A solid right circular cylinder has radius r cm and height h cm. The total surface area of the cylinder is 800 cm². (a) Show that the volume, V cm³, of the cylinder is given by V = 400r - πr²: (b) Given that r varies, use calculus to find the maximum value of V, to the nearest cm³. (c) Justify that the value of V you have found is a maximum.

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A solid right circular cylinder has radius r cm and height h cm - Edexcel - A-Level Maths Pure - Question 3 - 2009 - Paper 2

Question 3

A solid right circular cylinder has radius r cm and height h cm. The total surface area of the cylinder is 800 cm². (a) Show that the volume, V cm³, of the cylinde... show full transcript

Worked Solution & Example Answer:A solid right circular cylinder has radius r cm and height h cm - Edexcel - A-Level Maths Pure - Question 3 - 2009 - Paper 2

Step 1

(a) Show that the volume, V cm³, of the cylinder is given by

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Answer

To find the relationship between the volume and the given surface area, we start with the formula for the total surface area of a cylinder:

$S = 2\pi rh + 2\pi r^2$

Setting this equal to 800, we have:

$2\pi rh + 2\pi r^2 = 800$

From this, we can express h in terms of r:

$h = \frac{800 - 2\pi r^2}{2\pi r}$

Next, we can calculate the volume V of the cylinder:

$V = \pi r^2 h$

Substituting the expression for h:

$V = \pi r^2 \left( \frac{800 - 2\pi r^2}{2\pi r} \right)$

This simplifies to:

$V = \frac{800r}{2} - \pi r^2 \cdot \frac{r}{2}$

Thus,

$V = 400r - \pi r^2$

This confirms that the volume can be expressed as $V = 400r - \pi r^2$ .

Step 2

(b) use calculus to find the maximum value of V, to the nearest cm³.

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Answer

To find the maximum value of V, we differentiate V with respect to r:

$\frac{dV}{dr} = 400 - 2\pi r$

Setting the derivative equal to zero to find critical points:

$400 - 2\pi r = 0$

Solving for r gives:

$r = \frac{400}{2\pi} = \frac{200}{\pi} \approx 63.66 \text{ cm}$

Now we find the second derivative to confirm it's a maximum:

$\frac{d^2V}{dr^2} = -2\pi$

Since this is negative, it confirms a maximum. Now we substitute $r = \frac{200}{\pi}$ back into the volume equation:

$V = 400(\frac{200}{\pi}) - \pi (\frac{200}{\pi})^2$

Evaluating:

$V = \frac{80000}{\pi} - \frac{40000}{\pi} = \frac{40000}{\pi} \approx 12731 \text{ cm}^3$

So, the maximum volume to the nearest cm³ is 12731 cm³.

Step 3

(c) Justify that the value of V you have found is a maximum.

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Answer

We have already confirmed that the second derivative $\frac{d^2V}{dr^2} = -2\pi$ is negative, which indicates concavity downwards. This means that the critical point found at $r = \frac{200}{\pi}$ is indeed a maximum.

Furthermore, since we worked through the calculus of the function and identified that $\frac{dV}{dr}$ changes from positive to negative around this critical point, it provides further confirmation that the value of V found is truly a maximum.

A solid right circular cylinder has radius r cm and height h cm - Edexcel - A-Level Maths Pure - Question 3 - 2009 - Paper 2

Worked Solution & Example Answer:A solid right circular cylinder has radius r cm and height h cm - Edexcel - A-Level Maths Pure - Question 3 - 2009 - Paper 2

(a) Show that the volume, V cm³, of the cylinder is given by

(b) use calculus to find the maximum value of V, to the nearest cm³.

(c) Justify that the value of V you have found is a maximum.

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