7. (a) Express $ \frac{2}{P(P - 2)} $ in partial fractions. A team of biologists is studying a population of a particular species of animal. The population is modelled by the differential equation \[ \frac{dP}{dt} = \frac{1}{2} P(P - 2) \cos 2t, \quad t > 0 \] where $ P $ is the population in thousands, and $ t $ is the time measured in years since the start of the study. Given that $ P = 3 $ when $ t = 0 $, (b) solve this differential equation to show that \[ P = \frac{6}{3 - e^{-2\sin 2t}} \] (c) find the time taken for the population to reach 4000 for the first time. Give your answer in years to 3 significant figures.

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7. (a) Express $ \frac{2}{P(P - 2)} $ in partial fractions - Edexcel - A-Level Maths Pure - Question 8 - 2015 - Paper 4

Question 8

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7. (a) Express $ \frac{2}{P(P - 2)} $ in partial fractions. A team of biologists is studying a population of a particular species of animal. The population is mo... show full transcript

Worked Solution & Example Answer:7. (a) Express $ \frac{2}{P(P - 2)} $ in partial fractions - Edexcel - A-Level Maths Pure - Question 8 - 2015 - Paper 4

Step 1

Express $ \frac{2}{P(P - 2)} $ in partial fractions.

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Answer

To express ( \frac{2}{P(P - 2)} ) in partial fractions, we start by setting:

[ \frac{2}{P(P - 2)} = \frac{A}{P} + \frac{B}{P - 2} ]

Multiplying through by the common denominator ( P(P - 2) ) gives:

[ 2 = A(P - 2) + BP ]

To find ( A ) and ( B ), we can select suitable values for ( P ) to simplify.

Let ( P = 0 ): [ 2 = A(0 - 2) + 0 \Rightarrow A = -1 ]

Let ( P = 2 ): [ 2 = 0 + B(2) \Rightarrow B = 1 ]

Thus, we have:
[ \frac{2}{P(P - 2)} = \frac{-1}{P} + \frac{1}{P - 2} ]

Step 2

solve this differential equation to show that $ P = \frac{6}{3 - e^{-2\sin 2t}} $

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Answer

Starting with the differential equation:

[ \frac{dP}{dt} = \frac{1}{2} P(P - 2) \cos 2t ]

We separate variables:

[ \frac{1}{P(P - 2)} dP = \frac{1}{2} \cos 2t , dt ]

Integrating both sides gives:

[ \int \frac{1}{P(P - 2)} dP = \frac{1}{2} \int \cos 2t , dt ]

The left side integrates to:

[ \ln |P - 2| - \ln |P| = \sin 2t + C ]

Combining the logs: [ \ln \left( \frac{P - 2}{P} \right) = \sin 2t + C ]

Exponentiating: [ \frac{P - 2}{P} = e^{\sin 2t + C} \Rightarrow \frac{P - 2}{P} = e^C e^{\sin 2t} ]

Setting ( P = 3 ) when ( t = 0 ) helps us find ( C ): [ \frac{1}{3} = e^C \Rightarrow C = \ln 3 ]

Thus, we can express the equation as: [ P = \frac{6}{3 - e^{-2\sin 2t}} ]

Step 3

find the time taken for the population to reach 4000 for the first time.

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Answer

To find when the population reaches 4000, we set:

[ P = 4000 \Rightarrow \frac{6}{3 - e^{-2\sin 2t}} = 4000 ]

Rearranging gives: [ 3 - e^{-2\sin 2t} = \frac{6}{4000} \Rightarrow e^{-2\sin 2t} = 3 - \frac{3}{2000} ]

Solving for ( e^{-2\sin 2t} ): [ e^{-2\sin 2t} = \frac{5997}{2000} ]

Taking the natural logarithm: [ -2\sin 2t = \ln \left( \frac{5997}{2000} \right) ]

Next, solving for ( , t ): [ \sin 2t = -\frac{1}{2} \ln \left( \frac{5997}{2000} \right) ]

Finding ( 2t ) and then dividing by 2 gives the time in years. Finally, rounding to three significant figures will yield the answer.

7. (a) Express \( \frac{2}{P(P - 2)} \) in partial fractions - Edexcel - A-Level Maths Pure - Question 8 - 2015 - Paper 4

Worked Solution & Example Answer:7. (a) Express \( \frac{2}{P(P - 2)} \) in partial fractions - Edexcel - A-Level Maths Pure - Question 8 - 2015 - Paper 4

Express \( \frac{2}{P(P - 2)} \) in partial fractions.

solve this differential equation to show that \( P = \frac{6}{3 - e^{-2\sin 2t}} \)

find the time taken for the population to reach 4000 for the first time.

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