1. ESSENTIAL CALCULUS CH01 Functions & Limits

2. In this Chapter: 1.2 A Catalog of Essential Functions
1.1 Functions and Their Representations
1.2 A Catalog of Essential Functions
1.3 The Limit of a Function
1.4 Calculating Limits
1.5 Continuity
1.6 Limits Involving Infinity
Review

3. Some Terminologies： domain：set A range： independent varible：A symbol representing any number in the domain dependent varible： A symbol representing any number in the range
Chapter 1, 1.1, P2

4. A function f is a rule that assigns to each element x in a set A exactly one element, called f(x) , in a set B.
Chapter 1, 1.1, P2

5. Chapter 1, 1.1, P2

6. Chapter 1, 1.1, P2

7. If f is a function with domain A, then its graph is the set of ordered pairs
(Notice that these are input-output pairs.) In other words, the graph of f consists of all Points(x,y) in the coordinate plane such that y=f(x) and x is in the domain of f.
Chapter 1, 1.1, P2

8. Chapter 1, 1.1, P2

9. Chapter 1, 1.1, P2

10. Chapter 1, 1.1, P2

11. EXAMPLE 1 The graph of a function f is shown in Figure 6.
Find the values of f(1) and f(5) .
(b) What are the domain and range of f ?
Chapter 1, 1.1, P2

12. EXAMPLE 3 Find the domain of each function.
Chapter 1, 1.1, P4

13. THE VERTICAL LINE TEST A curve in the xy-plane is the graph of a function of x if and only if no vertical line intersects the curve more than once.
Chapter 1, 1.1, P4

14. Chapter 1, 1.1, P5

15. EXAMPLE 4 A function f is defined by
1-X if X≤1
X2 if X>1
f(x)=
Evaluate f(0) ,f(1) , and f(2) and sketch the graph.
Chapter 1, 1.1, P5

16. Chapter 1, 1.1, P5

17. EXAMPLE 5 Sketch the graph of the absolute value function f(x)=│X│.
Chapter 1, 1.1, P6

18. 0.39 if o<w≤1 0.63 if 1<w≤2 0.87 if 2<w≤3 1.11 if 3<w≤4
EXAMPLE 6 In Example C at the beginning of this section we considered the cost C(w)
of mailing a first-class letter with weight w. In effect, this is a piecewise defined function because, from the table of values, we have
if o<w≤1
if 1<w≤2
if 2<w≤3
if 3<w≤4
C(w)=
Chapter 1, 1.1, P6

19. Chapter 1, 1.1, P6

21. If a function f satisfies f(-x)=f(x) for every number x in its domain, then f is called an even function.
Chapter 1, 1.1, P6

22. Chapter 1, 1.1, P6

23. Chapter 1, 1.1, P6

24. If f satisfies f(-x)=-f(x) for every number x in its domain, then f is called an odd function.
Chapter 1, 1.1, 07

25. EXAMPLE 7 Determine whether each of the following functions is even, odd, or neither even nor odd.
f(x)=x5+x
g(x)=1-x4
h(x)=2x=x2
Chapter 1, 1.1, 07

26. Chapter 1, 1.1, 07

27. f (x1)< f (x2) whenever x1< x2 in I
A function f is called increasing on an interval if
f (x1)< f (x2) whenever x1< x2 in I
It is called decreasing on I if
f (x1)> f (x2) whenever x1 < x2 in I
Chapter 1, 1.1, 07

28. 1. The graph of a function f is given. (a) State the value of f(-1).
(b) Estimate the value of f(2).
(c) For what values of x is f(x)=2?
(d) Estimate the values of x such that f(x)=0 .
(e) State the domain and range of f .
(f ) On what interval is f increasing?
Chapter 1, 1.1, 08

29. Chapter 1, 1.1, 08

30. 2. The graphs of f and g are given.
(a) State the values of f(-4)and g(3).
(b) For what values of x is f(x)=g(x)?
(c) Estimate the solution of the equation f(x)=-1.
(d) On what interval is f decreasing?
(e) State the domain and range of f.
(f ) State the domain and range of g.
Chapter 1, 1.1, 08

31. Chapter 1, 1.1, 08

32. 3–6 ■ Determine whether the curve is the graph of a function of x
3–6 ■ Determine whether the curve is the graph of a function of x. If it is, state the domain and range of the function.
Chapter 1, 1.1, 08

33. 53–54 ■ Graphs of f and g are shown
53–54 ■ Graphs of f and g are shown. Decide whether each function is even, odd, or neither. Explain your reasoning.
Chapter 1, 1.1, 10

34. A function P is called a polynomial if
P(x)=anxn+an-1xn-1+‧‧‧+a2x2+a1x+a0
where n is a nonnegative integer and the numbers a0,a1,a2,…..an are constants
called the coefficients of the polynomial. The domain of any polynomial is R=(-∞,∞)
If the leading coefficient an≠0, then the degree of the polynomial is n.
Chapter 1, 1.2, 13

35. Chapter 1, 1.2, 14

36. Chapter 1, 1.2, 14

37. Chapter 1, 1.2, 14

38. Chapter 1, 1.2, 14

39. Chapter 1, 1.2, 14

40. Chapter 1, 1.2, 14

41. Chapter 1, 1.2, 14

42. Chapter 1, 1.2, 14

43. Chapter 1, 1.2, 14

44. Chapter 1, 1.2, 15

45. A rational function f is a ratio of two
polynomials:
Where P and Q are polynomials. The domain consists of all values of x such that Q(x)≠0.
Chapter 1, 1.2, 15

46. Chapter 1, 1.2, 15

47. Chapter 1, 1.2, 15

48. -1≤ son x≤1 -1≤ cos x≤1
Chapter 1, 1.2, 15

49. Chapter 1, 1.2, 16

50. Chapter 1, 1.2, 16

51. Chapter 1, 1.2, 16

52. Sin(x+2π)=sin x cos(x+2π)=cos x
Chapter 1, 1.2, 16

53. The exponential functions are the functions of the form f(x)=ax , where the base is a positive constant.
Chapter 1, 1.2, 16

54. are the inverse functions of the exponential functions.
The logarithmic functions f(x)=logax , where the base a is a positive constant,
are the inverse functions of the exponential functions.
Chapter 1, 1.2, 16

55. ■ Figure 15 illustrates these shifts by showing how the graph of y=(x+3)2+1 is obtained from the graph of the parabola y=x2: Shift 3 units to the left and 1 unit upward.
Y=(x+3)2+1
Chapter 1, 1.2, 17

56. VERTICAL AND HORIZONTAL SHIFTS Suppose c>0. To obtain the graph of
Y= f(x)+c, shift the graph of y=f(x) a distance c units c units upward
Y= f(x)- c, shift the graph of y=f(x) a distance c units c units downward
Y= f(x- c), shift the graph of y=f(x) a distance c units c units to the right
Y=f(x+ c), shift the graph of y=f(x) a distance c units c units to the left
Chapter 1, 1.2, 17

57. VERTICAL AND HORIZONTAL STRETCHING AND REFLECTING
Suppose c>1. To obtain the graph of
y=cf(x), stretch the graph of y=f(x) vertically by a factor of c
y=(1/c)f(x), compress the graph of y=f(x) vertically by a factor of c
Y=f(cx), compress the graph of y=f(x) horizontally by a factor of c
Y=f(x/c), stretch the graph of y=f(x) horizontally by a factor of c
Y=-f(x), reflect the graph of y=f(x) about the x-axis
Y=f(-x), reflect the graph of y=f(x) about theｙ-axis
Chapter 1, 1.2, 17

58. Chapter 1, 1.2, 17

59. Chapter 1, 1.2, 17

60. EXAMPLE 2 Given the graph of y= , use transformations to graph y= -2 , y= , y=- , y=2 , and y=
Chapter 1, 1.2, 18

61. Chapter 1, 1.2, 18

62. Chapter 1, 1.2, 18

63. Chapter 1, 1.2, 18

64. Chapter 1, 1.2, 18

65. Chapter 1, 1.2, 18

66. Chapter 1, 1.2, 18

67. EXAMPLE 3 Sketch the graph of the function y=1-sin x.
Chapter 1, 1.2, 18

68. Chapter 1, 1.2, 18

69. Chapter 1, 1.2, 18

70. (f+g)(x)=f(x)+g(x) (f-g)(x)=f(x)-g(x)
If the domain of f is A and the domain of g is B, then the domain of f + g is the intersection A ∩ B
Chapter 1, 1.2, 18

71. (fg)(x)=f(x)g(x)
The domain of fg is A ∩B, but we can’t divide by 0 and so the domain of f/g is
Chapter 1, 1.2, 18

72. DEFINITION Given two functions f and g , the composite function f。g (also called the composition of f and g ) is defined by
(f。g)(x)=f(g(x))
Chapter 1, 1.2, 19

73. Chapter 1, 1.2, 19

74. EXAMPLE 5 If f(x)= and g(x)= , find each function and its domain.
(a) f。g (b) g。f (c) f。f (d)g。g
Chapter 1, 1.2, 20

75. EXAMPLE 6 Given F(x)=cos2(x+9) , find functions f ,g ,and h such that F=f。g。H.
Chapter 1, 1.2, 20

76. 17. The graph of y=f(x) is given
17. The graph of y=f(x) is given. Match each equation with its graph and give reasons for your choices.
y=f(x-4)
y=f(x)+3
y= f(x)
y=-f(x+4)
y=2f(x+6)
Chapter 1, 1.2, 22

77. 18. The graph of f is given. Draw the graphs of the
following functions.
(a)y=f(x+4) (b) y=f(x)+4
(c) y=2f(x) (d) y=- f(x)+3
Chapter 1, 1.2, 22

78. (a) y=f(2x) (b) y=f( x) 19 The graph of f is given. Use it to graph
the following functions.
(a) y=f(2x) (b) y=f( x)
(c) y=f(-x) (d)y=-f(-x)
Chapter 1, 1.2, 22

79. f(g(2)) (b) g(f(0)) (c) (f。g)(0) (g。F)(6) (e) (g。g)(-2) (f) (f。f)(4)
53 Use the given graphs of f and g to evaluate each expression, or explain why it is undefined.
f(g(2)) (b) g(f(0)) (c) (f。g)(0)
(g。F)(6) (e) (g。g)(-2) (f) (f。f)(4)
Chapter 1, 1.2, 22

80. Chapter 1, 1.3, 25

81. Chapter 1, 1.3, 25

82. limf(x)=L 1 DEFINITION We write
X→a
and say “the limit of f(X), as x approaches , equals L ”
if we can make the values of f(x) arbitrarily close to L (as close to L as we like) by taking x to be sufficiently close to a (on either side of ) but not equal to a.
Chapter 1, 1.3, 25

83. which is usually read “f(x) approaches L as x approaches a.”
limf(x)=L
X→a
is f(x)→L as x→a
which is usually read “f(x) approaches L as x approaches a.”
Chapter 1, 1.3, 25

84. Chapter 1, 1.3, 26

85. Chapter 1, 1.3, 26

86. Chapter 1, 1.3, 26

87. Chapter 1, 1.3, 26

88. Chapter 1, 1.3, 26

89. Chapter 1, 1.3, 28

90. Chapter 1, 1.3, 28

91. 2. DEFINITION We write limf(x)=L
X→a-
and say the left-hand limit of f(x) as X approaches a [or the limit of f(x) as X
approaches a from the left] is equal to L if we can make the values of f(X) arbitrarily close to L by taking x to L be sufficiently close to a and x less than a.
Chapter 1, 1.3, 29

92. Chapter 1, 1.3, 30

93. Chapter 1, 1.3, 30

94. 3 limf(x)=L if and only if limf(x)=L and limf(x)=L
X→a X→a X→a+
Chapter 1, 1.3, 30

95. EXAMPLE 7 The graph of a function g is shown is Figure 10
EXAMPLE 7 The graph of a function g is shown is Figure 10. Use it to state the values(if they exist) of the following：
lim g(x) (b) lim g(x) (c)lim g(x)
(d) lim g(x) (e) lim g(x) (f)lim g(x)
X→2─ X→ X→2
X→5─ X→ x→5
Chapter 1, 1.3, 30

96. Chapter 1, 1.3, 30

97. Chapter 1, 1.3, 31

98. as approaches is , and we write
FINITION Let f be a function defined on some open interval that contains
the number a , except possibly at a itself. Then we say that the limit of
as approaches is , and we write
lim g(x)=L
X→a
if for every number ε>0 there is a corresponding
number δ>0 such that
if 0<│x-a│<δ then │f(x)-L│<ε
Chapter 1, 1.3, 31

99. Chapter 1, 1.3, 32

100. Chapter 1, 1.31, 32

101. Chapter 1, 1.3, 32

102. Chapter 1, 1.3, 32

103. Chapter 1, 1.3, 32

104. Chapter 1, 1.3, 33

105. Lim f(X) (b) lim f(X) (C)lim f(X) (d) Lim f(X) (e)F(5)
3. Use the given graph of f to state the value of each quantity, if it exists. If it does not exist, explain why.
Lim f(X) (b) lim f(X) (C)lim f(X)
(d) Lim f(X) (e)F(5)
X→1─ X→ X→1
X→5
Chapter 1, 1.3, 33

106. (a_Lim f(X) (b) lim f(X) (C)lim f(X) (d) Lim f(X) (e)F(5)
4. For the function f whose graph is given, state the value of each quantity, if it exists. If it does not exist, explain why.
(a_Lim f(X) (b) lim f(X) (C)lim f(X)
(d) Lim f(X) (e)F(5)
X→ X→ X→3+
X→3
Chapter 1, 1.3, 33

107. lim g(t) (b) lim g(t) (c) lim g(t)
5. For the function g whose graph is given, state the value of each quantity, if it exists. If it does not exist, explain why.
lim g(t) (b) lim g(t) (c) lim g(t)
(d)lim g(t) (e) lim g(t) (f) lim g(t)
(g)g(2) (h)lim g(t)
X→ X→ X→0
X→ X→ X→2
X→4
Chapter 1, 1.3, 33

108. lim﹝f(x)+g(x)﹞=lim f(x)+lim g(x) lim﹝f(x)-g(x)﹞=limf(x)-lim g(x)
LIMIT LAWS Suppose that c is a constant and the limits
lim f(X) and lim g(x)
Exist Then
lim﹝f(x)+g(x)﹞=lim f(x)+lim g(x)
lim﹝f(x)-g(x)﹞=limf(x)-lim g(x)
lim ﹝cf(x)﹞=c lim f(x)
lim ﹝f(x)g(x)﹞=lim f(x)‧lim g(x)
lim = if lim g(x)≠0
X→a X→a
X→a X→a X→a
X→a X→a X→a
X→a X→a
X→a X→a X→a
X→a X→a
Chapter 1, 1.4, 35

109. Sum Law Difference Law Constant Multiple Law Product Law Quotient Law
Chapter 1, 1.4, 36

110. 1. The limit of a sum is the sum of the limits.
2. The limit of a difference is the difference of
the limits.
3. The limit of a constant times a function is the
constant times the limit of the function.
4. The limit of a product is the product of the
limits.
5. The limit of a quotient is the quotient of the
limits (provided that the limit of the
denominator is not 0).
Chapter 1, 1.4, 36

111. 6. lim[f(x)]n=[limf(x)]n where n is a positive integer
X→a X→a
Chapter 1, 1.4, 36

112. 7. lim c=c lim x=a
X→a X→a
Chapter 1, 1.4, 36

113. 9. lim xn=an where n is a positive integer
X→a
Chapter 1, 1.4, 36

114. 10. lim = where n is a positive integer
(If n is even, we assume that a>0.)
X→a
Chapter 1, 1.4, 36

115. 11.Lim = where n is a positive integer
[If n is even, we assume that lim f(X)>0.]
X→a
X→a
X→a
Chapter 1, 1.4, 36

116. and is in the domain of f, then
DIRECT SUBSTITUTION PROPERTY If f is a polynomial or a rational function
and is in the domain of f, then
lim f(X)>f(a)
X→a
Chapter 1, 1.4, 37

117. If f(x)=g(x) when x ≠ a, then lim f(x)=lim g(x),
provided the limits exist.
X→a
X→a
Chapter 1, 1.4, 38

118. The graphs of the functions f (from Example 2) and g (from Example 3)
FIGURE 2
The graphs of the functions f (from Example 2) and g (from Example 3)
Chapter 1, 1.4, 39

119. 2 THEOREM lim f(x)=L if and only if lim f(x)=L=lim f(x)
X→a
X→a-
X→a+
Chapter 1, 1.4, 39

120. Chapter 1, 1.4, 40

121. Chapter 1, 1.4, 40

122. Chapter 1, 1.4, 40

123. 3. THEOREM If f(x)≤g(x) when x is near a (except possibly at a) and the limits of f and g both exist as x approaches a, then
lim f(x) ≤lim g(x)
X→a
X→a
Chapter 1, 1.4, 41

124. 4. THE SQUEEZE THEOREM If f(x) ≤g(x) ≤h(x) when x is near a (except possibly at a) and
limf(x)=lim h(X) =L
Then lim g(X)=L
X→a
X→a
X→a
Chapter 1, 1.4, 41

125. Chapter 1, 1.4, 41

126. Chapter 1, 1.4, 41

127. (a)lim[f(x)+g(x)] (b) lim [f(x)+g(x)] (c)lim [f(x)g(x)] (d) lim
2. The graphs of f and g are given. Use them to evaluate each limit, if it exists. If the limit does not exist, explain why.
(a)lim[f(x)+g(x)] (b) lim [f(x)+g(x)]
(c)lim [f(x)g(x)] (d) lim
(e)Lim[x3f(x)] (f) lim
X→2
X→1
X→0
X→ -1
X→2
X→1
Chapter 1, 1.4, 43

128. ■ As illustrated in Figure 1, if f is continuous,
then the points (x, f(x)) on the graph of f approach the point (a, f(a)) on the graph. So there is no gap in the curev.
Chapter 1, 1.5, 46

129. Chapter 1, 1.5, 46

130. DEFINITION A function f is continuous at a number a if lim f(X)=f(a)
X→a
Chapter 1, 1.5, 46

131. f(a)is defined (that is, a is in the domain of f ) lim f(x) exists
Notice that Definition I implicitly requires three things if f is continuous at a:
f(a)is defined (that is, a is in the domain of f )
lim f(x) exists
lim f(x) = f(a)
X→a
X→a
Chapter 1, 1.5, 46

132. If f is defined near a(in other words, f is defined on an open interval containing a, except perhaps at a), we say that f is discontinuous at a (or f has a discontinuity at a) if f is not continuous at a.
Chapter 1, 1.5, 46

133. And f is continuous from the left at a if
2. DEFINITION A function f is continuous from the right t a number a if
lim f(x)=f(a)
And f is continuous from the left at a if
X→a+
X→a-
Chapter 1, 1.5, 47

134. from the right or continuous from the left.)
3. DEFINITION A function f is continuous on an interval if it is continuous at every number in the interval. (If f is defined only on one side of an endpoint of the interval, we understand continuous at the endpoint to mean continuous
from the right or continuous from the left.)
Chapter 1, 1.5, 48

135. 4. THEOREM If f and g are continuous at a and c is a constant, then the following functions are also continuous at a :
f+g f-g cf
4. fg if g(a)≠0
Chapter 1, 1.5, 48

136. continuous on its domain.
5. THEOREM
Any polynomial is continuous everywhere; that is, it is continuous on R=(-∞,∞).
(b) Any rational function is continuous wherever it is defined; that is, it is
continuous on its domain.
Chapter 1, 1.5, 49

137. 6. THEOREM The following types of functions are continuous at every number in their domains: polynomials, rational functions, root functions, trigonometric functions
Chapter 1, 1.5, 50

138. 7. THEOREM If f is continuous at b and
lim g(x)=b, then lim f(g(X))=f(b). in
the words
lim f(g(X))=f(lim g(X))
X→a
X→a
X→a
X→a
Chapter 1, 1.5, 51

139. 8. THEOREM If g is continuous at a and f is continuous at g(a), then the composite function f。g given by(f。g)(x)=f(g(x)) is continuous at a.
Chapter 1, 1.5, 51

140. 9. INTERMEDIATE VALUE THEOREM Suppose that f is continuous on the closed interval [a,b] and let N be any number between f(a) and f(b) , where f(a)≠f(b). Then there exists a number c in(a,b) such that f(c)=N.
Chapter 1, 1.5, 52

141. Chapter 1, 1.5, 52

142. Chapter 1, 1.5, 52

143. Chapter 1, 1.5, 53

144. 3 (a) From the graph of f, state the numbers at
which f is discontinuous and explain why.
(b) For each of the numbers stated in part (a),
determine whether f is continuous from
the right, or from the left, or neither.
Chapter 1, 1.5, 54

145. 4. From the graph of g , state the intervals on which g is continuous.
Chapter 1, 1.5, 54

146. 1 DEFINITION The notation lim f(x)=∞
means that the values of f(x) can be made arbitrarily large (as large as we please) by taking x sufficiently close to a (on either side of a) but not equal to a.
X→a
Chapter 1, 1.6, 56

147. Chapter 1, 1.6, 57

148. Chapter 1, 1.6, 57

149. Chapter 1, 1.6, 57

150. Chapter 1, 1.6, 57

151. Chapter 1, 1.6, 57

152. Chapter 1, 1.6, 57

153. 2. DEFINITION The line x = a is called a vertical asymptote of the curve y=f(x) if at least one of the following statements is true:
lim f(x)=∞
lim f(x)=∞
lim f(x)=∞
X→a+
X→a
X→a-
lim f(x)=-∞
lim f(x)=-∞
lim f(x)=-∞
X→a
X→a-
X→a+
Chapter 1, 1.6, 57

154. Chapter 1, 1.6, 58

155. 3. DEFINITION Let f be a function defined on some interval(a, ∞) . Then
lim f(x)=L
means that the values of f(x) can be made as close to L as we like by taking x sufficiently large.
X→a
Chapter 1, 1.6, 59

156. Chapter 1, 1.6, 59

157. Chapter 1, 1.6, 59

158. Chapter 1, 1.6, 59

159. Chapter 1, 1.6, 60

160. Chapter 1, 1.6, 60

161. Chapter 1, 1.6, 60

162. lim f(x)=L or lim f(x)=L
4. DEFINITION The line y=L is called a horizontal asymptote of the curve y=f(x)
if either
lim f(x)=L or lim f(x)=L
X→∞
X→∞
Chapter 1, 1.6, 60

163. EXAMPLE 3 Find the infinite limits, limits at infinity, and asymptotes for the function f whose graph is shown in Figure 11.
Chapter 1, 1.6, 60

164. 5. If n is a positive integer, then lim =0 lin =0
X→∞
X→∞
Chapter 1, 1.6, 61

165. if 0<│x-a│<δ then f(x)>M
6. DEFINITION Let f be a function defined on some open interval that contains the number a, except possibly at a itself. Then
lim f(x)=∞
means that for every positive number M there is a positive number δsuch that
if 0<│x-a│<δ then f(x)>M
X→ a
Chapter 1, 1.6, 64

166. 7. DEFINITION Let f be a function defined on
some interval(a, ∞) . Then
lim f(x)=L
X→∞
means that for every ε>0 there is a corresponding
number N such that
if x>N then │f(x)-L│<ε
Chapter 1, 1.6, 65

167. Chapter 1, 1.6, 65

168. Chapter 1, 1.6, 65

169. if x>N then f(x)>M
8. DEFINITION Let f be a function defined on some interval(a, ∞) . Then
lim f(x)=∞
means that for every positive number M there is a corresponding positive number N such that
if x>N then f(x)>M
X→∞
Chapter 1, 1.6, 66

170. 1.For the function f whose graph is given, state the following.
lim f(x) (b) lim f(x)
(c) lim f(x) (d) lim f(x)
(e) lim f(x)
(f) The equations of the asymptotes
X→ 2
X→ -1-
X→∞
X→ -1+
X→ -∞
Chapter 1, 1.6, 66

171. Chapter 1, 1.6, 66

172. 2. For the function g whose graph is given, state the following.
lim g(x) (b) lim g(x)
(c) lim g(x) (d) lim g(x)
(e) lim g(x) (f) The equations of the asymptotes
X→ -∞
X→∞
X→3
X→ 0
X→ -2+
Chapter 1, 1.6, 67

173. 1. Let f be the function whose graph is given.
(a) Estimate the value of f(2).
(b) Estimate the values of x such that f(x)=3.
(c) State the domain of f.
(d) State the range of f.
(e) On what interval is increasing?
(f ) Is f even, odd, or neither even nor odd? Explain.
Chapter 1, Review, 70

174. Chapter 1, Review, 70

175. 2. Determine whether each curve is the graph of a function of x
2. Determine whether each curve is the graph of a function of x. If it is, state the domain and range of the function.
Chapter 1, Review, 71

176. (a)y=f(x-8) (b)y=-f(x) (c)y=2-f(x) (d)y= f(x)-1
8. The graph of f is given. Draw the graphs of the following functions.
(a)y=f(x-8) (b)y=-f(x)
(c)y=2-f(x) (d)y= f(x)-1
Chapter 1, Review, 71

177. Fine each limit, or explain why it doex not exist.
21. The graph of f is given.
Fine each limit, or explain why it doex not exist.
(i) lim f(x) (ii) lim f(x)
(iii) lim f(x) (iv) lim f(x)
(v) lim f(x) (vi) lim f(x)
(vii) lim f(x) (viii) lim f(x)
(b)State the equations of the horizontal asymptotes.
(c)State the equations of the vertical asymptotes.
(d)At what number is f discontinuous? Explain.
X→ 2+
X→ -3+
X→ 4
X→ -3
X→0
X→2-
X→∞
X→ -∞
Chapter 1, Review, 71

178. Chapter 1, Review, 71