Engineering at Dartmouth meant Rachel lived in data — running experiments, interpreting distributions, and making decisions based on probability and hypothesis testing. She brings that practical fluency to statistics tutoring, connecting concepts like standard deviation and confidence intervals to real scenarios instead of leaving them as abstract formulas.

Understanding when to use a t-test versus a z-test, or why a sampling distribution behaves the way it does, requires more than formula sheets — it takes genuine statistical intuition. Brian built that intuition through his economics coursework at Caltech, where statistical analysis was a daily tool, and he walks students through each concept with concrete data examples.

Most students walk into statistics expecting another math class and get blindsided by the emphasis on interpretation — explaining what a confidence interval actually means, or why correlation isn't causation. Amber tackles that interpretive layer head-on, teaching students to read context before crunching numbers. Her theater background gives her a knack for making abstract concepts like probability distributions feel concrete and memorable.

Running regression analyses, interpreting p-values, and choosing between parametric and nonparametric tests are things Martha does routinely in her social psychology research at Michigan. That hands-on fluency means she can explain not just how to compute a standard deviation or set up a hypothesis test, but why each step matters and what the results actually tell you. Rated 5.0 by students.

Understanding statistics means learning to think critically about variability, probability, and what data can actually tell you. Tashina applies statistical methods daily in her PhD research in brain sciences — hypothesis testing, confidence intervals, regression — and she unpacks each concept by connecting it to the kind of real analysis questions that make the material stick.

Probability distributions, hypothesis testing, and regression can feel like a foreign language the first time through. Nina breaks these concepts down by connecting them to real datasets and research questions drawn from her biostatistics training at Columbia and NYU. Rated 5.0 by students, she's especially effective at making the jump from formulas to interpretation feel intuitive.

A PhD statistician who also holds a biomedical engineering degree, Sam teaches introductory and intermediate statistics with an unusual amount of real-world context. Whether the topic is hypothesis testing, confidence intervals, or regression, he unpacks the logic behind each method so students can interpret results critically, not just run calculations.

Kathy's economics degree from Duke meant living inside datasets — regression analysis, probability distributions, hypothesis testing, and statistical inference were daily tools, not abstract concepts. She breaks down problems by connecting the math to what the numbers actually represent, which makes interpreting results feel intuitive rather than formulaic.

Studying Philosophy, Politics, and Economics at Penn means Kevin encounters statistics not as an abstract math course but as a tool for answering real questions — polling reliability, economic trends, policy evaluation. He unpacks topics like probability distributions, hypothesis testing, and regression with that applied lens. Students come away understanding not just how to compute a standard deviation but what it actually tells them.

An economics degree means Maggie didn't just study statistics in a textbook — she applied distributions, hypothesis testing, and regression analysis to real datasets. She teaches students to interpret what a p-value actually tells them and how to choose the right test for a given scenario, building the kind of statistical intuition that carries through exams and research projects alike.

Engineering at Dartmouth meant Rachel lived in data — running experiments, interpreting distributions, and making decisions based on probability and hypothesis testing. She brings that practical fluency to statistics tutoring, connecting concepts like standard deviation and confidence intervals to real scenarios instead of leaving them as abstract formulas.

Understanding when to use a t-test versus a z-test, or why a sampling distribution behaves the way it does, requires more than formula sheets — it takes genuine statistical intuition. Brian built that intuition through his economics coursework at Caltech, where statistical analysis was a daily tool, and he walks students through each concept with concrete data examples.

Most students walk into statistics expecting another math class and get blindsided by the emphasis on interpretation — explaining what a confidence interval actually means, or why correlation isn't causation. Amber tackles that interpretive layer head-on, teaching students to read context before crunching numbers. Her theater background gives her a knack for making abstract concepts like probability distributions feel concrete and memorable.

Running regression analyses, interpreting p-values, and choosing between parametric and nonparametric tests are things Martha does routinely in her social psychology research at Michigan. That hands-on fluency means she can explain not just how to compute a standard deviation or set up a hypothesis test, but why each step matters and what the results actually tell you. Rated 5.0 by students.

Understanding statistics means learning to think critically about variability, probability, and what data can actually tell you. Tashina applies statistical methods daily in her PhD research in brain sciences — hypothesis testing, confidence intervals, regression — and she unpacks each concept by connecting it to the kind of real analysis questions that make the material stick.

Probability distributions, hypothesis testing, and regression can feel like a foreign language the first time through. Nina breaks these concepts down by connecting them to real datasets and research questions drawn from her biostatistics training at Columbia and NYU. Rated 5.0 by students, she's especially effective at making the jump from formulas to interpretation feel intuitive.

A PhD statistician who also holds a biomedical engineering degree, Sam teaches introductory and intermediate statistics with an unusual amount of real-world context. Whether the topic is hypothesis testing, confidence intervals, or regression, he unpacks the logic behind each method so students can interpret results critically, not just run calculations.

Kathy's economics degree from Duke meant living inside datasets — regression analysis, probability distributions, hypothesis testing, and statistical inference were daily tools, not abstract concepts. She breaks down problems by connecting the math to what the numbers actually represent, which makes interpreting results feel intuitive rather than formulaic.

Studying Philosophy, Politics, and Economics at Penn means Kevin encounters statistics not as an abstract math course but as a tool for answering real questions — polling reliability, economic trends, policy evaluation. He unpacks topics like probability distributions, hypothesis testing, and regression with that applied lens. Students come away understanding not just how to compute a standard deviation but what it actually tells them.

An economics degree means Maggie didn't just study statistics in a textbook — she applied distributions, hypothesis testing, and regression analysis to real datasets. She teaches students to interpret what a p-value actually tells them and how to choose the right test for a given scenario, building the kind of statistical intuition that carries through exams and research projects alike.