Statistics FRQs: The Assumptions & Conditions Checklist Every AP Student Needs

Why assumptions and conditions matter (and why graders care)

If you’ve spent any time with AP Statistics free-response questions (FRQs), you already know that the problem doesn’t stop once you crunch numbers. The College Board wants more than an answer: it wants reasoning that connects statistical methods to real-world data through the correct assumptions and conditions. In short, assumptions and conditions are the backbone of valid inference. Skipping them can cost points even when your calculations are flawless.

Photo Idea : A student’s desk with an open AP Statistics FRQ booklet, calculator, and colorful sticky notes labeled “Assumptions” and “Checks” — warm natural light, close-up to show notes and a handwritten checklist.

How graders read your FRQ responses

Picture this: a grader flips to your FRQ and sees a correct test statistic but no statement that the sample is random, or no check that the sample size is large enough for the sampling distribution approximation. That’s a missed opportunity. Graders look for both technical execution and scientific reasoning — the method you choose must be justified by conditions specific to the scenario. Explicitly stating and checking assumptions signals that you understand when and why a method applies.

Three common grading traps

Using a z-procedure but failing to check normality or large-n approximation.
Assuming independence without addressing randomness or sampling without replacement.
Claiming causation from observational studies without noting lack of random assignment.

Top-level checklist: decide the method first

Before you list conditions, identify which inference procedure the question demands. Is it a confidence interval for a mean? A significance test for a proportion? A two-sample t-test for paired data? Different procedures require different checks. Choosing the correct method is step zero — everything else flows from that decision.

Quick decision map (in your head)

If the parameter is a proportion → consider procedures for proportions (one-sample z, two-sample z for difference in proportions, chi-square for goodness of fit/independence).
If the parameter is a mean → consider t procedures (one-sample t, two-sample t, paired t).
If the question involves relationships between two quantitative variables → regression inference for slope.
If it’s categorical associations with more than two categories → chi-square procedures.

Assumptions and conditions: the universal checklist

Below is a compact, exam-ready checklist you can memorize and adapt to any FRQ. When you write your answer, explicitly cite the relevant items and apply them to the problem’s context.

Check	Why it matters	How to state it on the FRQ
Randomness/Independence	Guarantees that sample is representative and that sampling variability is modeled correctly.	“Assume the sample was randomly selected; observations are independent.”
10% Condition (when sampling without replacement)	Ensures independence approximately holds if sample ≤ 10% of population.	“Sample size is less than 10% of the population, so independence approximately holds.”
Success-Failure Condition (for proportions)	Needed for the sampling distribution of the sample proportion to be approximately normal.	“np̂ and n(1−p̂) are both at least 10 (or 5 depending on prompt); CLT applies.”
Sample Size / CLT (for means)	Large enough n lets sampling distribution of the mean be approximately normal; if small, check data shape.	“n≥30 so CLT applies (or if n<30, data appear approximately normal/no strong skew or outliers)."
Nearly Normal Condition	When n is small, normality of population distribution is needed for t-procedures.	“Dotplot/histogram shows no strong skew or outliers; normal model reasonable.”
Equal Variances (for two-sample t when assumed)	Some two-sample methods assume similar population variances; if not, use Welch’s t.	“No indication of very different variability; use two-sample t or Welch’s as appropriate.”
Paired vs Independent Samples	Mismatching the design invalidates the method; paired data require differences.	“Data are paired (or independent); proceed with paired t (or two-sample t).”
Random Assignment (for causal claims)	Only randomized experiments support causal inference, not observational studies.	“Because treatment was randomly assigned, causation can be argued (if applicable).”
Model Fit (chi-square)	Expected counts should be large enough (often ≥5) for chi-square approximation.	“All expected counts ≥5 so chi-square approximation is reasonable.”

How to phrase checks on the exam (concise and exam-friendly)

College Board graders appreciate clear, concise wording. You don’t need to write an essay — just name the condition, show it applies (with numbers or context), and state its consequence.

Examples of strong wording

“Random sample is stated in the prompt, so independence is reasonable.”
“n = 120 and p̂ = 0.35 so np̂ = 42 and n(1−p̂) = 78 ≥ 10; normal approximation holds.”
“n = 12 and the dotplot shows one outlier and right skew; t-procedure may not be appropriate.”
“Because subjects were randomly assigned to treatment and control, a causal conclusion is justified if the result is significant.”

Worked examples — apply the checklist

Nothing beats practice. Below are three short, typical FRQ scenarios and model responses that emphasize assumptions and conditions. Practice writing these sentences quickly — they’re worth points.

1) One-sample proportion FRQ

Prompt (paraphrased): A survey of 250 students found 65 said they prefer later school start times. Construct a 95% CI for the true proportion and interpret.

Checklist application (concise answer):

Method: One-sample z interval for a proportion.
Randomness: “Assume the sample is a random sample of students; observations independent.”
Success-failure: “np̂ = 250(0.26) = 65 and n(1−p̂) = 185, both ≥ 10, so normal approx. is reasonable.”
10% condition (if population size given): “250 ≤ 10% of the population of 5,000 students?” — check numerically and state conclusion.

2) Two-sample t-test FRQ (independent samples)

Prompt (paraphrased): Compare mean test scores for two teaching methods using samples of n1 = 18 and n2 = 22.

Checklist application:

Method: Two-sample t (use Welch’s t if variances appear different).
Randomness/Independence: “Samples are independent random samples; independence holds.”
Nearly normal / sample size: “Both sample sizes are < 30; check distributions. The histograms show approximate symmetry with no extreme outliers, so t-procedures are reasonable."
Equal variances: “Sample SDs are similar (s1 = 8.4, s2 = 7.9), so pooled variance is plausible; otherwise use Welch’s correction.”

3) Inference for regression slope

Prompt (paraphrased): A study records hours studied and exam scores for 40 students. Perform a significance test for slope.

Checklist application:

Method: t-test for slope (regression inference).
Linearity: “Scatterplot shows a roughly linear relationship between hours studied and score.”
Independence: “Assume observations are independent (random sample or randomized selection).”
Normality of residuals: “Residuals appear roughly normal from the residual plot; no strong skew.”
Equal variance (homoscedasticity): “Residuals show constant spread across predicted values.”

Short scripts you can memorize for the exam

Memorize short, flexible phrases that you can tweak for any context. Say them aloud during practice so they come easily on test day.

“Assume random sample; observations independent.”
“n is large so CLT applies (or: n is small but distribution looks approximately normal).”
“Success-failure holds: np̂ and n(1−p̂) ≥ 10.”
“Expected counts ≥ 5 so chi-square is appropriate.”
“Random assignment was used, so a causal inference is appropriate if significant.”

Common areas students fumble — and how to fix them

Students often lose points in predictable ways. Here’s how to avoid those pitfalls.

Not tying the condition to the context

Bad: “Independence holds.” Good: “Independence holds because the students were selected at random from the school roster, so observations are independent.” Always tie the condition to the scenario given in the prompt.

Confusing random sampling with random assignment

Random sampling supports generalizing to a population (external validity); random assignment supports causal claims (internal validity). State which one is present. If neither is present, explain the limitations: “Because this was an observational study without random assignment, we cannot conclude causation.”

Failing to check the right condition for the procedure

If you’re using a z-interval for proportions, state success-failure. If you’re using a t-test with n < 30, say something about normality or show from plots that the condition is reasonable.

Scoring-savvy tips: where to earn easy points

Always write the check before or immediately after you state the method — it helps the grader follow your logic.
When a prompt gives a population size, always mention the 10% condition if sampling without replacement could be an issue.
When sample size is borderline (e.g., n = 25), comment on data shape if such information is provided.
When asked for interpretation, connect results back to the context (“We are 95% confident that the true proportion of all students…”).

Practice checklist — printable quick reference

Here’s a compact checklist you can copy or transcribe into your formula sheet during review sessions:

Procedure	Minimum Checks	Quick Example Phrase
One-sample Proportion	Random sample/independence, Success-failure, 10% if relevant	“Random sample; np̂ and n(1−p̂) ≥ 10; 10% holds.”
One-sample Mean (t)	Random sample, CLT or nearly normal	“Random sample; n≥30 so CLT applies (or data approx normal).”
Two-sample Mean	Independence, sample size/normality, equal variances if pooling	“Independent samples; check distributions; use Welch’s if variances differ.”
Paired t	Paired design, differences roughly normal or large n	“Data are paired; differences appear approx normal.”
Chi-square	Randomness, expected counts ≥ 5, independence of observations	“Expected counts all ≥5 so chi-square approx holds.”
Regression Slope	Linearity, independence, normal residuals, constant variance	“Scatterplot roughly linear; residuals look normal with constant spread.”

Study strategies that actually help (not just cram)

It’s one thing to memorize a checklist; it’s another to internalize the reasoning. Integrate these strategies into your prep routine.

1) Annotated practice FRQs

When you practice an FRQ, annotate the prompt immediately: mark sample sizes, note wording that implies random sampling or random assignment, and write down which procedure you’ll use and why. This habit turns an intimidating page of text into a clear plan.

2) Build a conditions flashcard deck

Use flashcards with the name of a condition on one side and a one-sentence explanation plus an example on the other. Shuffle them, quiz a friend, or time yourself during practice sessions so you can state checks quickly under pressure.

3) Practice short statements aloud

Saying your checks aloud trains you to write them succinctly. Time yourself: can you identify method and conditions in 30–60 seconds? That speed is a test-day advantage.

4) Review past FRQs and released scoring guidelines

Study the language used in scoring guides to understand what graders reward. Pay attention to how assumptions are cited in model answers.

How personalized tutoring can accelerate this learning curve

Mastering assumptions and conditions is largely pattern recognition plus clear communication — both of which improve dramatically with focused practice and feedback. That’s where personalized tutoring shines. A 1-on-1 tutor can:

Identify the exact gaps in how you state conditions and coach you with short scripts to fix them.
Create tailored practice FRQs that target your weaknesses — for example, small-sample normality checks or regression residual interpretation.
Use AI-driven insights to track recurring mistakes and adjust practice schedules so every minute you spend is high-impact.

If you decide to work with a tutor, look for one who gives fast, focused feedback on your writing — a small change in phrasing can recover several points on FRQs.

Final checklist to write on test day (copy into scratch book)

Identify method (explicitly write it).
List the 2–4 required conditions for that method.
Apply each condition to the context (numbers or short context phrase).
Proceed with computations and interpretation.
Double-check: Did you mention randomization vs sampling? Did you address normality or success-failure? If claiming causation, did you justify it?

Parting encouragement

Assumptions and conditions are not a trap — they are your friend. They give structure to your statistical reasoning and make your answers persuasive. Spend time practicing the art of concise justification: it’s arguably the highest-return part of AP Statistics prep. With a few scripted phrases, a reliable checklist, and targeted practice (or a bit of personalized tutoring), you’ll turn what feels like annoying formalism into clear points on the page that earn points every time.

Photo Idea : A student meeting with a tutor (laptop open to a practice FRQ, tutor pointing to a checklist), showing collaborative study — emphasizes 1-on-1 guidance and tailored study plans.

Go into the exam calm and deliberate: pick the right tool, check the right boxes, and explain them clearly. That combination is what turns a correct calculation into a full-credit response. Good luck — you’ve got this.