IB Maths AI HL Sample Mean Distributions Paper 1 & 2 ~7 min read

Sample Mean Distributions

Add or scale independent normal variables and the result is still normal — you just track the new mean and variance. The big idea here is the sample mean : take a sample of n values and average them. The averages have the same mean μ as the population but a smaller variance, σ2n. Bigger sample → tighter spread. Once you have the distribution of , every probability is just a normal-distribution GDC calculation.

📘 What you need to know

Combining normal variables

Take independent normals X1, …, Xn and build a linear combination X = a1X1 + … + anXn + b. The result is also normal — so you only need its mean and variance to do probabilities.

Distribution of a linear combination X ∼ N(a1μ1 + … + anμn + b,   a12σ12 + … + an2σn2) E(X) & Var(X) rules are in the booklet ✓ but “a sum of normals is normal” is NOT — know it ✗
The mean
always adds
E(X) works with or without independence — coefficients stay as they are.
The variance
needs independence
Var(X) only follows the rule if the variables are independent; coefficients are squared.

🧠 Memory aid — “square the coefficient, drop the constant”

When a variable is multiplied by a, its variance contribution is a2σ2 — the coefficient is squared. A standalone constant b moves the mean across but adds nothing to the variance (shifting data doesn’t change its spread).

🤔 Why is “3 presses” not the same as “3×W”?

Pressing a button three times gives three separate, independent draws W1 + W2 + W3, so the variance is σ2 + σ2 + σ2 = 3σ2. Multiplying one draw by 3 gives 3W, whose variance is 32σ2 = 9σ2. Same mean, very different spread — read the question carefully!

WE 1

Combining normals (Amber’s tea — distribution)

A vending machine dispenses water W ∼ N(100, 152) and milk M ∼ N(10, 22). Amber presses water 3 times and milk 2 times. The total is C = W1+W2+W3+M1+M2. Write down the distribution of C.

mean: add all five μ = 100+100+100+10+10 = 320 variance: add all five (independent) σ² = 15²+15²+15²+2²+2² = 683 a linear combination of normals is also normal C ∼ N(320, 683)
WE 2

A probability from the combination

Using C ∼ N(320, 683) from WE 1, find the probability that the total amount of liquid exceeds 360 ml.

set up the normal on the GDC μ = 320, σ = √683 ≈ 26.13 P(C > 360): lower = 360, upper = 9999… P(C > 360) = 0.062939… P(C > 360) ≈ 0.0629 (3sf) use √683 (not 683) as σ in the calculator.

The sample mean distribution

Take a sample of n observations from a population X and average them: = X1+…+Xnn. Different samples give different averages, so is itself a random variable — its distribution is the sample mean distribution. A single calculated average is one point estimate drawn from it.

Sample mean of a normal population X ∼ N(μ, σ2)  ⇒  ∼ N(μ, σ2n) NOT in the booklet — memorise it ✗
Where the variance comes from: E() = n = μ, and Var() = 2n2 = σ2n. Dividing a sum by n squares to dividing the variance by n2, but there are n terms — so the net effect is ÷ n.
More data → tighter sample mean
μ population X (or small n) X̄, moderate n X̄, large n
All three centre on μ; larger samples have variance σ²/n, so the curve gets narrower and taller.

🧭 Recipe — probability about a sample mean

  1. Write the population X ∼ N(μ, σ2) and read off μ, σ2, n.
  2. Form the sample mean: ∼ N(μ, σ2n).
  3. Convert variance to SD: enter σ = σ2n into the GDC, not the variance.
  4. Run the normal CD with the right lower/upper limits and round (3 sf).
WE 3

Distribution of a sample mean (Amber’s 15 cups)

Each cup of tea has C ∼ N(320, 683). Amber makes 15 cups and finds the mean . Write down the distribution of .

mean stays the same μ = 320 variance ÷ n σ²/n = 683/15 = 45.533… C̄ ∼ N(320, 683/15) keep 683/15 exact; for any probability later, GDC SD = √(683/15) ≈ 6.75.
WE 4

A probability for the sample mean

A population is X ∼ N(50, 82). A sample of n = 16 is taken. Find P( > 53).

form the sample mean distribution X̄ ∼ N(50, 8²/16) = N(50, 4) SD for the GDC σ = √4 = 2 P(X̄ > 53): lower = 53, upper = 9999… = 0.066807… P(X̄ > 53) ≈ 0.0668 (3sf) the sample mean SD (2) is 4× smaller than the population SD (8).
WE 5

Single value vs sample mean — the contrast

For X ∼ N(50, 82), compare P(X > 53) for a single observation with P( > 53) for a sample of 16.

single value: σ = 8 P(X > 53) = 0.354… ≈ 0.354 (3sf) sample mean: σ = 8/√16 = 2 P(X̄ > 53) = 0.0668… ≈ 0.0668 (3sf) an average of 16 is much less likely to stray 3 above μ than a single value.

💡 Top tips

⚠ Common mistakes

Next up — the Central Limit Theorem. So far we needed the population to be normal for to be normal. The CLT lifts that restriction: for a large enough sample (n > 30), the sample mean is approximately normal no matter what shape the population has — opening the door to confidence intervals for the mean.

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 →