IB Maths AI HL Kinematics Paper 1 & 2 ~7 min read

Calculus for Kinematics

Displacement, velocity, and acceleration are linked by calculus. Differentiate to step down the chain sva; integrate to climb back up avs. Differentiation handles rates and “at rest”; integration recovers motion from a rate and, with limits, measures displacement and distance.

📘 What you need to know

The calculus chain

Differentiate down, integrate up
s displacement v velocity a acceleration differentiate differentiate integrate integrate
Differentiating moves sva; integrating moves avs. Acceleration is the second derivative of displacement.
The kinematics calculus links v = dsdt,   a = dvdt = d2sdt2,   s = ∫ v dt,   v = ∫ a dt ✓ these relationships are in the formula booklet

🧠 “Differentiate down, integrate up”

Going down the chain sva you differentiate; going up avs you integrate. Each integration brings a “+ c” you must pin down with a condition.

Displacement vs distance with integrals

Displacement v dt Signed. Areas below the time axis subtract — the net change in position.
Distance |v| dt All areas add. Split where v = 0, or integrate the modulus on a GDC.
Key point: displacement and distance agree only if the particle never reverses. If v changes sign in the interval, you must use |v| (or split at the turning times) for distance.

🧭 Recipe — motion from a rate

  1. Differentiate for v or a; integrate for v or s.
  2. Find “+ c using an initial (“initially”, t = 0) or boundary condition.
  3. “At rest”: solve v(t) = 0.
  4. Displacement over [t1, t2]: v dt.
  5. Distance: |v| dt — use the GDC’s modulus graph.

Worked examples

Examples 1–2 use displacement s(t) = 2t3 − 27t2 + 84t; examples 3–5 use velocity v(t) = 8t3 − 12t2 − 2t with the particle starting at the origin.

WE 1

Find v(t) and a(t) for s(t) = 2t3 − 27t2 + 84t

Differentiate once for v, again for a.

v(t) = s′(t) = 6t² − 54t + 84 = 6(t − 7)(t − 2) a(t) = v′(t) = 12t − 54 = 6(2t − 9)
WE 2

Find the times at which the particle is at rest.

“At rest” means v = 0 — use the factorised velocity.

v(t) = 0 → 6(t − 7)(t − 2) = 0 at rest at t = 2 s and t = 7 s
WE 3

Given the particle starts at the origin, find an expression for its displacement s(t).

Integrate v, then use s = 0 at t = 0 to fix c.

s(t) = ∫ (8t³ − 12t² − 2t) dt = 2t⁴ − 4t³ − t² + c at t = 0, s = 0 → c = 0 s(t) = 2t⁴ − 4t³ − t²
WE 4

Find the displacement from the origin in the first 5 seconds.

Definite integral of velocity from 0 to 5 (or substitute into s(t)).

s = 05 (8t³ − 12t² − 2t) dt = s(5) = 2(625) − 4(125) − 25 = 1250 − 500 − 25 displacement = 725 m
WE 5

Find the distance travelled in the first 5 seconds.

The velocity changes sign early on (around t ≈ 1.65), so use |v| — best done on the GDC.

d = 05 |8t³ − 12t² − 2t| dt GDC: 736.734… distance ≈ 737 m (3 s.f.) larger than displacement because the particle reverses

💡 Top tips

⚠ Common mistakes

That wraps up Kinematics. The unit began with the language of motion — displacement, velocity, and acceleration as signed quantities, with speed and distance as their unsigned shadows — and read them off a velocity–time graph. Here calculus made the links exact: differentiate down the sva chain, integrate up it, pin down the constant with an initial condition, and use definite integrals for displacement (v) and distance (|v|). The gradient-and-area intuition from the graph and the exact calculus are two views of the same motion.

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