IB Maths AI HL Sample Mean Distributions Paper 1 & 2 ~6 min read

The Central Limit Theorem

Last topic, ∼ N(μ, σ2n) only worked because the population X was normal. The Central Limit Theorem (CLT) removes that condition: take a large enough sample from any distribution — even a weird, skewed, or discrete one — and the sample mean is approximately normal. In the exam, “large enough” means n > 30. That’s the whole idea — and it’s what lets you do normal-distribution probabilities on populations that aren’t normal at all.

📘 What you need to know

What the CLT says

Whatever shape the population X has, if you take a big enough random sample and average it, the distribution of those averages is approximately normal, centred on μ with variance σ2n.

Central Limit Theorem for large n:   ≈ N(μ, σ2n) NOT in the booklet — know the n > 30 rule ✗

🤔 Why does averaging “normalise” a weird distribution?

A single draw can land anywhere, but an average of many draws smooths out the extremes — high and low values cancel. The more values you average, the more the bumps and skew of the original distribution wash away, leaving the familiar bell shape. The bigger n is, the better the normal approximation.

Any population → normal sample mean
population X (skewed) take samples of size n > 30, average each sample mean X̄ (normal) μ
The population can be any shape; averaging large samples gives an approximately normal X̄ centred on μ.

When do I actually need it?

This is the part examiners test in the “explain” questions. The deciding factor is only whether the population is normal — not the sample size on its own.

Population is normal
CLT not needed
is exactly normal for any n — even small samples.
Population not normal
CLT needed
is only approximately normal, and only because n > 30.

🧠 Memory aid — “normal population? skip the theorem”

Ask one question: is the original population normal? If yes is normal automatically, no CLT. If no → you lean on the CLT, and you must check the sample is large (n > 30). The maths you do is identical either way; only the justification changes.

🧭 Recipe — a CLT probability question

  1. Read off the population mean μ, variance σ2, and sample size n.
  2. Check n > 30 (if the population isn’t normal) — this licenses the approximation.
  3. Model ≈ N(μ, σ2n) and find SD = σ2n for the GDC.
  4. Run the normal CD with the right limits and round (3 sf).
WE 1

Mean of a sample (Susie’s counters)

Counters numbered 1 to 29 are in a bag. One pick has expected value 15 and variance 70. Susie picks 40 integers (replacing each one) and finds their mean. Find the probability that the mean of her 40 numbers is less than 13.

n large (40 > 30) → CLT applies X̄ ≈ N(15, 70/40) = N(15, 1.75) SD for the GDC σ = √1.75 ≈ 1.32 P(X̄ < 13): lower = −999…, upper = 13 = 0.065285… P(X̄ < 13) ≈ 0.0653 (3sf) enter μ = 15, σ = √1.75 — use the SD, not the variance 1.75.
WE 2

Was the CLT necessary?

For the counters in WE 1, explain whether it was necessary to use the Central Limit Theorem.

check: is the population normal? the number on a counter is uniform over 1–29, NOT normal. conclusion Yes — CLT was necessary because the variable for the number picked is not normally distributed, so X̄ is only approximately normal thanks to n > 30.
WE 3

When the CLT is NOT needed

A population is X ∼ N(15, 70). A sample of n = 8 is taken. Explain whether the CLT is needed to model , and state its distribution.

is the population normal? yes — X is already N(15, 70) so X̄ is exactly normal, any n CLT not needed X̄ ∼ N(15, 70/8) = N(15, 8.75) a normal population gives a normal X̄ even with a small sample (n = 8).
WE 4

A “greater than” CLT probability

Using Susie’s counters (μ = 15, σ2 = 70, n = 40), find the probability that the mean of her 40 numbers is greater than 16.

model the sample mean X̄ ≈ N(15, 1.75), σ = √1.75 ≈ 1.32 P(X̄ > 16): lower = 16, upper = 999… = 0.224846… P(X̄ > 16) ≈ 0.225 (3sf) “greater than” → lower limit 16, large upper limit on the GDC.
WE 5

A range for the sample mean

For the same counters (μ = 15, σ2 = 70, n = 40), find the probability that the sample mean lies between 14 and 16.

model the sample mean X̄ ≈ N(15, 1.75), σ = √1.75 ≈ 1.32 P(14 < X̄ < 16): lower = 14, upper = 16 = 0.550308… P(14 < X̄ < 16) ≈ 0.550 (3sf) a range just uses both limits directly in the normal CD.

💡 Top tips

⚠ Common mistakes

Next up — the Confidence Interval for the Mean. A single sample mean is only a point estimate; a confidence interval gives a range the true mean μ is likely to sit in. The CLT (or a normal population) is exactly what makes those intervals valid, and you’ll choose a z-interval or t-interval depending on whether σ is known.

Need help with Sample Mean Distributions?

Get 1-on-1 help from an IB examiner who knows exactly what Paper 1 & 2 are looking for.

Book Free Session →