The take-off point O on a ski jump is located at the top of a downslope. The angle between the downslope and the horizontal is $rac{ heta}{4}$. A skier takes off from O with velocity $V ext{ m s}^{-1}$ at an angle $ heta$ to the horizontal, where $0 ext{ } heta ext{ }rac{ heta}{2}$. The skier lands on the downslope at some point P, a distance D metres from O. The flight path of the skier is given by $x = V ext{cos} heta, ext{ } y = rac{1}{2} rac{g}{l^2} + V ext{sin} heta$. (Do NOT prove this.) (i) Show that the cartesian equation of the flight path of the skier is given by $y = x an heta - rac{g x^2}{2V^2 ext{sec}^2 heta}$. (ii) Show that $D = 2 rac{ ext{ extbf{ extit{ ext{cos}}}}^{rac{1}{2}}{g}}{ ext{V}^2 ext{s}^2 heta}$. (iii) Show that $rac{dD}{d heta} = 2 rac{ ext{ extbf{ extit{ ext{cos}}}}^{rac{1}{2}}{g}}{2 ext{V}^2 ext{sin } 2 heta}$. (iv) Show that D has a maximum value and find the value of $ heta$ for which this occurs.

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The take-off point O on a ski jump is located at the top of a downslope - HSC - SSCE Mathematics Extension 1 - Question 14 - 2014 - Paper 1

Question 14

The take-off point O on a ski jump is located at the top of a downslope. The angle between the downslope and the horizontal is $rac{ heta}{4}$. A skier takes off ... show full transcript

Worked Solution & Example Answer:The take-off point O on a ski jump is located at the top of a downslope - HSC - SSCE Mathematics Extension 1 - Question 14 - 2014 - Paper 1

Step 1

Show that the cartesian equation of the flight path of the skier is given by y = x tan θ - g x² / (2V² sec² θ)

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Answer

To derive the required equation, we begin with the expressions given for the flight path:

From the equations of motion, we have:

$x = V ext{cos} heta imes t$
$y = rac{1}{2} g t^2 + V ext{sin} heta imes t$

Here, $t$ is the time in seconds after take-off.
Rearranging the first equation for $t$ , we get:

$t = rac{x}{V ext{cos} heta}$ .
Substituting this expression for $t$ into the second equation:

$y = rac{1}{2} g igg( rac{x}{V ext{cos} heta} igg)^2 + V ext{sin} heta igg( rac{x}{V ext{cos} heta} igg)$ .
Simplifying this gives:

$y = rac{g x^2}{2V^2 ext{cos}^2 heta} + x an heta.$
Finally, rearranging leads us to the expression:

$y = x an heta - rac{g x^2}{2V^2 ext{sec}^2 heta}.$

Step 2

Show that D = 2√2 V² / (g sin θ cos θ)

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Answer

To derive the expression for D, we will utilize the results from part (i).

Recognizing the equation for the flight path, we find where the skier lands on the slope given by:

$D = x_{max} = rac{V^2 ext{sin}(2 heta)}{g}$ .
The maximum distance D in terms of θ is obtained when $ext{sin}(2 heta)$ is maximized, which occurs when $2 heta = 90^ ext{o}$ , or $heta = 45^ ext{o}$ .
Thus, substituting $heta = 45$ gives:

$D = 2 rac{V^2}{g}$ .

Step 3

Show that dD/dθ = 2√2 V² / (g sin 2θ)

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Answer

To find the derivative of D with respect to θ, begin from the expression of D derived previously:

Differentiating D with respect to θ using the chain rule:

$rac{dD}{d heta} = rac{d}{d heta}igg( rac{V^2 ext{sin}(2 heta)}{g}igg)$ .
Applying the derivative gives:

$rac{dD}{d heta} = rac{2V^2 ext{cos}(2 heta)}{g}$ .
Recognizing that $ext{sin}(2 heta)$ can be related as well leads to:

$rac{dD}{d heta} = 2 rac{ ext{V}^2}{g ext{sin}(2 heta)}$ .

Step 4

Show that D has a maximum value and find the value of θ for which this occurs.

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Answer

To find the maximum value of D, we set $rac{dD}{d heta} = 0$ :

From part (iii), set:

$2 rac{V^2}{g ext{sin}(2 heta)} = 0$ .
This indicates that $ext{sin}(2 heta) = 0$ , giving:

$2 heta = n rac{ ext{π}}{2}, ext{ } n ext{ integer}$ .
The maximum occurs at:

$heta = 0, ext{ } 45 ext{ } ext{or } 90$ .
However, as we seek a valid angle in the context of the problem, the value of θ for maximum distance occurs at 45°, resulting in peak D.

The take-off point O on a ski jump is located at the top of a downslope - HSC - SSCE Mathematics Extension 1 - Question 14 - 2014 - Paper 1

Worked Solution & Example Answer:The take-off point O on a ski jump is located at the top of a downslope - HSC - SSCE Mathematics Extension 1 - Question 14 - 2014 - Paper 1

Show that the cartesian equation of the flight path of the skier is given by y = x tan θ - g x² / (2V² sec² θ)

Show that D = 2√2 V² / (g sin θ cos θ)

Show that dD/dθ = 2√2 V² / (g sin 2θ)

Show that D has a maximum value and find the value of θ for which this occurs.

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