Abstract
We developed and tested strategies for using spatial representations to help students understand core probability concepts, including the multiplication rule for computing a joint probability from a marginal and conditional probability, interpreting an odds value as the ratio of two probabilities, and Bayesian inference. The general goal of these strategies is to promote active learning by introducing concepts in an intuitive spatial format and then encouraging students to try to discover the explicit equations associated with the spatial representations. We assessed the viability of the proposed active-learning approach with two exercises that tested undergraduates’ ability to specify mathematical equations after learning to use the spatial solution method. A majority of students succeeded in independently discovering fundamental mathematical concepts underlying probabilistic reasoning. For example, in the second exercise, 76% of students correctly multiplied marginal and conditional probabilities to find joint probabilities, 86% correctly divided joint probabilities to get an odds value, and 69% did both to achieve full Bayesian inference. Thus, we conclude that the spatial method is an effective way to promote active learning of probability equations.
Highlights
Probability concepts are a cornerstone of Science, Technology, Engineering, and Math (STEM) education, especially in the many fields that rely on statistical methods to draw conclusions
Success rates for correctly answering all components of the math induction sheet went from 41% to 69%, success rates for correctly answering both of the multiplication rule questions went from 59% to 76%, and success rates for correctly answering the posterior odds question went from 55% to 86%
We showed that elements of the spatial display have a one-to-one mapping to important equations underlying probabilistic reasoning, and we suggested that educators could use the parallel representations to promote active learning by challenging students to discover these equations after learning a spatial method for approximating the desired quantities
Summary
Probability concepts are a cornerstone of Science, Technology, Engineering, and Math (STEM) education, especially in the many fields that rely on statistical methods to draw conclusions. Experiments investigating Bayesian reasoning typically use problems with two hypotheses (e.g., a patient has a disease not) and a dichotomous observed variable (e.g., a positive or negative diagnostic test for the disease), which is the simplest version of Bayesian inference and a good starting point for courses that cover Bayesian statistics (Kruschke 2011). Following this formula, a classic Bayesian reasoning example is finding the probability that a patient has a disease (hypothesis)
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