Innovations in teaching: Andrew Petersen
Convocation is a time to celebrate U of T's students. Although they may , graduating from one of the top-ranked universities in the world is a remarkable achievement.
When the 18,000 members of the Class of 2016 cross the stage at Convocation Hall 鈥 including an estimated 13,500 grads this spring 鈥 they'll be looking back at years of exams, essays, lab and field work, experiential learning, volunteer stints, creativity and hard work. And almost zero snow days.
On the stage with them 鈥 or and Instagram feeds 鈥 will be some of the professors and instructors who also invested countless hours in their students鈥 success.
Who are the teachers who helped make this day possible? You can learn about some of them in our Inside Con Hall series from student writer Krisha Ravikantharaja.
And you鈥檒l meet a few more in this ongoing series on Innovations in Teaching.
Meet Diane Horton
Meet Greg Evans
In this third instalment, U of T News writer Arthur Kaptainis profiles Professor Andrew Petersen of the 含羞草传媒 Mississauga.
To hear Andrew Petersen tell it, computer science, as a subject to be taught, is a little like life. It has certain difficulties that we cannot avoid and others we definitely can.
鈥淓ssential complexity is what you should be struggling with, what makes a problem really harder,鈥 explained the associate professor (teaching stream) in the department of mathematical and computational sciences at the 含羞草传媒 Mississauga. 鈥淎ccidental complexity is what we do ourselves when we make a problem harder.鈥
Petersen鈥檚 determination to deal forthrightly with the first kind of complexity and wage steady war on the second type made him one of the three His dedication has also earned him the esteem of colleagues on all three campuses, where the Programming Course Resource System (PCRS), which he developed collaboratively with students, is a staple tool of undergraduate courses.
Ioan Stefanovici, a PhD candidate in computer science and former teaching assistant, admires Petersen鈥檚 mastery of the topic material, ability to explain it at the level appropriate to any audience and 鈥 in particular 鈥 willingness to place it in a larger context.
鈥淗e always goes beyond 鈥榯oday's lesson鈥 and relates the material to everything else in the field,鈥 Stefanovici says. 鈥淭his gives the new material an anchor and foundation.鈥
One of the advantages of teaching in the online era is the quick availability of information about where a majority (or significant minority) of students are having trouble. Nevertheless, there are limits to what data, big or small, can tell us.
鈥淚n the end you have to approach students and say, 鈥楥an you tell me what is going through your head?鈥欌 Petersen said over the telephone from New Zealand, where he is finishing a sabbatical.
鈥淵ou have to understand what is getting in the way. And you鈥檙e only going to understand when you ask them.鈥
Such questions are more often teased out than posed bluntly. One of Petersen鈥檚 proven techniques is to undertake 鈥渓ive鈥 programming in a large-enrolment introductory course.
鈥淲hen you鈥檙e doing something you learn more than when you鈥檙e hearing something,鈥 Petersen says. 鈥淏ut this process also gives me an opportunity to discover what is working and is not working.鈥
His twist is to leave out a line of programming and require students not simply to fill in the blank but also to exchange proposals with their fellow students. Individuals then present not their own solutions but the solutions of their neighbours.
鈥淔irst, they validate it, if they think it鈥檚 good,鈥 Petersen says, by way of explaining the double benefit of this 鈥渁nonymous鈥 method. 鈥淪econd, there won鈥檛 be any embarrassment if it doesn鈥檛 work, because it鈥檚 not theirs.鈥
Petersen also makes sure to involve students in the upper rows as well as those who are seated, by accident or design, closer to the instructor.
鈥淵ou want to get a sense of whether they are participating,鈥 he says. 鈥淵ou want to know if they can write that one line. Because if they can write that one line, they know what the structure is."
In most computer science courses, some work happens outside the classroom, in accordance with the inverted teaching model. Petersen appreciates the benefits, which typically involve a video demonstration and a programming exercise. His own PCRS is an example of a product based on this teaching philosophy.
鈥淭his allows us, when we work with students in class, to know with some confidence that they have attempted to apply their knowledge, to get their hands dirty,鈥 Petersen says.
Active problem-solving is the modus operandi even in one-on-one encounters.
鈥淲hen a student comes in during office hours, I normally end up asking rather than answering questions,鈥 Petersen says. 鈥淚f the student doesn鈥檛 understand question 27 on page 17, my response usually is, there is a whiteboard behind you. Getting the students to start working on the question shows me where they are having trouble.鈥
Despite Petersen鈥檚 palpable success as an on-site and in-person instructor, the trend in computer science instruction has been toward more use of interactive technology. Will teachers and classrooms eventually be rendered obsolete?
鈥淚 don鈥檛 know that I鈥檝e got a good answer to that,鈥 Petersen says. 鈥淎lthough the current state of instruction certainly relies on experienced people listening to students, identifying the obstacles and relying on their experience to provide 鈥榡ust in time鈥 teaching, there is a lot of hype about how much of this activity can be turned over to a robot in 20 or 30 years.
鈥淎s professors, we think that educators are always going to be important. But as a computer scientist, I say: 鈥業 don鈥檛 know.鈥 Expert systems are getting pretty good. I don鈥檛 know what they鈥檙e going to be like in five years, let alone 20 years.
鈥淏ut I believe there will always be room for a human expert 鈥 curating the material that needs to be investigated; identifying what, specifically, students are asking questions about; and providing the right response as they ask those questions.鈥