Unit 2 - Functions and Their Graphs PDF

Summary

This document is a sample unit outline for a pre-calculus course, focusing on functions and their graphs. It covers topics like representing relations, domain and range, function notation, intercepts, critical points, and function transformations. It is geared towards secondary school students.

Full Transcript

PRE-CALCULUS

Unit

2

Created by: ALL THINGS ALGEBRA®

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Unit 2 – Functions & Their Graphs: Sample Unit Outline
TOPIC

HOMEWORK

Functions Review
DAY 1

•
•
•
•

Representing Relations (Tables, Mappings, Graphs, Equations)
Domain and Range
Relations vs. Functions
Function Notation & Evaluating Functions

HW #1

DAY 2

Intercepts; Zeros; Critical Points (Extrema & Points of
Inflection); Increasing & Decreasing Intervals

HW #2

DAY 3

Quiz 2-1

None

DAY 4

Continuity; End Behavior

HW #3

DAY 5

Tests for Symmetry; Even and Odd Functions

HW #4

DAY 6

Average Rate of Change

HW #5

DAY 7

Quiz 2-2

None

DAY 8

Parent Functions & Transformations

HW #6

DAY 9

Graphing Functions

HW #7

DAY 10

Piecewise Functions

HW #8

DAY 11

Quiz 2-3

None

DAY 12

Function Operations & Compositions of Functions

HW #9

DAY 13

Inverse Relations & Functions

DAY 14

Quiz 2-4

DAY 15

Unit 2 Review

DAY 16

UNIT 2 TEST

HW #10
None
Study
For Test
None

Note: The parent functions graphic organizer on Day 8 includes linear, absolute
value, quadratic, cubic, square root, cube root, reciprocal, exponential, logarithmic,
greatest integer, sine, and cosine. However, only these functions are included when
it comes to graphing functions: linear, absolute value, quadratic, cubic, square root,
cube root, reciprocal, and greatest integer. This unit focuses primarily on these
functions. Other functions will be the focus of later units.

© Gina W ilson (All Things Algebra ®, LLC), 2017

Name:

___________________________________________________
________________
Topic:

___________________________________________________
________________
Main Ideas/Questions
Notes/Examples

relations

Date:

_________________________________
_________________________________
Class:
_
_________________________________
_________________________________
_

Example:

Representing
Relations

x

y

DOMAIN
RANGE
Directions: Give the domain and range of each relation.

Examples

2.

1.

3.

x
-2
-1
0
1
2

{(-1, -1), (7, 4),
(3, 0), (-5, -1)}

D=

D=

D=

R=

R=

R=

y
0
1
4

Directions: Give the domain and range of each relation in set notation.

4.

5.

6.

D=

D=

D=

R=

R=

R=
© Gina Wilson (All Things Algebra®, LLC), 2017

Directions: Give the domain and range of each relation in interval notation.

7.

8.

9.

D=

D=

D=

R=

R=

R=

10.

11.

12.

D=

D=

D=

R=

R=

R=

A function is a special type of relation, in which each element

functions

of the ________________ is paired with ________________ ________
element of the ______________.
Directions: Determine whether the relation is a function.
13.

14.

x

y

-3
-1
2
5

-4
-2
1
4

x

y

-9
0
4

-2
-1
1
5

15.
{(-7, 2), (-5, 2),
(-2, 8), (0, 8)}

If a vertical line intercepts a relation at more than one point,
then the relation is not a function.

vertical
line test

Directions: Determine whether the relation is a function.
16.
17.
18.

© Gina Wilson (All Things Algebra®, LLC), 2017

Name:

___________________________________________________
________________
Topic:

___________________________________________________
________________
Main Ideas/Questions
Notes/Examples

EXPLICIT
EQUATIONS
IMPLICIT
EQUATIONS

EXAMPLES

Date:

_________________________________
_________________________________
Class:
_
_________________________________
_________________________________
_

Examples:

Examples:
Directions: Write each equation explicitly in terms of x. Then,
indicate whether the equation is a function.
1. x  4 y  20
2. x2  y2  25

3. ( y  1)2  x  3

4.

1
x
2

3

y 7

6. xy  5 y  1  2 x

5. x  y  1  8

Explicit functions are frequently written using function notation:

FUNCTION
NOTATION
evaluating
functions

Equation

Function Notation

This is read as “_______________________” and
interpreted as the value of the function f at x.
Directions: Evaluate each function for the given value.
7. f ( x)  x2  6x  23; f (5)

8. h( x)  7  x2 ; h(9)

© Gina Wilson (All Things Algebra®, LLC), 2017

9. p( x) 

x 1
; p(4)
2
2 x  4 x  13

10. g ( x)  x3  3 x2  7x  4; g (2)

1
x  14 ; p( 10)
2

11. q( x)  6  2 x ; q(15)

12. p( x) 

13. f ( x)  5  (3) ; f (4)

14. a( x)   2 x  7  1; a(17)

x

15. f ( x)  x3  x2 ; f (3 y 2 )

17. h( x)  x2  x  1; h(2a  7)

3

16. g ( x) 

3 x  10
; g ( 5c)
x5

18. k ( x)  4 x3  7; k (m  1)

Directions: Using the graph to the left, find each function value.
19. f (1)

20. f ( 2)

21. f (5)

22. f (0)
© Gina Wilson (All Things Algebra®, LLC), 2017

Name: ___________________________________

Unit 2: Functions & Their Graphs

Date: ________________________ Per: ______

Homework 1: Relations and Functions

** This is a 2-page document! **
Directions: Give the domain and range of each relation and determine whether it is a function.
1.
2.
3.

x

-5
-3
0
4

y

-2

{ ( −3, −9),( −2, −1),
( −2, −6),(−1, −9) }

-1
7

D=

D=

D=

R=

R=

R=

Function?

Function?

Function?

Directions: Give the domain and range of graphs 4, 5, and 6 in set notation and graphs 7, 8,
and 9 in interval notation. Determine whether each relation is a function.
4.

5.

6.

D=

D=

D=

R=

R=

R=

Function?

Function?

Function?

7.

8.

9.

D=

D=

D=

R=

R=

R=

Function?

Function?

Function?
© Gina Wilson (All Things Algebra®, LLC), 2017

Directions: Write each equation explicitly in terms of x. Then, indicate whether the equation is
a function.
3
11. y 2 − x2 + 1 = 50
10. x − y = −12
2

12. 3 xy + x = y − 6

13. y 2 + 6 y + 9 = x + 8

Directions: Evaluate each function for the given value.
3
2
14. f ( x) = − x + 2 x − 11; f (−3)

16. p( x) =

x2 − 4
; p(−8)
2x + 1

18. q( x) = 2 x4 − 3 x2 ; q(−2 x2 )

20. k ( x) =

−2 x − 15
; k (−6w)
x+9

15. g ( x) = 13 − x 2 ; g (11)

17. h( x) = 3 ⋅ 9x ; h(−2)

19. j( x) = − x2 + 3 x + 10; j(3 x − 2)

21. t ( x) = x3 − 2 x; t ( x + 4)

© Gina Wilson (All Things Algebra®, LLC), 2017

Name:

Date:

___________________________________________________

_________________________________

Topic:

Class:

___________________________________________________

_________________________________

Main Ideas/Questions

Notes/Examples
• Intercepts are points where a graph
intersects the _____ or _____- _________.

x- and yIntercepts

• An x-intercept occurs where ___________.

x-intercept

x-intercept

• A y-intercept occurs where ___________.
• A function can have 0+ x-intercepts,

y-intercept

but at most one y-intercept.

Examples

Directions: Identify the x- and y-intercepts of the functions graphed below.
1.
2.
3.

x-intercept(s):

x-intercept(s):

x-intercept(s):

y-intercept:

y-intercept:

y-intercept:

4.

5.

6.

x-intercept(s):

x-intercept(s):

x-intercept(s):

y-intercept:

y-intercept:

y-intercept:

Zeros
Find Zeros &
the y-intercept
Algebraically

• To find the zeros, set ____________________ and solve for ______.
• To find the y-intercept, find ______________.
© Gina Wilson (All Things Algebra®, LLC), 2017

Directions: Find the zero(s) and y-intercept of each function algebraically.

Examples

7. f ( x) = − x − 5 + 3

8. f ( x) = 2 x 2 − 7 x − 4

zero(s):

zero(s):

y-intercept:

y-intercept:

9. f ( x) = x 4 − 5 x 2 + 4

10. f ( x) = x 3 − 6 x 2 − 7 x

zero(s):

zero(s):

y-intercept:

y-intercept:

11. f ( x) = 3 x 3 + 13 x 2 − 10 x

12. f ( x) =

zero(s):

zero(s):

y-intercept:

y-intercept:

x +1 − 2

© Gina Wilson (All Things Algebra®, LLC), 2017

Name:

Date:

___________________________________________________

_________________________________

Topic:

Class:

___________________________________________________

_________________________________

Main Ideas/Questions

Notes/Examples
• Critical points are points where the graph

maximum

changes its __________________ or ______________.

CRITICAL
POINTS

• Extrema are points where the graph changes
_____________________. The function has a
minimum or maximum value (relative or
absolute) at these points.

point of inflection

• A point of inflection is where the graph

changes its ______________, but not its direction.

minimum

A point with the greatest value
compared to points around it.
(also called a local maximum)

Relative
& Absolute
EXTREMA

absolute maximum

relative maximum

The point with the greatest
value over the entire domain
of the function.
A point with the least value
compared to points around it.
(also called a local minimum)
relative minimum

The point with the least
value over the entire domain
of the function.

EXAMPLES

absolute minimum

Directions: Give the coordinates and classify the extrema for the graph of
each function. Use your graphing calculator to approximate if needed.
2

1. f ( x) = 2 x − 16 x + 27

4

2

2. f ( x) = − x + 4 x − 2 x − 4

© Gina Wilson (All Things Algebra®, LLC), 2017

3

2

5

3. f ( x) = − x − 5 x − 3 x + 4

3

4. f ( x) = x − 3 x + 3

Moving from left to right, a function may increase,
decrease, or remain constant on certain intervals.

INCREASING
& DECREASING

Behavior

EXAMPLES

For example, the function to the right is
•

increasing on the interval ____________.

•

constant on the interval ____________.

•

decreasing on the interval ____________.

Directions: Give the intervals on which each function increases or
decreases. Use your graphing calculator to approximate if necessary.
5.
6.
7.

Increasing
Interval(s):

Decreasing
Interval(s):

3

2

8. f ( x) = − x + 4 x − 2

Increasing
Interval(s):

Decreasing
Interval(s):

Increasing
Interval(s):

Decreasing
Interval(s):

4

3

2

9. f ( x) = x + x − 4 x + 1

Increasing
Interval(s):

Decreasing
Interval(s):

Increasing
Interval(s):

Decreasing
Interval(s):

5

10. f ( x) = x − 2 x

Increasing
Interval(s):

3

Decreasing
Interval(s):

© Gina Wilson (All Things Algebra®, LLC), 2017

Name: ___________________________________

Unit 2: Functions & Their Graphs

Date: ________________________ Per: ______

Homework 2: Intercepts, Zeros, Extrema

** This is a 2-page document! **
Directions: Identify the x- and y-intercepts of the functions graphed below.
1.
2.
3.

x-intercept(s):

x-intercept(s):

x-intercept(s):

y-intercept:

y-intercept:

y-intercept:

4.

5.

6.

x-intercept(s):

x-intercept(s):

x-intercept(s):

y-intercept:

y-intercept:

y-intercept:

Directions: Find the zero(s) and y-intercept of each function algebraically.
8. f ( x) = x 3 − 10 x 2 + 24 x

7. f ( x) = 2 x − 5 − 1

zero(s):

y-intercept:
4

2

9. f ( x) = 4 x − 17 x + 4

zero(s):

zero(s):

10. f ( x) =

y-intercept:

zero(s):

y-intercept:
1
x−3
2

y-intercept:
© Gina Wilson (All Things Algebra®, LLC), 2017

Directions: Give the coordinates and classify the extrema for the graph of each function. Use
your graphing calculator to approximate if needed.
11. f ( x) = 2 x 2 + 4 x − 5
12. f ( x) = x 3 + 6 x 2 + 9 x + 5

13. f ( x) = − x 5 + 4 x 3 − 2

14. f ( x) = x 4 − 4 x 3 + 9 x

Directions: Give the intervals on which each function increases or decreases. Use your graphing
calculator to approximate if necessary.
15.
16.
17.

Increasing
Interval(s):

Decreasing
Interval(s):

18. f ( x) = − x 5 + 3 x 3 + 1

Increasing
Interval(s):

Decreasing
Interval(s):

Increasing
Interval(s):

Decreasing
Interval(s):

19. f ( x) = − 2 x − 5 + 6

Increasing
Interval(s):

Decreasing
Interval(s):

Increasing
Interval(s):

Decreasing
Interval(s):

20. f ( x) = x 3 + 2 x 2 − 3 x − 4

Increasing
Interval(s):

Decreasing
Interval(s):

© Gina Wilson (All Things Algebra®, LLC), 2017

Name: _________________________________________________

Pre-Calculus

Date: ______________________________Per: ________

Unit 2: Functions & Their Graphs

Quiz 2-1: Characteristics of Functions (Part 1)
Directions: Give the domain and range of each relation using set notation. Then, indicate
whether the relation shown by the graph is a function.
1.

2.

3.

D = ________________________

D = ________________________

D = ________________________

R = ________________________

R = ________________________

R = ________________________

Function? _________

Function? _________

Function? _________

Directions: Write each equation explicitly in terms of x. Write your answer in the box,
then indicate whether the equation is a function.
1
2
4. 6 x − 3 y = 21
5. y − x + 2 x = −5
6. 8 x 2 + 4 y 2 = 12
3

Function? __________

Function? __________

Function? __________

Directions: Given f(x) = x3 + 2x and g(x) = -x2 – 5x + 12, find each function value. Write your
answers to the right.
7. f (−3)

8. g (9)

7. __________________
8. __________________
9. __________________

9. g ( −5a)

10. f (4c − 1)

10. __________________

© Gina Wilson (All Things Algebra®, LLC), 2017

Directions: Identify the x-intercepts (zeros) and y-intercept of each function graphed below.
11.

12.
x-intercept(s):

x-intercept(s):

y-intercept:

y-intercept:

Directions: Find the zero(s) and y-intercept of each function algebraically.
4
2
13. f ( x) = x − 10 x + 9

zero(s):

14. f ( x) =

x+4 −3

y-intercept:

zero(s):

y-intercept:

Directions: Using the graphs below, classify each point as a point of inflection, relative minimum,
absolute minimum, relative maximum, or absolute maximum.
Graph 1

F

Graph 2

C

D

15. Point A: _________________________________
16. Point B: __________________________________

E
B

17. Point E: __________________________________

A

18. Point F: __________________________________
Directions: Give the increasing and decreasing intervals of each function. Use your graphing
calculator to approximate if necessary.
19. f ( x) = −2 x 2 − 8 x − 1

20. f ( x) = x 3 − 9 x 2 + 24 x − 19
Increasing
Interval(s):

Increasing
Interval(s):

Decreasing
Interval(s):

Decreasing
Interval(s):

© Gina Wilson (All Things Algebra®, LLC), 2017

Name:

Date:

___________________________________________________

_________________________________

Topic:

Class:

___________________________________________________

_________________________________

Main Ideas/Questions

Notes/Examples
• A graph is said to be ______________________________
if there are no ______________ or _________________ in

Continuity

the graph.
• If there are breaks or holes in the graphs, it is
considered to be ______________________________.

Types of
Discontinuity
a

When f(x) increases or
decreases infinitely as x
approaches x = a from
the left or the right.

Examples

a

a

When the f(x) jumps
from one point to
another at x = a.

When f(x) is continuous
everywhere else except
for a hole at x = a.

Directions: Determine if the function shown on the graph is continuous. If not,
identify the type and location of discontinuity.
1.\
2.
3.

4.

5.

6.

© Gina Wilson (All Things Algebra®, LLC), 2017

End
Behavior

As x moves towards positive infinity and negative
infinity, end behavior describes what is happening
to the value of f(x).
Describe the end behavior of the
graph to the right:
As x → ∞ , f ( x) → ________
As x → −∞ , f ( x) → ________

Examples

Directions: Describe the end behavior of each graph.
7.
8.
9.

As x moves towards positive infinity and
negative infinity, it is possible for f(x) to be
approaching a certain value.

Graphs
Approaching
a Certain
Value

Describe the end behavior of the
graph to the right:
As x → ∞ , f ( x) → ________
As x → −∞ , f ( x) → ________

Examples

Directions: Describe the end behavior of each graph.
10.
11.
12.

13.

14.

15.

© Gina Wilson (All Things Algebra®, LLC), 2017

Name: ___________________________________

Unit 2: Functions & Their Graphs

Date: ________________________ Per: ______

Homework 3: Continuity & End Behavior

** This is a 2-page document! **
Directions: Determine if the function shown on the graph is continuous. If not, identify the type
and location of discontinuity.
1.
2.
3.

4.

5.

6.

7.

8.

9.

© Gina Wilson (All Things Algebra®, LLC), 2017

Directions: Describe the end behavior of each graph.
10.
11.

12.

13.

14.

15.

16.

17.

18.

© Gina Wilson (All Things Algebra®, LLC), 2017

Name:

Date:

___________________________________________________

_________________________________

Topic:

Class:

___________________________________________________

_________________________________

Main Ideas/Questions

TYPES OF
SYMMETRY

Notes/Examples

The graph can be folded along a
line so that the two halves match.

The graph remains unchanged
when rotated 180° about a point.

y

y

x

y

x

x

The _____-___________ and _____-___________ are common lines of symmetry.
The _______________ is a common point of symmetry.
The following graphical and algebraic tests can be used to
determine if the graph of a relation is symmetric to the
x-axis, y-axis, and/or origin.

TESTS FOR
SYMMETRY

origin

y-axis

x-axis

Graphical Test

Algebraic Test

For every point (x, y) on the

Replacing ______ with ______

graph, the point _________ is

results in equivalent equations.

also on the graph.
For every point (x, y) on the

Replacing ______ with ______

graph, the point _________ is

results in equivalent equations.

also on the graph.
For every point (x, y) on the

Replacing ______ with ______

graph, the point _________ is

AND ______ with ______ results

also on the graph.

in equivalent equations.

Directions: Use the graph to determine if the relation is symmetrical to the

Examples

x-axis, y-axis, and/or origin. Confirm your answer algebraically.
1. y = x 4 − 4 x 2

x-axis
y-axis
origin
none

2. xy = 6

x-axis
y-axis
origin
none

© Gina Wilson (All Things Algebra®, LLC), 2017

3. 4( x + 3)2 + y 2 = 16

5. y =

4. y 2 − x 2 = 1

x-axis
y-axis
origin
none

3

x −1

x-axis
y-axis
origin
none

6. y = − x − 2

x-axis
y-axis
origin
none

x-axis
y-axis
origin
none

Algebraic Check:

A function is __________ if it is symmetric with

EVEN AND ODD

respect to the _____-__________.

Functions

A function is __________ if it is symmetric with

Algebraic Check:

respect to the ________________.

Examples

Directions: Determine algebraically if the function is even, odd, or neither. If
even or odd, describe the symmetry.
3
2
7. f ( x) = x − x
8. f ( x) = − x + 6

9.

11.

f ( x) = x 3 − x 2 − 2 x

f ( x) =

−8
x

x2 − 4

10.

f ( x) =

12.

f ( x) = x + 1

© Gina Wilson (All Things Algebra®, LLC), 2017

Name: ___________________________________

Unit 2: Functions & Their Graphs

Date: ________________________ Per: ______

Homework 4: Tests for Symmetry;
Even and Odd Functions

** This is a 2-page document! **
Directions: Use the graph to determine if the relation is symmetrical to the x-axis, y-axis, and/or
origin. Confirm your answer algebraically.
2. xy  4
1
1. y  x 3
4

 x-axis

 x-axis

 y-axis
 origin
 none

 y-axis
 origin
 none

3. y  2 x  5






x-axis
y-axis
origin
none

5. y 2  x  4






x-axis
y-axis
origin
none

4. y  3 2 x  3






x-axis
y-axis
origin
none

6. x2  y2  36






x-axis
y-axis
origin
none

© Gina Wilson (All Things Algebra®, LLC), 2017

Directions: Determine algebraically if the function is even, odd, or neither. If even or odd,
describe the symmetry.
x
7. f ( x) = −3 x4 + 7x2 − 1
8. f ( x) =
7

9. f ( x) = x − 4

10. f ( x) = 5 x − 6

11. f ( x) = −4 x3 + 9x

12. f ( x) = x2 + 2 x − 5

13. f ( x) = 2 x − 9

14. f ( x) = 3 5x

© Gina Wilson (All Things Algebra®, LLC), 2017

Name:

Date:

___________________________________________________

_________________________________

Topic:

Class:

___________________________________________________

_________________________________

Main Ideas/Questions

Notes/Examples
Directions: Find the slope of the line that passes between the given points.

Slope
Review

Average
Rate of
Change

1.

2.

3.

4. (-9, 3) and (-5, -7)

5. (2, -1) and (-7, -4)

6. (-13, -5) and (-1, 3)

For linear functions, the slope is constant between each pair of points.
For nonlinear functions, the slope changes between different pairs of
points. Because of this, we find the average rate of change.
• The average rate of change of a function
between two points is the slope of the line
that passes through these points.
• This is called a _________________ __________.
• Formula for the average rate of change
of a function on the interval [a, b]:
a

Examples

b

Directions: Given the function graphed below, find the average rate of
change on each interval.
7. [-2, 1]

8. [0, 4]

© Gina Wilson (All Things Algebra®, LLC), 2017

Directions: Find the average rate of change of each function on the given
interval. Round your answer to the nearest hundredth if necessary.
2

9. f ( x) = − x + 6 x − 14; [−1, 2]

3

2

11. f ( x) = x − 2 x − 9 x + 1; [4, 7]

13. f ( x) =

Applications

x−4
; [2, 8]
x

2

10. f ( x) = 2 x + 28 x + 93; [−9, − 7]

4

2

12. f ( x) = − x + 3 x − 17; [−2, 5]

14. f ( x) =

x + 5; [−1, 7]

15. A company’s total cost C(x) in dollars to manufacture x units is given
by C(x) = 0.05x2 + 40x + 1200. Find the average rate of change of
total cost for the first 200 units manufactured.

16. A ball is thrown straight upward so that its height h(t), in feet, is given
by the equation h(t) = -16t2 + 80t, where t is time in seconds. Find the
average rate of change in the height of the ball from when it reaches
its maximum height until when it reaches the ground.

© Gina Wilson (All Things Algebra®, LLC), 2017

Name: ___________________________________

Unit 2: Functions & Their Graphs

Date: ________________________ Per: ______

Homework 5: Average Rate of Change

** This is a 2-page document! **
Directions: Given the function below, find the average rate of change on each interval.
1. [-5, -2]

2. [-3, 0]

3. [-9, 7]

4. [-2, 0]

Directions: Find the average rate of change of each function on the given interval. Round your
answer to the nearest hundredth if necessary.
5. f ( x) = x2 + 7 x − 11; [−8, − 5]
6. f ( x) = 7 − x ; [−9, 6]

7. f ( x) =

x
; [−1, 5]
x+3

8. f ( x) = −

1 2
x + 3 x + 1; [8,14]
2

© Gina Wilson (All Things Algebra®, LLC), 2017

9. f ( x) = x3 + 2 x2 − 5 x + 3; [1, 5]

10. f ( x) =

x2
; [−1,10]
x+2

11. f ( x) =

1 4
x − x 3 ; [−2, 2]
4

12. f ( x) = 3 4 x − 1; [0, 7]

13. f ( x) =

2x − 1
; [−3, 8]
x+4

14. f ( x) = x3 + 5 x 2 − 2; [−9, − 5]

15. The average low temperature by month in Nashville is represented by the function
f ( x) = −1.4 x 2 + 19x + 1.7 , where x is the month. Find the average rate of change from March to
August.

16. A rocket was launched into the air from a podium 6 feet off the ground. The rocket path is
represented by the equation h(t ) = −16t 2 + 120t + 6 , where h(t) represents the height, in feet,
and t is the time, in seconds. Find the average rate of change from the initial launch to the
maximum height.

© Gina Wilson (All Things Algebra®, LLC), 2017

Name: _________________________________________________

Pre-Calculus

Date: ______________________________Per: ________

Unit 2: Functions & Their Graphs

Quiz 2-2: Characteristics of Functions (Part 2)
Directions: Determine if the function shown on the graph is continuous. If not, identify the type
(infinite, jump, or removable) and location of discontinuity.
1.

2.

3.

❑ Continuous

❑ Continuous

❑ Continuous

❑ Discontinuous

❑ Discontinuous

❑ Discontinuous

Type: ____________________

Type: ____________________

Type: ____________________

Location: ________________

Location: _________________

Location: ________________

Directions: Describe the end behavior of each graph.
4.
5.

6.

__________________________

___________________________

__________________________

__________________________

___________________________

__________________________

Directions: Determine if the relation shown on the graph is symmetrical to the x-axis, y-axis,
and/or origin. Verify your answer algebraically in the box.
7. x 2 + y = 7

x-axis

y-axis
origin
none

© Gina Wilson (All Things Algebra®, LLC), 2017

2
2
8. x − y = 4

❑

x-axis

❑
❑
❑

y-axis
origin
none

Directions: Determine algebraically if the function is even, odd, or neither. Show your work in
the box.
2
x
4
2
9. f ( x) = 2 3 x
10. f ( x) =
11. f ( x) = −4 x + 13 x − 4
x −1

❑
❑
❑

even

❑
❑
❑

odd
neither

even

❑
❑
❑

odd
neither

even
odd
neither

Directions: Find the average rate of change of each function on the given interval.
3
12. f ( x) = x − 7 x + 3; [−2, 1]

2

13. f ( x) =

2x − 5
; [−8, − 4]
x +1

12. _________________
13. _________________
14. _________________

14. The height of an object thrown straight up from a height 5 feet above
the ground is given by the equation h(t) = -16t2 + 42t + 5, where t is the
time in seconds after the object is thrown. Find the average velocity of
the object from 1.5 to 2.25 seconds.

© Gina Wilson (All Things Algebra®, LLC), 2017

PARENT FUNCTIONS Graphic Organizer
A function family is a group of functions with similar characteristics. The parent function is the simplest of the
functions in a family. You must be able to recognize each of these functions along with their characteristics.

LINEAR

Parent Function:

Domain:

Range:

x-intercept(s):

y-intercept:

Extrema:
Increasing Interval(s):

Decreasing Interval(s):

ABSOLUTE VALUE

End Behavior:

Parent Function:

Even or Odd?

Domain:

Range:

x-intercept(s):

y-intercept:

Extrema:
Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

QUADRATIC

Parent Function:

Discontinuities?

Even or Odd?

Domain:

Range:

x-intercept(s):

y-intercept:

Extrema:
Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

Parent Function:

CUBIC

Discontinuities?

Discontinuities?

Even or Odd?

Domain:

Range:

x-intercept(s):

y-intercept:

Extrema:
Increasing Interval(s):

Decreasing Interval(s):

End Behavior:
Discontinuities?

Even or Odd?
© Gina Wilson (All Thing Algebra®, LLC), 2017

SQUARE ROOT

Parent Function:

Range:

x-intercept(s):

y-intercept:

Extrema:

Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

CUBE ROOT

Parent Function:

Discontinuities?

Even or Odd?

Domain:

Range:

x-intercept(s):

y-intercept:

Extrema:
Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

RECIPROCAL

Parent Function:

Discontinuities?

Even or Odd?

Domain:

Range:

x-intercept(s):

y-intercept:

Extrema:
Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

Parent Function:

EXPONENTIAL

Domain:

Discontinuities?

Even or Odd?

Domain:

Range:

x-intercept(s):

y-intercept:

Extrema:
Increasing Interval(s):

Decreasing Interval(s):

End Behavior:
Discontinuities?

Even or Odd?
© Gina Wilson (All Thing Algebra®, LLC), 2017

GREATEST INTEGER

LOGARITHMIC

Parent Function:

Domain:

Range:

x-intercept(s):

y-intercept:

Extrema:

Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

Parent Function:

Discontinuities?

Even or Odd?

Domain:

Range:

x-intercept(s):

y-intercept:

Extrema:
Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

SINE

Parent Function:

Discontinuities?

Even or Odd?

Domain:

Range:

x-intercept(s):

y-intercept:

Extrema:
Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

COSINE

Parent Function:

Discontinuities?

Even or Odd?

Domain:

Range:

x-intercept(s):

y-intercept:

Extrema:
Increasing Interval(s):

Decreasing Interval(s):

End Behavior:
Discontinuities?

Even or Odd?
© Gina Wilson (All Thing Algebra®, LLC), 2017

TRANSFORMATIONS Reference Sheet
Transformations affect the appearance of a parent function.
There are two main types of transformations:
• Rigid Transformations change the position or orientation of a function.
Translations and reflections are rigid transformations.
• Nonrigid Transformations distort the shape of the function by changing its size.
Dilations are nonrigid transformations.
The rules for transformations are given below. It is important to memorize these rules!

TRANSLATIONS (a shift)

REFLECTIONS (a flip)

DOWN

REFLECTION IN
THE X-AXIS:

UP

REFLECTION IN
THE Y-AXIS:

LEFT

RIGHT

DILATIONS (to compress or stretch)
VERTICAL DILATIONS

HORIZONTAL DILATIONS

COMPRESSION

COMPRESSION

STRETCH

STRETCH

The function will compress or

The function will compress or

stretch vertically by a factor of ______!

stretch horizontally by a factor of ______!
© Gina Wilson (All Thing Algebra®, LLC), 2017

Name:

___________________________________________________
________________

Date:

_________________________________
_________________________________
Topic:
Class:
_
___________________________________________________
_________________________________
________________
_________________________________
Main Ideas/Questions
Notes/Examples
_
Directions: Given each function, identify both the parent function and
the transformations from the parent function.

IDENTIFYING
TRANSFORMATIONS

1. f ( x)  x3  4

2. f ( x)  2 ( x  1)

2

1 
3. f ( x)    x   6
4 

5. f ( x) 

1
( x  6)2
2

3

7. f ( x)  4 x  1  2

9. f ( x)  

1
( x  4)  7
3

4. f ( x)  3( x  5)  2

6. f ( x)  

1
3
4x

8. f ( x) 

x5
1
2

3
10. f ( x)   ( x  3)3  8
2

© Gina W ilson (All Things Algebra®, LLC), 2017

WRITING
FUNCTIONS

Directions: Using the graph of each function, identify the parent
function, then write an equation for the function under each
transformation.
11.
a) Parent Function:
b) Translate 4 units right:

c) Reflect in the x-axis and translate 5 units up:

12.

a) Parent Function:
b) Translate 7 units down and 3 units left:

c) Horizontally stretch by a factor of 3 and
translate 2 units right:

13.

a) Parent Function:
b) Translate 1 unit up and vertically stretch by a
factor of 4:

c) Vertically compress by a factor of 1/3 and
translate 6 units left:

14.

a) Parent Function:
b) Reflect in the y-axis and translate 4 units
right:
c) Horizontally compress by a factor of 1/2 and
translate 5 units down:

15. If the function f ( x) = 2( x − 5)2 + 3 is reflected across the y-axis, then
translated right 6 units and down 2 units, write the equation of the
new function.
16. A function was vertically stretched by a factor of 2, then translated
2 units left and 5 units up. The resulting function is represented by
f ( x) = 6 x + 4 − 1. Write the equation of the original function.

© Gina Wilson (All Things Algebra®, LLC), 2017

Name: ___________________________________

Unit 2: Functions & Their Graphs

Date: ________________________ Per: ______

Homework 6: Parent Functions
& Transformations

** This is a 2-page document! **
Directions: Given each function, identify both the parent function and the transformations from
the parent function.
2. f (x) = (−x)3 + 7
2
f
(x)
=
x
−
4
1.
3

3. f (x) =

6
−1
x

4. f (x) = 4(x − 2) + 7

1 
5. f ( x) =  x  + 5
 2 

6. f ( x) = −

5
7. f ( x) = − ( x + 11)2
2

8. f ( x) =

9. f (x) = 2 −(x − 3)

10. f (x) = 3 −5(x + 9) − 4

x
2

1
+9
x−5

© Gina Wilson (All Things Algebra®, LLC), 2017

Directions: Using the graph of each function, identify the parent function, then write an equation
for the function under each transformation.
a) Parent Function:
11.

b) Translate 4 units down and 3 units left:

c) Vertically stretch by a factor of 2, then translate 5 units left:

12.

a) Parent Function:

b) Translate 3 units up and 8 units right:

c) Horizontally compress by a factor of ¼, then reflect in the y-axis:

13.

a) Parent Function:

b) Horizontally stretch by a factor of 3 and translate 4 units down:

c) Vertically stretch by a factor of 3/2, reflect in the x-axis, and
translate 8 units left:

14.

a) Parent Function:

b) Vertically compress by a factor of 1/2, then reflect in the y-axis
and translate 4 units right:
c) Reflect in the x-axis and, then translate 7 units up:

15. If the function f ( x) = 4 x + 1 is horizontally stretched by a factor of 2, reflected across the
x-axis, and translated up 3 units, write the equation of the new function.

16. A function was vertically stretched by a factor of 3, then translated 5 units down and 7 units
3
3
left. The resulting function is represented by f ( x) = − ( x + 4) − 2 . Write the equation of the
2
original function.
© Gina Wilson (All Things Algebra®, LLC), 2017

GRAPHING FUNCTIONS
Directions: Identify the parent function and transformations from the parent function given each
function. Then, graph the function using the transformations and identify its key characteristics.

1
f ( x) = − x − 1 + 7

Domain:

Range:

x-intercept(s):

y-intercept(s):

Parent Function:

Extrema:

Transformations:

Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

2
1 
f ( x) =  x 
4 

Domain:

Range:

x-intercept(s):

y-intercept(s):

2

Parent Function:

Extrema:

Transformations:

Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

3
f ( x) = 2 x − 5

Domain:

Range:

x-intercept(s):

y-intercept(s):

3

Parent Function:

Extrema:

Transformations:

Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

© Gina Wilson (All Things Algebra®, LLC), 2017

4
f ( x) = 3 −( x − 2)

Domain:

Range:

x-intercept(s):

y-intercept(s):

Parent Function:

Extrema:

Transformations:

Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

5
f ( x) = 3 2( x + 1) + 4

Domain:

Range:

x-intercept(s):

y-intercept(s):

Parent Function:

Extrema:

Transformations:

Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

6
f ( x) =

−4
x+3

Domain:

Range:

x-intercept(s):

y-intercept(s):

Parent Function:

Extrema:

Transformations:

Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

© Gina Wilson (All Things Algebra®, LLC), 2017

7
f ( x) = 3 −

1
x +4
3

Domain:

Range:

x-intercept(s):

y-intercept(s):

Parent Function:

Extrema:

Transformations:

Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

8
f ( x) =

1
−1
2x

Domain:

Range:

x-intercept(s):

y-intercept(s):

Parent Function:

Extrema:

Transformations:

Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

9
f ( x) =

1
x+2 +5
4

Domain:

Range:

x-intercept(s):

y-intercept(s):

Parent Function:

Extrema:

Transformations:

Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

© Gina Wilson (All Things Algebra®, LLC), 2017

10
f ( x) = −3( x − 4) + 6

Domain:

Range:

x-intercept(s):

y-intercept(s):

2

Parent Function:

Extrema:

Transformations:

Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

11
f ( x) =
x + 1  − 3

Domain:

Range:

x-intercept(s):

y-intercept(s):

Parent Function:

Extrema:

Transformations:

Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

12
f ( x ) = −2
x − 4  + 1

Domain:

Range:

x-intercept(s):

y-intercept(s):

Parent Function:

Extrema:

Transformations:

Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

© Gina Wilson (All Things Algebra®, LLC), 2017

Name: ___________________________________

Unit 2: Functions & Their Graphs

Date: ________________________ Per: ______

Homework 7: Graphing Functions

** This is a 2-page document! **
Directions: Identify the parent function and transformations from the parent function given each
function. Then, graph the function and identify its key characteristics.
1.

f ( x) = 2( x + 1)3 − 5

Domain:

Range:

x-intercept(s):

y-intercept(s):

Parent Function:

Extrema:

Transformations:

Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

2.

f ( x) =

5
−( x − 6)
2

Domain:

Range:

x-intercept(s):

y-intercept(s):

Parent Function:

Extrema:

Transformations:

Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

3.
f ( x) = −

1
( x + 3)
3

Domain:

Range:

x-intercept(s):

y-intercept(s):

Parent Function:

Extrema:

Transformations:

Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

© Gina Wilson (All Things Algebra®, LLC), 2017

4.

f ( x) = −

1
2
( x − 5) − 3
2

Domain:

Range:

x-intercept(s):

y-intercept(s):

Parent Function:

Extrema:

Transformations:

Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

5.

f ( x ) = 3 3 −2 x + 1

Domain:

Range:

x-intercept(s):

y-intercept(s):

Parent Function:

Extrema:

Transformations:

Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

6.

f ( x) =

−1
+3
x−4

Domain:

Range:

x-intercept(s):

y-intercept(s):

Parent Function:

Extrema:

Transformations:

Increasing Interval(s):

Decreasing Interval(s):

End Behavior:

© Gina Wilson (All Things Algebra®, LLC), 2017

Name:

Date:

___________________________________________________

_________________________________

Topic:

Class:

___________________________________________________

_________________________________

Main Ideas/Questions

Notes/Examples

Piecewise
Functions
Directions: Find each value given the piecewise function.

Evaluating
Piecewise
Functions

2 x−5
 2
1. f ( x) = − x + 4 x

 2x + 6

a) f (−5)

if x < −3
if − 3 ≤ x < 7
if x ≥ 7

b) f (2)

c) f (7)

 1 3
 2 x + 7 if x ≤ −4

2. g ( x) = 
8 if − 4 < x < −2

x − 4  if x ≥ − 2

a) g (−3)

Graphing
Piecewise

b) g (−8)

c) g (3.1)

Directions: Graph each function, then give the domain, range, and
identify the location and type of any discountinuities.
 x + 3 − 1 if x < 0
3. f ( x) = 
 2 x − 5 if x ≥ 0

Functions
Domain:

Range:

Discontinuities:

© Gina Wilson (All Things Algebra®, LLC), 2017

−4 − x if x ≤ −3

2
 − x if x > −3
 2

4. h( x) =  1

Domain:

Range:

Discontinuities:

 4
if x ≤ 1

5. f ( x) =  x + 3
2 x − 7 if x > 1

Domain:

Range:

Discontinuities:

3 x + 8 if x ≤ −4


6. g ( x) = 
− 1 if − 4 < x ≤ 2
( x − 2) 2 − 5 if x > 2

Domain:

Range:

Discontinuities:


7 if x < −1

3
7. f ( x) =  x − 1 if − 1 ≤ x ≤ 2

 − 2 x + 1 if x > 2
Domain:

Range:

Discontinuities:

© Gina Wilson (All Things Algebra®, LLC), 2017

Name: ___________________________________

Unit 2: Functions & Their Graphs

Date: ________________________ Per: ______

Homework 8: Piecewise Functions

** This is a 2-page document! **
Directions: Find each function value.

 x 3  1 if x  2
1. f ( x)  
3 x  5 if x  2

 x 2  7
if x  7

2. g ( x)   3 x  15 if  7  x  5
 6 x
if x  5


a) f (4)

a) g (7)

b) f (2)

if  7  x  2
 3 x
3. f ( x)  
 x  4  5 if x  2




4. h( x)  




a) f (1.2)

a) h(5)

b) f (2)

b) g (4)

3x  2

if x  5

x  5x
3
x7
2

if  5  x  0

2

if x  0

8
b) h  
 15 

Directions: Graph each function, then give the domain, range, and identify the location and
type of any discountinuities.

 1 2
if x  3
 x
5. f ( x)   2
 10  x if x  3
Domain:

Range:

Discontinuities:

© Gina Wilson (All Things Algebra®, LLC), 2017

 2
 x  1
6. h( x)  
 2 x4
 3

if x  3
if x  3

Domain:
Range:
Discontinuities:

 3 x  4 if x  2

 2 if  2  x  2
7. g ( x)  
 x 2  11 if x  2

Domain:
Range:
Discontinuities:

ì -(x + 3) if x < -4
ï
8. h(x) = í 2x - 7
if - 4 < x < 1
ï
if x ³ 1
î3x -1
Domain:
Range:
Discontinuities:


x

3
9. f ( x)  ( x  3)  5
 2 x 1


if x  5
if  5  x  2
if x  2

Domain:
Range:
Discontinuities:

© Gina Wilson (All Things Algebra®, LLC), 2017

Name: _________________________________________________

Pre-Calculus

Date: ______________________________Per: ________

Unit 2: Functions & Their Graphs

Quiz 2-3: Parent Functions, Transformations, Graphing
1. Which parent functions are odd and continuous? Check all that apply.
❑

Cubic

❑

Reciprocal

❑

Greatest Integer

❑ Absolute Value

❑

Square Root

❑

Exponential

❑

Sine

❑ Quadratic

❑

Cube Root

❑

Logarithmic

❑

Cosine

❑

Linear

2. Use the graph below to answer each part.
a) Give the equation for the parent function.

b) Suppose this function is horizontally compressed by a factor
of 1/3, reflected over the x-axis, then translated 5 units up.
Write an equation to represent the new function.

3. Describe all the transformations from the parent function: f ( x) 

( x  2)
4

3

______________________________________________________________________________________________________
______________________________________________________________________________________________________

Identify the parent function and transformations given each function. Then, graph the function
and identify the key characteristics.
4. f ( x) 

1
x 1 7
2

Parent Function:

Transformations:

Domain:

Range:

x-int(s):

y-int:

Extrema:
Increasing Interval(s):
Decreasing Interval(s):
End Behavior:

© Gina Wilson (All Things Algebra®, LLC), 2017

3

5. f ( x)  4 x  2
Parent Function:

Domain:

Range:

x-int(s):

y-int:

Extrema:

Transformations:

Increasing Interval(s):
Decreasing Interval(s):
End Behavior:

6. f ( x) 

3
1
x5

Parent Function:

Domain:

Range:

x-int(s):

y-int:

Extrema:

Transformations:

Increasing Interval(s):
Decreasing Interval(s):
End Behavior:

Use the following piecewise function for questions 7-8:
7. Evaluate for each value:
a) f(-7) =

( x  5)3  4 if x  3

f ( x)  
 x2  2 if  3  x  2

 1 x if x  2


b) f(-3) =

8. Graph, then give the domain, range,
and identify the location and type
of any discontinuities.

Domain:

Range:

Discontinuities:

© Gina Wilson (All Things Algebra®, LLC), 2017

Name:

___________________________________________________
________________

Date:

_________________________________
_________________________________
Topic:
Class:
_
___________________________________________________
_________________________________
________________
_________________________________
Main Ideas/Questions
Notes/Examples
_
Functions can be combined using addition, subtraction,
multiplication, and division to create a new function.

Operations

with Functions

The Domain of
Combined Functions
Example 1:

f(x) = x2 + x; g(x) = 3x – 1

Example 2:

Notation
Addition

( f  g )( x)

Subtraction

( f  g )( x)

Multiplication

( f  g )( x)

Division

 f 
  ( x)
g

Equivalent Operation

The domain of the new function is the intersection of the
combined functions. The domain is further restricted with the
quotient function to exclude values in which g ( x)  0.
Given f(x) and g(x), find each new function and state its domain.
a) ( f  g )( x)

b) ( f  g )( x)

c) ( f  g )( x)

 f 
d)   ( x)
g

a) ( f  g )( x)

b) ( f  g )( x)

c) ( f  g )( x)

 f 
d)   ( x)
g

f ( x)  x2  9 ; g( x)  x

© Gina Wilson (All Things Algebra®, LLC), 2017

Example 3:

a) ( g  f )( x)

b) ( f  g )( x)

c) ( f  g )( x)

 f 
d)   ( x)
g

a) ( f  g )( x)

b) ( g  f )( x)

c) ( g  f )( x)

 f 
d)   ( x)
g

a) ( g  f )( x)

b) ( f  g )( x)

c) ( g  f )( x)

 f 
d)   ( x)
g

f ( x)  2 x3 ; g ( x)  x2  4 x

Example 4:
2
1
f ( x)  ; g ( x) 
x
x2

Example 5:
f ( x) 

x  6 ; g ( x) 

x2

Example 6:
f ( x)  4  x2 ; g ( x)  2 x  8

Given f(x) and g(x), evaluate each function.
a) ( f  g )(5)

b) ( f  g )( 2)

© Gina Wilson (All Things Algebra®, LLC), 2017

Name:

Date:

___________________________________________________

_________________________________

Topic:

Class:

___________________________________________________

_________________________________

Main Ideas/Questions

COMPOSITION
of FUNCTIONS

Notes/Examples

Another method to combine functions is called a composition.
Given f(x) and g(x), the composite function ( f
g )( x ) is defined as:

The domain of the composite function ( f
g )( x) is
the domain of g such that g(x) is in the domain of f.

THE DOMAIN OF

Domain of g

( f
g )( x)
EXAMPLE 1:
2

f ( x) = x + 7 ; g ( x) = x − 4

EXAMPLE 2:
f ( x) = 3 − x ; g ( x) =

x

Domain of f

g

g(x)

f

f(g(x))

For examples 1-5:
Given f(x) and g(x), find each function and state its domain.
a) ( f
g )( x)
b) ( g
f )( x)

a) ( f
g )( x)

b) ( g
f )( x)

a) ( f
g )( x)

b) ( g
f )( x)

x
x +1

EXAMPLE 3:
3

f ( x) = 9 − 2 x ; g ( x) = 4 x + 1

© Gina Wilson (All Things Algebra®, LLC), 2017

EXAMPLE 4:
f ( x) =

x + 5 ; g ( x) = x

3

3

f ( x) = − 2 x ; g ( x) = x + 1

b) ( g
f )( x)

For examples 6-7:
Given f(x) and g(x), evaluate each function.
a) ( f
g )(3)
b) ( g
f )(−5)

a) ( f
g )(9)

EXAMPLE 7:
2

a) ( f
g )( x)
x+4

EXAMPLE 6:

f ( x) = x + 5 x ; g ( x) =

b) ( g
f )( x)

2

EXAMPLE 5:
f ( x) = x − 1; g ( x) =

a) ( f
g )( x)

b) ( g
f )(7)

x−4

Directions: Find two functions f and g such that ( f
g )( x ) = h( x ) .

DECOMPOSING
A FUNCTION

8. h( x) = (1− 2 x)

10. h( x) =

3

4
−1
x+7

9. h( x) =

3

2

x +1

11. h( x) = −

1
x+5 +3
2

© Gina Wilson (All Things Algebra®, LLC), 2017

Name: ___________________________________

Unit 2: Functions & Their Graphs

Date: ________________________ Per: ______

Homework 9: Function Operations &
Compositions of Functions

** This is a 2-page document! **
Using the given functions, find each function and state its domain.
1. f ( x) = x 2 + 2 x and g ( x) = 5 − x
a) ( f + g )( x)

b) ( g − f )( x)

c) ( f ⋅ g )( x)

g
d)   ( x)
 f 

2
4 x3
and g ( x) =
x
5
a) ( g + f )( x)

2. f ( x) = −

c) ( f ⋅ g )( x)

3. f (x) = x − 7 and g ( x) = 2 x
a) ( f + g )( x)

c) ( g ⋅ f )( x)

b) ( g − f )( x)

 f 
d)   ( x)
g

b) (g − f )(x)

g
d)   ( x)
 f 

© Gina Wilson (All Things Algebra®, LLC), 2017

x −1
x
b) (h
g )( x)

4. f ( x) = x 2 − 5 x , g ( x) = 3 x + 1, and h( x) =
a) ( g
f )( x)

c) ( f
g )( x)

5. f ( x) = x 3 + 6 , g ( x) = 3 4 x , and h( x) = 2 x − 5
a) (h
f )( x)

b) (h
g)(x)

c) (g
f )(x)

Use the given functions to evalaute each function.
6. f ( x) = x 2 − 4 x , g ( x) = 2 − 3 x and h( x) =

3
x

a) ( f − g )(−5)

b) ( g ⋅ f )(3)

c) ( g
h)( −6)

d) (h
f )(2)

Find two functions f and g such that ( f
g)( x) = h( x) .
7. h( x) = 2(3 x − 1)3

8. h( x) = −

3
+7
x+5

© Gina Wilson (All Things Algebra®, LLC), 2017

Name:

Date:

___________________________________________________

_________________________________

Topic:

Class:

___________________________________________________

_________________________________

Main Ideas/Questions

Notes/Examples
• What is the inverse of a relation? _______________________________________

Inverse
Relations

_________________________________________________________________________
• Notation: The inverse of a relation R is written as ________________
• Example: Give the inverse of relation R below.

R: {(0, -7), (-1, 2), (-4, -2), (6, 3)} R-1: __________________________________

One-to-One
Functions
• Recall: The vertical line test is used to determine whether a relation is
a function given a graph.

Horizontal
Line Test

• The horizontal line test is used to determine whether the _____________
of a relation is a function.

• BOTH the relation and its inverse must be a function in order to be a
one-to-one function.
Directions: Determine whether the relations are one-to-one functions.

Examples

1.

2.

3.

4.

5.

6.

© Gina Wilson (All Things Algebra®, LLC), 2017

• Notation: The inverse of a function f(x) is written as ________________

Inverse
Functions

• Not all functions have inverse functions.
• To find the inverse of a function: Replace f(x) with y

and y
•

Examples

h Interchange x

h Solve for y h Rewrite y as f-1(x).

Directions: Determine if f(x) has an inverse, if yes, find f-1(x). State any
restrictions in the domain.
7. f ( x) = 4 x − 8
1 3
8. f ( x) = x − 1
2

2

5
x−8

9. f ( x) = ( x − 4) + 6

10. f ( x) =

11. f ( x) = − x + 2 − 7

12. f ( x) = −

3

13. f ( x) =

x−9
4

3
x +1
2

2

14. f ( x) = 3 x − 1; x ≥ 0

© Gina Wilson (All Things Algebra®, LLC), 2017

Name:

Date:

___________________________________________________

_________________________________

Topic:

Class:

___________________________________________________

_________________________________

Main Ideas/Questions

VERIFYING
INVERSES
Graphically

Notes/Examples

Directions: Find the inverse of each function. Verify graphically.
1. f ( x) = 3 x − 6

3

2. f ( x) = x + 4

VERIFYING
INVERSES
Algebraically

Directions: Verify algebraically that f and g are inverse functions.
3. f ( x) =

x−7
and g ( x) = 2 x + 7
2

2

4. f ( x) = x − 5 (if x ≥ 0) and g ( x) =

x+5

© Gina Wilson (All Things Algebra®, LLC), 2017

5. f ( x) =

More Examples
6. f ( x) =

3

x +2

3
x+3
and g ( x) =
2x − 1
2x

Directions: Find the inverse of each function. State any restrictions in the
domain. Verify graphically and algebraically.
Verify Graphically

Verify Algebraically

2

7. f ( x ) = ( x + 4) − 2
(if x ≥ -4)

8. f ( x) =

5
+2
x

9. f (x) =

1
x+3
2

© Gina Wilson (All Things Algebra®, LLC), 2017

Name: ___________________________________

Unit 2: Functions & Their Graphs

Date: ________________________ Per: ______

Homework 10: Inverse Relations & Functions,
Verifying Inverses

** This is a 2-page document! **
Directions: Determine whether the relations are one-to-one functions.
1.
2.
3.

Directions: Determine if f(x) has an inverse, if yes, find f-1(x). State any restrictions in the domain.
4. f (x) =

3
x+3
4

5. f (x) = (x − 5)2 + 9

6. f (x) =

1
x+2

7. f (x) =

8. f (x) = 4 2x −1

9. f (x) =

3

x + 7 −1

2x + 5
x −7

© Gina Wilson (All Things Algebra®, LLC), 2017

Directions: Find the inverse of each function. State any restrictions in the domain. Verify graphically
and algebraically.
10. f (x) =

11. f (x) = −2(x − 1)

12. f (x) =

13. f (x) =

Verify Graphically

x−4
3

Verify Algebraically

3

3
x+4

x +2 −7

© Gina Wilson (All Things Algebra®, LLC), 2017

Name: _________________________________________________

Pre-Calculus

Date: ______________________________Per: ________

Unit 2: Functions & Their Graphs

Quiz 2-4: Function Operations, Compositions, and Inverses
Given f(x) = x2 + 3x – 10, g(x) = 6 – x3 , and h(x) = 2x + 1, find each function and state its domain.
1. ( f  h)( x)

2. (h  g )( x)

1. _____________________________

D: __________________________
2. _____________________________

2

3. ( f  g )( x)

h
4.   ( x)
f 

D: __________________________
3. _____________________________

D: __________________________
5. ( f

h)( x)

4. _____________________________

6. (h g )( x)

D: __________________________
5. _____________________________
7. Given f ( x)  x  3 and g ( x) 
state its domain.

x  6 , find ( f  g )( x) and

D: __________________________
6. _____________________________
D: __________________________

1
x 1
8. Given f ( x) 
and g ( x)  , find ( f  g )( x) and
x
2
state its domain.

7. _____________________________
D: __________________________
8. _____________________________
D: __________________________

9. Given f ( x)  x 2  4 and g ( x) 

x  1 , find ( f

g )( x) and

state its domain.

9. _____________________________
D: __________________________
10. ____________________________

10. Given h( x)  ( x  5)3  2 , find two functions, f and g,
such that ( f g )( x)  h( x).

____________________________

© Gina Wilson (All Things Algebra®, LLC), 2017

Given f ( x )  2  5 x , g ( x ) 

x2
3
, and h( x )   x  7 , evaluate each function.
x2
12. ( g  h)(8)

11. ( f  g )(6)

11. _______________
12. _______________

g
13.   (4)
f 

14. ( f

13. _______________

h)(1)

14. _______________

Given f(x), find f-1(x). State any restrictions in the domain.
x 6
2
15. f ( x)  ( x  1)  3 ; x  1
16. f ( x) 
x2

15. ___________________________
16. ___________________________

Verify graphically that f(x) and g(x) are inverse functions.
17. f ( x)  2 x  5 and g ( x) 

x5
2

18. f ( x) 

x  4 and g ( x)  ( x  4)2 ; x  4

Determine algebraically using compositions whether functions f and g are inverse functions.
3
19. f ( x)  2 x  6 and g ( x) 

3

x6
2

Inverses?

20. f ( x) 

 yes  no

4
4
 2 and g ( x) 
x
x2

Inverses?

 yes  no

© Gina Wilson (All Things Algebra®, LLC), 2017

Unit 2 Test Study Guide

Name: __________________________________________

(Functions & Their Graphs)

Date: ____________________________ Per: __________

Topic 1: Evaluating Functions
For questions 1 and 2, evaluate given f ( x ) 
1. f (9)

x2
.
2x  3
2. f ( x  1)

For questions 3 and 4, evaluate given g ( x )  3 x  x 2 .
3. g (2 x  1)

4. g (3 x)

 4 x  7 if x  3
For questions 5 and 6, evaluate given h( x )  
.
3
2
  x  2 x if x  3
5. h  7 
6. h(3)

Topic 2: Parent Functions, Transformations, and Graphing
For each function family below, give the parent function and sketch the shape of its graph.
7. Linear
8. Absolute Value
9. Quadratic
10. Cubic

11. Square Root

12. Cube Root

13. Reciprocal

14. Greatest Integer

© Gina W ilson (All Things Algebra®, LLC), 2017

15. If the quadratic parent function is reflected
in the y-axis and vertically compressed by a
factor of ½, write an equation to represent
the new function.

16. If the cube root parent function is
horizontally stretched by a factor of 4, then
translated 5 units right and 3 units up, write
an equation to represent the new function.

17. The absolute value parent function has
transformations applied such that it creates
an absolute maximum at (-2, 7). Write an
equation that could represent this new
function.

18. A certain function is vertically stretched by
a factor of 2, horizontally compressed by ¼,
and translated down 6. The new function is
represented by f ( x )  6
8 x   2 . Write the
equation of the original function.

19. Describe all transformations from the
parent function given the function below.

20. Describe all transformations from the
parent function given the function below.

3

1 
f ( x)  3  x   7
2 

f ( x) 

2
( x  5)  2
3

Graph each function and identify all key characteristics.
Domain:
3
1
21. f ( x) 
x4

Range:

x-int:

y-int:

Extrema
Increasing Interval:
Decreasing Interval:
End Behavior:

22. f ( x)  2( x  3)2  4

Domain:

Range:

x-int:

y-int:

Extrema
Increasing Interval:
Decreasing Interval:
End Behavior:

© Gina Wilson (All Things Algebra®, LLC), 2017

23. f ( x)  2 3 ( x  4)  3

Domain:

Range:

x-int:

y-int:

Extrema
Increasing Interval:
Decreasing Interval:
End Behavior:

Topic 3: Piecewise Functions
Identify the domain and range of each graph below. State the location and type of any
discontinuties.
Domain:
Domain:
24.
25.
Range:

Range:

Discontinuities:

Discontinuities:

26. Graph the function below. Identify the domain and range,
then, state the location and type of any discontinuties.

 3
 2 x  6

f ( x)    x

 x 1 3


Domain:

Range:

if x  4
if  4  x  1
if x  1

Discontinuities:

Topic 4: Average Rate of Change
Find the average rate of change of the function on the given interval.
2x  1
27. f ( x)  2 x 2  3 x  1; [-3, 2]
; [-10, -5]
28. f ( x) 
x3

© Gina W ilson (All Things Algebra®, LLC), 2017

29. A football is kicked from a point on the ground such that its height h(t ), in feet, is given by the
equation h(t )  16 t 2  80t , where t is time in seconds. Find the average rate of change in
the height of the ball from when it reaches its maximum height until it reaches the ground.

Topic 5: Tests for Symmetry / Even & Odd Functions
Use the graph to determine if the relations given below are symmetrical to the x-axis, y-axis,
and/or origin. Confirm your answer algebraically.
31. y  2 x  5
30. x 2  y 2  4

Determine whether the function below is even, odd, or neither. Prove your answer algebraically.
32. f ( x)  3 x 3  5 x

33. f ( x)  5 x 2  2 x  1

Topic 6: Function Operations & Compositions of Functions
Use f ( x )  3  2 x , g( x )  x  7 , and h( x )  x 2  5 x to find each function below. Be sure to state
any domain restrictions, wherever necessary.
34.  g  f  ( x)
35.  h  f  ( x)
f 
36.   ( x)
h

© Gina W ilson (All Things Algebra®, LLC), 2017

Use f ( x )   x 2  2 x , g( x ) 
domain for each.
37. (h f )( x)

x  7 , and h( x)  3 x  1 to find each function below. Give the

38. ( f

39. ( f

g )( x)

Given h(x) below, find two functions, f and g, such that ( f
40. h( x) 

5
2
x9

g )( x )  h( x ).

41. h( x)   2( x  5)  7

Use f ( x)  10  2 x , g( x )  3 2 x  3 , and h( x) 
42. ( g  f )(15)

h)( x)

h
43.   (12)
g

1
x  5 to evaluate each function below.
2
44. ( g h)  6 

Topic 7: Inverse Functions
Determine if the graph represents a one-to-one function.
45.

46.

47.

© Gina W ilson (All Things Algebra®, LLC), 2017

Determine if f(x) has an inverse, if yes, find f-1(x). State any restrictions in the domain.
49. f ( x)  2 x  5
48. f ( x)  3 x  7  2

50. f ( x)  4 x 2  7; x  0

51. f ( x) 

x 6
x5

Prove f (x) and g(x) are inverses both algebraically and graphically.
4
52. f ( x)   2
x
4
g ( x) 
x2

3

1 
53. f ( x)   x   3
2 
g ( x)  2 3 x  3

© Gina W ilson (All Things Algebra®, LLC), 2017

Na