IB Maths AI HL Further Integration Paper 1 & 2 ~6 min read

Integration by Substitution

Substitution is the systematic version of the reverse chain rule. You let u stand for the “messy inside”, swap every x and dx for u and du, and an awkward integral collapses into a simple one. Get the du step right and the rest is routine integration.

📘 What you need to know

The method

Integration by substitutionf(g(x)) g(x) dx = ∫ f(u) du,   where u = g(x) ✓ substitution result is in the formula booklet

🤔 Why can we treat du = g(x) dx?

The chain rule says dudx = g(x). Although dudx is a single derivative, in integration it behaves like a ratio, so multiplying across by dx gives du = g(x) dx. That tidy swap is exactly what replaces the x-part of the integral with a u-part.

🧠 “Let u, find du, swap, integrate, swap back”

Five beats: let u = inside, find du, swap everything into u, integrate, then swap back to x (or change limits for a definite integral).

Carrying it out

🧭 Recipe — substitution

  1. Let u = g(x) — the inside whose derivative is also present.
  2. Differentiate: dudx = g(x), so du = g(x) dx (rearrange for dx if needed).
  3. Substitute to get an integral purely in u.
  4. Integrate in u.
  5. Finish: substitute x back (indefinite, + c) or change limits to u and evaluate (definite).
Definite integrals — change the limits. If u = g(x), then the lower limit x = a becomes u = g(a) and the upper x = b becomes u = g(b). Then you never need to convert back to x.

Worked examples

WE 1

Find ∫ 2x(x2 + 1)4 dx

Let u = x²+1, so du = 2x dx — the 2x dx is already there.

u = x²+1, du = 2x dx ∫ u4 du = u55 (x²+1)55 + c
WE 2

Find ∫ x(x2 + 3)5 dx

Let u = x²+3, du = 2x dx. We only have x dx, so x dx = 12 du.

u = x²+3, du = 2x dx → x dx = ½ du 12 ∫ u5 du = 12 · u66 (x²+3)612 + c
WE 3

Find ∫ (2x + 1)(x2 + x + 4)3 dx

Let u = x²+x+4, so du = (2x+1) dx — matched exactly.

u = x²+x+4, du = (2x+1) dx ∫ u3 du = u44 (x²+x+4)44 + c
WE 4

Evaluate ∫01 2x(x2 + 1)4 dx by changing the limits

Same substitution as WE 1, but convert the limits: x=0 → u=1, x=1 → u=2.

u = x²+1; x:0→1 gives u:1→2 12 u4 du = u55 from 1 to 2 = 32515 315 (= 6.2)
WE 5

Find ∫ cos x (sin x)3 dx

Let u = sin x, so du = cos x dx — the cos x dx is present.

u = sin x, du = cos x dx ∫ u3 du = u44 (sin x)44 + c

💡 Top tips

⚠ Common mistakes

That wraps up Further Integration. The unit built one idea in layers: you started with the standard integrals for the special functions (1x, ex, sin, cos), met the reverse chain rule for spotting a composite alongside its inside’s derivative, and finished with substitution — the systematic tool that makes that reversal work every time by switching to a new variable u. Differentiation and integration stay mirror images: the chain rule going forwards, substitution coming back.

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