Question 6 - A-Level Maths

OCR MEI M1 — Question 6 8 marks

Exam Board	OCR MEI
Module	M1 (Mechanics 1)
Marks	8
Paper	Download PDF ↗
Mark scheme	Download PDF ↗
Topic	Projectiles
Type	Horizontal projection from height
Difficulty	Moderate -0.8 This is a straightforward projectile motion question requiring only basic SUVAT equations with constant acceleration. Students apply standard formulas (s = ut + ½at² for vertical motion, s = ut for horizontal motion) and solve for time when height equals -5m, then find horizontal distance. It's more routine than average A-level questions as it involves direct application of memorized formulas with minimal problem-solving or conceptual challenge.
Spec	3.02d Constant acceleration: SUVAT formulae 3.02i Projectile motion: constant acceleration model

6 A small ball is kicked off the edge of a jetty over a calm sea. Air resistance is negligible. Fig. 6 shows

the point of projection, O,
the initial horizontal and vertical components of velocity,
the point A on the jetty vertically below O and at sea level,
the height, OA , of the jetty above the sea.

\begin{figure}[h]

\includegraphics[alt={},max width=\textwidth]{bb65e726-a5e0-4060-81a6-6837dea82e64-4_451_1000_596_600} \captionsetup{labelformat=empty} \caption{Fig. 6}

\end{figure} The time elapsed after the ball is kicked is \(t\) seconds.

Find an expression in terms of \(t\) for the height of the ball above O at time \(t\). Find also an expression for the horizontal distance of the ball from O at this time.
Determine how far the ball lands from A .

Show mark scheme Show mark scheme source

Question 6:

Part (i):

Answer	Marks	Guidance
Answer/Working	Mark	Guidance
Vertical: \(y = 8t - 4.9t^2\)	M1	Use of \(s = ut + 0.5at^2\) with \(g = \pm 9.8, \pm 10\). Accept \(u = 0\) or \(14.4...\) or \(14.4\sin\theta\) or \(u\sin\theta\) but not 12. Allow use of \(+3.6\).
A1	Accept derivation of \(-4.9\) not clear. cao
Horizontally \(x = 12t\)	B1

Part (ii) - Method 1:

Answer	Marks	Guidance
Answer/Working	Mark	Guidance
Require \(y = -3.6\), so \(-3.6 = 8t - 4.9t^2\)	M1	Equating their \(y\) to \(\pm 3.6\) or equiv. Any form.
Use of formula or \(4.9(t-2)(t + \frac{18}{49}) = 0\)	M1	A method for solving a 3 term quadratic to give at least 1 root. Allow their \(y\) and re-arrangement errors.
Roots are \(2\) and \(-\frac{18}{49}\) \((= -0.367346...)\)	A1	WWW. Accept no reference to \(2^{nd}\) root. [Award SC3 for \(t = 2\) seen WWW]
Horizontal distance is \(12 \times 2 = 24\)	M1	FT their \(x\) and \(t\).
\(24\) m	F1	FT only their \(t\) (as long as it is \(+\)ve and is not obtained with sign error(s) e.g. \(-\)ve sign just dropped)

Part (ii) - Method 2:

Answer	Marks	Guidance
Answer/Working	Mark	Guidance
Require \(y = -3.6\), so \(-3.6 = 8t - 4.9t^2\); eliminate \(t\) between \(x = 12t\) and \(-3.6 = 8t - 4.9t^2\)	M1	Equating their \(y\) to \(\pm 3.6\) or equiv. Any form.
M1	Expressions in any form. Elimination must be complete.
\(0 = 3.6 + \frac{8x}{12} - \frac{4.9x^2}{144}\)	A1	Accept in any form. May be implied.
Use of formula or factorise	M1	A method for solving a 3 term quadratic to give at least 1 root. Allow their \(y\) and re-arrangement errors.
\(+\)ve root is \(24\), so \(24\) m	F1	FT from their quadratic after re-arrangement. Must be \(+\)ve.

Part (ii) - Method 3 (sections):

Answer	Marks	Guidance
Answer/Working	Mark	Guidance
Combination of A, B and C may be used	M1	Attempt to find times or distances for sections that give the total horizontal distance travelled
M1	Correct method for one section to find time or distance
(A) \(0.8163..\) s; \(9.7959..\) m: (B) \(0.816...\)s; \(9.7959..\) m	A1	Any time or distance for a section correct
(C): \(0.3673...\) s; \(4.4081...\) m	A1	\(2^{nd}\) time or distance correct (The two sections must not be A and B)
A1	cao

## Question 6:

### Part (i):

| Answer/Working | Mark | Guidance |
|---|---|---|
| Vertical: $y = 8t - 4.9t^2$ | M1 | Use of $s = ut + 0.5at^2$ with $g = \pm 9.8, \pm 10$. Accept $u = 0$ or $14.4...$ or $14.4\sin\theta$ or $u\sin\theta$ but not 12. Allow use of $+3.6$. |
| | A1 | Accept derivation of $-4.9$ not clear. cao |
| Horizontally $x = 12t$ | B1 | |

### Part (ii) - Method 1:

| Answer/Working | Mark | Guidance |
|---|---|---|
| Require $y = -3.6$, so $-3.6 = 8t - 4.9t^2$ | M1 | Equating **their** $y$ to $\pm 3.6$ or equiv. Any form. |
| Use of formula or $4.9(t-2)(t + \frac{18}{49}) = 0$ | M1 | A method for solving a 3 term quadratic to give at least 1 root. Allow **their** $y$ and re-arrangement errors. |
| Roots are $2$ and $-\frac{18}{49}$ $(= -0.367346...)$ | A1 | WWW. Accept no reference to $2^{nd}$ root. [Award SC3 for $t = 2$ seen WWW] |
| Horizontal distance is $12 \times 2 = 24$ | M1 | FT **their** $x$ and $t$. |
| $24$ m | F1 | FT only **their** $t$ (as long as it is $+$ve and is not obtained with sign error(s) e.g. $-$ve sign just dropped) |

### Part (ii) - Method 2:

| Answer/Working | Mark | Guidance |
|---|---|---|
| Require $y = -3.6$, so $-3.6 = 8t - 4.9t^2$; eliminate $t$ between $x = 12t$ and $-3.6 = 8t - 4.9t^2$ | M1 | Equating **their** $y$ to $\pm 3.6$ or equiv. Any form. |
| | M1 | Expressions in any form. Elimination must be complete. |
| $0 = 3.6 + \frac{8x}{12} - \frac{4.9x^2}{144}$ | A1 | Accept in any form. May be implied. |
| Use of formula or factorise | M1 | A method for solving a 3 term quadratic to give at least 1 root. Allow **their** $y$ and re-arrangement errors. |
| $+$ve root is $24$, so $24$ m | F1 | FT from **their** quadratic after re-arrangement. Must be $+$ve. |

### Part (ii) - Method 3 (sections):

| Answer/Working | Mark | Guidance |
|---|---|---|
| Combination of A, B and C may be used | M1 | Attempt to find times or distances for sections that give the total horizontal distance travelled |
| | M1 | Correct method for one section to find time or distance |
| (A) $0.8163..$ s; $9.7959..$ m: (B) $0.816...$s; $9.7959..$ m | A1 | Any time or distance for a section correct |
| (C): $0.3673...$ s; $4.4081...$ m | A1 | $2^{nd}$ time or distance correct (The two sections must not be A and B) |
| | A1 | cao |

---

Show LaTeX source

6 A small ball is kicked off the edge of a jetty over a calm sea. Air resistance is negligible. Fig. 6 shows

\begin{itemize}
  \item the point of projection, O,
  \item the initial horizontal and vertical components of velocity,
  \item the point A on the jetty vertically below O and at sea level,
  \item the height, OA , of the jetty above the sea.
\end{itemize}

\begin{figure}[h]
\begin{center}
  \includegraphics[alt={},max width=\textwidth]{bb65e726-a5e0-4060-81a6-6837dea82e64-4_451_1000_596_600}
\captionsetup{labelformat=empty}
\caption{Fig. 6}
\end{center}
\end{figure}

The time elapsed after the ball is kicked is $t$ seconds.\\
(i) Find an expression in terms of $t$ for the height of the ball above O at time $t$. Find also an expression for the horizontal distance of the ball from O at this time.\\
(ii) Determine how far the ball lands from A .

\hfill \mbox{\textit{OCR MEI M1  Q6 [8]}}

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