The rate of increase of the number, N, of fish in a lake is modelled by the differential equation dN dt = (k - t)(5000 - N) t > 0, 0 < N < 5000 In the given equation, the time t is measured in years from the start of January 2000 and k is a positive constant. (a) By solving the differential equation, show that N = 5000 - A e^{-kt} where A is a positive constant. After one year, at the start of January 2001, there are 1200 fish in the lake. After two years, at the start of January 2002, there are 1800 fish in the lake. (b) Find the exact value of the constant A and the exact value of the constant k. (c) Hence find the number of fish in the lake after five years. Give your answer to the nearest hundred fish.

A-Level Edexcel Maths Pure Exponential & Logarithms: The rate of increase of the numb

The rate of increase of the number, N, of fish in a lake is modelled by the differential equation dN dt = (k - t)(5000 - N) t > 0, 0 < N < 5000 In the given equation, the time t is measured in years from the start of January 2000 and k is a positive constant - Edexcel - A-Level Maths Pure - Question 7 - 2014 - Paper 8

Question 7

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The rate of increase of the number, N, of fish in a lake is modelled by the differential equation dN dt = (k - t)(5000 - N) t > 0, 0 < N < 5000 In the given equati... show full transcript

Worked Solution & Example Answer:The rate of increase of the number, N, of fish in a lake is modelled by the differential equation dN dt = (k - t)(5000 - N) t > 0, 0 < N < 5000 In the given equation, the time t is measured in years from the start of January 2000 and k is a positive constant - Edexcel - A-Level Maths Pure - Question 7 - 2014 - Paper 8

Step 1

(a) By solving the differential equation, show that N = 5000 - A e^{-kt}

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Answer

To solve the differential equation, we will first separate the variables:

$\frac{dN}{(5000 - N)} = (k - t) \frac{1}{t} dt$

Integrating both sides gives:

$\int \frac{1}{5000 - N} dN = \int (k - t) \frac{1}{t} dt$

The left integral yields:

$-\ln(5000 - N) = k \ln(t) - \int t^{-1} dt$

The right integral is:

$-\ln(5000 - N) = k \ln(t) - \ln(t) + C$

By simplifying and exponentiating both sides, we have:

$5000 - N = A e^{-kt} \\ N = 5000 - A e^{-kt}$

where A is an arbitrary constant.

Step 2

(b) Find the exact value of the constant A and the exact value of the constant k.

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Answer

Using the conditions provided:

At t = 1 (January 2001), N = 1200:

$1200 = 5000 - A e^{-k(1)} \\ A e^{-k} = 3800 \quad \text{(1)}$
At t = 2 (January 2002), N = 1800:

$1800 = 5000 - A e^{-k(2)} \\ A e^{-2k} = 3200 \quad \text{(2)}$

Dividing equation (1) by equation (2):

$\frac{3800}{3200} = e^{k} \\ k = \ln\left(\frac{19}{8}\right)$

Substituting back to find A:

Using (1):

$A e^{-k} = 3800 \\ A = 9025$

Thus, the values are:

A = 9025
k = \ln\left(\frac{19}{8}\right)

Step 3

(c) Hence find the number of fish in the lake after five years.

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Answer

Using the formula found:

$N = 5000 - 9025 e^{-5k}$

Substituting k:

$N = 5000 - 9025 e^{-5\ln\left(\frac{19}{8}\right)}$

Calculating, we find:

$N = 4402.828401... \approx 4400 \text{ (to the nearest hundred)}$

(a) By solving the differential equation, show that N = 5000 - A e^{-kt}

(b) Find the exact value of the constant A and the exact value of the constant k.

(c) Hence find the number of fish in the lake after five years.

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