MAT-326E

A sample space (Ω) is the set of all possible outcomes of a random experiment. An event is a subset of the sample space. Probability is a function P that assigns a number between 0 and 1 to each event, satisfying Kolmogorov’s axioms: P(Ω) = 1, probabilities are non-negative, and the probability of a union of mutually exclusive events is the sum of their individual probabilities.

Assignment questions at this stage often ask you to set up sample spaces for compound experiments (rolling dice, drawing cards, sampling components), then apply addition and multiplication rules. The common mistake is treating every problem as if outcomes are equally likely — which is only valid when the problem explicitly says so. Probability distributions come precisely from situations where outcomes are not equally likely.

Conditional probability — P(A | B), the probability of A given that B has occurred — is where the course introduces real complexity. The formula P(A | B) = P(A ∩ B) / P(B) looks simple but hides a lot: you need to figure out whether the problem gives you P(A ∩ B) directly or requires you to derive it. Most problems don’t hand you the intersection — you construct it from other information.

Two events are independent if P(A ∩ B) = P(A) · P(B), which is equivalent to saying P(A | B) = P(A). Independence is a mathematical condition, not an intuitive one. A common exam mistake is assuming independence because events “seem unrelated” — on MAT-326E, you must verify it algebraically, not assert it. Assignment problems specifically test whether you can distinguish independence from mutual exclusivity (which are different, and often confused).

Bayes’ theorem is used when you know the conditional probability in one direction and want the probability in the other. The classic engineering setup: you know the false-positive and true-positive rates of a test, and you want the probability that a positive test is actually correct given the prevalence of the condition in the population. Every Bayes’ problem has the same structure — it just gets dressed up in different contexts on different assignments.

The Law of Total Probability is usually the first step: P(B) = Σ P(B | Aᵢ) · P(Aᵢ), summing over all mutually exclusive and exhaustive events Aᵢ. Then Bayes follows naturally. The difficulty is correctly identifying what the partition is. Draw a tree diagram before writing equations — it organizes the conditional relationships visually and almost always makes the setup clear.

Bayes’ theorem problems appear on virtually every MAT-326E midterm and final. If you can’t set up the tree and identify P(Aᵢ), P(B | Aᵢ), and what the question is actually asking for, you lose marks on a high-weight question. Getting the Bayes setup right is one of the best places to invest practice time in this course.

The Binomial distribution — B(n, p) — models the number of successes in n independent, identical Bernoulli trials with success probability p. Key conditions: fixed number of trials, each trial independent, each trial binary (success/failure), constant p. If any condition fails, you’re not in Binomial territory. Mean = np, Variance = np(1−p).

The Negative Binomial distribution (or Pascal distribution) models the number of trials needed to achieve the rth success. If r = 1, it’s the Geometric distribution — the number of trials until the first success. Assignment problems on this distribution often swap between “number of trials” and “number of failures before success” formulations, which changes the PMF. Read the problem statement carefully before setting up.

The Poisson distribution models the number of events occurring in a fixed interval of time or space when events occur at a constant average rate λ and independently. P(X = k) = e^(−λ) · λᵏ / k!. Mean = Variance = λ. Poisson is also used as a limiting approximation for Binomial when n is large and p is small (λ ≈ np). Recognizing the Poisson setup: problems mentioning “on average X per hour,” “number of defects per unit,” or “arrivals per minute” are Poisson territory.

The Exponential distribution models the time between events in a Poisson process. If events arrive at rate λ per unit time, the waiting time between events is Exponential(λ). Its key property — memorylessness — means P(X > s + t | X > s) = P(X > t). Exam questions specifically test whether you recognize when memorylessness applies and when it doesn’t (it does for exponential; it doesn’t for most other distributions).

The Gamma distribution generalizes the exponential: it models the waiting time until the rth event in a Poisson process. When r = 1, it collapses to exponential. The Gamma(r, λ) distribution has mean r/λ and variance r/λ². The chi-square distribution — which comes up in hypothesis testing — is a special case of Gamma with specific parameters.

The Normal distribution N(μ, σ²) is the most important continuous distribution in MAT-326E. Its PDF has no closed-form integral — probabilities are computed by standardizing to Z = (X − μ)/σ and using Z-tables or statistical software. Assignments require fluency with: computing P(a < X < b) using the Z-table, finding quantiles (z-scores for given probabilities), and using the normal distribution as an approximation for Binomial when n is large (by the Central Limit Theorem).

The joint PDF f(x, y) describes the combined behavior of two continuous random variables X and Y. To compute P(X and Y lie in region R), you integrate f(x, y) over R. Getting the limits of integration right — especially for non-rectangular regions — is the most common source of lost marks on joint distribution problems.

The marginal PDF of X is obtained by integrating out y: f_X(x) = ∫ f(x, y) dy. This retrieves the distribution of X alone from the joint distribution. The conditional PDF of Y given X = x is f(y | x) = f(x, y) / f_X(x). Conditional distributions are the multivariate analog of conditional probability — the joint divided by the marginal of the conditioning variable.

Two random variables are independent if and only if f(x, y) = f_X(x) · f_Y(y) — the joint factors into the product of the marginals. This is the test for independence in multivariate problems. If the joint doesn’t factor, the variables are dependent. Many assignment problems ask you to test this and then compute expectations or variances accordingly.

Covariance Cov(X, Y) = E[XY] − E[X]E[Y] measures how X and Y move together. Positive covariance: they tend to increase together. Negative: when one increases, the other decreases. Zero covariance means no linear relationship — but not necessarily independence (independence implies zero covariance, but zero covariance does not imply independence).

Correlation ρ = Cov(X, Y) / (σ_X · σ_Y) standardizes covariance to the interval [−1, 1]. This is dimensionless — it doesn’t depend on the units of X and Y — which makes it interpretable and comparable. Assignments often ask you to compute E[XY] via a double integral, then plug into the covariance formula. The computation is mechanically straightforward; the setup of the integral is where errors happen.

A point estimator θ̂ is unbiased if E[θ̂] = θ — on average across repeated sampling, it equals the true parameter. The sample mean X̄ is an unbiased estimator of μ. The sample variance S² = Σ(Xᵢ − X̄)²/(n−1) is an unbiased estimator of σ² — note the n−1 denominator, which is why we divide by n−1 rather than n.

Estimators are also assessed by their efficiency (lower variance among unbiased estimators) and consistency (converges to the true parameter as n increases). The two main construction methods in MAT-326E are method of moments (match population moments to sample moments and solve for parameters) and maximum likelihood estimation (find the parameter value that makes the observed data most probable). MLE problems require setting up the likelihood function, taking its log, differentiating with respect to the parameter, and solving — a calculus-intensive process that appears on most MAT-326E exams.

A 95% confidence interval does not mean “there is a 95% probability that the true parameter lies in this interval.” The parameter is fixed — it either is or isn’t in the interval. What 95% means is that if you repeated the sampling procedure many times and built a confidence interval each time, 95% of those intervals would contain the true parameter. The interval is random; the parameter is not. This distinction appears explicitly on MAT-326E exams.

For a population mean with known σ: X̄ ± z_(α/2) · σ/√n. With unknown σ, replace z with the t critical value at n−1 degrees of freedom: X̄ ± t_(α/2, n−1) · S/√n. Wider intervals for smaller n, smaller α (more confidence), or larger variance — all of which make intuitive sense. Assignment problems often ask you to compute the interval, then interpret it, then determine the sample size needed to achieve a given margin of error. The sample size formula — n = (z_(α/2) · σ / E)² — comes from solving for n in the margin of error expression.

The simple linear regression model is Y = β₀ + β₁X + ε, where ε ~ N(0, σ²) is the random error term. The least squares estimates of the coefficients — β̂₁ = Σ(xᵢ − x̄)(yᵢ − ȳ) / Σ(xᵢ − x̄)² and β̂₀ = ȳ − β̂₁x̄ — minimize the sum of squared residuals. Assignment problems require computing these by hand from summary statistics (Σxᵢ, Σyᵢ, Σxᵢ², Σxᵢyᵢ, n) and interpreting the results in context.

Interpreting β̂₁: “for a one-unit increase in X, the predicted value of Y changes by β̂₁ units, holding all else constant.” Interpreting β̂₀: the predicted value of Y when X = 0 — only meaningful if X = 0 is within the range of the data. Extrapolation beyond the observed data range is dangerous and is tested explicitly on MAT-326E exams.

The significance of the regression slope is tested with H₀: β₁ = 0 (the predictor has no linear relationship with Y) against H₁: β₁ ≠ 0, using a t-test: t = β̂₁ / SE(β̂₁). If you reject H₀, there is evidence of a significant linear relationship. This test, along with the F-test of overall model significance and the coefficient of determination R², forms the core of a regression analysis write-up on MAT-326E assignments.