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Calculus 1 : Constant of Proportionality

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Example Question #31 : Constant Of Proportionality

The rate of decrease of baceterial cells in response to a new antibiotic is proportional to the population. The population decreased from 15800 to 6540 between 3:15 and 4:00. What is the expected population at 8:30?

Possible Answers:

2490

3175

1148

113

Correct answer:

Explanation:

We're told that the rate of growth of the population is proportional to the population itself, meaning that this problem deals with exponential growth/decay. The population can be modeled thusly:

$p(t)=p_0e^{kt}$

Where p_0 is an initial population value, and is the constant of proportionality.

Since the population decreased from 15800 to 6540 between 3:15 and 4:00, we can solve for this constant of proportionality. Treat the minutes as decimal values for the hour:

$6540=15800e^{k(4-3.25)}$

$\frac{6540}{15800}=e^{0.75k}$

$0.75k=ln(\frac{6540}{15800})$

$k=\frac{ln(\frac{6540}{15800})}{0.75}=-1.176$

Using this, we can calculate the expected value from 4:00 to 8:30:

$P=6540e^{(8.5-4)(-1.176)} \approx 33$

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Example Question #32 : Constant Of Proportionality

The rate of growth of the population of electric mice in Japan is proportional to the population. The population increased from 1800 to 2500 between 2012 and 2015. Determine the expected population in 2018.

Possible Answers:

3933

3684

4152

3200

3472

Correct answer:

3472

Explanation:

We're told that the rate of growth of the population is proportional to the population itself, meaning that this problem deals with exponential growth/decay. The population can be modeled thusly:

$p(t)=p_0e^{kt}$

Where p_0 is an initial population value, represents a measure of elapsed time relative to this population value, and is the constant of proportionality.

Since the population increased from 1800 to 2500 between 2012 and 2015, we can solve for this constant of proportionality:

$2500=1800e^{k(2015-2012)}$

$\frac{25}{18}=e^{3k}$

$3k=ln(\frac{25}{18})$

$k=\frac{ln(\frac{25}{18})}{3}=0.1095$

Now that the constant of proportionality is known, we can use it to find an expected population value relative to an initial population value due to the difference in time points:

$P=2500e^{(2018-2015)(0.1095)} \approx 3472$

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Example Question #33 : Constant Of Proportionality

The rate of growth of the bacteria in a petri dish is proportional to the population. The population increased from 4900 to 7193 between 3:54 and 4:21. Determine the expected population at 5:12.

Possible Answers:

14852

13789

12964

15390

14112

Correct answer:

14852

Explanation:

We're told that the rate of growth of the population is proportional to the population itself, meaning that this problem deals with exponential growth/decay. The population can be modeled thusly:

$p(t)=p_0e^{kt}$

Where p_0 is an initial population value, represents a measure of elapsed time relative to this population value, and is the constant of proportionality.

Since the population increased from 4900 to 7193 between 3:54 and 4:21, we can solve for this constant of proportionality. Treat the minutes as decimals of an hour by dividing by 60:

$7193=4900e^{k(4.35-3.9)}$

$\frac{7193}{4900}=e^{0.45k}$

$0.45k=ln(\frac{7193}{4900})$

$k=\frac{ln(\frac{7193}{4900})}{0.45}=0.853$

Now that the constant of proportionality is known, we can use it to find an expected population value relative to an initial population value due to the difference in time points:

$P=7193e^{(5.20-4.35)(0.853)} \approx 14852$

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Example Question #34 : Constant Of Proportionality

The rate of growth of the yeast in a loaf of bread is proportional to the population. The population increased from 178 to 413 between 3:15 and 3:45. Determine the expected population at 5:20.

Possible Answers:

2877

1998

1724

5929

896

Correct answer:

5929

Explanation:

We're told that the rate of growth of the population is proportional to the population itself, meaning that this problem deals with exponential growth/decay. The population can be modeled thusly:

$p(t)=p_0e^{kt}$

Where p_0 is an initial population value, represents a measure of elapsed time relative to this population value, and is the constant of proportionality.

Since the population increased from 178 to 413 between 3:15 and 3:45, we can solve for this constant of proportionality. Treat the minutes as decimals after the hour by dividing them by 60:

$413=178e^{k(3.75-3.25)}$

$\frac{413}{178}=e^{0.5k}$

$0.5k=ln(\frac{413}{178})$

$k=\frac{ln(\frac{413}{178})}{0.5}=1.683$

Now that the constant of proportionality is known, we can use it to find an expected population value relative to an initial population value due to the difference in time points:

$P=413e^{(5.333-3.75)(1.683)} \approx 5929$

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Example Question #35 : Constant Of Proportionality

The rate of growth of the population of sentient self-replicating toy soldiers is proportional to the population. The population increased from 12 to 43 between Monday and Wednesday. Determine the expected population on Saturday.

Possible Answers:

292

207

253

188

271

Correct answer:

292

Explanation:

We're told that the rate of growth of the population is proportional to the population itself, meaning that this problem deals with exponential growth/decay. The population can be modeled thusly:

$p(t)=p_0e^{kt}$

Where p_0 is an initial population value, represents a measure of elapsed time relative to this population value, and is the constant of proportionality.

Since the population increased from 12 to 43 between Monday and Wednesday, we can solve for this constant of proportionality. Assign the days numbers based on the occurence in the week:

$43=12e^{k(4-2)}$

$\frac{43}{12}=e^{2k}$

$2k=ln(\frac{43}{12})$

$k=\frac{ln(\frac{43}{12})}{2}=0.638$

Now that the constant of proportionality is known, we can use it to find an expected population value relative to an initial population value due to the difference in time points:

$P=43e^{(7-4)(0.638)} \approx 292$

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Example Question #36 : Constant Of Proportionality

The rate of growth of the prokaryotes of Lake Tahoe is proportional to the population. The population increased from 193678 to 254183 between 2014 and 2015. Determine the expected population in 2021.

Possible Answers:

1299915

1136241

897775

1398602

1200068

Correct answer:

1299915

Explanation:

We're told that the rate of growth of the population is proportional to the population itself, meaning that this problem deals with exponential growth/decay. The population can be modeled thusly:

$p(t)=p_0e^{kt}$

Where p_0 is an initial population value, represents a measure of elapsed time relative to this population value, and is the constant of proportionality.

Since the population increased from 193678 to 254183 between 2014 and 2015, we can solve for this constant of proportionality:

$254183=193678e^{k(2015-2014)}$

$\frac{254183}{193678}=e^{k}$

$k=ln(\frac{254183}{193678})=0.272$

Now that the constant of proportionality is known, we can use it to find an expected population value relative to an initial population value due to the difference in time points:

$P=254183e^{(2021-2015)(0.272)} \approx 1299915$

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Example Question #37 : Constant Of Proportionality

The rate of growth of the alien spores flooding the atmostphere is proportional to the population. The population increased from 19000 to 58000 between 2013 and 2014. Determine the expected population in 2017.

Possible Answers:

1649855

1213964

2549818

1887903

2136621

Correct answer:

1649855

Explanation:

We're told that the rate of growth of the population is proportional to the population itself, meaning that this problem deals with exponential growth/decay. The population can be modeled thusly:

$p(t)=p_0e^{kt}$

Where p_0 is an initial population value, represents a measure of elapsed time relative to this population value, and is the constant of proportionality.

Since the population increased from 19000 to 58000 between 2013 and 2014, we can solve for this constant of proportionality:

$58000=19000e^{k(2014-2013)}$

$\frac{58}{19}=e^{k}$

$k=ln(\frac{58}{19})=1.116$

Now that the constant of proportionality is known, we can use it to find an expected population value relative to an initial population value due to the difference in time points:

$P=58000e^{(2017-2014)(1.116)} \approx 1649855$

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Example Question #38 : Constant Of Proportionality

The rate of growth of the algae in Bill's unkempt swimming pool is proportional to the population. The population increased from 17902 to 39551 between March and May. Determine the expected population in July.

Possible Answers:

87321

102256

154479

192788

136894

Correct answer:

87321

Explanation:

We're told that the rate of growth of the population is proportional to the population itself, meaning that this problem deals with exponential growth/decay. The population can be modeled thusly:

$p(t)=p_0e^{kt}$

Where p_0 is an initial population value, represents a measure of elapsed time relative to this population value, and is the constant of proportionality.

Since the population increased from 17902 to 39551 between March and May, we can solve for this constant of proportionality. Assign the months their number in the calendar to determine time elapsed:

$39551=17902e^{k(5-3)}$

$\frac{39551}{17902}=e^{2k}$

$2k=ln(\frac{39551}{17902})$

$k=\frac{ln(\frac{39551}{17902})}{2}=0.396$

Now that the constant of proportionality is known, we can use it to find an expected population value relative to an initial population value due to the difference in time points:

$P=39551e^{(7-5)(0.396)} \approx 87321$

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Example Question #39 : Constant Of Proportionality

The rate of decrease of the population of Bengal tigers has been proportional to the population. The population decreased from 45000 to 1800 between 1900 and 1972. Determine the constant of proportionality for this decrease.

Possible Answers:

0.0039

-0.1808

-0.0447

0.0188

-0.0065

Correct answer:

-0.0447

Explanation:

We're told that the rate of decrease of the population is proportional to the population itself, meaning that this problem deals with exponential growth/decay. The population can be modeled thusly:

$p(t)=p_0e^{kt}$

Where p_0 is an initial population value, represents a measure of elapsed time relative to this population value, and is the constant of proportionality.

Since the population decreased from 45000 to 1800 between 1900 and 1972, we can solve for this constant of proportionality:

$1800=45000e^{k(1972-1900)}$

$\frac{1800}{45000}=e^{72k}$

$72k=ln(\frac{1800}{45000})$

$k=\frac{ln(\frac{1800}{45000})}{72}=-0.0447$

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Example Question #40 : Constant Of Proportionality

The rate of growth of the population of robomen is proportional to the population. The population increased from 100 units to 1500 between 2008 and 2015. Determine the expected population in 2055.

Possible Answers:

7924462944

6012348

77812342

583094

8941326112

Correct answer:

7924462944

Explanation:

We're told that the rate of growth of the population is proportional to the population itself, meaning that this problem deals with exponential growth/decay. The population can be modeled thusly:

$p(t)=p_0e^{kt}$

Where p_0 is an initial population value, represents a measure of elapsed time relative to this population value, and is the constant of proportionality.

Since the population increased from 100 units to 1500 between 2008 and 2015, we can solve for this constant of proportionality:

$1500=100e^{k(2015-2008)}$

$15=e^{7k}$

7k=ln(15)

$k=\frac{ln(15)}{7}=0.387$

Now that the constant of proportionality is known, we can use it to find an expected population value relative to an initial population value due to the difference in time points:

$P=1500e^{(2055-2015)(0.387)} \approx 7924462944$

Better unplug that production facility.

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Calculus 1 : Constant of Proportionality

Study concepts, example questions & explanations for Calculus 1

All Calculus 1 Resources

Example Questions

Example Question #31 : Constant Of Proportionality

Example Question #32 : Constant Of Proportionality

Example Question #33 : Constant Of Proportionality

Example Question #34 : Constant Of Proportionality

Example Question #35 : Constant Of Proportionality

Example Question #36 : Constant Of Proportionality

Example Question #37 : Constant Of Proportionality

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