How do you reconcile…
principles of standards-based grading; “begin with the end in mind and work backwards;” understanding by design; and other more convergent learning ideas
project-, problem-, challenge-, and/or inquiry-based learning; creativity; innovation; collaboration; and our need for more divergent thinkers?
My answer: I don’t reconcile the two, nor am I sure that I should. I do both. Separately.
As frequent readers of this blog will know, I’ve been experimenting with standards-based assessment and grading for a couple of years now and am to the point that I feel reasonably expert in structuring my classroom around standards. I typically start off each course in the fall by discussing the specific standards that students will meet during the year and explaining how they might go about proving that they’ve met those standards. We then proceed to work together as a class to do a variety of activities and labs designed to help students meet the standards that I have laid out. This works well in my biology, anatomy, and chemistry classes, all of which are concurrent college credit and so are matched to my state’s community college system guidelines for each particular course. Very, very convergent stuff. All students focus their learning on mostly the same set of ideas, even going so far as to complete electronic portfolios based on a common template that I provide for them. This system works nicely and the portfolios that students are producing are excellent, with lots of evidence that they’ve learned particular skill and content standards.
But what about physics? This year I had the opportunity to take over the job of physics teacher because: a) no one else wanted to teach it, and b) I had a lot of proto-engineers begging me to teach anything besides biology or anatomy. This class turned out to be radically different from anything else that I’ve ever taught. It was radically different because I didn’t go into the class with a defined set of standards. The class was not concurrent college credit so I didn’t have to concern myself with matching a college syllabus. The state of Colorado does have physical science standards for students, but they had mostly fulfilled those in their freshman and sophomore level courses, and the kids taking physics were Juniors and Seniors.
With nothing to prove to anyone about whether I had correctly learnified my students, I was free to structure the class as I saw fit. I decided to let the students run it. On the first day of school I explained that they would be designing the class, not me. We spent the next few days brainstorming what sorts of things normally go on in a physics class, which topics they ought to leave physics knowing about, and how to do assessments of said goals. In other words, the students and I were still in a very standards-based frame of mind.
But then we diverged. Big time. Our brainstorming sessions had revealed a lot of different student interests: What about building that hovercraft you were telling us about and just how much power does a shop vac produce? Can we build some sort of catapult? How about a potato gun? By the third week of school, we had all carried out a couple of the standard labs on measuring motion using video analysis and motion sensors but that was the last time we did anything as a whole group. The rest of the year was project based. Completely student designed and initiated to the point they started calling the class “phunsics.” My lesson plan book for the class was a mess. Usually it just said “Projects” until after class when I could actually fill in what students worked on that day, and when I did fill it in, I often had to summarize four or five different projects for the same class period. And so it went all year, sometimes in great bursts of activity, sometimes in lulls of senioritis and apathy, but always there were one or two major projects underway and several on the back burners.
To try to explain the course to future generations of phunsics students (and anyone else curious about what the class looked like), students created several videos about their experience. A playlist of some of their videos is worth watching for some different perspectives on the class. Also, here’s my tribute video for the Phunsics team.
How then do we decide which type of course is better for learning, the convergent “let’s meet the standards” kind of class or the divergent “follow your interests” kind of class? That all depends on how you measure learning, I suppose. On the one hand, students in anatomy, biology, and chemistry have portfolios of the work they accomplished during the year and anyone curious enough could see exactly what sorts of standards they had met. On the other hand, the phunsics students exhibited self-direction, organizational skills, coping with failure, teamwork, and creativity. Our current set of standardized assessments would completely overlook the achievements of these students, should we choose to assess them that way.
Would I teach the anatomy, biology, and chemistry courses the same way that I did physics this year? I’m not so sure I would. Some subjects lend themselves to true inquiry and self-direction better than others. Disciplines like physics and engineering will always have an advantage over subjects like biology and anatomy where real inquiry involves very specialized equipment and a ton of background knowledge that students may not yet possess. Likewise inquiry in chemistry has to be bounded both by safety considerations and the background knowledge of students. Don’t get me wrong, I work in as many open-ended and inquiry labs as possible in these disciplines but these labs or “problems” are still often defined by the teacher and not the learner. Probably I still suck at PBL and just need to get better at it, but for now any sort of PBL short of giving full control to students seems kind of artificial to me.
In conclusion, I’m going to try to offer the physics course as often as I can, which at this point is every other year in rotation with AP Biology. I think a student-designed course like that is vital to help students understand what real scientific inquiry is like, with teams working together to solve problems and meet design challenges they meet along the way. And, at least for now, I’ll keep the anatomy, biology, and chemistry courses as standards-based courses, but attempt to move them in a direction of more student control about how and when they meet the particular standards.