2. There are three numbers in an exponential notation.
The Logarithmic Functions
4 3 = 64
3. There are three numbers in an exponential notation.
The Logarithmic Functions
the base
4 3 = 64
4. There are three numbers in an exponential notation.
The Logarithmic Functions
the exponent
the base
4 3 = 64
5. There are three numbers in an exponential notation.
The Logarithmic Functions
the exponent
the base
the output
4 3 = 64
6. There are three numbers in an exponential notation.
Given the above expression, we say that
“(base) 4 raised to the exponent (power) 3 gives 64”.
The Logarithmic Functions
the exponent
the base
the output
4 3 = 64
7. There are three numbers in an exponential notation.
The Logarithmic Functions
the exponent
the base
the output
4 3 = 64
Given the above expression, we say that
“(base) 4 raised to the exponent (power) 3 gives 64”.
The focus of the above statement is that when 43 is
executed, the output is 64.
8. There are three numbers in an exponential notation.
The Logarithmic Functions
the exponent
the base
the output
4 3 = 64
However if we are given the output is 64 from
raising 4 to a power,
Given the above expression, we say that
“(base) 4 raised to the exponent (power) 3 gives 64”.
The focus of the above statement is that when 43 is
executed, the output is 64.
9. There are three numbers in an exponential notation.
The Logarithmic Functions
the exponent
the base
the output
4 3 = 64
However if we are given the output is 64 from
raising 4 to a power,
the power
the base the output
4 = 64
3
Given the above expression, we say that
“(base) 4 raised to the exponent (power) 3 gives 64”.
The focus of the above statement is that when 43 is
executed, the output is 64.
10. There are three numbers in an exponential notation.
The Logarithmic Functions
the exponent
the base
the output
4 3 = 64
However if we are given the output is 64 from
raising 4 to a power, then the
needed power is called
log4(64)
the power = log4(64)
the base the output
4 = 64
3
Given the above expression, we say that
“(base) 4 raised to the exponent (power) 3 gives 64”.
The focus of the above statement is that when 43 is
executed, the output is 64.
11. There are three numbers in an exponential notation.
The Logarithmic Functions
the exponent
the base
the output
4 3 = 64
However if we are given the output is 64 from
raising 4 to a power, then the
needed power is called
log4(64) which is 3.
the power = log4(64)
the base the output
4 = 64
3
Given the above expression, we say that
“(base) 4 raised to the exponent (power) 3 gives 64”.
The focus of the above statement is that when 43 is
executed, the output is 64.
12. There are three numbers in an exponential notation.
The Logarithmic Functions
the exponent
the base
the output
4 3 = 64
However if we are given the output is 64 from
raising 4 to a power, then the
needed power is called
log4(64) which is 3.
the power = log4(64)
the base the output
4 = 64
3
or that log4(64) = 3 and we say
that “log–base–4 of 64 is 3”.
Given the above expression, we say that
“(base) 4 raised to the exponent (power) 3 gives 64”.
The focus of the above statement is that when 43 is
executed, the output is 64.
13. The Logarithmic Functions
Just as the sentence
“Bart's dad is Homer.”
contains the same information as
“Homer's son is Bart.”,
14. The Logarithmic Functions
Just as the sentence
“Bart's dad is Homer.”
contains the same information as
“Homer's son is Bart.” The expression
“64 = 43”
contains the same information as
“log4(64) = 3”.
15. The Logarithmic Functions
Just as the sentence
“Bart's dad is Homer.”
contains the same information as
“Homer's son is Bart.” The expression
“64 = 43”
contains the same information as
“log4(64) = 3”.
The expression “64 = 43” is called the exponential form
and “log4(64) = 3” is called the logarithmic form of the
expressed relation.
16. The Logarithmic Functions
Just as the sentence
“Bart's dad is Homer.”
contains the same information as
“Homer's son is Bart.” The expression
“64 = 43”
contains the same information as
“log4(64) = 3”.
The expression “64 = 43” is called the exponential form
and “log4(64) = 3” is called the logarithmic form of the
expressed relation.
In general, we say that
“log–base–b of y is x” or
logb(y) = x
17. The Logarithmic Functions
Just as the sentence
“Bart's dad is Homer.”
contains the same information as
“Homer's son is Bart.” The expression
“64 = 43”
contains the same information as
“log4(64) = 3”.
The expression “64 = 43” is called the exponential form
and “log4(64) = 3” is called the logarithmic form of the
expressed relation.
In general, we say that
“log–base–b of y is x” or
logb(y) = x if y = bx (b > 0).
18. The Logarithmic Functions
Just as the sentence
“Bart's dad is Homer.”
contains the same information as
“Homer's son is Bart.” The expression
“64 = 43”
contains the same information as
“log4(64) = 3”.
The expression “64 = 43” is called the exponential form
and “log4(64) = 3” is called the logarithmic form of the
expressed relation.
In general, we say that
“log–base–b of y is x” or
logb(y) = x if y = bx (b > 0).
the power = logb(y)
the base the output
b = y
x
19. The Logarithmic Functions
Just as the sentence
“Bart's dad is Homer.”
contains the same information as
“Homer's son is Bart.” The expression
“64 = 43”
contains the same information as
“log4(64) = 3”.
The expression “64 = 43” is called the exponential form
and “log4(64) = 3” is called the logarithmic form of the
expressed relation.
In general, we say that
“log–base–b of y is x” or
logb(y) = x if y = bx (b > 0),
i.e. logb(y) is the exponent x.
the power = logb(y)
the base the output
b = y
x
20. The Logarithmic Functions
When working with the exponential form or the
logarithmic expressions, always identify the base
number b first.
21. The Logarithmic Functions
When working with the exponential form or the
logarithmic expressions, always identify the base
number b first.
All the following exponential expressions yield 64.
22. The Logarithmic Functions
When working with the exponential form or the
logarithmic expressions, always identify the base
number b first.
All the following exponential expressions yield 64.
43 → 64
82 → 64
26 → 64
exp–form
23. The Logarithmic Functions
When working with the exponential form or the
logarithmic expressions, always identify the base
number b first.
All the following exponential expressions yield 64.
Their corresponding
log–form are differentiated
by the bases and the
different exponents
required.
43 → 64
82 → 64
26 → 64
exp–form log–form
24. The Logarithmic Functions
When working with the exponential form or the
logarithmic expressions, always identify the base
number b first.
All the following exponential expressions yield 64.
43 → 64
82 → 64
26 → 64
log4(64)
log8(64)
log2(64)
exp–form log–formTheir corresponding
log–form are differentiated
by the bases and the
different exponents
required.
25. The Logarithmic Functions
When working with the exponential form or the
logarithmic expressions, always identify the base
number b first.
All the following exponential expressions yield 64.
Their corresponding
log–form are differentiated
by the bases and the
different exponents
required.
43 → 64
82 → 64
26 → 64
log4(64) →
log8(64) →
log2(64) →
exp–form log–form
26. The Logarithmic Functions
When working with the exponential form or the
logarithmic expressions, always identify the base
number b first.
All the following exponential expressions yield 64.
43 → 64
82 → 64
26 → 64
log4(64) → 3
log8(64) →
log2(64) →
exp–form log–formTheir corresponding
log–form are differentiated
by the bases and the
different exponents
required.
27. The Logarithmic Functions
When working with the exponential form or the
logarithmic expressions, always identify the base
number b first.
All the following exponential expressions yield 64.
43 → 64
82 → 64
26 → 64
log4(64) → 3
log8(64) → 2
log2(64) →
exp–form log–formTheir corresponding
log–form are differentiated
by the bases and the
different exponents
required.
28. The Logarithmic Functions
When working with the exponential form or the
logarithmic expressions, always identify the base
number b first.
All the following exponential expressions yield 64.
43 → 64
82 → 64
26 → 64
log4(64) → 3
log8(64) → 2
log2(64) → 6
exp–form log–formTheir corresponding
log–form are differentiated
by the bases and the
different exponents
required.
29. The Logarithmic Functions
When working with the exponential form or the
logarithmic expressions, always identify the base
number b first.
All the following exponential expressions yield 64.
43 → 64
82 → 64
26 → 64
log4(64) → 3
log8(64) → 2
log2(64) → 6
exp–form log–formTheir corresponding
log–form are differentiated
by the bases and the
different exponents
required.
Both numbers b and y appearing in the log notation
“logb(y)” must be positive.
30. The Logarithmic Functions
When working with the exponential form or the
logarithmic expressions, always identify the base
number b first.
All the following exponential expressions yield 64.
43 → 64
82 → 64
26 → 64
log4(64) → 3
log8(64) → 2
log2(64) → 6
exp–form log–formTheir corresponding
log–form are differentiated
by the bases and the
different exponents
required.
Both numbers b and y appearing in the log notation
“logb(y)” must be positive. Switch to x as the input,
the domain of logb(x) is the set D = {x l x > 0 }.
31. The Logarithmic Functions
When working with the exponential form or the
logarithmic expressions, always identify the base
number b first.
All the following exponential expressions yield 64.
43 → 64
82 → 64
26 → 64
log4(64) → 3
log8(64) → 2
log2(64) → 6
exp–form log–formTheir corresponding
log–form are differentiated
by the bases and the
different exponents
required.
Both numbers b and y appearing in the log notation
“logb(y)” must be positive. Switch to x as the input,
the domain of logb(x) is the set D = {x l x > 0 }.
We would get an error message if we execute
log2(–1) with software.
33. The Logarithmic Functions
To convert the exp-form to the log–form:
b = y
x
logb( y ) = x→
Identity the base and the
correct log–function
34. The Logarithmic Functions
To convert the exp-form to the log–form:
b = y
x
logb( y ) = x→
insert the exponential
output.
35. The Logarithmic Functions
To convert the exp-form to the log–form:
b = y
x
logb( y ) = x→
The log–output is the
required exponent.
36. The Logarithmic Functions
Example A. Rewrite the exp-form into the log-form.
a. 42 = 16
b. w = u2+v
To convert the exp-form to the log–form:
b = y
x
logb( y ) = x→
37. The Logarithmic Functions
Example A. Rewrite the exp-form into the log-form.
a. 42 = 16 log4(16) = 2
b. w = u2+v
To convert the exp-form to the log–form:
b = y
x
logb( y ) = x→
38. The Logarithmic Functions
Example A. Rewrite the exp-form into the log-form.
a. 42 = 16 log4(16) = 2
b. w = u2+v
To convert the exp-form to the log–form:
b = y
x
logb( y ) = x→
39. The Logarithmic Functions
Example A. Rewrite the exp-form into the log-form.
a. 42 = 16 log4(16) = 2
b. w = u2+v
To convert the exp-form to the log–form:
b = y
x
logb( y ) = x→
40. The Logarithmic Functions
Example A. Rewrite the exp-form into the log-form.
a. 42 = 16 log4(16) = 2
b. w = u2+v logu(w) = 2+v
To convert the exp-form to the log–form:
b = y
x
logb( y ) = x→
41. The Logarithmic Functions
Example A. Rewrite the exp-form into the log-form.
a. 42 = 16 log4(16) = 2
b. w = u2+v logu(w) = 2+v
To convert the exp-form to the log–form:
b = y
x
logb( y ) = x→
42. The Logarithmic Functions
Example A. Rewrite the exp-form into the log-form.
a. 42 = 16 log4(16) = 2
b. w = u2+v logu(w) = 2+v
To convert the exp-form to the log–form:
b = y
x
logb( y ) = x→
43. The Logarithmic Functions
Example A. Rewrite the exp-form into the log-form.
a. 42 = 16 log4(16) = 2
b. w = u2+v logu(w) = 2+v
To convert the exp-form to the log–form:
b = y
x
→
To convert the log–form to the exp–form:
logb( y ) = x
logb( y ) = x
44. The Logarithmic Functions
Example A. Rewrite the exp-form into the log-form.
a. 42 = 16 log4(16) = 2
b. w = u2+v logu(w) = 2+v
To convert the exp-form to the log–form:
b = y
x
→
To convert the log–form to the exp–form:
b = y
x
logb( y ) = x→
logb( y ) = x
45. The Logarithmic Functions
Example A. Rewrite the exp-form into the log-form.
a. 42 = 16 log4(16) = 2
b. w = u2+v logu(w) = 2+v
To convert the exp-form to the log–form:
b = y
x
→
To convert the log–form to the exp–form:
b = y
x
logb( y ) = x→
logb( y ) = x
46. The Logarithmic Functions
Example A. Rewrite the exp-form into the log-form.
a. 42 = 16 log4(16) = 2
b. w = u2+v logu(w) = 2+v
To convert the exp-form to the log–form:
b = y
x
→
To convert the log–form to the exp–form:
b = y
x
logb( y ) = x→
logb( y ) = x
47. The Logarithmic Functions
Example B. Rewrite the log-form into the exp-form.
a. log3(1/9) = –2
b. 2w = logv(a – b)
Example A. Rewrite the exp-form into the log-form.
a. 42 = 16 log4(16) = 2
b. w = u2+v logu(w) = 2+v
To convert the exp-form to the log–form:
b = y
x
logb( y ) = x→
To convert the log–form to the exp–form:
b = y
x
logb( y ) = x→
48. The Logarithmic Functions
Example B. Rewrite the log-form into the exp-form.
a. log3(1/9) = –2 3-2 = 1/9
b. 2w = logv(a – b)
Example A. Rewrite the exp-form into the log-form.
a. 42 = 16 log4(16) = 2
b. w = u2+v logu(w) = 2+v
To convert the exp-form to the log–form:
b = y
x
logb( y ) = x→
To convert the log–form to the exp–form:
b = y
x
logb( y ) = x→
49. The Logarithmic Functions
Example B. Rewrite the log-form into the exp-form.
a. log3(1/9) = –2 3-2 = 1/9
b. 2w = logv(a – b)
Example A. Rewrite the exp-form into the log-form.
a. 42 = 16 log4(16) = 2
b. w = u2+v logu(w) = 2+v
To convert the exp-form to the log–form:
b = y
x
logb( y ) = x→
To convert the log–form to the exp–form:
b = y
x
logb( y ) = x→
50. The Logarithmic Functions
Example B. Rewrite the log-form into the exp-form.
a. log3(1/9) = –2 3-2 = 1/9
b. 2w = logv(a – b)
Example A. Rewrite the exp-form into the log-form.
a. 42 = 16 log4(16) = 2
b. w = u2+v logu(w) = 2+v
To convert the exp-form to the log–form:
b = y
x
logb( y ) = x→
To convert the log–form to the exp–form:
b = y
x
logb( y ) = x→
51. The Logarithmic Functions
Example B. Rewrite the log-form into the exp-form.
a. log3(1/9) = –2 3-2 = 1/9
b. 2w = logv(a – b) v2w = a – b
Example A. Rewrite the exp-form into the log-form.
a. 42 = 16 log4(16) = 2
b. w = u2+v logu(w) = 2+v
To convert the exp-form to the log–form:
b = y
x
logb( y ) = x→
To convert the log–form to the exp–form:
b = y
x
logb( y ) = x→
52. The Logarithmic Functions
Example B. Rewrite the log-form into the exp-form.
a. log3(1/9) = –2 3-2 = 1/9
b. 2w = logv(a – b) v2w = a – b
Example A. Rewrite the exp-form into the log-form.
a. 42 = 16 log4(16) = 2
b. w = u2+v logu(w) = 2+v
To convert the exp-form to the log–form:
b = y
x
logb( y ) = x→
To convert the log–form to the exp–form:
b = y
x
logb( y ) = x→
53. The Logarithmic Functions
Example B. Rewrite the log-form into the exp-form.
a. log3(1/9) = –2 3-2 = 1/9
b. 2w = logv(a – b) v2w = a – b
Example A. Rewrite the exp-form into the log-form.
a. 42 = 16 log4(16) = 2
b. w = u2+v logu(w) = 2+v
To convert the exp-form to the log–form:
b = y
x
logb( y ) = x→
To convert the log–form to the exp–form:
b = y
x
logb( y ) = x→
54. The Logarithmic Functions
Example B. Rewrite the log-form into the exp-form.
a. log3(1/9) = –2 3-2 = 1/9
b. 2w = logv(a – b) v2w = a – b
Example A. Rewrite the exp-form into the log-form.
a. 42 = 16 log4(16) = 2
b. w = u2+v logu(w) = 2+v
To convert the exp-form to the log–form:
b = y
x
logb( y ) = x→
To convert the log–form to the exp–form:
b = y
x
logb( y ) = x→
The output of logb(x), i.e. the exponent in the defined
relation, may be positive or negative.
55. The Logarithmic Functions
Example C.
a. Rewrite the exp-form into the log-form.
4–3 = 1/64
8–2 = 1/64
log4(1/64) = –3
log8(1/64) = –2
exp–form log–form
b. Rewrite the log-form into the exp-form.
(1/2)–2 = 4log1/2(4) = –2
log1/2(8) = –3
exp–formlog–form
(1/2)–3 = 8
56. The Logarithmic Functions
The Common Log and the Natural Log
Example C.
a. Rewrite the exp-form into the log-form.
4–3 = 1/64
8–2 = 1/64
log4(1/64) = –3
log8(1/64) = –2
exp–form log–form
b. Rewrite the log-form into the exp-form.
(1/2)–2 = 4log1/2(4) = –2
log1/2(8) = –3
exp–formlog–form
(1/2)–3 = 8
57. The Logarithmic Functions
Base 10 is called the common base.
The Common Log and the Natural Log
Example C.
a. Rewrite the exp-form into the log-form.
4–3 = 1/64
8–2 = 1/64
log4(1/64) = –3
log8(1/64) = –2
exp–form log–form
b. Rewrite the log-form into the exp-form.
(1/2)–2 = 4log1/2(4) = –2
log1/2(8) = –3
exp–formlog–form
(1/2)–3 = 8
58. The Logarithmic Functions
Base 10 is called the common base. Log with
base10, written as log(x) without the base number b,
is called the common log,
The Common Log and the Natural Log
Example C.
a. Rewrite the exp-form into the log-form.
4–3 = 1/64
8–2 = 1/64
log4(1/64) = –3
log8(1/64) = –2
exp–form log–form
b. Rewrite the log-form into the exp-form.
(1/2)–2 = 4log1/2(4) = –2
log1/2(8) = –3
exp–formlog–form
(1/2)–3 = 8
59. The Logarithmic Functions
Base 10 is called the common base. Log with
base10, written as log(x) without the base number b,
is called the common log, i.e. log(x) is log10(x).
The Common Log and the Natural Log
Example C.
a. Rewrite the exp-form into the log-form.
4–3 = 1/64
8–2 = 1/64
log4(1/64) = –3
log8(1/64) = –2
exp–form log–form
b. Rewrite the log-form into the exp-form.
(1/2)–2 = 4log1/2(4) = –2
log1/2(8) = –3
exp–formlog–form
(1/2)–3 = 8
60. Base e is called the natural base.
The Common Log and the Natural Log
61. Base e is called the natural base.
Log with base e is written as ln(x) and it’s called
the natural log,
The Common Log and the Natural Log
62. Base e is called the natural base.
Log with base e is written as ln(x) and it’s called
the natural log, i.e. In(x) is loge(x).
The Common Log and the Natural Log
63. Base e is called the natural base.
Log with base e is written as ln(x) and it’s called
the natural log, i.e. In(x) is loge(x).
The Common Log and the Natural Log
Example D. Convert to the other form.
exp-form log-form
103 = 1000
ln(1/e2) = -2
ert =
log(1) = 0
A
P
64. Base e is called the natural base.
Log with base e is written as ln(x) and it’s called
the natural log, i.e. In(x) is loge(x).
The Common Log and the Natural Log
Example D. Convert to the other form.
exp-form log-form
103 = 1000 log(1000) = 3
ln(1/e2) = -2
ert =
log(1) = 0
A
P
65. Base e is called the natural base.
Log with base e is written as ln(x) and it’s called
the natural log, i.e. In(x) is loge(x).
The Common Log and the Natural Log
Example D. Convert to the other form.
exp-form log-form
103 = 1000 log(1000) = 3
e-2 = 1/e2 ln(1/e2) = -2
ert =
log(1) = 0
A
P
66. Base e is called the natural base.
Log with base e is written as ln(x) and it’s called
the natural log, i.e. In(x) is loge(x).
The Common Log and the Natural Log
Example D. Convert to the other form.
exp-form log-form
103 = 1000 log(1000) = 3
e-2 = 1/e2 ln(1/e2) = -2
ert = ln( ) = rt
log(1) = 0
A
P
A
P
67. Base e is called the natural base.
Log with base e is written as ln(x) and it’s called
the natural log, i.e. In(x) is loge(x).
The Common Log and the Natural Log
Example D. Convert to the other form.
exp-form log-form
103 = 1000 log(1000) = 3
e-2 = 1/e2 ln(1/e2) = -2
ert = ln( ) = rt
100 = 1 log(1) = 0
A
P
A
P
68. Base e is called the natural base.
Log with base e is written as ln(x) and it’s called
the natural log, i.e. In(x) is loge(x).
The Common Log and the Natural Log
Example D. Convert to the other form.
exp-form log-form
103 = 1000 log(1000) = 3
e-2 = 1/e2 ln(1/e2) = -2
ert = ln( ) = rt
100 = 1 log(1) = 0
A
P
A
P
Most log and powers can’t be computed efficiently by
hand.
69. Base e is called the natural base.
Log with base e is written as ln(x) and it’s called
the natural log, i.e. In(x) is loge(x).
The Common Log and the Natural Log
Example D. Convert to the other form.
exp-form log-form
103 = 1000 log(1000) = 3
e-2 = 1/e2 ln(1/e2) = -2
ert = ln( ) = rt
100 = 1 log(1) = 0
A
P
A
P
Most log and powers can’t be computed efficiently by
hand. We need a calculation device to extract
numerical solutions.
70. The Common Log and the Natural Log
Example E. Calculate each of the following logs
using a calculator. Then convert the relation into the
exp–form and confirm the exp–form with a calculator.
a. log(50) =
71. The Common Log and the Natural Log
Example E. Calculate each of the following logs
using a calculator. Then convert the relation into the
exp–form and confirm the exp–form with a calculator.
a. log(50) = 1.69897...
72. The Common Log and the Natural Log
Example E. Calculate each of the following logs
using a calculator. Then convert the relation into the
exp–form and confirm the exp–form with a calculator.
a. log(50) = 1.69897...
In the exp–form, it’s101.69897 =
73. The Common Log and the Natural Log
Example E. Calculate each of the following logs
using a calculator. Then convert the relation into the
exp–form and confirm the exp–form with a calculator.
a. log(50) = 1.69897...
In the exp–form, it’s101.69897 = 49.9999995...≈50
74. The Common Log and the Natural Log
Example E. Calculate each of the following logs
using a calculator. Then convert the relation into the
exp–form and confirm the exp–form with a calculator.
a. log(50) = 1.69897...
In the exp–form, it’s101.69897 = 49.9999995...≈50
b. ln(9) =
75. The Common Log and the Natural Log
Example E. Calculate each of the following logs
using a calculator. Then convert the relation into the
exp–form and confirm the exp–form with a calculator.
a. log(50) = 1.69897...
In the exp–form, it’s101.69897 = 49.9999995...≈50
b. ln(9) = 2.1972245..
76. The Common Log and the Natural Log
Example E. Calculate each of the following logs
using a calculator. Then convert the relation into the
exp–form and confirm the exp–form with a calculator.
a. log(50) = 1.69897...
In the exp–form, it’s101.69897 = 49.9999995...≈50
b. ln(9) = 2.1972245..
In the exp–form, it’s e2.1972245 =
77. The Common Log and the Natural Log
Example E. Calculate each of the following logs
using a calculator. Then convert the relation into the
exp–form and confirm the exp–form with a calculator.
a. log(50) = 1.69897...
In the exp–form, it’s101.69897 = 49.9999995...≈50
b. ln(9) = 2.1972245..
In the exp–form, it’s e2.1972245 = 8.9999993...≈ 9
78. The Common Log and the Natural Log
Example E. Calculate each of the following logs
using a calculator. Then convert the relation into the
exp–form and confirm the exp–form with a calculator.
a. log(50) = 1.69897...
In the exp–form, it’s101.69897 = 49.9999995...≈50
b. ln(9) = 2.1972245..
c. Calculate the power using a calculator.
Then convert the relation into the log–form and
confirm the log–form by the calculator.
e4.3 =
In the exp–form, it’s e2.1972245 = 8.9999993...≈ 9
79. The Common Log and the Natural Log
Example E. Calculate each of the following logs
using a calculator. Then convert the relation into the
exp–form and confirm the exp–form with a calculator.
a. log(50) = 1.69897...
In the exp–form, it’s101.69897 = 49.9999995...≈50
b. ln(9) = 2.1972245..
c. Calculate the power using a calculator.
Then convert the relation into the log–form and
confirm the log–form by the calculator.
e4.3 = 73.699793..
In the exp–form, it’s e2.1972245 = 8.9999993...≈ 9
80. The Common Log and the Natural Log
Example E. Calculate each of the following logs
using a calculator. Then convert the relation into the
exp–form and confirm the exp–form with a calculator.
a. log(50) = 1.69897...
In the exp–form, it’s101.69897 = 49.9999995...≈50
b. ln(9) = 2.1972245..
c. Calculate the power using a calculator.
Then convert the relation into the log–form and
confirm the log–form by the calculator.
e4.3 = 73.699793..→ In(73.699793) =
In the exp–form, it’s e2.1972245 = 8.9999993...≈ 9
81. The Common Log and the Natural Log
Example E. Calculate each of the following logs
using a calculator. Then convert the relation into the
exp–form and confirm the exp–form with a calculator.
a. log(50) = 1.69897...
In the exp–form, it’s101.69897 = 49.9999995...≈50
b. ln(9) = 2.1972245..
c. Calculate the power using a calculator.
Then convert the relation into the log–form and
confirm the log–form by the calculator.
e4.3 = 73.699793..→ In(73.699793) = 4.299999..≈ 4.3
In the exp–form, it’s e2.1972245 = 8.9999993...≈ 9
82. The Common Log and the Natural Log
Example E. Calculate each of the following logs
using a calculator. Then convert the relation into the
exp–form and confirm the exp–form with a calculator.
a. log(50) = 1.69897...
In the exp–form, it’s101.69897 = 49.9999995...≈50
b. ln(9) = 2.1972245..
c. Calculate the power using a calculator.
Then convert the relation into the log–form and
confirm the log–form by the calculator.
e4.3 = 73.699793..→ In(73.699793) = 4.299999..≈ 4.3
Your turn. Follow the instructions in part c for 10π.
In the exp–form, it’s e2.1972245 = 8.9999993...≈ 9
83. Equations may be formed with log–notation.
The Common Log and the Natural Log
84. Equations may be formed with log–notation. Often we
need to restate them in the exp–form.
The Common Log and the Natural Log
85. Equations may be formed with log–notation. Often we
need to restate them in the exp–form. We say we
"drop the log" when this step is taken.
The Common Log and the Natural Log
86. Example F. Solve for x
a. log9(x) = –1
Equations may be formed with log–notation. Often we
need to restate them in the exp–form. We say we
"drop the log" when this step is taken.
The Common Log and the Natural Log
87. Example F. Solve for x
a. log9(x) = –1
Drop the log and get x = 9–1.
Equations may be formed with log–notation. Often we
need to restate them in the exp–form. We say we
"drop the log" when this step is taken.
The Common Log and the Natural Log
88. Example F. Solve for x
a. log9(x) = –1
Drop the log and get x = 9–1.
So x = 1/9
Equations may be formed with log–notation. Often we
need to restate them in the exp–form. We say we
"drop the log" when this step is taken.
The Common Log and the Natural Log
89. Example F. Solve for x
a. log9(x) = –1
Drop the log and get x = 9–1.
So x = 1/9
b. logx(9) = –2
Equations may be formed with log–notation. Often we
need to restate them in the exp–form. We say we
"drop the log" when this step is taken.
The Common Log and the Natural Log
90. Example F. Solve for x
a. log9(x) = –1
Drop the log and get x = 9–1.
So x = 1/9
b. logx(9) = –2
Drop the log and get 9 = x–2,
Equations may be formed with log–notation. Often we
need to restate them in the exp–form. We say we
"drop the log" when this step is taken.
The Common Log and the Natural Log
91. Example F. Solve for x
a. log9(x) = –1
Drop the log and get x = 9–1.
So x = 1/9
b. logx(9) = –2
Drop the log and get 9 = x–2, i.e. 9 =
1
x2
Equations may be formed with log–notation. Often we
need to restate them in the exp–form. We say we
"drop the log" when this step is taken.
The Common Log and the Natural Log
92. Example F. Solve for x
a. log9(x) = –1
Drop the log and get x = 9–1.
So x = 1/9
b. logx(9) = –2
Drop the log and get 9 = x–2, i.e. 9 =
So 9x2 = 1
1
x2
Equations may be formed with log–notation. Often we
need to restate them in the exp–form. We say we
"drop the log" when this step is taken.
The Common Log and the Natural Log
93. Example F. Solve for x
a. log9(x) = –1
Drop the log and get x = 9–1.
So x = 1/9
b. logx(9) = –2
Drop the log and get 9 = x–2, i.e. 9 =
So 9x2 = 1
x2 = 1/9
x = 1/3 or x= –1/3
1
x2
Equations may be formed with log–notation. Often we
need to restate them in the exp–form. We say we
"drop the log" when this step is taken.
The Common Log and the Natural Log
94. Example F. Solve for x
a. log9(x) = –1
Drop the log and get x = 9–1.
So x = 1/9
b. logx(9) = –2
Drop the log and get 9 = x–2, i.e. 9 =
So 9x2 = 1
x2 = 1/9
x = 1/3 or x= –1/3
Since the base b > 0, so x = 1/3 is the only solution.
1
x2
Equations may be formed with log–notation. Often we
need to restate them in the exp–form. We say we
"drop the log" when this step is taken.
The Common Log and the Natural Log
96. The Logarithmic Functions
Graphs of the Logarithmic Functions
1/4
1/2
1
2
4
8
x y=log2(x)
Recall that the domain of logb(x) is the set of all x > 0.
Hence to make a table to plot the graph of y = log2(x),
we only select positive x’s.
97. The Logarithmic Functions
Graphs of the Logarithmic Functions
2
4
8
x y=log2(x)
Recall that the domain of logb(x) is the set of all x > 0.
Hence to make a table to plot the graph of y = log2(x),
we only select positive x’s. In particular we select x’s
related to base 2 for easy computation of the y’s.
98. The Logarithmic Functions
Graphs of the Logarithmic Functions
1/4
1/2
1
2
4
8
x y=log2(x)
Recall that the domain of logb(x) is the set of all x > 0.
Hence to make a table to plot the graph of y = log2(x),
we only select positive x’s. In particular we select x’s
related to base 2 for easy computation of the y’s.
99. The Logarithmic Functions
Graphs of the Logarithmic Functions
1/4 -2
1/2
1
2
4
8
x y=log2(x)
Recall that the domain of logb(x) is the set of all x > 0.
Hence to make a table to plot the graph of y = log2(x),
we only select positive x’s. In particular we select x’s
related to base 2 for easy computation of the y’s.
100. The Logarithmic Functions
Graphs of the Logarithmic Functions
1/4 -2
1/2 -1
1
2
4
8
x y=log2(x)
Recall that the domain of logb(x) is the set of all x > 0.
Hence to make a table to plot the graph of y = log2(x),
we only select positive x’s. In particular we select x’s
related to base 2 for easy computation of the y’s.
101. The Logarithmic Functions
Graphs of the Logarithmic Functions
1/4 -2
1/2 -1
1 0
2
4
8
x y=log2(x)
Recall that the domain of logb(x) is the set of all x > 0.
Hence to make a table to plot the graph of y = log2(x),
we only select positive x’s. In particular we select x’s
related to base 2 for easy computation of the y’s.
102. The Logarithmic Functions
Graphs of the Logarithmic Functions
1/4 -2
1/2 -1
1 0
2 1
4
8
x y=log2(x)
Recall that the domain of logb(x) is the set of all x > 0.
Hence to make a table to plot the graph of y = log2(x),
we only select positive x’s. In particular we select x’s
related to base 2 for easy computation of the y’s.
103. The Logarithmic Functions
Graphs of the Logarithmic Functions
1/4 -2
1/2 -1
1 0
2 1
4 2
8 3
x y=log2(x)
Recall that the domain of logb(x) is the set of all x > 0.
Hence to make a table to plot the graph of y = log2(x),
we only select positive x’s. In particular we select x’s
related to base 2 for easy computation of the y’s.
104. The Logarithmic Functions
(1, 0)
(2, 1)
(4, 2)
(8, 3)
(16, 4)
(1/2, -1)
(1/4, -2)
y=log2(x)
Graphs of the Logarithmic Functions
1/4 -2
1/2 -1
1 0
2 1
4 2
8 3
x y=log2(x)
Recall that the domain of logb(x) is the set of all x > 0.
Hence to make a table to plot the graph of y = log2(x),
we only select positive x’s. In particular we select x’s
related to base 2 for easy computation of the y’s.
x
y
105. The Logarithmic Functions
To graph log with base b = ½, we have
log1/2(4) = –2, log1/2(8) = –3, log1/2(16) = –4
106. The Logarithmic Functions
x
y
(1, 0)
(8, -3)
To graph log with base b = ½, we have
log1/2(4) = –2, log1/2(8) = –3, log1/2(16) = –4
(4, -2)
(16, -4)
y = log1/2(x)
107. The Logarithmic Functions
x
y
(1, 0)
(8, -3)
To graph log with base b = ½, we have
log1/2(4) = –2, log1/2(8) = –3, log1/2(16) = –4
(4, -2)
(16, -4)
y = log1/2(x)
x x
y
(1, 0)(1, 0)
y = logb(x), b > 1
y = logb(x), 1 > b
Here are the general shapes of log–functions.
y
(b, 1)
(b, 1)
108. 1. b0 = 1
2. br · bt = br+t
3. = br-t
4. (br)t = brt
bt
br
Properties of Logarithm
Recall the following
Rules of Exponents:
The corresponding
Rules of Logs are:
109. 1. logb(1) = 01. b0 = 1
2. br · bt = br+t
3. = br-t
4. (br)t = brt
bt
br
Properties of Logarithm
Recall the following
Rules of Exponents:
The corresponding
Rules of Logs are:
110. 1. logb(1) = 0
2. logb(x·y) = logb(x)+logb(y)
1. b0 = 1
2. br · bt = br+t
3. = br-t
4. (br)t = brt
bt
br
Properties of Logarithm
Recall the following
Rules of Exponents:
The corresponding
Rules of Logs are:
111. 1. logb(1) = 0
2. logb(x·y) = logb(x)+logb(y)
3. logb( ) = logb(x) – logb(y)x
y
1. b0 = 1
2. br · bt = br+t
3. = br-t
4. (br)t = brt
bt
br
Properties of Logarithm
Recall the following
Rules of Exponents:
The corresponding
Rules of Logs are:
112. 1. logb(1) = 0
2. logb(x·y) = logb(x)+logb(y)
3. logb( ) = logb(x) – logb(y)
4. logb(xt) = t·logb(x)
x
y
1. b0 = 1
2. br · bt = br+t
3. = br-t
4. (br)t = brt
bt
br
Properties of Logarithm
Recall the following
Rules of Exponents:
The corresponding
Rules of Logs are:
113. 1. logb(1) = 0
2. logb(x·y) = logb(x)+logb(y)
3. logb( ) = logb(x) – logb(y)
4. logb(xt) = t·logb(x)
x
y
1. b0 = 1
2. br · bt = br+t
3. = br-t
4. (br)t = brt
bt
br
Properties of Logarithm
Recall the following
Rules of Exponents:
The corresponding
Rules of Logs are:
We veryify part 2: logb(xy) = logb(x) + logb(y), x, y > 0.
Proof:
114. 1. logb(1) = 0
2. logb(x·y) = logb(x)+logb(y)
3. logb( ) = logb(x) – logb(y)
4. logb(xt) = t·logb(x)
x
y
1. b0 = 1
2. br · bt = br+t
3. = br-t
4. (br)t = brt
bt
br
Properties of Logarithm
Recall the following
Rules of Exponents:
The corresponding
Rules of Logs are:
We veryify part 2: logb(xy) = logb(x) + logb(y), x, y > 0.
Proof:
Let x and y be two positive numbers.
115. 1. logb(1) = 0
2. logb(x·y) = logb(x)+logb(y)
3. logb( ) = logb(x) – logb(y)
4. logb(xt) = t·logb(x)
x
y
1. b0 = 1
2. br · bt = br+t
3. = br-t
4. (br)t = brt
bt
br
Properties of Logarithm
Recall the following
Rules of Exponents:
The corresponding
Rules of Logs are:
We veryify part 2: logb(xy) = logb(x) + logb(y), x, y > 0.
Proof:
Let x and y be two positive numbers. Let logb(x) = r
and logb(y) = t, which in exp-form are x = br and y = bt.
116. 1. logb(1) = 0
2. logb(x·y) = logb(x)+logb(y)
3. logb( ) = logb(x) – logb(y)
4. logb(xt) = t·logb(x)
x
y
1. b0 = 1
2. br · bt = br+t
3. = br-t
4. (br)t = brt
bt
br
Properties of Logarithm
Recall the following
Rules of Exponents:
The corresponding
Rules of Logs are:
We veryify part 2: logb(xy) = logb(x) + logb(y), x, y > 0.
Proof:
Let x and y be two positive numbers. Let logb(x) = r
and logb(y) = t, which in exp-form are x = br and y = bt.
Therefore x·y = br+t,
117. 1. logb(1) = 0
2. logb(x·y) = logb(x)+logb(y)
3. logb( ) = logb(x) – logb(y)
4. logb(xt) = t·logb(x)
x
y
1. b0 = 1
2. br · bt = br+t
3. = br-t
4. (br)t = brt
bt
br
Properties of Logarithm
Recall the following
Rules of Exponents:
The corresponding
Rules of Logs are:
We veryify part 2: logb(xy) = logb(x) + logb(y), x, y > 0.
Proof:
Let x and y be two positive numbers. Let logb(x) = r
and logb(y) = t, which in exp-form are x = br and y = bt.
Therefore x·y = br+t, which in log-form is
logb(x·y) = r + t = logb(x)+logb(y).
118. 1. logb(1) = 0
2. logb(x·y) = logb(x)+logb(y)
3. logb( ) = logb(x) – logb(y)
4. logb(xt) = t·logb(x)
x
y
1. b0 = 1
2. br · bt = br+t
3. = br-t
4. (br)t = brt
bt
br
Properties of Logarithm
Recall the following
Rules of Exponents:
The corresponding
Rules of Logs are:
We veryify part 2: logb(xy) = logb(x) + logb(y), x, y > 0.
Proof:
Let x and y be two positive numbers. Let logb(x) = r
and logb(y) = t, which in exp-form are x = br and y = bt.
Therefore x·y = br+t, which in log-form is
logb(x·y) = r + t = logb(x)+logb(y).
The other rules may be verified similarly.
120. 3x2
y
log( ) = log( ),3x2
y
3x2
y1/2
Properties of Logarithm
a. Write log( ) in terms of log(x) and log(y).
Example G.
121. 3x2
y
log( ) = log( ), by the quotient rule
= log (3x2) – log(y1/2)
3x2
y
3x2
y1/2
Properties of Logarithm
a. Write log( ) in terms of log(x) and log(y).
Example G.
122. 3x2
y
log( ) = log( ), by the quotient rule
= log (3x2) – log(y1/2)
product rule
= log(3) + log(x2)
3x2
y
3x2
y1/2
Properties of Logarithm
a. Write log( ) in terms of log(x) and log(y).
Example G.
123. 3x2
y
log( ) = log( ), by the quotient rule
= log (3x2) – log(y1/2)
product rule power rule
= log(3) + log(x2) – ½ log(y)
3x2
y
3x2
y1/2
Properties of Logarithm
a. Write log( ) in terms of log(x) and log(y).
Example G.
124. 3x2
y
log( ) = log( ), by the quotient rule
= log (3x2) – log(y1/2)
product rule power rule
= log(3) + log(x2) – ½ log(y)
= log(3) + 2log(x) – ½ log(y)
3x2
y
3x2
y1/2
Properties of Logarithm
a. Write log( ) in terms of log(x) and log(y).
Example G.
125. 3x2
y
log( ) = log( ), by the quotient rule
= log (3x2) – log(y1/2)
product rule power rule
= log(3) + log(x2) – ½ log(y)
= log(3) + 2log(x) – ½ log(y)
3x2
y
3x2
y1/2
Properties of Logarithm
a. Write log( ) in terms of log(x) and log(y).
b. Combine log(3) + 2log(x) – ½ log(y) into one log.
Example G.
126. 3x2
y
log( ) = log( ), by the quotient rule
= log (3x2) – log(y1/2)
product rule power rule
= log(3) + log(x2) – ½ log(y)
= log(3) + 2log(x) – ½ log(y)
3x2
y
3x2
y1/2
Properties of Logarithm
a. Write log( ) in terms of log(x) and log(y).
log(3) + 2log(x) – ½ log(y) power rule
= log(3) + log(x2) – log(y1/2)
b. Combine log(3) + 2log(x) – ½ log(y) into one log.
Example G.
127. 3x2
y
log( ) = log( ), by the quotient rule
= log (3x2) – log(y1/2)
product rule power rule
= log(3) + log(x2) – ½ log(y)
= log(3) + 2log(x) – ½ log(y)
3x2
y
3x2
y1/2
Properties of Logarithm
a. Write log( ) in terms of log(x) and log(y).
log(3) + 2log(x) – ½ log(y) power rule
= log(3) + log(x2) – log(y1/2) product rule
= log (3x2) – log(y1/2)
b. Combine log(3) + 2log(x) – ½ log(y) into one log.
Example G.
128. 3x2
y
log( ) = log( ), by the quotient rule
= log (3x2) – log(y1/2)
product rule power rule
= log(3) + log(x2) – ½ log(y)
= log(3) + 2log(x) – ½ log(y)
3x2
y
3x2
y1/2
Properties of Logarithm
a. Write log( ) in terms of log(x) and log(y).
log(3) + 2log(x) – ½ log(y) power rule
= log(3) + log(x2) – log(y1/2) product rule
= log (3x2) – log(y1/2)= log( )3x2
y1/2
b. Combine log(3) + 2log(x) – ½ log(y) into one log.
Example G.
quotient rule
129. Recall that given a pair of inverse functions, f and f -1,
then f(f -1(x)) = x and f -1(f(x)) = x.
Properties of Logarithm
130. Recall that given a pair of inverse functions, f and f -1,
then f(f -1(x)) = x and f -1(f(x)) = x. Let expb(x) ≡ bx.
Properties of Logarithm
131. Recall that given a pair of inverse functions, f and f -1,
then f(f -1(x)) = x and f -1(f(x)) = x. Let expb(x) ≡ bx.
Since expb(x) and logb(x) is a pair of inverse functions,
we have that:
a. logb(expb(x)) = x or logb(bx) = x
Properties of Logarithm
132. Recall that given a pair of inverse functions, f and f -1,
then f(f -1(x)) = x and f -1(f(x)) = x. Let expb(x) ≡ bx.
Since expb(x) and logb(x) is a pair of inverse functions,
we have that:
a. logb(expb(x)) = x or logb(bx) = x
b. expb(logb(x)) = x or blog (x) = x
Properties of Logarithm
b
133. Recall that given a pair of inverse functions, f and f -1,
then f(f -1(x)) = x and f -1(f(x)) = x. Let expb(x) ≡ bx.
Since expb(x) and logb(x) is a pair of inverse functions,
we have that:
a. logb(expb(x)) = x or logb(bx) = x
b. expb(logb(x)) = x or blog (x) = x
Properties of Logarithm
b
Example H. Simplify
a. log2(2-5) =
b. 8log (xy) =
c. e2+ln(7) =
8
134. Recall that given a pair of inverse functions, f and f -1,
then f(f -1(x)) = x and f -1(f(x)) = x. Let expb(x) ≡ bx.
Since expb(x) and logb(x) is a pair of inverse functions,
we have that:
a. logb(expb(x)) = x or logb(bx) = x
b. expb(logb(x)) = x or blog (x) = x
Properties of Logarithm
b
Example H. Simplify
a. log2(2-5) = -5
b. 8log (xy) =
c. e2+ln(7) =
8
135. Recall that given a pair of inverse functions, f and f -1,
then f(f -1(x)) = x and f -1(f(x)) = x. Let expb(x) ≡ bx.
Since expb(x) and logb(x) is a pair of inverse functions,
we have that:
a. logb(expb(x)) = x or logb(bx) = x
b. expb(logb(x)) = x or blog (x) = x
Properties of Logarithm
b
Example H. Simplify
a. log2(2-5) = -5
b. 8log (xy) = xy
c. e2+ln(7) =
8
136. Recall that given a pair of inverse functions, f and f -1,
then f(f -1(x)) = x and f -1(f(x)) = x. Let expb(x) ≡ bx.
Since expb(x) and logb(x) is a pair of inverse functions,
we have that:
a. logb(expb(x)) = x or logb(bx) = x
b. expb(logb(x)) = x or blog (x) = x
Properties of Logarithm
b
Example H. Simplify
a. log2(2-5) = -5
b. 8log (xy) = xy
c. e2+ln(7) = e2·eln(7)
8
137. Recall that given a pair of inverse functions, f and f -1,
then f(f -1(x)) = x and f -1(f(x)) = x. Let expb(x) ≡ bx.
Since expb(x) and logb(x) is a pair of inverse functions,
we have that:
a. logb(expb(x)) = x or logb(bx) = x
b. expb(logb(x)) = x or blog (x) = x
Properties of Logarithm
b
Example H. Simplify
a. log2(2-5) = -5
b. 8log (xy) = xy
c. e2+ln(7) = e2·eln(7) = 7e2
8
138. Recall that given a pair of inverse functions, f and f -1,
then f(f -1(x)) = x and f -1(f(x)) = x. Let expb(x) ≡ bx.
Since expb(x) and logb(x) is a pair of inverse functions,
we have that:
a. logb(expb(x)) = x or logb(bx) = x
b. expb(logb(x)) = x or blog (x) = x
Properties of Logarithm
b
Example H. Simplify
a. log2(2-5) = -5
b. 8log (xy) = xy
c. e2+ln(7) = e2·eln(7) = 7e2
8
Logb(x) and expb(x) along with trig. and inverse trig.
functions are the most important explicit inverse
function pairs in mathematics.
139. 1.
Exercise A. Rewrite the following exp-form into the log-form.
2. 3.
4. 5. 6.
7. 8. 9.
10.
The Logarithmic Functions
Exercise B. Rewrite the following log–form into the exp-form.
52 = 25 33 = 27
1/25 = 5–2 x3 = y
y3 = x ep = a + b
e(a + b) = p 10x–y = z11. 12.
1/25 = 5–2
1/27 = 3–3
1/a = b–2
A = e–rt
log3(1/9) = –2 –2 = log4(1/16)13. 14. log1/3(9) = –215.
2w = logv(a – b)17. logv(2w) = a – b18.log1/4(16) = –216.
log (1/100) = –2 1/2 = log(√10)19. 20. ln(1/e2) = –221.
rt = ln(ert)23. ln(1/√e) = –1/224.log (A/B) = 322.
140. Exercise C. Convert the following into the exponential form
then solve for x.
The Logarithmic Functions
logx(9) = 2 x = log2(8)1. 2. log3(x) = 23.
5. 6.4.
7. 9.8.
logx(x) = 2 2 = log2(x) logx(x + 2) = 2
log1/2(4) = x 4 = log1/2(x) logx(4) = 1/2
11. 12.10.
13. 15.14.
ln(x) = 2 2 = log(x) log(4x + 15) = 2
In(x) = –1/2 a = In(2x – 3) log(x2 – 15x) = 2
143. Continuous Compound Interest
F. Given the following projection of the world
populations, find the growth rate between each
two consecutive data.
Is there a trend in the growth rates used?