Answers – 1.2 – Motion

IGCSE Physics  |  Practice Test — Answers & Worked Solutions

Section A — Recall
Questions 1–10
1.

Write down the definition of speed.

Answer

Speed is the distance travelled per unit time.

Speed = distance travelled ÷ time taken
Revision: Speed tells you how fast an object is moving, but not which direction. It is a scalar quantity (magnitude only). The standard unit of speed is metres per second (m/s).
2.

Write down the definition of velocity and explain how it differs from speed.

Answer

Velocity is speed in a given direction.

Velocity = speed + direction   (e.g. 30 m/s northward)
Revision: Speed only tells you how fast an object moves (scalar). Velocity also tells you which direction it moves (vector). For example, 30 m/s is a speed; 30 m/s north is a velocity. Two objects can have the same speed but different velocities if they are moving in different directions.
3.

Write down the equation for speed and state the unit of each quantity.

Answer
$$v = \frac{s}{t}$$
  • $v$ = speed  —  unit: m/s (metres per second)
  • $s$ = distance  —  unit: m (metres)
  • $t$ = time  —  unit: s (seconds)
$v = \dfrac{s}{t}$
Revision: You can rearrange this formula to find distance ($s = v \times t$) or time ($t = s \div v$). Always check that your units are consistent — distance in metres and time in seconds gives speed in m/s.
4.

State the approximate value of $g$, the acceleration of free fall near the surface of the Earth. Include the unit.

Answer
$g \approx 9.8\ \text{m/s}^2$
Revision: The value of $g$ is approximately constant near Earth’s surface. This means every freely falling object (with no air resistance) accelerates at the same rate — 9.8 m/s² — regardless of its mass. After 1 s it is falling at 9.8 m/s, after 2 s at 19.6 m/s, and so on.
5.

On a distance–time graph, what does a horizontal (flat) line tell you about the motion of an object?

Answer

A horizontal line means the distance is not changing. The object is at rest (stationary).

The object is at rest — it is not moving.
Revision: On a distance–time graph, the gradient (slope) equals the speed. A horizontal line has a gradient of zero, so speed = 0 → the object is stationary. A steeper upward slope means a higher speed.
6.

On a speed–time graph, a straight line slopes downward from a positive value to zero. What is the object doing?

Answer

The object is decelerating — its speed is decreasing at a constant rate until it stops.

The object is decelerating (slowing down at a constant rate).
Revision: On a speed–time graph: upward slope = accelerating; horizontal line = constant speed; downward slope = decelerating. A straight (not curved) line means the rate of change is constant.
7.

What physical quantity is represented by the area under a speed–time graph?

Answer
The area under a speed–time graph represents the distance travelled.
Revision: For a rectangle (constant speed), area = width × height = time × speed = distance. For a triangle (constant acceleration from rest), area = ½ × base × height. For a trapezium, use: distance = ½ × (v₁ + v₂) × t.
8.

Write down the definition of acceleration, state the equation used to calculate it, and give the unit of acceleration. Supplement

Answer

Acceleration is the change in velocity per unit time.

$$a = \frac{\Delta v}{\Delta t}$$
  • $a$ = acceleration — unit: m/s²
  • $\Delta v$ = change in velocity (final velocity − initial velocity) — unit: m/s
  • $\Delta t$ = time taken — unit: s
$a = \dfrac{\Delta v}{\Delta t}$    Unit: m/s²
Revision: $\Delta v$ means “change in velocity” = final velocity − initial velocity. If the object is slowing down, $\Delta v$ is negative, giving a negative acceleration (deceleration). Acceleration is a vector quantity — it has both magnitude and direction.
9.

Define terminal velocity. State the condition (in terms of forces) that causes a falling object to reach terminal velocity. Supplement

Answer

Terminal velocity is the maximum constant speed that a falling object reaches when the forces acting on it are balanced.

Terminal velocity is reached when air resistance = weight (net force = 0, so acceleration = 0).
Revision: At terminal velocity, the upward air resistance exactly equals the downward weight. Because the net force is zero, there is no acceleration — the object falls at a constant (terminal) velocity. A heavier object has a higher terminal velocity because it needs more air resistance (= greater speed) to balance its larger weight.
10.

On a speed–time graph, how can you tell the difference between constant acceleration and changing (non-constant) acceleration? Supplement

Answer
  • Constant acceleration → the speed–time graph shows a straight sloping line (the gradient is constant).
  • Changing acceleration → the speed–time graph shows a curved line (the gradient is changing).
Straight slope = constant acceleration  |  Curved line = changing acceleration
Revision: The gradient of a speed–time graph equals the acceleration. If the gradient is the same throughout (straight line), the acceleration is constant. If the gradient changes (curve), the acceleration is changing. A curve that becomes less steep indicates the acceleration is decreasing (as seen when an object approaches terminal velocity).
Section B — Application
Questions 11–20
11.

A car travels 200 m in 8 s. Calculate its speed.

Answer
  1. Formula: $$v = \frac{s}{t}$$
  2. Given: $s = 200\ \text{m}$, $t = 8\ \text{s}$
  3. Substitute: $$v = \frac{200}{8}$$
  4. Calculate: $$v = 25\ \text{m/s}$$
Speed = 25 m/s
Revision: Always write the formula first, then substitute. Check your units — distance in metres and time in seconds gives speed in m/s.
12.

A cyclist moves at a constant speed of 6 m/s. Calculate the distance the cyclist travels in 45 s.

Answer
  1. Formula: $s = v \times t$ (rearranged from $v = s/t$)
  2. Given: $v = 6\ \text{m/s}$, $t = 45\ \text{s}$
  3. Substitute: $$s = 6 \times 45$$
  4. Calculate: $$s = 270\ \text{m}$$
Distance = 270 m
Revision: When rearranging $v = s/t$, multiply both sides by $t$ to get $s = v \times t$. Speed × time = distance.
13.

A ball rolls at a speed of 3 m/s and covers a distance of 27 m. Calculate the time taken.

Answer
  1. Formula: $t = s \div v$ (rearranged from $v = s/t$)
  2. Given: $v = 3\ \text{m/s}$, $s = 27\ \text{m}$
  3. Substitute: $$t = \frac{27}{3}$$
  4. Calculate: $$t = 9\ \text{s}$$
Time = 9 s
Revision: Rearranging $v = s/t$: multiply both sides by $t$ then divide both sides by $v$ to get $t = s/v$.
14.

A bus travels 12 km in 20 minutes. Calculate the average speed of the bus in m/s.

Answer
  1. Convert units to metres and seconds:
    Distance: $12\ \text{km} = 12 \times 1000 = 12\,000\ \text{m}$
    Time: $20\ \text{min} = 20 \times 60 = 1\,200\ \text{s}$
  2. Formula: $$\text{average speed} = \frac{\text{total distance}}{\text{total time}}$$
  3. Substitute: $$\text{average speed} = \frac{12\,000}{1\,200}$$
  4. Calculate: $$\text{average speed} = 10\ \text{m/s}$$
Average speed = 10 m/s
Revision: Always convert to SI units before substituting: km → m (multiply by 1000); minutes → seconds (multiply by 60). Failure to convert units is a very common IGCSE mistake.
15.

A distance–time graph shows a straight line from the point (0 s, 0 m) to the point (5 s, 30 m). Calculate the speed of the object.

Answer
  1. Speed = gradient of the distance–time graph
  2. Formula: $$\text{speed} = \frac{\Delta s}{\Delta t}$$
  3. $\Delta s = 30 – 0 = 30\ \text{m}$,   $\Delta t = 5 – 0 = 5\ \text{s}$
  4. Substitute: $$\text{speed} = \frac{30}{5}$$
  5. Calculate: $$\text{speed} = 6\ \text{m/s}$$
Speed = 6 m/s
Revision: The gradient of a straight section of a distance–time graph equals the speed. Always use $\Delta s / \Delta t$ (change in distance over change in time) for the gradient, using two clearly separated points on the line.
16.

A speed–time graph shows a horizontal line at $v = 8$ m/s from $t = 0$ s to $t = 10$ s. Calculate the distance travelled by the object.

Answer
  1. Distance = area under the speed–time graph
  2. Shape: a rectangle (constant speed)
  3. Area = width × height = time × speed $$\text{Distance} = 10\ \text{s} \times 8\ \text{m/s}$$
  4. Calculate: $$\text{Distance} = 80\ \text{m}$$
Distance = 80 m
Revision: A horizontal line on a speed–time graph means constant speed. The area under the graph is a rectangle: area = base × height = time × speed = distance.
17.

A speed–time graph shows a straight line from (0 s, 0 m/s) to (6 s, 12 m/s). Calculate the distance travelled by the object.

Answer
  1. Distance = area under the speed–time graph
  2. Shape: a triangle (speed starts at zero and increases)
  3. Area = ½ × base × height $$\text{Distance} = \frac{1}{2} \times 6\ \text{s} \times 12\ \text{m/s}$$
  4. Calculate: $$\text{Distance} = 36\ \text{m}$$
Distance = 36 m
Revision: When speed starts at zero and increases at a constant rate, the area under the graph is a triangle. Use area = ½ × base × height. If the object does not start from rest, the shape is a trapezium — use area = ½(v₁ + v₂) × t.
18.

A motorcycle accelerates from 10 m/s to 30 m/s in 5 s. Calculate the acceleration. Supplement

Answer
  1. Formula: $$a = \frac{\Delta v}{\Delta t}$$
  2. Given: initial velocity = 10 m/s, final velocity = 30 m/s, $\Delta t = 5\ \text{s}$
  3. Change in velocity: $\Delta v = 30 – 10 = 20\ \text{m/s}$
  4. Substitute: $$a = \frac{20}{5}$$
  5. Calculate: $$a = 4\ \text{m/s}^2$$
Acceleration = +4 m/s²
Revision: $\Delta v$ = final velocity − initial velocity. A positive result means the object is speeding up. Always state the unit: m/s².
19.

A train decelerates from 40 m/s to 10 m/s in 6 s. Calculate the acceleration. State whether your answer is positive or negative and explain what the sign tells you. Supplement

Answer
  1. Formula: $$a = \frac{\Delta v}{\Delta t}$$
  2. Given: initial velocity = 40 m/s, final velocity = 10 m/s, $\Delta t = 6\ \text{s}$
  3. Change in velocity: $\Delta v = 10 – 40 = -30\ \text{m/s}$
  4. Substitute: $$a = \frac{-30}{6}$$
  5. Calculate: $$a = -5\ \text{m/s}^2$$
Acceleration = −5 m/s²

The answer is negative. This shows the train is decelerating — its velocity is decreasing. A negative acceleration means the acceleration acts in the opposite direction to the motion.

Revision: Deceleration is a negative acceleration. Always subtract in the correct order: $\Delta v$ = final − initial. If the final speed is lower than the initial speed, $\Delta v$ is negative, giving a negative acceleration.
20.

A speed–time graph shows a straight line from (0 s, 4 m/s) to (10 s, 14 m/s). Calculate the distance travelled during this time.

Answer
  1. Distance = area under the speed–time graph
  2. Shape: a trapezium (speed does not start from zero)
  3. Formula for trapezium area: $$\text{Distance} = \frac{1}{2}(v_1 + v_2) \times t$$
  4. Given: $v_1 = 4\ \text{m/s}$, $v_2 = 14\ \text{m/s}$, $t = 10\ \text{s}$
  5. Substitute: $$\text{Distance} = \frac{1}{2}(4 + 14) \times 10 = \frac{1}{2} \times 18 \times 10$$
  6. Calculate: $$\text{Distance} = 90\ \text{m}$$
Distance = 90 m
Revision: When the speed does not start from zero, the area under the graph is a trapezium. The trapezium rule is: ½ × (sum of parallel sides) × height = ½(v₁ + v₂) × t. You can also split it into a rectangle (4 m/s for 10 s = 40 m) plus a triangle (½ × 10 × 10 = 50 m) to get 90 m — same answer.
Section C — Challenge
Questions 21–25
21.

A speed–time graph for a car journey shows three phases:

  • Phase 1 — from $t = 0$ s to $t = 5$ s: speed increases from 0 to 20 m/s (straight line)
  • Phase 2 — from $t = 5$ s to $t = 15$ s: speed is constant at 20 m/s
  • Phase 3 — from $t = 15$ s to $t = 20$ s: speed decreases from 20 m/s to 0 (straight line)

(a) Describe the motion.   (b) Calculate the acceleration in Phase 1.   (c) Calculate the total distance.

Answer
0 5 10 15 20 0 5 10 15 20 25 Time (s) Speed (m/s) Phase 1 Phase 2 Phase 3 50 m 200 m 50 m

Speed–time graph for the car journey (shaded areas represent distance travelled in each phase)

(a) Description of motion
  • Phase 1 (0–5 s): The car is accelerating — speed increases at a constant rate from 0 to 20 m/s.
  • Phase 2 (5–15 s): The car moves at constant speed — 20 m/s with no acceleration.
  • Phase 3 (15–20 s): The car is decelerating — speed decreases at a constant rate from 20 m/s back to 0.
(b) Acceleration during Phase 1 Supplement
  1. Formula: $$a = \frac{\Delta v}{\Delta t}$$
  2. $\Delta v = 20 – 0 = 20\ \text{m/s}$,   $\Delta t = 5 – 0 = 5\ \text{s}$
  3. Substitute: $$a = \frac{20}{5}$$
  4. $$a = 4\ \text{m/s}^2$$
Acceleration = 4 m/s²
(c) Total distance travelled
  1. Distance = total area under the speed–time graph
  2. Phase 1 area (triangle): $$d_1 = \frac{1}{2} \times 5 \times 20 = 50\ \text{m}$$
  3. Phase 2 area (rectangle): $$d_2 = 10 \times 20 = 200\ \text{m}$$
  4. Phase 3 area (triangle): $$d_3 = \frac{1}{2} \times 5 \times 20 = 50\ \text{m}$$
  5. Total: $$d = 50 + 200 + 50 = 300\ \text{m}$$
Total distance = 300 m
Revision: For a multi-phase journey, split the area into recognisable shapes (triangles, rectangles, trapezoids) and add them. The gradient of the line in each phase tells you the acceleration. Phases 1 and 3 have the same gradient magnitude (4 m/s²) — Phase 1 is +4 m/s² (speeding up) and Phase 3 is −4 m/s² (slowing down).
22.

A speed–time graph for an accelerating object shows a straight line from the point (2 s, 6 m/s) to the point (8 s, 18 m/s). Calculate the acceleration of the object. Supplement

Answer
  1. Acceleration = gradient of the speed–time graph
  2. Formula: $$a = \frac{\Delta v}{\Delta t}$$
  3. $\Delta v = 18 – 6 = 12\ \text{m/s}$,   $\Delta t = 8 – 2 = 6\ \text{s}$
  4. Substitute: $$a = \frac{12}{6}$$
  5. Calculate: $$a = 2\ \text{m/s}^2$$
Acceleration = 2 m/s²
Revision: When the graph does not start at $t = 0$, you must still use $\Delta v / \Delta t$ — using the change in each quantity between the two given points. Do not use the raw values directly: it is the difference that matters.
23.

An object is released from rest and falls freely under gravity with no air resistance. (a) State the acceleration. (b) Calculate the speed after 4 s. (c) Sketch the speed–time graph.

Answer
(a) Acceleration
$g = 9.8\ \text{m/s}^2$ (downward)

The acceleration is equal to $g$, the acceleration of free fall, which is approximately constant at 9.8 m/s² near Earth’s surface.

(b) Speed after 4 s Supplement
  1. Use: $$a = \frac{\Delta v}{\Delta t} \implies \Delta v = a \times \Delta t$$
  2. Object released from rest: initial speed = 0 m/s
  3. $\Delta v = 9.8 \times 4$
    Written method: $(10 – 0.2) \times 4 = 40 – 0.8 = 39.2\ \text{m/s}$
  4. Final speed = initial speed + $\Delta v = 0 + 39.2 = 39.2\ \text{m/s}$
Speed after 4 s = 39.2 m/s
(c) Speed–time graph for free fall Supplement
(4 s, 39.2 m/s) 0 1 2 3 4 5 0 10 20 30 40 50 Time (s) Speed (m/s)

Speed–time graph for free fall (no air resistance). The line is straight because the acceleration is constant at 9.8 m/s².

Revision: Free fall with no air resistance means constant acceleration ($g = 9.8\ \text{m/s}^2$). On a speed–time graph this gives a straight line through the origin with gradient = 9.8 m/s². The shaded triangle area represents the distance fallen: at $t = 4$ s, distance = ½ × 4 × 39.2 = 78.4 m.
24.

A stone is dropped from rest through the air. Air resistance acts on the stone as it falls. (a) State the two forces. (b) Explain why acceleration decreases. (c) Describe terminal velocity and the force relationship. Supplement

Answer
(a) Two forces acting on the stone
1. Weight (gravitational force) — acting downward
2. Air resistance (drag) — acting upward, opposing the motion
(b) Why acceleration decreases
  1. At the start: weight is much greater than air resistance → large net downward force → large downward acceleration.
  2. As the stone speeds up, air resistance increases (drag increases with speed).
  3. The net force (weight − air resistance) therefore decreases.
  4. A smaller net force means a smaller acceleration — the stone is still speeding up, but more slowly.
As speed increases, air resistance increases, reducing the net force and therefore reducing the acceleration.
(c) Terminal velocity

At terminal velocity, the stone is falling at a constant speed — there is no acceleration. This happens because:

Air resistance = Weight   (net force = 0 → acceleration = 0 → constant speed)

The stone has reached its maximum speed and will continue to fall at this speed unless something changes.

Revision: The sequence is: large acceleration → decreasing acceleration → zero acceleration (terminal velocity). On a speed–time graph, this appears as a curve that gets less steep and eventually levels off into a horizontal line at the terminal velocity.
25.

A parachutist jumps from an aircraft and falls through the air. (a) Explain initial rapid acceleration. (b) Explain how air resistance affects acceleration. (c) State the condition for terminal velocity. (d) Describe what happens when the parachute opens. Supplement

Answer
(a) Why the parachutist accelerates rapidly at the start

At the moment of jumping, speed is zero, so air resistance is very small. The weight of the parachutist is much greater than the air resistance. There is a large net downward force, which causes a large downward acceleration.

Weight ≫ Air resistance → large net downward force → large downward acceleration.
(b) Effect of increasing air resistance on acceleration

As the parachutist falls faster:

  1. Air resistance increases (drag increases with speed).
  2. The net downward force (weight − air resistance) decreases.
  3. The acceleration decreases — the parachutist is still speeding up, but more slowly.
Air resistance increases → net force decreases → acceleration decreases (but still positive — still speeding up).
(c) Condition for terminal velocity
Terminal velocity is reached when: Air resistance = Weight
The net force is zero, so acceleration = 0 and speed is constant.
(d) Opening the parachute

When the parachute opens, the air resistance suddenly becomes much greater than the weight. This means:

  1. The net force is now upward (air resistance > weight).
  2. This upward net force causes an upward acceleration — a negative acceleration (deceleration).
  3. The parachutist’s speed decreases rapidly.
  4. As speed decreases, air resistance decreases until a new (much lower) terminal velocity is reached.
Sign of acceleration: negative (deceleration). The parachutist’s speed decreases rapidly.
Revision: The full sequence for a parachutist: (1) accelerates rapidly; (2) acceleration decreases as air resistance grows; (3) terminal velocity — constant speed; (4) parachute opens → large deceleration; (5) new, lower terminal velocity. This is a classic IGCSE extended-tier question. The key phrase is always: “net force = 0 → no acceleration → constant (terminal) velocity.”
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