions in terms of f(x) may be translated precisely intothe corresponding manipulation of the graph.Vertical TranslationsChanging the y–coordinate to f(x) + 3 moves P vertically up 3 units.
(x, f(x)+3)
x
Vertical Translations
Given a function y = f(x) and P = (x, y = f(x)) a generic point on the graph as shown, the output f(x) = y represents the height of the point.
x
P = (x, f(x))
f(x) = ht y= f(x)
Hence expressions in terms of f(x) may be translated precisely intothe corresponding manipulation of the graph.Vertical TranslationsChanging the y–coordinate to f(x) + 3 moves P vertically up 3 units.
(x, f(x)+3) y= f(x) + 3
Hence setting y = f(x) + 3 to all the points on the graph means to move the entire graph 3 units up as shown.
x
Vertical Translations
Given a function y = f(x) and P = (x, y = f(x)) a generic point on the graph as shown, the output f(x) = y represents the height of the point.
x
P = (x, f(x))
f(x) = ht y= f(x)
Hence expressions in terms of f(x) may be translated precisely intothe corresponding manipulation of the graph.Vertical TranslationsChanging the y–coordinate to f(x) + 3 moves P vertically up 3 units.Hence setting y = f(x) + 3 to all the points on the graph means to move the entire graph 3 units up as shown. Likewise changing the y–coordinate to f(x) – 3 corresponds to moving y = f(x) down 3 units.
(x, f(x)+3)
(x, f(x)–3)
y= f(x) – 3
y= f(x) + 3
x
Vertical Translations
The graph of (x, y = f(x) + c) is the vertical translation of the graph (x, f(x)).
Vertical TranslationsVertical Translations
The graph of (x, y = f(x) + c) is the vertical translation of the graph (x, f(x)).
Vertical Translations
P = (x, f(x)) y= f(x)
(x, f(x)+c) where c > 0
(x, f(x)+c) where c < 0
Vertical Translations
The graph of (x, y = f(x) + c) is the vertical translation of the graph (x, f(x)).
Vertical Translations
P = (x, f(x)) y= f(x)
(x, f(x)+c) where c > 0
(x, f(x)+c) where c < 0 Here are the graphs of:
y = f(x) = x2 vs. y = f(x) + 5 = x2 + 5
y = x2
y = x2 + 5
(0, 0)
(0, 5)
Vertical Translations
Vertical Translations
P = (x, f(x)) y= f(x)
(x, f(x)+c) where c > 0
(x, f(x)+c) where c < 0 Here are the graphs of:
y = f(x) = x2 vs. y = f(x) + 5 = x2 + 5
y = x2
y = x2 + 5
(0, 0)
(0, 5)
x
Vertical Translations
The graph of (x, y = f(x) + c) is the vertical translation of the graph (x, f(x)). Assuming c > 0, move the graph (x, f(x)) up to obtain the graph (x, f(x) + c).
Vertical Translations
P = (x, f(x)) y= f(x)
(x, f(x)+c) where c > 0
(x, f(x)+c) where c < 0 Here are the graphs of:
y = f(x) = x2 vs. y = f(x) + 5 = x2 + 5
y = f(x) = x2 vs. y = f(x) – 5 = x2 – 5
y = x2
y = x2 + 5
y = x2 – 5
y = x2
(0, 0)
(0, 5)
(0, 0)
(0, –5)
xx
Vertical Translations
The graph of (x, y = f(x) + c) is the vertical translation of the graph (x, f(x)). Assuming c > 0, move the graph (x, f(x)) up to obtain the graph (x, f(x) + c).
The graph of (x, y = f(x) + c) is the vertical translation of the graph (x, f(x)). Assuming c > 0, move the graph (x, f(x)) up to obtain the graph (x, f(x) + c).
Vertical Translations
move the graph (x, f(x)) down to obtain the graph (x, f(x) – c).
P = (x, f(x)) y= f(x)
(x, f(x)+c) where c > 0
(x, f(x)+c) where c < 0 Here are the graphs of:
y = f(x) = x2 vs. y = f(x) + 5 = x2 + 5
y = f(x) = x2 vs. y = f(x) – 5 = x2 – 5
y = x2
y = x2 + 5
y = x2 – 5
y = x2
(0, 0)
(0, 5)
(0, 0)
(0, –5)
xx
Vertical Translations
Given a function y = f(x) and P = (x, y = f(x)) a generic point on the graph as shown.
Vertical Stretches and Compressions
P = (x, f(x)) y= f(x)
Vertical Stretches and Compressions
Given a function y = f(x) and P = (x, y = f(x)) a generic point on the graph as shown. Changing the y–coordinate to 3f(x)would triple the height of the point P.
Vertical Stretches and Compressions
P = (x, f(x)) y= f(x)
Vertical Stretches and Compressions
Given a function y = f(x) and P = (x, y = f(x)) a generic point on the graph as shown. Changing the y–coordinate to 3f(x)would triple the height of the point P.
Vertical Stretches and Compressions
P = (x, f(x)) y= f(x)
Hence setting y = 3f(x) to all the points on the graph means to elongate the entire graph 3 times while the x–intercepts (x, 0)’s remain fixed because 3(0) = 0.
y= 3f(x)
Vertical Stretches and Compressions
Given a function y = f(x) and P = (x, y = f(x)) a generic point on the graph as shown. Changing the y–coordinate to 3f(x)would triple the height of the point P.
Vertical Stretches and Compressions
P = (x, f(x)) y= f(x)
Hence setting y = 3f(x) to all the points on the graph means to elongate the entire graph 3 times while the x–intercepts (x, 0)’s remain fixed because 3(0) = 0.
y= 3f(x)
Vertical Stretches and Compressions
Given a function y = f(x) and P = (x, y = f(x)) a generic point on the graph as shown. Changing the y–coordinate to 3f(x)would triple the height of the point P.
Vertical Stretches and Compressions
P = (x, f(x)) y= f(x)
Hence setting y = 3f(x) to all the points on the graph means to elongate the entire graph 3 times while the x–intercepts (x, 0)’s remain fixed because 3(0) = 0.
Likewise setting y = (1/3)f(x) would compress the entire graph to a third of it’s original size while the x–intercepts or (x, 0)’s remain fixed.
y= 3f(x)
Vertical Stretches and Compressions
Given a function y = f(x) and P = (x, y = f(x)) a generic point on the graph as shown. Changing the y–coordinate to 3f(x)would triple the height of the point P.
Vertical Stretches and Compressions
P = (x, f(x)) y= f(x)
Hence setting y = 3f(x) to all the points on the graph means to elongate the entire graph 3 times while the x–intercepts (x, 0)’s remain fixed because 3(0) = 0.
Likewise setting y = (1/3)f(x) would compress the entire graph to a third of it’s original size while the x–intercepts or (x, 0)’s remain fixed.
y= 3f(x)
y= f(x)/3
Vertical Stretches and Compressions
Vertical Stretches and CompressionsAssuming c > 0, the graph of y = cf(x) is the vertical-stretch or compression of y = f(x).
Vertical Stretches and Compressions
Vertical Stretches and CompressionsAssuming c > 0, the graph of y = cf(x) is the vertical-stretch or compression of y = f(x).
Here are the graphs of: y = f(x) = 4 – x2 vs. y = 3f(x) = 3(4 – x2)
y = 4 – x2
y = 3(4 – x2)
(0, 4)
(0, 12)
(–2, 0) (2, 0) x
Vertical Stretches and Compressions
Vertical Stretches and CompressionsAssuming c > 0, the graph of y = cf(x) is the vertical-stretch or compression of y = f(x). If c > 1, it is a vertical stretch by a factor of c.
Here are the graphs of: y = f(x) = 4 – x2 vs. y = 3f(x) = 3(4 – x2)
y = 4 – x2
y = 3(4 – x2)
(0, 4)
(0, 12)
(–2, 0) (2, 0)
c = 3
x
Vertical Stretches and Compressions
Vertical Stretches and CompressionsAssuming c > 0, the graph of y = cf(x) is the vertical-stretch or compression of y = f(x). If c > 1, it is a vertical stretch by a factor of c.
Here are the graphs of: y = f(x) = 4 – x2 vs. y = 3f(x) = 3(4 – x2)
y = f(x) = 4 – x2 vs. y = f(x)/2 = (4 – x2)/2
y = 4 – x2
y = 3(4 – x2)y = 4 – x2
y = (4 – x2)/2
(0, 4)
(0, 12)
(0, 4)
(0, 2)
(–2, 0) (2, 0)
(–2, 0) (2, 0)
c = 3 c = 1/2
xx
Vertical Stretches and Compressions
Vertical Stretches and CompressionsAssuming c > 0, the graph of y = cf(x) is the vertical-stretch or compression of y = f(x). If c > 1, it is a vertical stretch by a factor of c. If 0 < c < 1, it is a vertical compression by a factor of c.Here are the graphs of: y = f(x) = 4 – x2 vs. y = 3f(x) = 3(4 – x2)
y = f(x) = 4 – x2 vs. y = f(x)/2 = (4 – x2)/2
y = 4 – x2
y = 3(4 – x2)y = 4 – x2
y = (4 – x2)/2
(0, 4)
(0, 12)
(0, 4)
(0, 2)
(–2, 0) (2, 0)
(–2, 0) (2, 0)
c = 3 c = 1/2
xx
Vertical Stretches and Compressions
Changing the y-coordinate to –f(x) reflects the point P vertically across the x–axis to Q(x, –f(x)) as shown.
P = (x, f(x))
y= f(x) x
Vertical Stretches and Compressions
Changing the y-coordinate to –f(x) reflects the point P vertically across the x–axis to Q(x, –f(x)) as shown.
P = (x, f(x))
y= f(x)
Q = (x, –f(x))
x
Vertical Stretches and Compressions
Changing the y-coordinate to –f(x) reflects the point P vertically across the x–axis to Q(x, –f(x)) as shown.
P = (x, f(x))
y= f(x)
Hence setting y = –f(x) to all the points on the graph means to reflect the entire graph vertically across the x–axis.
y= –f(x)
Q = (x, –f(x))
x
Vertical Stretches and Compressions
Changing the y-coordinate to –f(x) reflects the point P vertically across the x–axis to Q(x, –f(x)) as shown.
P = (x, f(x))
y= f(x)
Hence setting y = –f(x) to all the points on the graph means to reflect the entire graph vertically across the x–axis. Hence settingy = –cf(x) = c*(–f(x)) to all the points means to reflect the entire graph (x, f(x)) vertically, then stretch the reflection by a factor of c.
y= –f(x)
Q = (x, –f(x))
x
Vertical Stretches and Compressions
Changing the y-coordinate to –f(x) reflects the point P vertically across the x–axis to Q(x, –f(x)) as shown.
P = (x, f(x))
y= f(x)
Hence setting y = –f(x) to all the points on the graph means to reflect the entire graph vertically across the x–axis. Hence settingy = –cf(x) = c*(–f(x)) to all the points means to reflect the entire graph (x, f(x)) vertically, then stretch the reflection by a factor of c.
y= –f(x)
y= –2f(x)
Q = (x, –f(x))
(x, –2f(x))
x
Vertical Stretches and Compressions
Changing the y-coordinate to –f(x) reflects the point P vertically across the x–axis to Q(x, –f(x)) as shown.
P = (x, f(x))
y= f(x)
Hence setting y = –f(x) to all the points on the graph means to reflect the entire graph vertically across the x–axis. Hence settingy = –cf(x) = c*(–f(x)) to all the points means to reflect the entire graph (x, f(x)) vertically, then stretch the reflection by a factor of c. The order of applying stretching vs. reflecting does not matter, “reflect then stretch” or “stretch then reflect” yields the same result. This is not the case for “stretch” vs. “vertical shift”.
y= –f(x)
y= –2f(x)
Q = (x, –f(x))
(x, –2f(x))
x
Vertical Stretches and Compressions
Example A. a. Given the graph of y = f(x),graph y = g(x) = –2f(x) + 3
(–3, 1)
(–1, –1)
(1, 1) (2, 1)
x
Vertical Stretches and Compressions
Example A. a. Given the graph of y = f(x),graph y = g(x) = –2f(x) + 3
(–3, 1)
(–1, –1)
(1, 1) (2, 1)
“–2f(x)" corresponds stretching the graph by a factor of 2, then reflecting the entire graph across the x axis. Afterwards move the graph vertically up by 3.
x
Vertical Stretches and Compressions
Example A. a. Given the graph of y = f(x),graph y = g(x) = –2f(x) + 3
(–3, 1)
(–1, –1)
(1, 1) (2, 1)
“–2f(x)" corresponds stretching the graph by a factor of 2, then reflecting the entire graph across the x axis. Afterwards move the graph vertically up by 3.To draw the graph, track the “important points” on the graph.
x
Vertical Stretches and Compressions
Example A. a. Given the graph of y = f(x),graph y = g(x) = –2f(x) + 3
(–3, 1)
(–1, –1)
(1, 1) (2, 1)
“–2f(x)" corresponds stretching the graph by a factor of 2, then reflecting the entire graph across the x axis. Afterwards move the graph vertically up by 3.To draw the graph, track the “important points” on the graph. Plug in their x–values to find the corresponding y–values, then plot their destinations.
x
Vertical Stretches and Compressions
Example A. a. Given the graph of y = f(x),graph y = g(x) = –2f(x) + 3
(–3, 1)
(–1, –1)
(1, 1) (2, 1)
“–2f(x)" corresponds stretching the graph by a factor of 2, then reflecting the entire graph across the x axis. Afterwards move the graph vertically up by 3.To draw the graph, track the “important points” on the graph. Plug in their x–values to find the corresponding y–values, then plot their destinations.
(–3, 1)
x
Vertical Stretches and Compressions
y = g(x) = –2f(x) + 3y = f(x)
Example A. a. Given the graph of y = f(x),graph y = g(x) = –2f(x) + 3
(–3, 1)
(–1, –1)
(1, 1) (2, 1)
“–2f(x)" corresponds stretching the graph by a factor of 2, then reflecting the entire graph across the x axis. Afterwards move the graph vertically up by 3.To draw the graph, track the “important points” on the graph. Plug in their x–values to find the corresponding y–values, then plot their destinations.
(–3, 1) (–3, –2f(–3) + 3 = 1)
x
Vertical Stretches and Compressions
y = g(x) = –2f(x) + 3y = f(x)
Example A. a. Given the graph of y = f(x),graph y = g(x) = –2f(x) + 3
(–3, 1)
(–1, –1)
(1, 1) (2, 1)
“–2f(x)" corresponds stretching the graph by a factor of 2, then reflecting the entire graph across the x axis. Afterwards move the graph vertically up by 3.To draw the graph, track the “important points” on the graph. Plug in their x–values to find the corresponding y–values, then plot their destinations.
(–3, 1) (–3, –2f(–3) + 3 = 1)(–1, –1) (–1, –2f(–1) + 3 = 5)
x
Vertical Stretches and Compressions
y = g(x) = –2f(x) + 3y = f(x)
Example A. a. Given the graph of y = f(x),graph y = g(x) = –2f(x) + 3
(–3, 1)
(–1, –1)
(1, 1) (2, 1)
“–2f(x)" corresponds stretching the graph by a factor of 2, then reflecting the entire graph across the x axis. Afterwards move the graph vertically up by 3.To draw the graph, track the “important points” on the graph. Plug in their x–values to find the corresponding y–values, then plot their destinations.
(–3, 1) (–3, –2f(–3) + 3 = 1)(–1, –1) (–1, –2f(–1) + 3 = 5)(1, 1) (1, –2f(1) + 3 = 1)(2, 1) (2, –2f(2) + 3 = 1)
x
Vertical Stretches and Compressions
y = g(x) = –2f(x) + 3y = f(x)
Example A. a. Given the graph of y = f(x),graph y = g(x) = –2f(x) + 3
(–3, 1)
(–1, –1)
(1, 1) (2, 1)
“–2f(x)" corresponds stretching the graph by a factor of 2, then reflecting the entire graph across the x axis. Afterwards move the graph vertically up by 3.To draw the graph, track the “important points” on the graph. Plug in their x–values to find the corresponding y–values, then plot their destinations.
(–3, 1) (–3, –2f(–3) + 3 = 1)(–1, –1) (–1, –2f(–1) + 3 = 5)(1, 1) (1, –2f(1) + 3 = 1)(2, 1) (2, –2f(2) + 3 = 1)
(–3, 1)
(–1, 5)
(1, 1)(2, 1)
x
x
Vertical Stretches and Compressions
y = g(x) = –2f(x) + 3y = f(x) Graph of y = g(x)
Horizontal Translationsy= f(x)
x
Let y = f(x) be as shown.
Horizontal Translationsy= f(x)
x
Let y = f(x) be as shown.Let’s define g(x) = f(x + 1), and the goal is to graph g(x).
Horizontal Translations
x
y= f(x)
x
Let y = f(x) be as shown.Let’s define g(x) = f(x + 1), and the goal is to graph g(x).For the point x, the output isy = g(x) = f(x + 1),
Horizontal Translations
x
(x+1, f(x+1))
ht =f(x+1)
y= f(x)
x
Let y = f(x) be as shown.Let’s define g(x) = f(x + 1), and the goal is to graph g(x).For the point x, the output isy = g(x) = f(x + 1),
x+1
Horizontal Translations
x
(x+1, f(x+1))
ht =f(x+1)
y= f(x)
x
Let y = f(x) be as shown.Let’s define g(x) = f(x + 1), and the goal is to graph g(x).For the point x, the output isy = g(x) = f(x + 1), so the point (x, g(x) = f(x +1)) is on the graph of g(x). x+1
Horizontal Translations
x
(x+1, f(x+1))
ht =f(x+1)
y= f(x)
x
Let y = f(x) be as shown.Let’s define g(x) = f(x + 1), and the goal is to graph g(x).For the point x, the output isy = g(x) = f(x + 1), so the point (x, g(x) = f(x +1)) is on the graph of g(x). x+1
(x, f(x +1))
Horizontal Translations
x
(x+1, f(x+1))
ht =f(x+1)
y= f(x)
x
Let y = f(x) be as shown.Let’s define g(x) = f(x + 1), and the goal is to graph g(x).For the point x, the output isy = g(x) = f(x + 1), so the point (x, g(x) = f(x +1)) is on the graph of g(x). ux+1
(x, f(x +1))
Likewise if the input is u,
Horizontal Translations
x
(x+1, f(x+1))
ht =f(x+1)
y= f(x)
x
Let y = f(x) be as shown.Let’s define g(x) = f(x + 1), and the goal is to graph g(x).For the point x, the output isy = g(x) = f(x + 1), so the point (x, g(x) = f(x +1)) is on the graph of g(x). u
(u+1, f(u+1))
ht = f(u+1)
u+1x+1
(x, f(x +1))
Likewise if the input is u, then y = g(u) = f(u + 1)
Horizontal Translations
x
(x+1, f(x+1))
ht =f(x+1)
y= f(x)
x
Let y = f(x) be as shown.Let’s define g(x) = f(x + 1), and the goal is to graph g(x).For the point x, the output isy = g(x) = f(x + 1), so the point (x, g(x) = f(x +1)) is on the graph of g(x). u
(u+1, f(u+1))
ht = f(u+1)
u+1x+1
(x, f(x +1))
(u, f(u +1))
Likewise if the input is u, then y = g(u) = f(u + 1) so the point (u, f(u +1)) is on the graph of g(x).
Hence to obtain the graph of y = f(x + 1),shift the entire graph of y = f(x) left by 1 unit.
Horizontal Translations
x
(x+1, f(x+1))
ht =f(x+1)
y= f(x)
x
Let y = f(x) be as shown.Let’s define g(x) = f(x + 1), and the goal is to graph g(x).For the point x, the output isy = g(x) = f(x + 1), so the point (x, g(x) = f(x +1)) is on the graph of g(x). u
(u+1, f(u+1))
ht = f(u+1)
u+1x+1
y = g(x) or y = f(x + 1)
(x, f(x +1))
(u, f(u +1))
Likewise if the input is u, then y = g(u) = f(u + 1) so the point (u, f(u +1)) is on the graph of g(x).
Shifting left by 1
Hence to obtain the graph of y = f(x + 1),shift the entire graph of y = f(x) left by 1 unit.
Horizontal Translations
x
(x+1, f(x+1))
ht =f(x+1)
y= f(x)
x
Let y = f(x) be as shown.Let’s define g(x) = f(x + 1), and the goal is to graph g(x).For the point x, the output isy = g(x) = f(x + 1), so the point (x, g(x) = f(x +1)) is on the graph of g(x). u
(u+1, f(u+1))
ht = f(u+1)
u+1x+1
y = g(x) or y = f(x + 1)
(x, f(x +1))
(u, f(u +1))
Likewise if the input is u, then y = g(u) = f(u + 1) so the point (u, f(u +1)) is on the graph of g(x).
Shifting left by 1
Similarly demonstrations show that to obtain the graph of y = f(x – 1), shift the graph of y = f(x) right by 1 unit.
Horizontal Translations The graphs of y = f(x + c) are the horizontal shifts (or translations) of y = f(x) by c units,
Horizontal Translations
Horizontal Translations The graphs of y = f(x + c) are the horizontal shifts (or translations) of y = f(x) by c units,
Horizontal Translations
Example B. Graph the following functions by shiftingthe graph of y = f(x) = x2. Label their vertices.a. g(x) = (x + 2)2 = f(x + 2)
x
y=x 2
b. h(x) = (x – 2)2 = f(x – 2)
Horizontal Shifts
Horizontal Translations The graphs of y = f(x + c) are the horizontal shifts (or translations) of y = f(x) by c units, assuming c > 0:
Horizontal Translations
moves y = f(x) to the left for y = f(x + c).
Example B. Graph the following functions by shiftingthe graph of y = f(x) = x2. Label their vertices.a. g(x) = (x + 2)2 = f(x + 2)
b. h(x) = (x – 2)2 = f(x – 2)x
y=x 2
Horizontal Shifts
Horizontal Translations The graphs of y = f(x + c) are the horizontal shifts (or translations) of y = f(x) by c units, assuming c > 0:
Horizontal Translations
moves y = f(x) to the left for y = f(x + c).
b. h(x) = (x – 2)2 = f(x – 2)
Example B. Graph the following functions by shiftingthe graph of y = f(x) = x2. Label their vertices.a. g(x) = (x + 2)2 = f(x + 2)Shift of the graph of y = x2
left 2 units.
x
y=x 2
Horizontal Shifts
Horizontal Translations The graphs of y = f(x + c) are the horizontal shifts (or translations) of y = f(x) by c units, assuming c > 0:
y=(x + 2)2
Horizontal Translations
moves y = f(x) to the left for y = f(x + c).
Example B. Graph the following functions by shiftingthe graph of y = f(x) = x2. Label their vertices.a. g(x) = (x + 2)2 = f(x + 2)Shift of the graph of y = x2
left 2 units.
x
y=x 2
b. h(x) = (x – 2)2 = f(x – 2)
Horizontal Shifts
Horizontal Translations The graphs of y = f(x + c) are the horizontal shifts (or translations) of y = f(x) by c units, assuming c > 0:
y=(x + 2)2
Horizontal Translations
moves y = f(x) to the left for y = f(x + c).
Example B. Graph the following functions by shiftingthe graph of y = f(x) = x2. Label their vertices.a. g(x) = (x + 2)2 = f(x + 2)Shift of the graph of y = x2
left 2 units. The vertex of g(x) = (x + 2)2 is (–2, 0).
x
y=x 2
b. h(x) = (x – 2)2 = f(x – 2)
Horizontal Shifts
(–2, 0)
Horizontal Translations The graphs of y = f(x + c) are the horizontal shifts (or translations) of y = f(x) by c units, assuming c > 0:
y=(x + 2)2
Horizontal Translations
moves y = f(x) to the left for y = f(x + c).moves y = f(x) to the right for y = f(x – c). Example B. Graph the following functions by shifting
the graph of y = f(x) = x2. Label their vertices.a. g(x) = (x + 2)2 = f(x + 2)Shift of the graph of y = x2
left 2 units. The vertex of g(x) = (x + 2)2 is (–2, 0).
x
y=x 2
b. h(x) = (x – 2)2 = f(x – 2)
Horizontal Shifts
(–2, 0)
Horizontal Translations The graphs of y = f(x + c) are the horizontal shifts (or translations) of y = f(x) by c units, assuming c > 0:
y=(x + 2)2
Horizontal Translations
moves y = f(x) to the left for y = f(x + c).moves y = f(x) to the right for y = f(x – c). Example B. Graph the following functions by shifting
the graph of y = f(x) = x2. Label their vertices.a. g(x) = (x + 2)2 = f(x + 2)Shift of the graph of y = x2
left 2 units. The vertex of g(x) = (x + 2)2 is (–2, 0).
x
y=x 2
b. h(x) = (x – 2)2 = f(x – 2)Shift the graph of y = x2 right 2 units. The vertex of h(x) is (2, 0). Horizontal Shifts
(–2, 0)
Horizontal Translations The graphs of y = f(x + c) are the horizontal shifts (or translations) of y = f(x) by c units, assuming c > 0:
y=(x + 2)2 y=(x – 2)2
Horizontal Translations
moves y = f(x) to the left for y = f(x + c).moves y = f(x) to the right for y = f(x – c). Example B. Graph the following functions by shifting
the graph of y = f(x) = x2. Label their vertices.a. g(x) = (x + 2)2 = f(x + 2)Shift of the graph of y = x2
left 2 units. The vertex of g(x) = (x + 2)2 is (–2, 0).
x
y=x 2
b. h(x) = (x – 2)2 = f(x – 2)Shift the graph of y = x2 right 2 units. The vertex of h(x) is (2, 0). Horizontal Shifts
(–2, 0) (2, 0)
Horizontal Stretches and Compressions
x
Let y = f(x) with its graph shown here and letg(x) = f(2x).
0
y= f(x)
Horizontal Stretches and Compressions
Horizontal Stretches and Compressions
x
Let y = f(x) with its graph shown here and letg(x) = f(2x).For the point x, the output is g(x) = f(2x)
x0
y= f(x)
Horizontal Stretches and Compressions
x
Horizontal Stretches and Compressions
x
Let y = f(x) with its graph shown here and letg(x) = f(2x).For the point x, the output is g(x) = f(2x)so the point (x, y = f(2x)) is on the graph of g(x).
x0
y= f(x)
Horizontal Stretches and Compressions
x
Horizontal Stretches and Compressions
x
Let y = f(x) with its graph shown here and letg(x) = f(2x).For the point x, the output is g(x) = f(2x)so the point (x, y = f(2x)) is on the graph of g(x).
0
y= f(x)
Horizontal Stretches and Compressions
2x
ht =f(2x)
(2x, f(2x))
x
Horizontal Stretches and Compressions
2x
ht =f(2x) x
Let y = f(x) with its graph shown here and letg(x) = f(2x).For the point x, the output is g(x) = f(2x) so the point (x, y = f(2x)) is on the graph of g(x).
x0
y= f(x)
(2x, f(2x))
Horizontal Stretches and Compressions
(x, g(x)=f(2x))
Horizontal Stretches and Compressions
2x
ht =f(2x) x
Let y = f(x) with its graph shown here and letg(x) = f(2x).For the point x, the output is g(x) = f(2x) so the point (x, y = f(2x)) is on the graph of g(x).
x0
y= f(x)
(2x, f(2x))
Horizontal Stretches and Compressions
x
Likewise for the point u, the output is g(u) = f(2u) so the point (u, y = f(2u)) is on the graph of g(x).
(x, g(x)=f(2x))
u
Horizontal Stretches and Compressions
2x
ht =f(2x) x
Let y = f(x) with its graph shown here and letg(x) = f(2x).For the point x, the output is g(x) = f(2x) so the point (x, y = f(2x)) is on the graph of g(x).
x0
y= f(x)
(2x, f(2x))
Horizontal Stretches and Compressions
x
2u
(2u, f(2u))
ht = f(2u)
Likewise for the point u, the output is g(u) = f(2u) so the point (u, y = f(2u)) is on the graph of g(x).
(x, g(x)=f(2x))
u
Horizontal Stretches and Compressions
2x
ht =f(2x) x
Let y = f(x) with its graph shown here and letg(x) = f(2x).For the point x, the output is g(x) = f(2x) so the point (x, y = f(2x)) is on the graph of g(x).
x0
y= f(x)
(2x, f(2x))
Horizontal Stretches and Compressions
x
2u
(2u, f(2u))
ht = f(2u)
Likewise for the point u, the output is g(u) = f(2u) so the point (u, y = f(2u)) is on the graph of g(x).
(x, g(x)=f(2x))
u
(u,g(u))=f(2u)
Horizontal Stretches and Compressions
2x
(u,g(u))=f(2u)
ht =f(2x)
y=g(x)=f(2x)
x
2u
(2u, f(2u))
ht = f(2u)
u
Let y = f(x) with its graph shown here and letg(x) = f(2x).For the point x, the output is g(x) = f(2x) so the point (x, y = f(2x)) is on the graph of g(x).Likewise for the point u, the output is g(u) = f(2u) so the point (u, y = f(2u)) is on the graph of g(x).
x0
y= f(x)
Horizontal stretch by a factor of 2
Hence we see that the graph of y = f(2x) is the horizontal compression of the graph y = f(x) by a factor of ½ .
(x, g(x)=f(2x)) (2x, f(2x))
Horizontal Stretches and Compressions
Horizontal Stretches and Compressions
2x
(u,g(u))=f(2u)
ht =f(2x)
y=g(x)=f(2x)
x
2u
(2u, f(2u))
ht = f(2u)
u
Let y = f(x) with its graph shown here and letg(x) = f(2x).For the point x, the output is g(x) = f(2x) so the point (x, y = f(2x)) is on the graph of g(x).Likewise for the point u, the output is g(u) = f(2u) so the point (u, y = f(2u)) is on the graph of g(x).
x0
y= f(x)
Horizontal stretch by a factor of 2
Hence we see that the graph of y = f(2x) is the horizontal compression of the graph y = f(x) by a factor of ½ . Similarly, the graph of y = f(½ * x) is the horizontal stretch the graph of y = f(x) by a factor of 2. (Convince yourself of this fact.)
(x, g(x)=f(2x)) (2x, f(2x))
Horizontal Stretches and Compressions
Horizontal ReflectionsHorizontal Stretches and Compressions
Let y = f(x) with its graph shown here and letg(x) = f(–x).
x
y= f(x)y
0
Horizontal reflection
Horizontal ReflectionsHorizontal Stretches and Compressions
Let y = f(x) with its graph shown here and letg(x) = f(–x).For the point x, the output is g(x) = f(–x)
x
y= f(x)
x
y
0
Horizontal reflection
Horizontal ReflectionsHorizontal Stretches and Compressions
Let y = f(x) with its graph shown here and letg(x) = f(–x).For the point x, the output is g(x) = f(–x)so the point (x, y = f(–x)) is on the graph of g(x).
x
y= f(x)
x
y
–x0
Horizontal reflection
Horizontal ReflectionsHorizontal Stretches and Compressions
Let y = f(x) with its graph shown here and letg(x) = f(–x).For the point x, the output is g(x) = f(–x)so the point (x, y = f(–x)) is on the graph of g(x).
x
y= f(x)
x
y
–x
(x, g(x)=f(–x))
0
Horizontal reflection
Horizontal Reflections
x
Let y = f(x) with its graph shown here and letg(x) = f(–x).For the point x, the output is g(x) = f(–x)so the point (x, y = f(–x)) is on the graph of g(x).
0
y= f(x)
Horizontal Stretches and Compressions
x–x
(x, g(x)=f(–x))
u
Likewise for the point u, the output is g(u) = f(–u) so the point (u, y = f(–u)) is on the graph of g(x).
y
Horizontal reflection
Horizontal Reflections
x
Let y = f(x) with its graph shown here and letg(x) = f(–x).For the point x, the output is g(x) = f(–x)so the point (x, y = f(–x)) is on the graph of g(x).
0
y= f(x)
Horizontal Stretches and Compressions
x–x
(x, g(x)=f(–x))
–uu
Likewise for the point u, the output is g(u) = f(–u) so the point (u, y = f(–u)) is on the graph of g(x).
y
Horizontal reflection
Horizontal Reflections
x
Let y = f(x) with its graph shown here and letg(x) = f(–x).For the point x, the output is g(x) = f(–x)so the point (x, y = f(–x)) is on the graph of g(x).
0
y= f(x)
Horizontal Stretches and Compressions
x–x
(x, g(x)=f(–x))
–uu
Likewise for the point u, the output is g(u) = f(–u) so the point (u, y = f(–u)) is on the graph of g(x).
(u, g(u)=f(–u))
y
Horizontal reflection
Horizontal Reflections
x
Let y = f(x) with its graph shown here and letg(x) = f(–x).For the point x, the output is g(x) = f(–x)so the point (x, y = f(–x)) is on the graph of g(x).
0
y= f(x)
Horizontal Stretches and Compressions
x–x
(x, g(x)=f(–x))
–uu
Likewise for the point u, the output is g(u) = f(–u) so the point (u, y = f(–u)) is on the graph of g(x).
(u, g(u)=f(–u))
y
Horizontal reflection
Hence we reflect the graph of y = f(x) horizontally across the y–axis to obtain the graph of y = f(–x).
Horizontal Reflections
x
Let y = f(x) with its graph shown here and letg(x) = f(–x).For the point x, the output is g(x) = f(–x)so the point (x, y = f(–x)) is on the graph of g(x).
0
y= f(x)
Horizontal Stretches and Compressions
x–x
(x, g(x)=f(–x))
–uu
(u, g(x)=f(–x))
Likewise for the point u, the output is g(u) = f(–u) so the point (u, y = f(–u)) is on the graph of g(x).
(u, g(u)=f(–u))
y
Horizontal reflection
Hence we reflect the graph of y = f(x) horizontally across the y–axis to obtain the graph of y = f(–x).
Horizontal Reflections
x
Let y = f(x) with its graph shown here and letg(x) = f(–x).For the point x, the output is g(x) = f(–x)so the point (x, y = f(–x)) is on the graph of g(x).
0
y= f(x)
Horizontal Stretches and Compressions
x–x
(x, g(x)=f(–x))
–uu
(u, g(x)=f(–x))
Likewise for the point u, the output is g(u) = f(–u) so the point (u, y = f(–u)) is on the graph of g(x).
(u, g(u)=f(–u))
y
Horizontal reflection
Hence we reflect the graph of y = f(x) horizontally across the y–axis to obtain the graph of y = f(–x).To graph y = f(–2x), we compress y = f(x) by a factor of ½ to obtain the graph of y = f(2x), then reflect the result to obtain the graph of y = f(–2x).
Summary of vertical transformations of graphs (c > 0).
Transformations of Graphs
Vertical Shifts Vertical Stretches and Compressions
xy= f(x)
y= f(x)
x
Summary of vertical transformations of graphs (c > 0).
Transformations of Graphs
Vertical Shifts Vertical Stretches and Compressions
xy= f(x)
y= f(x)
y = f(x) + c moves f up by cy = f(x) – c move f down by c
x
Summary of vertical transformations of graphs (c > 0).
Transformations of Graphs
Vertical Shifts Vertical Stretches and Compressions
y= f(x) + 1
x
y= f(x) + 2
y= f(x)
y= f(x)
y = f(x) + c moves f up by cy = f(x) – c move f down by c
x
Summary of vertical transformations of graphs (c > 0).
Transformations of Graphs
Vertical Shifts Vertical Stretches and Compressions
y= f(x)–1
y= f(x) + 1
x
y= f(x) + 2
y= f(x)–2
y= f(x)–3
y= f(x)
y= f(x)
y = f(x) + c moves f up by cy = f(x) – c move f down by c
x
Summary of vertical transformations of graphs (c > 0).
Transformations of Graphs
Vertical Shifts Vertical Stretches and Compressions
y= f(x)–1
y= f(x) + 1
x
y= f(x) + 2
y= f(x)–2
y= f(x)–3
y= f(x)
y= f(x)
y = f(x) + c moves f up by cy = f(x) – c move f down by c
x
c > 1, y = cf(x) stretches f vertically
Summary of vertical transformations of graphs (c > 0).
Transformations of Graphs
Vertical Shifts Vertical Stretches and Compressions
y= f(x)–1
y= f(x) + 1
x
y= f(x) + 2
y= f(x)–2
y= f(x)–3
y= f(x)
y= 2f(x) y= f(x)
y = f(x) + c moves f up by cy = f(x) – c move f down by c c > 1, y = cf(x) stretches f vertically
x
Summary of vertical transformations of graphs (c > 0).
Transformations of Graphs
Vertical Shifts Vertical Stretches and Compressions
y= f(x)–1
y= f(x) + 1
x
y= f(x) + 2
y= f(x)–2
y= f(x)–3
y= f(x)
y= 3f(x)
y= 2f(x) y= f(x)
y = f(x) + c moves f up by cy = f(x) – c move f down by c c > 1, y = cf(x) stretches f vertically
x
Summary of vertical transformations of graphs (c > 0).
Transformations of Graphs
Vertical Shifts Vertical Stretches and Compressions
y= f(x)–1
y= f(x) + 1
x
y= f(x) + 2
y= f(x)–2
y= f(x)–3
y= f(x)
y= 3f(x)
y= f(x)/3
y= 2f(x) y= f(x)
y = f(x) + c moves f up by cy = f(x) – c move f down by c c > 1, y = cf(x) stretches f vertically
0 < c < 1, y = cf(x) compresses f
x
Summary of vertical transformations of graphs (c > 0).
Transformations of Graphs
Vertical Shifts Vertical Stretches and Compressions
y= f(x)–1
y= f(x) + 1
x
y= f(x) + 2
y= f(x)–2
y= f(x)–3
y= f(x)
y= 3f(x)
y= f(x)/3
y= 2f(x)
y= –f(x)
y= f(x)
y = f(x) + c moves f up by cy = f(x) – c move f down by c c > 1, y = cf(x) stretches f vertically
y = –f(x) reflects f vertically
0 < c < 1, y = cf(x) compresses f
x
Summary of vertical transformations of graphs (c > 0).
Transformations of Graphs
Vertical Shifts Vertical Stretches and Compressions
y= f(x)–1
y= f(x) + 1
x
y= f(x) + 2
y= f(x)–2
y= f(x)–3
y= f(x)
y= 3f(x)
y= f(x)/3
y= 2f(x)
y= –f(x) y= –2f(x)
y= –3f(x)
y= f(x)
y = f(x) + c moves f up by cy = f(x) – c move f down by c c > 1, y = cf(x) stretches f vertically
y = –f(x) reflects f vertically
0 < c < 1, y = cf(x) compresses f
x
x
–1
Transformations of Graphs
Horizontal Shiftsy=f(x)
y=f(x)
–2–3
y
Horizontal Stretches and Compressions
Summary of horizontal transformations of graph (c > 0).
x
x
–1
Transformations of Graphs
Horizontal Shiftsy=f(x)
y=f(x)
–2–3
y
Horizontal Stretches and Compressions
y = f(x + c) moves f left by cy = f(x – c) moves f right by c
Summary of horizontal transformations of graph (c > 0).
x
Transformations of Graphs
Horizontal Shiftsy=f(x)
y=f(x+2) y=f(x+1)
Horizontal Stretches and Compressions
y = f(x + c) moves f left by cy = f(x – c) moves f right by c
Summary of horizontal transformations of graph (c > 0).
x
x
–1
y=f(x)
–2–3
y
Transformations of Graphs
Horizontal Shiftsy=f(x)
y=f(x+2) y=f(x+1)
y=f(x–2) y=f(x–1)
Horizontal Stretches and Compressions
y = f(x + c) moves f left by cy = f(x – c) moves f right by c
Summary of horizontal transformations of graph (c > 0).
x
x
–1
y=f(x)
–2–3
y
Transformations of Graphs
Horizontal Shiftsy=f(x)
y=f(x+2) y=f(x+1)
y=f(x–2) y=f(x–1)
Horizontal Stretches and Compressions
y = f(x + c) moves f left by cy = f(x – c) moves f right by c
Summary of horizontal transformations of graph (c > 0).
x
x
–1
y=f(x)
–2–3
y
c > 1, y = f(cx) compresses f horizontally0 < c < 1, y = f(cx) stretches f horizontally.
–1
Transformations of Graphs
Horizontal Shiftsy=f(x)
y=f(x+2) y=f(x+1)
y=f(x–2) y=f(x–1)
y=f(x) y=f(2x)
–2–3
y
Horizontal Stretches and Compressions
(0,f(0))
y = f(x + c) moves f left by cy = f(x – c) moves f right by c
c > 1, y = f(cx) compresses f horizontally0 < c < 1, y = f(cx) stretches f horizontally.
Summary of horizontal transformations of graph (c > 0).
x
x
–1
Transformations of Graphs
Horizontal Shiftsy=f(x)
y=f(x+2) y=f(x+1)
y=f(x–2) y=f(x–1)
y=f(x) y=f(2x)
–2–3
y=f(3x) y
Horizontal Stretches and Compressions
(0,f(0))
y = f(x + c) moves f left by cy = f(x – c) moves f right by c
c > 1, y = f(cx) compresses f horizontally0 < c < 1, y = f(cx) stretches f horizontally.
Summary of horizontal transformations of graph (c > 0).
x
x
–1
Transformations of Graphs
Horizontal Shiftsy=f(x)
y=f(x+2) y=f(x+1)
y=f(x–2) y=f(x–1)
y=f(x)y=f(x/2)
y=f(x/3)
y=f(2x)
–2–3
y=f(3x) y
Horizontal Stretches and Compressions
(0,f(0))
y = f(x + c) moves f left by cy = f(x – c) moves f right by c
c > 1, y = f(cx) compresses f horizontally0 < c < 1, y = f(cx) stretches f horizontally.
Summary of horizontal transformations of graph (c > 0).
x
x
–1
Transformations of Graphs
Horizontal Shiftsy=f(x)
y=f(x+2) y=f(x+1)
y=f(x–2) y=f(x–1)
y=f(x)y=f(x/2)
y=f(x/3)
y=f(2x)
–2–3
y=f(3x) y
Horizontal Stretches and Compressions
y = f(–x) reflect f horizontally
y=f(–x/3)
(0,f(0))
y = f(x + c) moves f left by cy = f(x – c) moves f right by c
c > 1, y = f(cx) compresses f horizontally0 < c < 1, y = f(cx) stretches f horizontally.
Summary of horizontal transformations of graph (c > 0).
x
Horizontal TranslationsLet y = f(x) be a function with the interval [0, 1] as its domain as shown.
y
1x
2 3½
y = f(x)
Horizontal TranslationsLet y = f(x) be a function with the interval [0, 1] as its domain as shown.The graph of y = g(x) = f(½ * x) is the horizontal stretch, by a factor of 2, of the graph of y = f(x).
y
1x
2 3½
y = f(x) y=g(x)=f(½ * x)
Horizontal TranslationsLet y = f(x) be a function with the interval [0, 1] as its domain as shown.The graph of y = g(x) = f(½ * x) is the horizontal stretch, by a factor of 2, of the graph of y = f(x). The domain of y = g(x) = f(½ * x) correspondingly is the stretch of the domain of y = f(x), from [0, 1] to [0, 2].
y
1x
2 3½
y = f(x) y=g(x)=f(½ * x)
Horizontal TranslationsLet y = f(x) be a function with the interval [0, 1] as its domain as shown.
y
y = f(x)
1x
2 3
The graph of y = g(x) = f(½ * x) is the horizontal stretch, by a factor of 2, of the graph of y = f(x). The domain of y = g(x) = f(½ * x) correspondingly is the stretch of the domain of y = f(x), from [0, 1] to [0, 2].
y=g(x)=f(½ * x)
½
y = f(x/3)
Horizontal TranslationsLet y = f(x) be a function with the interval [0, 1] as its domain as shown.The graph of y = g(x) = f(½ * x) is the horizontal stretch, by a factor of 2, of the graph of y = f(x). The domain of y = g(x) = f(½ * x) correspondingly is the stretch of the domain of y = f(x), from [0, 1] to [0, 2].Similarly the domain of y = h(x) = f(2x) is the compression from [0, 1] to [0, ½ ].
y
1x
2 3½
y = f(x) y=g(x)=f(½ * x)y = f(2x) y = f(x/3)
Horizontal TranslationsLet y = f(x) be a function with the interval [0, 1] as its domain as shown.
y
y = f(x)
1x
2 3
The graph of y = g(x) = f(½ * x) is the horizontal stretch, by a factor of 2, of the graph of y = f(x). The domain of y = g(x) = f(½ * x) correspondingly is the stretch of the domain of y = f(x), from [0, 1] to [0, 2].Similarly the domain of y = h(x) = f(2x) is the compression from [0, 1] to [0, ½ ].
y = f(x/3)y=g(x)=f(½ * x)y = f(2x)y = f(3x)
½
Horizontal TranslationsLet y = f(x) be a function with the interval [0, 1] as its domain as shown.
y
y = f(x)
1x
2 3
The graph of y = g(x) = f(½ * x) is the horizontal stretch, by a factor of 2, of the graph of y = f(x). The domain of y = g(x) = f(½ * x) correspondingly is the stretch of the domain of y = f(x), from [0, 1] to [0, 2].Similarly the domain of y = h(x) = f(2x) is the compression from [0, 1] to [0, ½ ].
y=g(x)=f(½ * x)The Domain of y = f(cx), c > 0If the domain of y = f(x) is [0, a], then the domain of y = f(cx) is [0, a/c].
y = f(2x)
½
y = f(x/3)y = f(3x)
Horizontal TranslationsExample C. a. Given the graph of the function y = f(x) with the domain [–2, 2], graph y = (x – 3)2 – 1 by applying the transformation rules. Give the new domain and label the end points of the graph.
f(x)=x2
x
(2,4) (–2,4)
2–2 (0,0)
Horizontal TranslationsExample C. a. Given the graph of the function y = f(x) with the domain [–2, 2], graph y = (x – 3)2 – 1 by applying the transformation rules. Give the new domain and label the end points of the graph.
f(x)=x2
x
(2,4) (–2,4)
2–2
i. Shift right 3 units the graph of f(x) = x2 to obtain the graph of y = (x – 3)2.
(0,0)
2–2
Shift right 3 units
Horizontal TranslationsExample C. a. Given the graph of the function y = f(x) with the domain [–2, 2], graph y = (x – 3)2 – 1 by applying the transformation rules. Give the new domain and label the end points of the graph.
f(x)=x2
x
(2,4) (–2,4)
2–2
i. Shift right 3 units the graph of f(x) = x2 to obtain the graph of y = (x – 3)2.
(0,0)
ii. Lower the graph of y = (x – 3)2 by 1 unit forthe graph of y = (x – 3)2 – 1.
2–2
(5,3) (1,3)
(3,–1)
Shift right 3 units
Lower by
1 unit
Horizontal TranslationsExample C. a. Given the graph of the function y = f(x) with the domain [–2, 2], graph y = (x – 3)2 – 1 by applying the transformation rules. Give the new domain and label the end points of the graph.
f(x)=x2
x
(2,4) (–2,4)
2–2
i. Shift right 3 units the graph of f(x) = x2 to obtain the graph of y = (x – 3)2.
(0,0)
ii. Lower the graph of y = (x – 3)2 by 1 unit forthe graph of y = (x – 3)2 – 1.
2–2
(5,3) (1,3)
(3,–1)
Shift right 3 units
Lower by
1 unit
The new domain is [–2 + 3, 2 + 3] = [1, 5]. The new vertex is (3, –1) and end points (1, 3) and (5, 3).
Horizontal Translations
x
(4,2)
(0,0)
y=g(x)=√x
4
b. Given the graphs of the function y = g(x) = √x and y = G(x) a transformation of y = g(x) as shown,express G(x) using g(x).
cy=G(x)
(6,2)
62
Horizontal Translations
The graph of y = G(x) is obtained by horizontally compressing the graph of
x
(4,2)
(0,0)
y=g(x)=√x
4
b. Given the graphs of the function y = g(x) = √x and y = G(x) a transformation of y = g(x) as shown,express G(x) using g(x).
cy=G(x)
(6,2)
62
y = g(x) by a factor of ½, which gives the graph ofh(x) = g(2x) = √2x as shown,
x
(4,2)
(0,0)
y=g(x)=√x
4 62
(2,2)
cy=h(x)=√2x horizontal
compression
Horizontal Translations
The graph of y = G(x) is obtained by horizontally compressing the graph of
x
(4,2)
(0,0)
y=g(x)=√x
4
b. Given the graphs of the function y = g(x) = √x and y = G(x) a transformation of y = g(x) as shown,express G(x) using g(x).
cy=G(x)
(6,2)
62
y = g(x) by a factor of ½, which gives the graph ofh(x) = g(2x) = √2x as shown,
x
(4,2)
(0,0)
y=g(x)=√x
4 62
(2,2)
c
then moving h(x) to the right by 4 units.
y=h(x)=√2x
x
(0,0) 4
cy=G(x)
(6,2)
62
(2,2)
cy=h(x)=√2x
horizontal compression
horizontal shift
Horizontal Translations
The graph of y = G(x) is obtained by horizontally compressing the graph of
x
(4,2)
(0,0)
y=g(x)=√x
4
b. Given the graphs of the function y = g(x) = √x and y = G(x) a transformation of y = g(x) as shown,express G(x) using g(x).
cy=G(x)
(6,2)
62
y = g(x) by a factor of ½, which gives the graph ofh(x) = g(2x) = √2x as shown,
x
(4,2)
(0,0)
y=g(x)=√x
4 62
(2,2)
c
then moving h(x) to the right by 4 units. HenceG(x) = h(x – 4) = √2(x – 4) or thatG(x) = √2x – 8.
y=h(x)=√2x
x
(0,0) 4
cy=G(x)
(6,2)
62
(2,2)
cy=h(x)=√2x
horizontal compression
horizontal shift
Absolute-Value Flip
Absolute-Value Flip
y = f(x) = x
x -2 -1 0 1
y -2 -1 0 1
Absolute-Value Flip
y = f(x) = x
x -2 -1 0 1
y -2 -1 0 1
Absolute-Value Flip
y = f(x) = x y = |f(x)| = |x|
x -2 -1 0 1
y -2 -1 0 1
x -2 -1 0 1
y 2 1 0 1
Absolute-Value Flip
y = f(x) = x y = |f(x)| = |x|
x -2 -1 0 1
y -2 -1 0 1
x -2 -1 0 1
y 2 1 0 1
Absolute-Value Flip
y = f(x) = x
The graph of y = |f(x)| is obtained by reflecting the portion of the graph below the x-axis to above the x-axis.
y = |f(x)| = |x|
x -2 -1 0 1
y -2 -1 0 1
x -2 -1 0 1
y 2 1 0 1
Absolute-Value FlipAnother example,
y = x2 – 1
(0,–1)
Absolute-Value FlipAnother example,
y = x2 – 1 y = |x2 – 1|
(0,–1)
Absolute-Value FlipAnother example,
y = x2 – 1 y = |x2 – 1|
(0,–1)
(1,0)
Absolute-Value FlipAnother example,
y = x2 – 1 y = |x2 – 1|
y = |x2 – 1| – 1
(0,–1)
(1,0)
Absolute-Value FlipAnother example,
y = x2 – 1 y = |x2 – 1|
y = |x2 – 1| – 1
(0,–1)
(0,0)
(1,0)
Absolute-Value FlipAnother example,
y = x2 – 1 y = |x2 – 1|
y = |x2 – 1| – 1 y = 2(|x2 – 1| – 1)
(0,–1)
(0,0)
(1,0)
Absolute-Value FlipAnother example,
y = x2 – 1 y = |x2 – 1|
y = |x2 – 1| – 1 y = 2(|x2 – 1| – 1)
(0,–1)
(0,0) (0,0)
(1,0)
Horizontal FlipThe graph of y = f(–x) is the horizontal reflection of the graph of y = f(x) across the y axis.
Horizontal FlipThe graph of y = f(–x) is the horizontal reflection of the graph of y = f(x) across the y axis.
y = f(x) = x3 – x2
Horizontal FlipThe graph of y = f(–x) is the horizontal reflection of the graph of y = f(x) across the y axis.
y = f(x) = x3 – x2
y = f(-x) = (-x)3 – (-x)2
Horizontal FlipThe graph of y = f(–x) is the horizontal reflection of the graph of y = f(x) across the y axis.
y = f(x) = x3 – x2
y = f(-x) = (-x)3 – (-x)2
y = f(-x) = – x3 – x2
Horizontal FlipThe graph of y = f(–x) is the horizontal reflection of the graph of y = f(x) across the y axis.
y = f(x) = x3 – x2
y = f(-x) = (-x)3 – (-x)2
y = f(-x) = – x3 – x2
Horizontal FlipThe graph of y = f(–x) is the horizontal reflection of the graph of y = f(x) across the y axis.
y = f(x) = x3 – x2
y = f(-x) = (-x)3 – (-x)2
y = f(-x) = – x3 – x2
A function is said to be even if f(x) = f(– x). Graphs of even functions are symmetric to the y-axis.
Horizontal FlipThe graph of y = f(–x) is the horizontal reflection of the graph of y = f(x) across the y axis.
y = f(x) = x3 – x2
y = f(-x) = (-x)3 – (-x)2
y = f(-x) = – x3 – x2
A function is said to be even if f(x) = f(– x). Graphs of even functions are symmetric to the y-axis.
Graph of an even function
x
(x, f(x))
–x
(–x, f(–x))
Horizontal FlipThe graph of y = f(–x) is the horizontal reflection of the graph of y = f(x) across the y axis.
y = f(x) = x3 – x2
y = f(-x) = (-x)3 – (-x)2
y = f(-x) = – x3 – x2
A function is said to be even if f(x) = f(– x). Graphs of even functions are symmetric to the y-axis.
Graph of an even function
x
(x, f(x))
–x
(–x, f(–x))
Horizontal Flip
Polynomial-functions whose terms are all even powers are even. The graph on the right is the even polynomial–function y = x4 – 4x2. y = x4 – 4x2
Horizontal Flip
A function is said to be odd iff f(–x) = – f(x).
Polynomial-functions whose terms are all even powers are even. The graph on the right is the even polynomial–function y = x4 – 4x2. y = x4 – 4x2
Horizontal Flip
y = x4 – 4x2
A function is said to be odd iff f(–x) = – f(x). Graphs of odd functions are symmetric to the origin,
Polynomial-functions whose terms are all even powers are even. The graph on the right is the even polynomial–function y = x4 – 4x2.
Horizontal Flip
A function is said to be odd iff f(–x) = – f(x). Graphs of odd functions are symmetric to the origin, that is, they're the same as reflecting across the y-axis followed by reflecting across the x-axis.
Polynomial-functions whose terms are all even powers are even. The graph on the right is the even polynomial–function y = x4 – 4x2. y = x4 – 4x2
Horizontal Flip
Graph of an odd function
A function is said to be odd iff f(–x) = – f(x). Graphs of odd functions are symmetric to the origin, that is, they're the same as reflecting across the y-axis followed by reflecting across the x-axis.
x–x0
(x, f(x))
(–x, –f(x))
Polynomial-functions whose terms are all even powers are even. The graph on the right is the even polynomial–function y = x4 – 4x2. y = x4 – 4x2
Horizontal Flip
Graph of an odd function
A function is said to be odd iff f(–x) = – f(x). Graphs of odd functions are symmetric to the origin, that is, they're the same as reflecting across the y-axis followed by reflecting across the x-axis.
x–x0
(x, f(x))
(–x, –f(x))
u
(u, f(u))
(–u, –f(u))
–u
Polynomial-functions whose terms are all even powers are even. The graph on the right is the even polynomial–function y = x4 – 4x2. y = x4 – 4x2
Horizontal Flip
Polynomial-functions whose terms are all even powers are even. The graph on the right is the even polynomial–function y = x4 – 4x2. y = x4 – 4x2
Graph of an odd function
A function is said to be odd iff f(–x) = – f(x). Graphs of odd functions are symmetric to the origin, that is, they're the same as reflecting across the y-axis followed by reflecting across the x-axis.
x–x0
(x, f(x))
(–x, –f(x))
u
(u, f(u))
(–u, –f(u))
–u
Horizontal Flip
Polynomial-functions whose terms are all odd powers are odd.
Horizontal Flip
y = x3 – 4x
Polynomial-functions whose terms are all odd powers are odd. The graph on the right is the odd polynomial–function y = x3 – 4x.
Horizontal Flip
Polynomial-functions whose terms are all odd powers are odd. The graph on the right is the odd polynomial–function y = x3 – 4x. y = x3 – 4x
Theorem (even and odd):
Horizontal Flip
y = x3 – 4x
Theorem (even and odd):I. The sum of even functions is even. The sum of odd functions is odd.
Polynomial-functions whose terms are all odd powers are odd. The graph on the right is the odd polynomial–function y = x3 – 4x.
Horizontal Flip
y = x3 – 4x
Theorem (even and odd):I. The sum of even functions is even. The sum of odd functions is odd.II. The product of even functions is even.
Polynomial-functions whose terms are all odd powers are odd. The graph on the right is the odd polynomial–function y = x3 – 4x.
Horizontal Flip
y = x3 – 4x
Theorem (even and odd):I. The sum of even functions is even. The sum of odd functions is odd.II. The product of even functions is even. The product of odd functions is even.
Polynomial-functions whose terms are all odd powers are odd. The graph on the right is the odd polynomial–function y = x3 – 4x.
Horizontal Flip
y = x3 – 4x
Theorem (even and odd):I. The sum of even functions is even. The sum of odd functions is odd.II. The product of even functions is even. The product of odd functions is even. The product of an even function with an odd function is odd.
Polynomial-functions whose terms are all odd powers are odd. The graph on the right is the odd polynomial–function y = x3 – 4x.
Horizontal Flip
y = x3 – 4x
Theorem (even and odd):I. The sum of even functions is even. The sum of odd functions is odd.II. The product of even functions is even. The product of odd functions is even. The product of an even function with an odd function is odd. (The same hold for quotient.)
Polynomial-functions whose terms are all odd powers are odd. The graph on the right is the odd polynomial–function y = x3 – 4x.
Horizontal Flip
y = x3 – 4x
Theorem (even and odd):I. The sum of even functions is even. The sum of odd functions is odd.II. The product of even functions is even. The product of odd functions is even. The product of an even function with an odd function is odd. (The same hold for quotient.)
is odd, x x4 + 1
Polynomial-functions whose terms are all odd powers are odd. The graph on the right is the odd polynomial–function y = x3 – 4x.
Horizontal Flip
y = x3 – 4x
Theorem (even and odd):I. The sum of even functions is even. The sum of odd functions is odd.II. The product of even functions is even. The product of odd functions is even. The product of an even function with an odd function is odd. (The same hold for quotient.)
is odd, is even, x x4 + 1
x2 x4 + 1
Polynomial-functions whose terms are all odd powers are odd. The graph on the right is the odd polynomial–function y = x3 – 4x.
Horizontal Flip
y = x3 – 4x
Theorem (even and odd):I. The sum of even functions is even. The sum of odd functions is odd.II. The product of even functions is even. The product of odd functions is even. The product of an even function with an odd function is odd. (The same hold for quotient.)
is odd, is even, x + 1 is neither.x x4 + 1
x2 x4 + 1
Polynomial-functions whose terms are all odd powers are odd. The graph on the right is the odd polynomial–function y = x3 – 4x.
HWUse the graph of y=x2, sketch thegraphs of:
1. y = 3x2
2. y = -2x2
3. y = -0.5x2
4. y=x2 – 1 5. y=2x2 – 16. y= -x2 – 2 7. y=(x+1)2
8. y=(x–3)2
Transformations of Graphs
Transformations of Graphs
Transformations of Graphs
Transformations of Graphs
Transformations of Graphs