Literature Index

A number of theoretical positions in psychology - including variants of case-based reasoning, instance-based analogy, and connectionist models - maintain that abstract rules are not involved in human reasoning, or at best play a minor role. Other views hold that the use of abstract rules is a core aspect of human reasoning. We propose eight criteria for determining whether or not people use abstract rules in reasoning, and examine evidence relevant to each criterion for several rule systems. We argue that there is substantial evidence that several different inferential rules, including modus ponens, contractual rules, causal rules, and the law of large numbers, are used in solving everyday problems. We discuss the implications for various theoretical positions and consider hybrid mechanisms that combine aspects of instance and rule models.

Projects can be a good way for students to apply what they've learned in class. I have my students pick a topic of interest to them; they gather and collect the data; present it via a research report which is due at the end of the semester. It definitely helps their grades and provides some meaning and perspective to the semester's work. The students picked some very interesting subjects as well. All of this was explored in the workshop.

Usually the PC is used in statistics to do quickly and conveniently what we have always been doing. This is a misuse of the PC since it has the potential to change statistical practice fundamentally. Historically, statistics was developed when computation was hard and expensive. To avoid massive computation a lot of sophisticated theory based on asymptotics was developed. Now computation is cheap and easy. The PC should replace sophisticated theory by simple computations, and make statistics more comprehensible. We should strive for understanding. Sophisticated statistical software is pedagogically harmful. We do not want to solve a dozen problems a day by using recipes. We want to solve a few paradigmatic examples in a few weeks. School statistics should solve a small number of fundamental problems, not quickly, but leisurely. We should derive programs for the solutions, which are general enough, so that they solve a whole class of problems. I do not advocate much deep programming, which is quite difficult. On the other hand, statistical software is for professionals. To learn its use requires an effort comparable to the effort of learning a new programming language. Design of a program is an important part of the learning process. A problem is solved if you have an efficient algorithm for its solution, which you understand.

Over the past decade there has been an increasingly strong call for statistics<br>education to focus on statistical literacy, statistical reasoning, and statistical<br>thinking. Our goal in creating this book is to provide a useful resource for educators<br>and researchers interested in helping students at all educational levels to develop<br>these cognitive processes and learning outcomes. This book includes cutting-edge<br>research on teaching and learning statistics, along with specific pedagogical<br>implications. We designed the book for academic audiences interested in statistics<br>education as well as for teachers, curriculum writers, and technology developers. (From preface)