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The First Rule of Thoughtful Learning

The first rule of thoughtful learning as I see it is that, short of abuse, pretty much any pedagical technique is sometimes appropriate. The...

Saturday, March 24, 2018

Two Ideas for Promoting Transfer

Often, one of the hardest things for students to do is apply a newly learned skill in a new setting, even one that looks almost the same to the teacher. The technical term for this is transfer and promoting transfer is one of the most difficult tasks in education.

The key to transferring knowledge from one situation to another is noticing that, despite superficial differences, the two situations are somehow the same on a deeper level -- in technical terms, they share the same deep structure. For example, an arms race and the ice-albedo feedback loop that enhances warming at the poles are both situations where a change in some quantity (the amount of weapons owned by country A, the amount of ice at the north pole) leads to a further change in the same direction as the initial one. Both are positive feedback loops. Transfer would involve a student who learned about positive feedback loops in the context of arms races applying their understanding to climate change, or vice versa.

Two recent papers have described promising results in promoting transfer. One is an elaboration of methods that many teachers already use, while the other is fairly new (although we sometimes use a very similar one in LS 30 and related courses).

The first paper describes something called concreteness fading. It's exactly what it sounds like -- starting with a concrete example of a topic and then gradually moving toward a fully abstract one. In this particular study, the researchers taught second- and third-graders about equivalence problems of the type 2+5+3 = 2 + __. The teaching was done either through concrete examples (sharing stickers and making balances balance), paper-and-pencil math problems, or a concreteness fading condition that started with stickers and balances, then moved to paper representations of these things, and then moved to actual problems with numbers.
   
From http://www.learningscientists.org/blog/2018/2/1-1

After the initial learning stage, the kids were presented with problems, including word problems, more complex than anything they had been taught. This was the transfer stage. The kids who were taught entirely using concrete methods performed worst, followed by those taught abstractly. The ones taught using concreteness fading did best.

What happened? Students who only see concrete examples have a hard time generalizing. They may not see the deep structure of what they are doing. (Using a variety of examples may mitigate this but is not always practical.) Abstract learning is general but often difficult. Concreteness fading may bridge the gap between the two, making the abstract learning more effective.

The other study gave undergraduates a classic problem that was analogous to a story they had read. Most people find the analogy difficult to see unless told to look for it. However, their performance improved substantially (from a 10% success rate to a 25% one) if they were asked to come up with a problem analogous to the one they were trying to solve before actually solving it.

This is a very practical result. In some cases, it may be enough to ask students to come up with examples of a new concept, which I already do (there are a number of such problems in Modeling Life) and could do more of. For more complex problems, perhaps including programming problems, asking students to come up with a problem analogous to what they are trying to solve could make sense.  At the very least, it's worth a try.

Wednesday, March 21, 2018

All Learning is Active

One of the most intellectually engaging classroom experiences of my life took place during my senior year at UCLA, in Rick Vance's Mathematical Ecology class. In a small classroom that was somewhat the worse for wear but had the advantage of ample blackboard space, Prof. Vance derived and analyzed models of ecological processes and the rest of the class and I followed along. A visitor to the class would have observed me doing absolutely nothing, not even taking notes (a physical disability makes me unable to do so). But I was concentrating intently, my brain firing on all cylinders, pushed to its maximum capacity for following a chain of reasoning. Thought, no matter how intense, gives no outward sign.

“…the term “passive learning” is an oxymoron. There is no such thing. If students are learning, then they are NOT passive, and learning does not always include moving or talking…” Yes.  Yes. Yes.  So well said, and sums up in less than fifty words what took me over six hundred words to say in this post on engagement.
 Engagement and learning is an exercise of focused cognition.  Without mentally attending to material/information, there can be no learning.  The idea of passive learning vs. active learning as an outward expression of engagement is very misleading.  A student can look ‘active’ with their learning because they are having a discussion with others or using a manipulative, but without assessment of the student’s cognition, we (students and teachers) should not   assume learning has occurred.  Conversely, a student can appear ‘passive’ in their learning because they are quietly reading; not in a collaborative group or creatively working with material.  In both instances, the student(s) may or may not be learning.

Thought is both the end and the means of education. We learn to think, but we also think to learn. Things we think about are remembered; things we don't think about are not. In the words of cognitive psychologist Daniel Willingham, "Memory is the residue of thought."

This is why we must shift the discussion from active learning to thoughful learning. The methods commonly referred to as "active learning" can be effective but outward activity is only a means of provoking and guiding thought. It cannot be a goal in itself and particularly should not be presented to novice educators that way. (I sometimes want to ask how Stephen Hawking would have fared in an active learning physics class.) Start with what you want students to learn, identify what they should think about, and only then decide how to evoke that thought.

Sunday, March 11, 2018

Why I Have a Soft Spot for Inquiry-Based Learning (in Math)

Someday, I am going to get punched for saying, "That's a terribly designed experiment" or "How could they analyze their data this way?" one too many times. My long-suffering colleagues routinely listen to me rant about papers with avoidably confounded variables, uninterpretable multiple regressions (there's a paper in the works) and pseudoreplication in the education literature. If you claim to have data supporting something, I want to look at it, pick it apart and think of five alternative explanations for it. Not surprisingly, I'm a big fan of the Kirscher, Sweller and Clark paper "Why Minimal Guidance During Instruction Does Not Work" (I found this link by typing the title verbatim into Google) and definitely not a fan of discovery learning. However, there is one exception. Sort of.

This exception, as the reader already knows, is inquiry-based learning in math. Specifically, and this is important, it is inquiry-based learning (IBL) in upper division or majors-oriented lower division college math classes. What I am about to say is not meant to apply in any other context.

Inquiry-based learning in college math consists of having students learn math largely or entirely by working through sequences of problems and proofs. The version in which all proofs are done by the students, who are not allowed to use any outside references, is often called the Moore method. Less pure versions also exist and seem to be more commonly used.


The basic framework of an IBL math course has students work on proofs outside of class. Class sessions consist mainly of having students present their work and other students critiquing it as necessary. The instructor provides the problems or theorem statements and a bit of guidance during discussions but otherwise stands back.

An IBL math class embodies thoughtful learning in a way few other teaching methods in any subject do. Thinking is the entire point. Furthermore, since most of the actual work is done outside of class, students have time to think deeply and to grapple with serious problems. There is an alternation between solitary and communal thinking that takes advantage of the strengths of both -- the concentration possible alone and the error-checking and fresh viewpoints provided by others. Indeed, this is how real scientific collaborations often work.

Also, IBL fits its subject in a way that is rarely possible in the sciences. (It does bear some resemblance to seminars and writing workshops in the humanities.) While it may not be (and probably isn't) the most effective way to teach specific mathematical content because of the high cognitive load imposed by figuring out a proof and the very real possibility of proving something without understanding it, if teaching a particular way of thinking is an important goal, IBL succeeds admirably.

There is another, idiosyncratic reason why I have a soft spot for IBL. A few years ago, I was sent to a week-long workshop on the subject. Of that week, no more than 20-30 minutes were devoted to reviewing research, most of which was on active learning in general. The rest was looking at implementation and the details of what actually happens in the classroom. Rather than using bad data to try to show that a particular method of teaching was best, the workshop leaders in effect said, "Here's a way to teach we think is good and here are ways to do it". In keeping with the (apocryphal but frequently misattributed to Mark Twain) principle that "It ain't what we know that gives us trouble, it's what we think we know that just ain't so," no data can be better than bad data because it doesn't cause false confidence in the way bad data does. Perhaps grist for a future post?
Read more at: https://www.brainyquote.com/quotes/mark_twain_109