Education ∪ Math ∪ Technology

Year: 2013 (page 14 of 15)

450,728 reasons to blog

Wordcount

I used a tool recently which counts the number of words I’ve posted on my blog. I’ve written a total of 339,254 words on my blog (as posts and comments), and other people have written a total of 111,474 words as comments on my posts.

This level of engagement and thinking has got to make a difference on my understanding of education, and at least indirectly on my skill as a teacher. When I say that blogging has made me a better teacher, I mean it.

The future of learning

A few years ago, as an assignment for my Master’s degree, I created a video on the future of learning. I was never very happy with the quality of the final product, nor do I completely agree now with the vision I presented then. That being said, here are some of the slides I used. It looks like some of the text in the comics is uncited, but I have citations near the end of the video I created.

Some of the slides below offer some ideas as to how technology may change how we learn in the future. Some offer quotes from other thinkers in the field, in case you want to explore more.

 

 

Education reform ineptness

"If you are absolutely no good at something at all, then you lack exactly the skills that you need to know that you are absolutely no good at it."

John Cleese

Perhaps this is part of the reason that so many education reforms that are attempted fail so badly? Could it be that at least some of the people involved in education reform are just so completely inept that they are not even able to judge their own performance at all?

The good news is, if you know you are bad at something, then at least you are not completely inept, because if you were, you might think you were good at it. The bad news is, people who are completely inept are unable to judge or recognize their ineptness, which may make them push ahead in ways which are harmful to the rest of us.

Learning outside of school

I realized that I have done a lot of learning outside of school as a kid. Here are some examples.

  • I took apart almost every piece of electronics we owned (except the television as I was told this was dangerous) and then put it back together, most of the time.
  • I explored every inch of the island I grew up on within 5 kilometres of our house, usually on bike, often with my dog.
  • We had a library of many hundreds of books in our house, and I read most of them.
  • I taught myself how to program, and I created a computer game in grade 10.
  • I (re)discovered the sum of triangular numbers formula, and the quadratic formula on my own.
  • I planned a trip to Mars in as much detail as I could, right down to where the bathrooms would be located on my rotating space-ship.
  • I collected a sample of every different kind of grass I could find on my island. I ended up with over 50 different types.
  • I played a lot of games, including Dungeons and Dragons and many exciting computer games.
  • I watched way too much television (with a strong preference for science fiction). I don’t know how valuable a learning experience this was, but in the interest of being honest, I thought I should include it.
  • I went for regular jogs around town. One time I finished my run, wasn’t tired enough, and so I went for another loop.
  • I wrote poetry, sometimes in the middle of the night.

I’m not offering this list to brag about my childhood, but simply to suggest that there are plenty of ways kids can learn outside of school, but they must have the time, space, and support to do so.

A factoring success story

I covered a couple of my colleague’s classes yesterday so he could attend a math conference. The afternoon class was a somewhat boisterous grade 10 group. I was asked to teach students how to find the greatest common factor, and if I had time, introduce them to more general factoring techniques.

I decided that the greatest common factor is a topic students find relatively easy, and so I just showed some examples of how to do it (actually, I drew the "how to" out of the class by asking them questions, but this is my standard technique) after verifying that they understood the distributive principle. I then assigned some practice problems, which then each student wrote their solution up on the board, and we discussed. I then showed students a couple of different techniques for multiplying binomials (like (x+2)(x+3) for example).

Next, I put up the following 4 questions.

1. x2 + 7x + 12

2. 2x2 + 7x + 3

3. x2 – 25

4. x3 + 8

I asked students to try and figure out how to write these expressions as one set of brackets times another, just like with the example from before, but I suggested to them that what we are trying to do is undo the distributive rule.

I went around the room and encouraged students, gave them hints when they needed them, asked them questions to prod their thinking, and observed their problem solving strategies. Students were engaged in the problem solving activity for a good 30 minutes. Once some of the students’ attentions started to wane a bit, I gave them a sheet with a description of how to do factoring by grouping and some problems to work on the back.

A group of students though really dove into question 4, which, as you may notice is actually quite a bit more difficult than the other three problems. I ended up having to give students two hints: I told them that the expression broke into two factors, one of which was (x+2) and the other of which was three terms long. The group of students worked feverishly on solving the 4th problem for a good twenty minutes, and then all of a sudden, one of the girls in the group leapt out of her seat and screamed, "I GOT IT!! YES!!" I circled around to see if she had the right answer, asked her how she was so sure it was right (she had multiplied everything back through using the distributive rule), and then gave her group x3+27 to solve (which she did quickly) and then x3 + a3 to solve.

At 5:30pm that night, I received an email from the girl, excitedly telling me how she had an inspiration while she was on the bus home on how to solve the general question, and had then figured out the general formula for how to factor a sum of cubes.

I emailed her back and congratulated her on becoming a mathematician.

Investigation into scoring systems

I played ultimate tonight, and we usually keep score with shoes. Our normal scoring system is to count in base 5. Tonight, I tried to use binary, but at half-time I switched back to base 5 when most of our team struggled to read our score quickly.

I took some pictures of the arrangement of shoes during the game (when I wasn’t playing).

01000

11000

01100

00010

10010

11010

 

I can imagine some investigations could be made out of these photos.

  • Given the numbers associated with each photo, try and determine how to count in this number system,
  • More challenging: From these photos, try and determine the missing numbers.

If you want a project that might take a while:

  • Design a scoring system using shoes. It should be easy to maintain and not require too many shoes.

Teaching division algorithms

I’m assisting our 4th grade teachers in finding resources for their upcoming unit on division, and I’m hoping to avoid either of these situations from arising (see the videos below). Actually, these videos could be great hooks to see if students can figure out what mistakes the people in them are making…


 

A key problem in both of these videos is that these (fictional) people are making key mistakes in their use of a standard algorithm which they clearly do not understand, nor do they seem able judge how accurate their solutions are. Now, my suspicion is that students will not make such egregious mistakes, but they may make more subtle mistakes based on the same principles.

The key components of any division instruction should help students by:

  • emphasizing understanding what they are doing when they use a division algorithm,
  • providing tools for students to estimate their answer,
  • encouraging them to use their estimation skills to check the reasonableness of their answer,
  • suggesting alternate techniques to double check the accuracy of their answer,
  • giving time to see the connection between different division algorithms,
  • embedding the use of division in a problem solving context.

If I were going to teach division, (after confirming that students understand multiplication very well) I might start with a problem about equal sharing for students to do that every student can access. Next I might gradually increase the size of the numbers in the problem until students start to see that their "naive" strategies may work, but are very inefficient. One obvious problem I can foresee happening here is that some of the students in many grade four classrooms already know a division algorithm, and may be reluctant to come up with their own strategies as a result.

Next, I would compare different strategies that students use in a whole group setting. We would spend some class time discussing the strategies and talk about the benefits and drawbacks of each. We might also explore some other alternate strategies not yet shared, perhaps using a gigsaw technique where each group explores a specific strategy, perhaps suggested by a video.

One interesting activity for students might be to watch the videos above and try and figure what mistake the people in the video are making when they calculate.

Here are some division strategies that your students may not have seen before:

 

I’m also looking for projects and/or puzzles which require the use of division as a strategy for solving the problem/puzzle.

 

An aside: I am not convinced that these algorithms have much value for our students. More time spent understanding what exactly what division is would be more useful, I think, for our students in the long run, and then just give them a calculator. However, that is not my decision to make, it is up to the BC Ministry of Education to decide.

Social interactions and learning

A conversation on learning
(Image credit: Vandy CFT)

One of the trends with technology today is that it is beginning to redefine the means through which we are social. Prior to the invention of writing, social learning meant discussing ideas with someone in person, the invention of writing allowed social interactions to span geographic and chronological barriers. The trend throughout history has generally been to expand the distance between participants in a conversation and reduce the time delay in a response until today we can potentially interact with people on the other side of the planet via video link with almost no delay.

But what does it mean, "to be social"? If I leave a comment on a five year old blog post amongst hundreds of other comments, how much have I really interacted with anyone? If I see someone else’s response in a learning management system, is this social interaction? Technology has begun to make fuzzy what used to be a clear definition of social interaction. Can we come to a definition of social interaction which clears up some of this fuzziness? Maybe the exact definition of social interaction doesn’t matter?

There is plenty of evidence that learning works better in a social context. BF Skinner’s teaching machines and IPI, both attempts to automate learning, are failures without social interaction. The key affordable of social interactions in learning is timely, contextual feedback on the schema the learner is attempting to build. Without this feedback, it is too easy for our brains, designed to find concrete patterns more easily than abstract patterns, to construct an alternate set of schema that might satisfy all of the information we have, but which is too inflexible to add new information. It is my experience that we tend to more complicated, convulsed explanations of reality without feedback, than less complex but more abstract explanations.

This affordance of a social interaction will help us define what the minimum amount of social interaction should be in a robust learning environment. If the interactions between participants of a learning space lack timeliness and context, then they are unlikely to be useful as a social tool for learning. It may be that they are one-way timely (where you write or say something in a video, and when I consume it years later it acts as useful feedback to me in that moment) but these interactions lack the fore-knowledge of the non-interactive party of what understandings the interacting party has. A one-way interaction cannot give personalized feedback based on the interaction.

If social interactions are so critical to learning, why is it so many learning experiences are designed solely around content? Given the ability of technology to connect people across vast distances, why is so little of this technology available in the learning environments of today’s online courses which include, at best, primitive forum discussions? The primary difference between the MOOCs offered by Stanford, MIT, and others, and the more organically designed cMOOCs (like #etmooc and #oldsmooc) is that the first set of MOOCs treat social interactions as a side-line to the main show, whereas in the cMOOCs, the social interactions ARE the show.

Raising mathematicians

I read a recent article about the importance of early number talk with children and was pleased that this issue was being brought up. The article shares research on a few of the stark differences in how parents talk with their children about numbers. For example, parents tend to talk to their daughters about half as much about numbers as their sons. Parents also range in how much they use number words around their children from about a dozen times a week, to as much as 1800 times per week.

However, I felt that the list of suggestions the article had at the bottom was incomplete. The article’s author essentially makes suggestions which I feel will only help children develop an instrumental understanding of mathematics, as opposed to a more useful, interesting, relational understanding.

Here are some more things my wife and I do with our children from a very young age to help them develop a deeper understanding of numbers.

  • We play games with our children that involve numbers. We roll dice, we play cards, we solve puzzles together, and we play hopscotch. Through these games, my children gain an understanding of the relationship between numbers and actions we take in the games themselves. We ask questions like "how many ways can you get a 10?" My son recently answered that question with this sequence of answers: 20 – 10, 30 – 20, 40 – 30, 50 – 40, etc…
     
  • We talk about how we use numbers in our day to day life. We talk about fractions of food (that are physically present in front of us), and talk about the relationships between these different fractions. We cook, do our finances, and share as many uses of numbers as we can with our children.
     
  • We look for patterns in numbers. We play with relationships between different numbers. We celebrate discoveries our children make. For example, my eldest son noticed that he only needed to remember the very last digit in a large number to figure out if a number was odd or even. Now, he delights in asking people to give him gigantic numbers like 30,938,309,830,983 and being able to tell right away if the number is odd or even. As a mathematician father, I try hard to balance between giving my sons space to come up with their own discoveries, and expanding where their explorations might go.
     
  • I also try very hard to remember that when my son makes a mistake, with further experiences, it is likely that he will discover these mistakes later for himself. For example, my son was convinced for a long time that numbers went 90, 100, 110, 200. He did not understand place value well enough, but over time, and with further exposure to our use of numbers, this misconception of his has disappeared. He now has a very good understanding of place value up to 1000, although he still does not understand larger numbers (he will say things like 233 hundred thousand, 293 million, 389 billion, and 43), but I am confident that as he continues to be exposed to numbers in his day to day experience, he will understand these numbers better.
     
  • We balance our discussion of patterns in numbers with other types of patterns. We look for patterns in art work, in sidewalks, in tiled floors, and wherever else they may form. We create patterns ourselves in our art work and notice where they came from. We doodle, we draw shapes, we watch clouds, and we look at maps, all of which help my son develop a sense of shape and space.
     
  • We ask for evidence from our sons about why they think something is true, whether or not what they are saying is accurate or not. When they have discovered something, and provided solid evidence for why they think it is true, we celebrate it. We might ask questions like, "How did you discover that?" or "Wow, that’s neat. Does it work all the time?"
     
  • We give our children plenty of creative time to explore the world through art work, Lego, blocks, reading, playing games, and other self-exploration activities.
     
  • We see the development of our children’s numeracy as a process, rather than a race. I have no interest in accelerating my sons through the elementary school curriculum, instead I focus more on providing opportunities for enrichment.

The key to all of these activities is that we view numbers and quantities as ways of exploring, and we nurture our children’s sense of wonder about the world.

Andragogy vs pedagogy

Andragogy is a theory of learning as learning applies to adults rather than children (pedagogy). According to Malcolm Knowles, there are 6 key components of adult education.

  1. Adults need to know the reason for learning something (Need to Know)
  2. Experience (including error) provides the basis for learning activities (Foundation).
  3. Adults need to be responsible for their decisions on education; involvement in the planning and evaluation of their instruction (Self-concept).
  4. Adults are most interested in learning subjects having immediate relevance to their work and/or personal lives (Readiness).
  5. Adult learning is problem-centered rather than content-oriented (Orientation).
  6. Adults respond better to internal versus external motivators (Motivation).

I fail to see how these six things are not also true for children.

The objects that adults produce as part of their learning should be different than the objects children produce. Adults don’t need to create posters (although this may still be a valuable learning experience depending on the context) at the same rate that children do during their learning.

Adults have some different external concerns (children, job, home, etc…) than do children that sometimes interfere with their ability to learn in a classroom setting, but these concerns are just different than the concerns of children, they are no less important to the learner.

Adults come to their learning with more experiences than children, and this may make any unlearning (if necessary) more challenging for them, but the fundamental process through which they learn should be significantly similar to the process children go through.

The primary difference I see between adult learning and children learning is how much power they are granted during their learning.