For constant acceleration (straight line): area = ½ × base × height (triangle) + rectangle.
For horizontal section: area = base × height (rectangle).
SHAPES:
Horizontal line → constant velocity.
Straight line up → constant acceleration.
Straight line down → constant deceleration.
Curved → changing acceleration.
Using v² = u² + 2as
The equation v² = u² + 2as is useful when TIME is not given.
EXAMPLE:
A car starts from rest (u = 0) and accelerates at 3 m/s² over 75 m. Find the final speed.
v² = 0² + 2 × 3 × 75 = 450
v = √450 ≈ 21.2 m/s
EXAMPLE 2:
Car moving at 20 m/s decelerates at 4 m/s² to a stop. Find the braking distance.
v = 0, u = 20 m/s, a = −4 m/s²
0 = 400 + 2 × (−4) × s
8s = 400
s = 50 m
CALCULATING DISTANCE FROM v–t GRAPH:
Distance = area under the v–t graph.
Use triangle area (½bh) for constant acceleration from rest.
Use trapezium area for constant acceleration with initial velocity.
⚠️ Common Mistake
Gradient of a v–t graph = ACCELERATION (not distance or speed). Area under a v–t graph = DISTANCE. This is the opposite of the d–t graph where gradient = speed. Don't confuse the two graphs.
📐 Variables
aAcceleration (a) is measured in m/s² (m/s²)
vFinal velocity (v) is measured in m/s (m/s)
uInitial velocity (u) is measured in m/s (m/s)
tTime (t) is measured in seconds (s)
sDistance (s) is measured in metres (m)
📐 Key Equations
a = (v − u) ÷ t
v² = u² + 2as
📌 Key Note
a = (v−u)/t. v² = u² + 2as. Units: m/s². Positive a = speeding up; negative a = decelerating. v–t graph: gradient = acceleration; area = distance. Horizontal v–t = constant velocity. Steep v–t = large acceleration.
🎯 Matching Activity — Acceleration Calculations
Match each scenario to the correct acceleration or distance. — drag the symbols on the right to match the component names on the left.
4 m/s²
Drop here
−2 m/s²
Drop here
Area = distance
Drop here
Gradient = acceleration
Drop here
Car decelerates from 20 m/s to 0 in 10 s — a = −20÷10
The gradient of a velocity–time graph gives acceleration
The area under a velocity–time graph gives distance travelled
Velocity increases from 10 m/s to 30 m/s in 5 s — a = 20÷5
⚽ FIFA Worked Examples
Acceleration
A train accelerates from rest to 50 m/s in 25 s. Calculate the acceleration.
F
a = (v − u) ÷ t
I
v = 50 m/s, u = 0 m/s, t = 25 s
F
a = (50 − 0) ÷ 25 = 50 ÷ 25
A
a = 2 m/s²
🎯 Test Yourself
Question 1 of 2
1. A car decelerates from 24 m/s to 6 m/s in 9 s. What is the acceleration?
2. A v–t graph shows a straight horizontal line at 12 m/s for 6 seconds. What is the distance covered?
⭐ How Well Do You Understand This Topic?
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🤖 Ask Mr Badmus AI
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