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OCR MEI Paper 1 2024 June Q11
11 The first three terms of a geometric sequence are \(5 k - 2,3 k - 6 , k + 2\), where \(k\) is a constant.
  1. Show that \(k\) satisfies the equation \(k ^ { 2 } - 11 k + 10 = 0\).
  2. When \(k\) takes the smaller of the two possible values, find the sum of the first 20 terms of the sequence.
  3. When \(k\) takes the larger of the two possible values, find the sum to infinity of the sequence.
OCR MEI Paper 1 2024 June Q12
12 In this question the unit vectors \(\mathbf { i }\) and \(\mathbf { j }\) are in the \(x\) - and \(y\)-directions respectively.
The velocity \(\mathbf { v } \mathrm { m } \mathrm { s } ^ { - 1 }\) of a particle is given by \(\mathbf { v } = 3 \mathbf { i } + \left( 6 t ^ { 2 } - 5 \right) \mathbf { j }\). The initial position of the particle is \(7 \mathbf { j } \mathrm {~m}\).
  1. Find an expression for the position vector of the particle at time \(t \mathrm {~s}\).
  2. Find the Cartesian equation of the path of the particle.
OCR MEI Paper 1 2024 June Q13
13 The curve with equation \(\mathrm { y } = \mathrm { px } + \frac { 8 } { \mathrm { x } ^ { 2 } } + \mathrm { q }\), where \(p\) and \(q\) are constants, has a stationary point at \(( 2,7 )\).
  1. Determine the values of \(p\) and \(q\).
  2. Find \(\frac { d ^ { 2 } y } { d x ^ { 2 } }\).
  3. Hence determine the nature of the stationary point at (2, 7).
OCR MEI Paper 1 2024 June Q14
14 A man runs at a constant speed of \(4 \mathrm {~m} \mathrm {~s} ^ { - 1 }\) along a straight horizontal road. A woman is standing on a bridge that spans the road. At the instant that the man passes directly below the woman she throws a ball with initial speed \(u \mathrm {~ms} ^ { - 1 }\) at \(\alpha ^ { \circ }\) above the horizontal. The path of the ball is directly above the road. The man catches the ball 2.4 s after it is thrown. At the instant the man catches it, the ball is 3.6 m below the level of the point of projection.
  1. Explain what it means that the ball is modelled as a particle.
  2. Find the vertical component of the ball's initial velocity.
  3. Find each of the following.
    • The value of \(u\)
    • The value of \(\alpha\)
OCR MEI Paper 1 2024 June Q15
15 The circle \(x ^ { 2 } + y ^ { 2 } + 2 x - 14 y + 25 = 0\) has its centre at the point \(C\). The line \(7 y = x + 25\) intersects the circle at points A and B . Prove that triangle ABC is a right-angled triangle.
OCR MEI Paper 1 2024 June Q16
16 A block of mass \(m\) kg rests on rough horizontal ground. The coefficient of friction between the block and the ground is \(\mu\). A force of magnitude \(T \mathrm {~N}\) is applied at an angle \(\theta\) radians above the horizontal as shown in the diagram and the block slides without tilting or lifting.
\includegraphics[max width=\textwidth, alt={}, center]{1d0ca3d5-6529-435f-a0b8-50ea4859adde-10_291_707_388_239}
  1. Show that the acceleration of the block is given by \(\frac { T } { m } \cos \theta - \mu g + \frac { T } { m } \mu \sin \theta\). For a fixed value of \(T\), the acceleration of the block depends on the value of \(\theta\). The acceleration has its greatest value when \(\theta = \alpha\).
  2. Find an expression for \(\alpha\) in terms of \(\mu\).
OCR MEI Paper 1 2020 November Q1
2 marks
1 Simplify \(\left( \frac { 27 } { x ^ { 9 } } \right) ^ { \frac { 2 } { 3 } } \times \left( \frac { x ^ { 4 } } { 9 } \right)\).
[0pt] [2]
OCR MEI Paper 1 2020 November Q2
2 Express \(\frac { a + \sqrt { 2 } } { 3 - \sqrt { 2 } }\) in the form \(\mathrm { p } + \mathrm { q } \sqrt { 2 }\), giving \(p\) and \(q\) in terms of \(a\).
OCR MEI Paper 1 2020 November Q3
3 The points \(A\) and \(B\) have position vectors \(\mathbf { a } = \left( \begin{array} { r } 3
2
- 1 \end{array} \right)\) and \(\mathbf { b } = \left( \begin{array} { r } - 1
4
8 \end{array} \right)\) respectively.
Show that the exact value of the distance \(A B\) is \(\sqrt { \mathbf { 1 0 1 } }\).
OCR MEI Paper 1 2020 November Q4
4 Find the second derivative of \(\left( x ^ { 2 } + 5 \right) ^ { 4 }\), giving your answer in factorised form.
OCR MEI Paper 1 2020 November Q5
5 A child is running up and down a path. A simplified model of the child's motion is as follows:
  • he first runs north for 5 s at \(4 \mathrm {~m} \mathrm {~s} ^ { - 1 }\);
  • he then suddenly stops and waits for 8 s ;
  • finally he runs in the opposite direction for 7 s at \(3.5 \mathrm {~m} \mathrm {~s} ^ { - 1 }\).
    1. Taking north to be the positive direction, sketch a velocity-time graph for this model of the child's motion.
Using this model,
  • calculate the total distance travelled by the child,
  • find his final displacement from his original position.
    •
    OCR MEI Paper 1 2020 November Q6
    6 A uniform ruler AB has mass 28 g and length 30 cm . As shown in Fig. 6, the ruler is placed on a horizontal table so that it overhangs a point C at the edge of the table by 25 cm . A downward force of \(F \mathrm {~N}\) is applied at A . This force just holds the ruler in equilibrium so that the contact force between the table and the ruler acts through C . \begin{figure}[h]
    \includegraphics[alt={},max width=\textwidth]{7de77679-59c0-4431-a9cb-6ab11d2f9062-05_188_1431_502_246} \captionsetup{labelformat=empty} \caption{Fig. 6}
    \end{figure}
    1. Complete the force diagram in the Printed Answer Booklet, labelling the forces and all relevant distances.
    2. Calculate the value of \(F\). Answer all the questions.
      Section B (78 marks)
    OCR MEI Paper 1 2020 November Q8
    8 Fig. 8.1 shows the cross-section of a straight driveway 4 m wide made from tarmac. \begin{figure}[h]
    \includegraphics[alt={},max width=\textwidth]{7de77679-59c0-4431-a9cb-6ab11d2f9062-06_139_1135_1027_248} \captionsetup{labelformat=empty} \caption{Fig. 8.1}
    \end{figure} The height \(h \mathrm {~m}\) of the cross-section at a displacement \(x \mathrm {~m}\) from the middle is modelled by \(\mathrm { h } = \frac { 0.2 } { 1 + \mathrm { x } ^ { 2 } }\) for \(- 2 \leqslant x \leqslant 2\). A lower bound of \(0.3615 \mathrm {~m} ^ { 2 }\) is found for the area of the cross-section using rectangles as shown in Fig. 8.2. \begin{figure}[h]
    \includegraphics[alt={},max width=\textwidth]{7de77679-59c0-4431-a9cb-6ab11d2f9062-06_266_1276_1594_248} \captionsetup{labelformat=empty} \caption{Fig. 8.2}
    \end{figure}
    1. Use a similar method to find an upper bound for the area of the cross-section.
    2. Use the trapezium rule with 4 strips to estimate \(\int _ { 0 } ^ { 2 } \frac { 0.2 } { 1 + x ^ { 2 } } d x\).
    3. The driveway is 10 m long. Use your answer in part (b) to find an estimate of the volume of tarmac needed to make the driveway.
    OCR MEI Paper 1 2020 November Q9
    9 A particle is moving in a straight line. The acceleration \(a \mathrm {~m} \mathrm {~s} ^ { - 2 }\) of the particle at time \(t \mathrm {~s}\) is given by \(\mathrm { a } = 0.8 \mathrm { t } + 0.5\). The initial velocity of the particle is \(3 \mathrm {~m} \mathrm {~s} ^ { - 1 }\) in the positive \(x\)-direction. Determine whether the particle is ever stationary.
    OCR MEI Paper 1 2020 November Q11
    11 A block of mass 2 kg is placed on a rough horizontal table. A light inextensible string attached to the block passes over a smooth pulley attached to the edge of the table. The other end of the string is attached to a sphere of mass 0.8 kg which hangs freely. The part of the string between the block and the pulley is horizontal. The coefficient of friction between the table and the block is 0.35 . The system is released from rest.
    1. Draw a force diagram showing all the forces on the block and the sphere.
    2. Write down the equations of motion for the block and the sphere.
    3. Show that the acceleration of the system is \(0.35 \mathrm {~m} \mathrm {~s} ^ { - 2 }\).
    4. Calculate the time for the block to slide the first 0.5 m . Assume the block does not reach the pulley.
    OCR MEI Paper 1 2020 November Q12
    12 A function is defined by \(\mathrm { f } ( x ) = x ^ { 3 } - x\).
    1. By considering \(\frac { f ( x + h ) - f ( x ) } { h }\), show from first principles that \(f ^ { \prime } ( x ) = 3 x ^ { 2 } - 1\).
    2. Sketch the gradient function \(\mathrm { f } ^ { \prime } ( x )\).
    3. Show that the curve \(y = f ( x )\) has a single point of inflection which is not a stationary point.
    OCR MEI Paper 1 2020 November Q13
    13 A projectile is fired from ground level at \(35 \mathrm {~m} \mathrm {~s} ^ { - 1 }\) at an angle of \(\theta ^ { \circ }\) above the horizontal.
    1. State a modelling assumption that is used in the standard projectile model.
    2. Find the cartesian equation of the trajectory of the projectile. The projectile travels above horizontal ground towards a wall that is 110 m away from the point of projection and 5 m high. The projectile reaches a maximum height of 22.5 m .
    3. Determine whether the projectile hits the wall.
    OCR MEI Paper 1 2020 November Q14
    14 Douglas wants to construct a model for the height of the tide in Liverpool during the day, using a cosine graph to represent the way the height changes. He knows that the first high tide of the day measures 8.55 m and the first low tide of the day measures 1.75 m . Douglas uses \(t\) for time and \(h\) for the height of the tide in metres. With his graph-drawing software set to degrees, he begins by drawing the graph of \(\mathrm { h } = 5.15 + 3.4\) cost.
    1. Verify that this equation gives the correct values of \(h\) for the high and low tide. Douglas also knows that the first high tide of the day occurs at 1 am and the first low tide occurs at 7.20 am. He wants \(t\) to represent the time in hours after midnight, so he modifies his equation to \(h = 5.15 + 3.4 \cos ( a t + b )\).
      1. Show that Douglas's modified equation gives the first high tide of the day occurring at the correct time if \(\mathrm { a } + \mathrm { b } = 0\).
      2. Use the time of the first low tide of the day to form a second equation relating \(a\) and \(b\).
      3. Hence show that \(a = 28.42\) correct to 2 decimal places.
    3. Douglas can only sail his boat when the height of the tide is at least 3 m . Use the model to predict the range of times that morning when he cannot sail.
    4. The next high tide occurs at 12.59 pm when the height of the tide is 8.91 m . Comment on the suitability of Douglas's model.
    OCR MEI Paper 1 2020 November Q15
    15 Fig. 15 shows a particle of mass \(m \mathrm {~kg}\) on a smooth plane inclined at \(30 ^ { \circ }\) to the horizontal. Unit vectors \(\mathbf { i }\) and \(\mathbf { j }\) are parallel and perpendicular to the plane, in the directions shown. \begin{figure}[h]
    \includegraphics[alt={},max width=\textwidth]{7de77679-59c0-4431-a9cb-6ab11d2f9062-09_369_536_349_246} \captionsetup{labelformat=empty} \caption{Fig. 15}
    \end{figure}
    1. Express the weight \(\mathbf { W }\) of the particle in terms of \(m , g , \mathbf { i }\) and \(\mathbf { j }\). The particle is held in equilibrium by a force \(\mathbf { F }\), and the normal reaction of the plane on the particle is denoted by \(\mathbf { R }\). The units for both \(\mathbf { F }\) and \(\mathbf { R }\) are newtons.
    2. Write down an equation relating \(\mathbf { W } , \mathbf { R }\) and \(\mathbf { F }\).
    3. Given that \(\mathbf { F } = 6 \mathbf { i } + 8 \mathbf { j }\),
      • show that \(m = 1.22\) correct to 3 significant figures,
      • find the magnitude of \(\mathbf { R }\).
    OCR MEI Paper 1 2021 November Q1
    1 Beth states that for all real numbers \(p\) and \(q\), if \(p ^ { 2 } > q ^ { 2 }\) then \(p > q\). Prove that Beth is not correct.
    OCR MEI Paper 1 2021 November Q2
    2 An unmanned spacecraft has a weight of 5200 N on Earth. It lands on the surface of the planet Mars where the acceleration due to gravity is \(3.7 \mathrm {~m} \mathrm {~s} ^ { - 2 }\). Calculate the weight of the spacecraft on Mars.
    OCR MEI Paper 1 2021 November Q3
    3
    1. The diagram shows the line \(y = x + 5\) and the curve \(y = 8 - 2 x - x ^ { 2 }\). The shaded region is the finite region between the line and the curve. The curved part of the boundary is included in the region but the straight part is not included. Write down the inequalities that define the shaded region.
      \includegraphics[max width=\textwidth, alt={}, center]{4fac72cb-85cb-48d9-8817-899ef3f80a0f-04_846_716_1379_322} \section*{(b) In this question you must show detailed reasoning.} Solve the inequality \(8 - 2 x - x ^ { 2 } > x + 5\) giving your answer in exact form.
    OCR MEI Paper 1 2021 November Q4
    4
    1. The first four terms of a sequence are \(2,3,0,3\) and the subsequent terms are given by \(\mathrm { a } _ { \mathrm { k } + 4 } = \mathrm { a } _ { \mathrm { k } }\).
      1. State what type of sequence this is.
      2. Find \(\sum _ { \mathrm { k } = 1 } ^ { 200 } \mathrm { a } _ { \mathrm { k } }\).
    2. A different sequence is given by \(\mathrm { u } _ { \mathrm { n } } = \mathrm { b } ^ { \mathrm { n } }\) where \(b\) is a constant and \(n \geqslant 1\).
      1. State the set of values of \(b\) for which this is a divergent sequence.
      2. In the case where \(b = \frac { 1 } { 3 }\), find the sum of all the terms in the sequence.
    OCR MEI Paper 1 2021 November Q5
    5 ABCD is a rectangular lamina in which AB is 30 cm and AD is 10 cm .
    Three forces of 20 N and one force of 30 N act along the sides of the lamina as shown in the diagram.
    \includegraphics[max width=\textwidth, alt={}, center]{4fac72cb-85cb-48d9-8817-899ef3f80a0f-05_558_981_1263_233} An additional force \(F \mathrm {~N}\) is also applied at right angles to AB to a point on the edge \(\mathrm { AB } x \mathrm {~cm}\) from A .
    1. Given that the lamina is in equilibrium, calculate the values of \(F\) and \(x\). The point of application of the force \(F \mathrm {~N}\) is now moved to B , but the magnitude and direction of the force remain the same.
    2. Explain the effect of the new system of forces on the lamina.
    OCR MEI Paper 1 2021 November Q6
    6
    1. The diagram shows part of the graph of \(\mathrm { y } = \operatorname { cosec } \mathrm { x }\), where \(x\) is in radians. State the equations of the three vertical asymptotes that can be seen.
      \includegraphics[max width=\textwidth, alt={}, center]{4fac72cb-85cb-48d9-8817-899ef3f80a0f-06_734_672_603_324} The tangent to the graph at the point P with \(x\)-coordinate \(\frac { \pi } { 3 }\) meets the \(x\)-axis at Q .
    2. Show that the \(x\)-coordinate of Q is \(\frac { \pi } { 3 } + \sqrt { 3 }\). (You may use without proof the result that the derivative of \(\operatorname { cosec } x\) is \(- \operatorname { cosec } x \cot x\).)