Question 1

Solve the equation. $$\left( \frac { 4 } { 5 } \right) ^ { x } = \frac { 625 } { 256 }$$&#10;A)x = 6&#10;B)x = -4&#10;C)x = -6&#10;D)x = -5&#10;E)x = 4

Accepted Answer

x = -4&#10;

Question 2

Graph the exponential function. $$f ( x ) = e ^ { - x }$$&#10;A)  &#10;B)  &#10;C)  &#10;D)

Accepted Answer

11ec1c5f_a150_5509_bb8d_4750016a2d6f_TBX8966_11

Question 3

Suppose that the present population of a city is 550,000. Use the equation P ( t )= 550,000 e^{0.034 t} to estimate future growth. Estimate the population 50 years from now. A)P = 3,012,651 B)P = 3,010,671 C)P = 3,010,093 D)P = 3,010,805 E)P = 3,010,950

Accepted Answer

P = 3,010,671

Question 4

Complete the following chart, which illustrates what happens to $8,000 invested at 12% for different lengths of time and different numbers of compounding periods. Round all of your answers to the nearest dollar. $\begin{array} { | c | c | c | c | c | } \hline & \text { l year } & \text { T years } & \text { 14 years } & \text { 28 years } \\\hline \text { Compounded annually } & & & & \\\hline \text { Compoundedsemiannually } & & & & \\\hline \text { Compounded quatterly } & & & & \\\hline \text { Compounded monthly } & & & & \\\hline \text { Compounded continuously } & & & & \\\hline\end{array}$

A)

\begin{array} { | c | c | c | c | } \hline 4480 & 8843 & 19548 & 95535 \\\hline 4494 & 9044 & 20447 & 104517 \\\hline 4502 & 9152 & 20938 & 109605 \\\hline 4507 & 9227 & 21284 & 113251 \\\hline 4510 & 9265 & 21462 & 115157 \\\hline\end{array}

B)

\begin{array} { | l | l | l | l | } \hline 9020 & 18531 & 42924 & 230314 \\\hline 9015 & 18454 & 42568 & 226502 \\\hline 9004 & 18303 & 41877 & 219209 \\\hline 8989 & 18087 & 40893 & 209035 \\\hline 8960 & 17685 & 39097 & 191071 \\\hline\end{array}

C)

\begin{array} { | c | c | c | c | } \hline 8960 & 17685 & 39097 & 191071 \\\hline 26966 & 54262 & 122680 & 627104 \\\hline 27012 & 54910 & 125631 & 657628 \\\hline 27044 & 55361 & 127703 & 679505 \\\hline 27060 & 55593 & 128773 & 690941 \\\hline\end{array}

D)

\begin{array} { | c | c | c | c | } \hline 8960 & 17685 & 39097 & 191071 \\\hline 8989 & 18087 & 40893 & 209035 \\\hline 9004 & 18303 & 219209 & 41877 \\\hline 9015 & 18454 & 226502 & 42568 \\\hline 9020 & 18531 & 230314 & 230314 \\\hline\end{array}

E)

\begin{array} { | l | l | l | l | } \hline 8960 & 17685 & 39097 & 191071 \\\hline 8989 & 18087 & 40893 & 209035 \\\hline 9004 & 18303 & 41877 & 219209 \\\hline 9015 & 18454 & 42568 & 226502 \\\hline 9020 & 18531 & 42924 & 230314 \\\hline\end{array}

Accepted Answer

Compounding continuously will give the largest return, followed closely by compounding daily or monthly. Compounding annually or semiannually will give the smallest return. Therefore, the best choices are E, which includes the highest returns.

Question 5

Complete the following chart, which illustrates what happens to $16,000 invested at various rates of interest for different lengths of time but always compounded continuously. Round your answers to the nearest dollar. $\begin{array} { | c | c | c | c | c | } \hline & \mathbf { 8 } \% & \mathbf { 1 0 } \% & \mathbf { 1 2 } \% & \mathbf { 1 4 } \% \\\hline 5 \text { years } & & & & \\\hline 8 \text { years } & & & & \\\hline 11 \text { years } & & & & \\\hline 14 \text { years } & & & & \\\hline 17 \text { years } & & & & \\\hline\end{array}$

A)

\begin{array} { | c | c | c | c | c | } \hline & \mathbf { 8 } \% & \mathbf { 1 0 } \% & \mathbf { 1 2 } \% & \mathbf { 1 4 } \% \\\hline 5 \text { years } & 23869 & 26380 & 29154 & 32220 \\\hline 8 \text { years } & 30344 & 35609 & 41787 & 49038 \\\hline 11 \text { years } & 38574 & 48067 & 59895 & 74633 \\\hline 14 \text { years } & 49038 & 64883 & 85849 & 113589 \\\hline 17 \text { years } & 62339 & 87583 & 123050 & 172878 \\\hline\end{array}

B)

\begin{array} { | c | c | c | c | c | } \hline & \mathbf { 8 } \% & \mathbf { 1 0 } \% & \mathbf { 1 2 } \% & \mathbf { 1 4 } \% \\\hline 5 \text { years } & 32220 & 29154 & 26380 & 23869 \\\hline 8 \text { years } & 49038 & 41787 & 35609 & 30344 \\\hline 11 \text { years } & 74633 & 59895 & 48067 & 38574 \\\hline 14 \text { years } & 113589 & 85849 & 64883 & 49038 \\\hline 17 \text { years } & 172878 & 123050 & 87583 & 62339 \\\hline\end{array}

C)

\begin{array} { | c | c | c | c | c | } \hline & \mathbf { 8 } \% & \mathbf { 1 0 } \% & \mathbf { 1 2 } \% & \mathbf { 1 4 } \% \\\hline 5 \text { years } & 47738 & 52759 & 58308 & 64440 \\\hline 8 \text { years } & 60687 & 71217 & 83574 & 98075 \\\hline 11 \text { years } & 77149 & 96133 & 119789 & 149267 \\\hline 14 \text { years } & 98075 & 129766 & 171698 & 227178 \\\hline 17 \text { years } & 124678 & 175166 & 246099 & 345757 \\\hline\end{array}

D)

\begin{array} { | c | c | c | c | c | } \hline & \mathbf { 8 } \% & \mathbf { 1 0 } \% & \mathbf { 1 2 } \% & \mathbf { 1 4 } \% \\\hline 5 \text { years } & 11935 & 13190 & 14577 & 16110 \\\hline 8 \text { years } & 15172 & 17804 & 20894 & 24519 \\\hline 11 \text { years } & 19287 & 24033 & 29947 & 37317 \\\hline 14 \text { years } & 24519 & 32442 & 42924 & 56795 \\\hline 17 \text { years } & 31170 & 43792 & 61525 & 86439 \\\hline\end{array}

E)

\begin{array} { | c | c | c | c | c | } \hline & \mathbf { 8 } \% & \mathbf { 1 0 } \% & \mathbf { 1 2 } \% & \mathbf { 1 4 } \% \\\hline 5 \text { years } & 62339 & 87583 & 123050 & 172878 \\\hline 8 \text { years } & 49038 & 64883 & 85849 & 113589 \\\hline 11 \text { years } & 38574 & 48067 & 59895 & 74633 \\\hline 14 \text { years } & 30344 & 35609 & 41787 & 49038 \\\hline 17 \text { years } & 23869 & 26380 & 29154 & 32220 \\\hline\end{array}

Accepted Answer

The correct values are calculated using the formula for continuous compounding interest, $A = P e^{rt}$, where $A$ is the amount of money accumulated after n years, including interest, $P$ is the principal amount (the initial amount of money), $r$ is the annual interest rate (decimal), and $t$ is the time the money is invested for in years. The values in option A are consistent with the results obtained from this formula when applied with the given interest rates and time periods, rounded to the nearest dollar.

Question 6

Suppose that Nora invested $400 at 8.5% compounded annually for 6 years and Patti invested $400 at 8% compounded quarterly for 6 years. At the end of 6 years, who will have the most money and by how much (to the nearest dollar)?

A)Patti by $9
B)Nora by $1
C)Patti by $1
D)Nora by $9
E)They will have equal amounts of money.

Accepted Answer

To determine who will have the most money and by how much, we calculate the future value for both Nora and Patti's investments using the formula for compound interest: $A = P(1 + \frac{r}{n})^{nt}$, where $A$ is the amount of money accumulated after n years, including interest, $P$ is the principal amount (the initial amount of money), $r$ is the annual interest rate (decimal), $n$ is the number of times that interest is compounded per year, and $t$ is the time the money is invested for in years.For Nora, the investment is compounded annually ($n = 1$), so the calculation is straightforward:- $P = $400$- $r = 8.5\% = 0.085$- $n = 1$- $t = 6$$$A_{Nora} = 400(1 + \frac{0.085}{1})^{1 \times 6} = 400(1.085)^6 \approx \$610.79$$For Patti, the investment is compounded quarterly ($n = 4$), so:- $P = $400$- $r = 8\% = 0.08$- $n = 4$- $t = 6$$$A_{Patti} = 400(1 + \frac{0.08}{4})^{4 \times 6} = 400(1 + 0.02)^{24} = 400(1.02)^{24} \approx \$601.80$$Comparing the two amounts, Nora has more money than Patti by approximately $610.79 - 601.80 = \$8.99$, which rounds to \$9.Therefore, Nora will have more money than Patti by about $9.

Question 7

Suppose that a certain radioactive substance has a half-life of 45 years. If there are presently 1,920 milligrams of the substance, how much, to the nearest milligram, will remain after 180 years?&#10;A)Q = 130 milligram&#10;B)Q = 120 milligram&#10;C)Q = 135 milligram&#10;D)Q = 95 milligram&#10;E)Q = 125 milligram

Accepted Answer

The answer of Suppose that a certain radioactive substance has...

Question 8

Solve the equation. $$\left( \frac { 1 } { 5 } \right) ^ { 2 x } = 625$$&#10;A)x = -3&#10;B)x = 2&#10;C)x = -2&#10;D)x = 4&#10;E)x = -4

Accepted Answer

The answer of Solve the equation. \[\left( \frac { 1...

Question 9

Graph the exponential function. f ( x )= 3 ^x A) B) C) D)

Accepted Answer

The answer of Graph the exponential function. f ( x...

Question 10

Graph the exponential function. f ( x )= 3 ^x ^{+ 2} A) B) C) D)

Accepted Answer

The graph of an exponential function with base greater than 1 (like 3 in this case) will be increasing and asymptotic to the x-axis. The term (+2) in the function shifts the graph up by 2 units. The graph should pass through the point (0,5) since f(0) = 3^0 + 2 = 3 + 2 = 5. Choice B correctly represents all of these characteristics.

Question 11

Graph the function. $$f ( x ) = \frac { e ^ { x } + e ^ { - x } } { 5 }$$&#10;A)  &#10;B)  &#10;C)  &#10;D)  &#10;E)none of these

Accepted Answer

The answer of Graph the function. \[f ( x )...

Question 12

The number of bacteria present at a given time under certain conditions is given by the equation Q = 4,000 e^{0.01 t}, where t is expressed in minutes. How many bacteria are present at the end of 45 minutes? Please round the answers to the nearest whole.

A)Q = 6,344 bacteria
B)Q = 6,273 bacteria
C)Q = 6,287 bacteria
D)Q = 6,298 bacteria
E)Q = 6,282 bacteria

Accepted Answer

The answer of The number of bacteria present at a...

Question 13

The half-life of radium is approximately 1,600 years. If the present amount of radium in a certain location is 900 grams, how much will remain after 400 years? Express your answer to the nearest gram.&#10;A)Q = 734 gram&#10;B)Q = 768 gram&#10;C)Q = 757 gram&#10;D)Q = 752 gram&#10;E)Q = 744 gram

Accepted Answer

The answer of The half-life of radium is approximately 1,600...

Question 14

The number of grams Q of a certain radioactive substance present after t seconds is given by the equation $Q = 7,000 e ^ { - 0.1 t }$ . How many grams remain after 17 seconds? Please round the answers to the nearest whole.

A)Q = 1,355 grams
B)Q = 1,329 grams
C)Q = 1,536 grams
D)Q = 1,278 grams
E)Q = 1,279 grams

Accepted Answer

The answer of The number of grams Q of a...

Question 15

Graph the exponential function. f ( x )= e ^x - 5 A) B) C) D)

Accepted Answer

The answer of Graph the exponential function. f ( x...

Question 16

Solve the equation. $$\left( 4 ^ { 3 x - 6 } \right) \left( 4 ^ { x + 4 } \right) = 64$$&#10;A) $x = - \frac { 3 } { 4 }$&#10;B) $x = - \frac { 5 } { 4 }$&#10;C) $x = \frac { 5 } { 4 }$&#10;D) $x = \frac { 1 } { 4 }$&#10;E) $x = \frac { 9 } { 4 }$

Accepted Answer

The answer of Solve the equation. \[\left( 4 ^ {...

Question 17

Write 2⁹ = 512 in logarithmic form. For example, 2³ = 8 becomes log₂ 8 = 3 in logarithmic form. A)log₂9 = 512 B)log₅₁₂2 = 9 C)log₅₁₂9 = 2 D)log₂512 = 9 E)log₉512 = 2

Accepted Answer

The answer of Write 2⁹ = 512 in logarithmic...

Question 18

Suppose that in a certain culture, the equation $\mathcal { Q } ( t ) = 900 e ^ { 0.5 t }$ expresses the number of bacteria present as a function of the time t , where t is expressed in hours. How many bacteria are present at the end of 2 hours? The choices are rounded to the nearest whole.

A)3,670 bacteria
B)6,605 bacteria
C)1,631 bacteria
D)906 bacteria
E)2,446 bacteria

Accepted Answer

The answer of Suppose that in a certain culture, the...

Question 19

Graph the exponential function. $$f ( x ) = \left( \frac { 1 } { 3 } \right) ^ { x }$$&#10;A)  &#10;B)  &#10;C)  &#10;D)

Accepted Answer

The answer of Graph the exponential function. \[f ( x...

Question 20

Write 10⁶ = 1,000,000 in logarithmic form. For example, 2³ = 8 becomes log₂ 8 = 3 in logarithmic form. A)log₁₀6 = 1,000,000 B)log₆1,000,000 = 10 C)log_1,000,00010 = 6 D)log_1,000,0006 = 10 E)log₁₀1,000,000 = 6

Accepted Answer

The answer of Write 10⁶ = 1,000,000 in logarithmic...

Question 21

Solve the equation log₉ x + log₉ ( x - 24)= 2. A)x = 29 B)x = -3 C)x = 27 D)x = 3 E)x = 729

Accepted Answer

The answer of Solve the equation log₉ x...

Question 22

Use your calculator to find x when given ln x . Express answer to four decimal places. $$\ln x = 0.5973$$&#10;A)1.8672&#10;B)1.8072&#10;C)1.8472&#10;D)1.8172&#10;E)1.8372

Accepted Answer

The answer of Use your calculator to find x when...

Question 23

Solve the equation log₆ x = 2. A)x = 64 B)x = 42 C)x = 2 D)x = 6 E)x = 36

Accepted Answer

The answer of Solve the equation log₆ x...

Question 24

Graph the function $y = 3 + \log _ { 2 } x$ . Remember that the graph of $f ( x ) = \log _ { 2 } x$ is given.  &#10;A)  &#10;B)  &#10;C)

Accepted Answer

The answer of Graph the function \(y = 3 +...

Question 25

Evaluate the following. $$\log _ { 8 } 8 ^ { 6 }$$&#10;A)8&#10;B)1&#10;C)6&#10;D)0&#10;E)none of these

Accepted Answer

The answer of Evaluate the following. \[\log _ { 8...

Question 26

Write the following equation in logarithmic form. For example, 2³ = 8 becomes log₂ 8 = 3 in logarithmic form. $$2 ^ { - 5 } = \frac { 1 } { 32 }$$ A) $\log _ { 5 } \frac { 1 } { 32 } = - 2$ B) $\log _ { 2 } 5 = - 32$ C) $\log _ { 2 } \frac { 1 } { 5 } = - 32$ D) $\log _ { 2 } \frac { 1 } { 32 } = - 5$ E) $\log _ { 5 } \frac { 1 } { 2 } = - 2 ^ { 5 }$

Accepted Answer

The answer of Write the following equation in logarithmic form....

Question 27

Solve the equation log₃ x + log₃2 = 2. A)x = 18 B)x = 5.5 C)x = 4.5 D)x = 5 E)x = 4

Accepted Answer

The answer of Solve the equation log₃ x +...

Question 28

Solve the logarithmic equation. Check the solution. $$\log ( 8 x + 5 ) - \log ( 7 x + 8 ) = 0$$&#10;A)x = 1&#10;B)x = 0&#10;C)x = 3&#10;D)x = 4

Accepted Answer

The answer of Solve the logarithmic equation. Check the solution....

Question 29

Solve the logarithmic equation. Check the solution. $$\log \left( x ^ { 2 } + 7 x \right) = \log \left( x ^ { 2 } + 56 \right)$$&#10;A)x = 9&#10;B)x = 8&#10;C)x = 11&#10;D)x = 10

Accepted Answer

The answer of Solve the logarithmic equation. Check the solution....

Question 30

Graph $y = \log _ { 6 } x$ by reflecting the graph of $g ( x ) = 6 ^ { x }$ across the line y = x .&#10;A)  &#10;B)  &#10;C)

Accepted Answer

The answer of Graph \(y = \log _ { 6...

Question 31

Graph $y = \log _ { \frac { 1 } { 4 } } x$ by graphing $\left( \frac { 1 } { 4 } \right) ^ { y } = x$ .&#10;A)  &#10;B)  &#10;C)

Accepted Answer

The answer of Graph \(y = \log _ { \frac...

Question 32

Solve the logarithmic equation. Check the solution. $$\log x ^ { 3 } = 9$$&#10;A) $x =$ 1,000&#10;B) $x =$ 100&#10;C) $x =$ 10,000&#10;D) $x =$ 10&#10;E) $x =$ 1

Accepted Answer

The answer of Solve the logarithmic equation. Check the solution....

Question 33

Use a calculator and the change-of-base formula to find the logarithm to four decimal places. $$\log _ { \frac { 1 } { 3 } } 3$$&#10;A)0.5769&#10;B)- 1.0000&#10;C)1.1005&#10;D)- 1.0078&#10;E)1.7654

Accepted Answer

The answer of Use a calculator and the change-of-base formula...

Question 34

Solve the equation. $$\log _ { \frac { 2 } { 3 } } \frac { n } { p } = 5$$&#10;A) $\frac { n } { p } = 32$&#10;B) $\frac { n } { p } = 243$&#10;C) $\frac { n } { p } = \frac { 32 } { 243 }$&#10;D) $\frac { n } { p } = \frac { 243 } { 32 }$&#10;E)none of these

Accepted Answer

The answer of Solve the equation. \[\log _ { \frac...

Question 35

Evaluate the following. $$\log _ { b } 1$$&#10;A)0&#10;B) $b$&#10;C)1&#10;D) $\frac { 1 } { b }$&#10;E)none of these

Accepted Answer

The answer of Evaluate the following. \[\log _ { b...

Question 36

Assume that $x$ , $y$ , $Z$ , and $b ( b \neq 1 )$ are positive numbers Use the properties of logarithms to write the expression in terms of the logarithms of $x$ , $y$ , and $Z$ . $\log _ { b } x y ^ { 5 } z ^ { 6 }$

A)

\log _ { b } x + \frac { \log _ { b } y } { 5 } + \frac { \log _ { b } z } { 6 }

B)

\log _ { b } x + \left( \log _ { b } y \right) ^ { 5 } + \left( \log _ { b } z \right) ^ { 6 }

C)

\log _ { b } x + 5 \log _ { b } y + 6 \log _ { b } z

D)

- \log _ { b } x - 5 \log _ { b } y - 6 \log _ { b } z

E)

\log _ { b } x - \frac { \log _ { b } y } { 5 } - \frac { \log _ { b } z } { 6 }

Accepted Answer

The answer of Assume that $x$ , $y$ , $Z$...

Question 37

Assume that $x$ , $y$ , $z$ , and $\text { a }$ $( b \neq 1 )$ are positive numbers.Use the properties of logarithms to write the expression in terms of the logarithms of x , y , and z . $\log _ { b } \frac { x } { y z }$

A)log_b x log_b y log_b z
B)log_b x + log_b y + log_b z
C)- log_b x - log_b y - log_b z
D)log_b x - log_b y - log_b z

Accepted Answer

The answer of Assume that $x$ , $y$ , $z$...

Question 38

Solve the equation. $$\log _ { 27 } x = \frac { 4 } { 3 }$$&#10;A)x = 2&#10;B)x = 68&#10;C)x = 16&#10;D)x = 81&#10;E)x = 64

Accepted Answer

The answer of Solve the equation. \[\log _ { 27...

Question 39

Evaluate the expression log₉(log₂8). A) $\frac { 1 } { 4 }$ B) $\frac { 1 } { 3 }$ C) $9$ D) $2$ E) $\frac { 1 } { 2 }$

Accepted Answer

The answer of Evaluate the expression log₉(log_2...

Question 40

Solve the equation log₃ (2 x - 1)- log₃ ( x - 2)= 1. A)x = 4 B)x = 5 C)x = 2 D)x = 7 E)x = 6

Accepted Answer

The answer of Solve the equation log₃ (2 x...

Question 41

Find the value of $x$ . $\log _ { 81 } x = \frac { 1 } { 2 }$&#10;A)9&#10;B) $\frac { 1 } { 9 }$&#10;C)2&#10;D) $\frac { 1 } { 2 }$&#10;E) $1$

Accepted Answer

The answer of Find the value of $x$ . \(\log...

Question 42

Find the value of $x$ . $\log _ { 3 } 81 = x$&#10;A)3&#10;B)5&#10;C)6&#10;D)2&#10;E)4

Accepted Answer

The answer of Find the value of $x$ . \(\log...

Question 43

How long will it take $700 to double itself if it is invested at 13% interest compounded semiannually? Please round the answer to the nearest tenth.&#10;A)5.5 years&#10;B)8.5 years&#10;C)6.0 years&#10;D)4.5 years&#10;E)6.5 years

Accepted Answer

The answer of How long will it take $700 to...

Question 44

Solve the exponential equation and express solution to the nearest hundredth. $$2 e ^ { x } = 28.8$$&#10;A)x = 2.37&#10;B)x = 2.97&#10;C)x = 2.47&#10;D)x = 2.67&#10;E)x = 2.57

Accepted Answer

The answer of Solve the exponential equation and express solution...

Question 45

A principal sum of money P is invested at the end of each year in an annuity earning annual interest at a rate of r . The amount in the annuity account will be A dollars after n years, where $n = \frac { \log \left( \frac { A v } { P } + 1 \right) } { \log ( 1 + r ) }$ If $2,000 is invested each year in an annuity earning 9% annual interest, how long will it take for the account to be worth $15,000? Round the answer to the nearest tenth of the year.

A)7.5 years
B)6.0 years
C)4.2 years
D)6.7 years
E)5.1 years

Accepted Answer

The answer of A principal sum of money P is...

Question 46

Use your calculator to find x when given ln x . Express answer to four decimal places. $$\ln x = 2.5138$$&#10;A)12.4018&#10;B)12.3418&#10;C)12.3818&#10;D)12.3518&#10;E)12.3718

Accepted Answer

The answer of Use your calculator to find x when...

Question 47

Solve the exponential equation and express approximate solutions to the nearest hundredth. e^{x - 4} = 38 A)x = 7.11 B)x = 4.00 C)x = 8.17 D)x = 7.64 E)x = 7.52

Accepted Answer

The answer of Solve the exponential equation and express approximate...

Question 48

Use a calculator and the change-of-base formula to find the logarithm to four decimal places. $$\log _ { 3 } \pi$$&#10;A)0.6189&#10;B)1.0420&#10;C)1.8074&#10;D)1.0342&#10;E)0.9415

Accepted Answer

The answer of Use a calculator and the change-of-base formula...

Question 49

Solve the equation. $$10 ^ { x } = 0.01$$&#10;A)x = -4&#10;B)x = 2&#10;C)x = 3&#10;D)x = 4&#10;E)x = -2

Accepted Answer

The answer of Solve the equation. \[10 ^ { x...

Question 50

Use your calculator to find x when given ln x . Express answer to four decimal places. $$\ln x = - 2.2449$$&#10;A)0.1059&#10;B)0.1259&#10;C)0.1559&#10;D)0.1359&#10;E)0.0959

Accepted Answer

The answer of Use your calculator to find x when...

Question 51

Use a calculator and the change-of-base formula to find the logarithm to four decimal places.

Accepted Answer

The answer of Use a calculator and the change-of-base formula...

Question 52

Calculate how many times more intense an earthquake with a Richter number of 8.3 is than an earthquake with a Richter number of 6.9. Please round the answer to the whole number.&#10;A)30&#10;B)33&#10;C)25&#10;D)35&#10;E)27

Accepted Answer

The answer of Calculate how many times more intense an...

Question 53

An earthquake in the Japan in 2011 was about 10 9 times as intense as the reference intensity. Find the Richter number for that earthquake. NOTE: Seismologists use the Richter scale to measure and report the magnitude of earthquakes. The equation $R = \log \frac { I } { I _ { 0 } }$ compares the intensity I of an earthquake to a minimum or reference intensity I 0 .&#10;A)10 9 &#10;B)10&#10;C)9&#10;D)none of these

Accepted Answer

The answer of An earthquake in the Japan in 2011...

Question 54

Business equipment is often depreciated using the double declining-balance method. In this method, a piece of equipment with a life expectancy of N years, costing C dollars, will depreciate to a value of V dollars in n years, where n is given by the formula: $n = \frac { \log V - \log C } { \log \left( 1 - \frac { 2 } { N } \right) }$ A computer that cost $10,000 has a life expectancy of 5 years. If it has depreciated to a value of $2,000, how old is it? Round the answer to the nearest tenth of the year.&#10;A)3.2 years old&#10;B)2.2 years old&#10;C)1.9 years old&#10;D)2.5 years old&#10;E)2.8 years old

Accepted Answer

The answer of Business equipment is often depreciated using the...

Question 55

An earthquake has a period of $\frac { 1 } { 2 }$ second, and an amplitude of $500,000$ micrometers. Find its measure on the Richter scale.&#10;A) $3$&#10;B) $2$&#10;C) $5$&#10;D) $6$&#10;E) $8$

Accepted Answer

The answer of An earthquake has a period of \(\frac...

Question 56

Solve the logarithmic equation. Check the solution. $$\log _ { 2 } x = \log _ { 2 } \frac { 1 } { x } + 6$$&#10;A) $x =$ 10&#10;B) $x =$ 27&#10;C) $x =$ 6.&#10;D) $x =$ 6&#10;E) $x =$ 8

Accepted Answer

The answer of Solve the logarithmic equation. Check the solution....

Question 57

Use the change of base formula to identify the expression that is equivalent to $\log _ { 9 } 7$ .&#10;A) $\frac { \log 7 } { \log 9 }$&#10;B) $\frac { \log 9 } { \log 7 }$&#10;C) $\frac { \ln 9 } { \ln 7 }$&#10;D) $9 \log 7$

Accepted Answer

The answer of Use the change of base formula to...

Deck 11: Exponential and Logarithmic Functions