Figure 1 is a graph showing the trajectory of a rugby ball. The height of the ball above the ground, H metres, has been plotted against the horizontal distance, x metres, measured from the point where the ball was kicked. The ball travels in a vertical plane. The ball reaches a maximum height of 12 metres and hits the ground at a point 40 metres from where it was kicked. (a) Find a quadratic equation linking H with x that models this situation. (b) The ball passes over the horizontal bar of a set of rugby posts that is perpendicular to the path of the ball. The bar is 3 metres above the ground. (c) Use your equation to find the greatest horizontal distance of the bar from O. (d) Give one limitation of the model.

A-Level Edexcel Maths Pure Differential Equations: Figure 1 is a graph showing the

Figure 1 is a graph showing the trajectory of a rugby ball - Edexcel - A-Level Maths Pure - Question 10 - 2018 - Paper 2

Question 10

Figure 1 is a graph showing the trajectory of a rugby ball. The height of the ball above the ground, H metres, has been plotted against the horizontal distance, x m... show full transcript

Worked Solution & Example Answer:Figure 1 is a graph showing the trajectory of a rugby ball - Edexcel - A-Level Maths Pure - Question 10 - 2018 - Paper 2

Step 1

Find a quadratic equation linking H with x that models this situation.

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Answer

To derive the quadratic equation relating H to x, we recognize that the height reaches a maximum of 12 metres at its vertex when x = 20 metres (halfway to the point where it lands).

Using the vertex form of a quadratic equation, we can express H as:

$H = a(x - 20)^2 + 12$

Given that the ball hits the ground at x = 40, we have H = 0:

$0 = a(40 - 20)^2 + 12$

Solving this, we find:

$0 = 100a + 12 \Rightarrow a = -\frac{12}{100} = -\frac{3}{25}$

Thus, the complete equation is:

$H = -\frac{3}{25}(x - 20)^2 + 12$

Step 2

The ball passes over the horizontal bar of a set of rugby posts that is perpendicular to the path of the ball. The bar is 3 metres above the ground.

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Answer

To find the x distance where the ball is at least 3 metres high:

Set H = 3 in the derived equation like so:

$3 = -\frac{3}{25}(x - 20)^2 + 12$

Rearranging gives:

$\frac{3}{25}(x - 20)^2 = 12 - 3$

Simplifying further:

$\frac{3}{25}(x - 20)^2 = 9 \Rightarrow (x - 20)^2 = 75$

Taking the square root yields two potential x-values:

$x - 20 = \pm 5\sqrt{3}\Rightarrow x = 20 \pm 5\sqrt{3}$

The distances are thus approximately 20 - 8.66 m and 20 + 8.66 m.

Step 3

Use your equation to find the greatest horizontal distance of the bar from O.

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Answer

The greatest horizontal distance of the bar, which is at 3 m above the ground, is found in the previous calculation. Using:

$x = 20 + 5\sqrt{3}\approx 28.66 ext{ metres}$

This signifies that the bar's greatest horizontal distance from point O is about 28.66 metres.

Step 4

Give one limitation of the model.

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Answer

One limitation of the model is that it assumes the ball follows a perfect parabolic trajectory, neglecting factors such as wind resistance and the ball being affected by spin, which could alter its path in real situations.

Figure 1 is a graph showing the trajectory of a rugby ball - Edexcel - A-Level Maths Pure - Question 10 - 2018 - Paper 2

Worked Solution & Example Answer:Figure 1 is a graph showing the trajectory of a rugby ball - Edexcel - A-Level Maths Pure - Question 10 - 2018 - Paper 2

Find a quadratic equation linking H with x that models this situation.

The ball passes over the horizontal bar of a set of rugby posts that is perpendicular to the path of the ball. The bar is 3 metres above the ground.

Use your equation to find the greatest horizontal distance of the bar from O.

Give one limitation of the model.

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