(1) ending required sameness (2) rejecting the flipped classroom (3) re-thinking rigor (4) its not about 1:1 (5) start to dream again (6) learning to be a society (again) (7) reconsidering what literature means (9) changing rooms (10)
undoing academic time (11) social networks beyond Zuckerbergism (12) knowing less about students, seeing more (13) why we fight
"In Essays in Humanistic Mathematics, Philip Davis likens mathematics to literature. Like literature, mathematics has metaphor, ambiguity, paradox, and mystery. It has history. Mathematics has contributed mightily to philosophy. It has a sense of outcome, a feeling of rightness, a sense of catharsis... Like music, mathematics has harmony and dissonance." from Cut the Knot by Alex Bogomolny
"In Essays in Humanistic Mathematics, Philip Davis likens mathematics to literature. Like literature, mathematics has metaphor, ambiguity, paradox, and mystery. It has history. Mathematics has contributed mightily to philosophy. It has a sense of outcome, a feeling of rightness, a sense of catharsis... Like music, mathematics has harmony and dissonance." from Cut the Knot by Alex Bogomolny
I am really tired of schools chasing students away from mathematics. And I am really tired of schools confusing arithmetic - a mechanical grammar of numbers - with the field of mathematics. We need kids to get interested in maths. Mathematics is something essential in our society, and in our future, and we just cannot afford to continue to chase the bulk of kids away from the possibilities which come with math skills, interests, and capabilities. We cannot continue to either allow the assumption that there are "math kids" and "non-math kids" (as if math is a magical gift), or to separate students into "creative types" and "math types."
Because the "next world" - the jobs of the future which are, as we speak, constructing the world we will live in tomorrow - is being built by the creative mathematicians of the world, and our students will either be part of that, or they won't. They will be able to develop their own solutions and have power over their world or they will be helpless consumers locked into their "App Store Education" (Will Richardson must read) and "App Store Existence." They will be participants or bystanders. And largely, that is for us, as educators, to decide.
"Why is this exciting? Why do I want to tell you this story?"
"Mathematics is not about 3+3..."
Let's begin here, with a quote from the end of the clip above, "Adding in clock notation, all of computer science begins when you say 1+1 = 0. It's not that you were wrong when you said 1+1 = 2, its just a different way of seeing it."
If this is over your head in some way, and you teach math in school, we need to talk. We need to talk now, because step eight of Changing Gears 2012 is re-understanding what mathematics are, and how we bring kids and mathematics together.
Two primary issues which lead to the bigger ones, no matter what age kids you teach. First, maths are creative, they are imaginative, they are powerful, and they are fascinating. Second, arithmetic cannot continue to be your gateway, your filter, blocking children from mathematics.
For the first, what have you done with Fibonacci lately, just as a first question? How does a maths idea shape how students perceive the spaces they are in? For the second, well, lets go back a month to a post I wrote, "In a math lesson a day later I watched a seventh grader, a kid who really struggled to divide 64 by 2 in his head, or 32 by 2, or, for that matter, 16 by 2, work diligently to explain to his disbelieving teacher how he knew - and he knew instantly - how many games are in the NCAA basketball tournament. He knew, because math is about rules and logic, and his logic was perfect and his understanding of the rules I had described was perfect, and because math is not arithmetic, no matter how much our poorly educated national and state leaders think it is. He and his classmates also understood, almost instantly, that the question - no calculators or paper or Google allowed - "If the temperature in Detroit, Michigan is 50 degrees what is the temperature likely to be in Windsor, Ontario? was about (a) culture, and then (b) understanding comparable scales, and then (c) order of operations."
For the first, what have you done with Fibonacci lately, just as a first question? How does a maths idea shape how students perceive the spaces they are in? For the second, well, lets go back a month to a post I wrote, "In a math lesson a day later I watched a seventh grader, a kid who really struggled to divide 64 by 2 in his head, or 32 by 2, or, for that matter, 16 by 2, work diligently to explain to his disbelieving teacher how he knew - and he knew instantly - how many games are in the NCAA basketball tournament. He knew, because math is about rules and logic, and his logic was perfect and his understanding of the rules I had described was perfect, and because math is not arithmetic, no matter how much our poorly educated national and state leaders think it is. He and his classmates also understood, almost instantly, that the question - no calculators or paper or Google allowed - "If the temperature in Detroit, Michigan is 50 degrees what is the temperature likely to be in Windsor, Ontario? was about (a) culture, and then (b) understanding comparable scales, and then (c) order of operations."
If we get past these two ideas, we can begin to bring students into what mathematics is...
Pulling two quotes from a mathematics discussion board begins to get at the issues, the question being that old classic, does two plus two always equal four...
"I think this discussion goes right back to Aristotle (or another Greek of similar vintage). The question is pretty much: Three clouds; three pebbles; three goats; three thoughts; three olives; when you take away clouds, pebbles, goats, thoughts, olives, then what do you have left? The concept of threeness! Each such ....ness is an integer, and there is a reasonably obvious rule to move between such concepts. This rule permits of repetition, and thus establishes the countable numbers."
"I think this discussion goes right back to Aristotle (or another Greek of similar vintage). The question is pretty much: Three clouds; three pebbles; three goats; three thoughts; three olives; when you take away clouds, pebbles, goats, thoughts, olives, then what do you have left? The concept of threeness! Each such ....ness is an integer, and there is a reasonably obvious rule to move between such concepts. This rule permits of repetition, and thus establishes the countable numbers."
however...
"For a cook, 2 apples + 2 apples might well accurately equal 5 apples if
those 4 apples are larger than normal. The mathematician would argue
that 2 large apples + 2 large apples must equal 4 large apples. Correct.
That’s the mathematical axiom Jon Richfield is talking about. The
trouble is, in reality no apple is the same size as another, so the
mathematician’s axiom is limited somewhat to arithmetic theory. So why
should mathematicians get the final say? The cook’s application is
commonsensical and thus more accurate and fair, so in real life 2 + 2
doesn’t always equal 4. Using the equation 2 + 2 = 5, the apple pie
turns out normally, as intended. Nothing meaningless about that."
10 candies? Can these be evenly divided in half? Or are these all completely different things? |
And here we have established the arithmetic conundrum which pulls kids away from mathematics. It should never be taught in a reductionist form which removes the possibility of creativity.
Every child knows that not every apple, every piece of cake (even if the same size you have those differences in frostings), every student, is the same (a fact those who work in quantitative educational statistics have been trained to forget). Thus, the question about two apples plus two apples, as suggested above, becomes one we can argue and debate, even with five-year-olds.
That is not a path to nowhere, it is, rather, the path to understanding, and to bringing students into mathematics. We have to help them learn that mathematics is a set of systems which we can apply when helpful, or rethink and re-imagine if not helpful. A long time ago I wrote a piece called "Real World Math" and one of the things I talked about was why I loved sport statistics in school maths. You cannot compute a batting average in baseball without knowing the rules about what an "At Bat" is and how that differs from a "Plate Appearance." You need to know the difference, in football, between a "Shot" and a "Shot on Goal." You need to know, in American football, how a quarterback "sack" is counted in "run yards" even if that quarterback was tackled while running forward. So these statistics do not just connect maths to a kid's interests, they explain how mathematical systems work, and how a slight change in the rules which govern that system, would change the answer.
Every child knows that not every apple, every piece of cake (even if the same size you have those differences in frostings), every student, is the same (a fact those who work in quantitative educational statistics have been trained to forget). Thus, the question about two apples plus two apples, as suggested above, becomes one we can argue and debate, even with five-year-olds.
That is not a path to nowhere, it is, rather, the path to understanding, and to bringing students into mathematics. We have to help them learn that mathematics is a set of systems which we can apply when helpful, or rethink and re-imagine if not helpful. A long time ago I wrote a piece called "Real World Math" and one of the things I talked about was why I loved sport statistics in school maths. You cannot compute a batting average in baseball without knowing the rules about what an "At Bat" is and how that differs from a "Plate Appearance." You need to know the difference, in football, between a "Shot" and a "Shot on Goal." You need to know, in American football, how a quarterback "sack" is counted in "run yards" even if that quarterback was tackled while running forward. So these statistics do not just connect maths to a kid's interests, they explain how mathematical systems work, and how a slight change in the rules which govern that system, would change the answer.
At the grocery, sometimes 2+2=4, sometimes not... |
Here we go...
"A particularly vexing problem is comparing players from different eras. One complicating factor is that the baseball rule book has changed every year since the first rule book for the National League was issued in 1877.
For example, did you know that prior
to the 1930 American League season, and prior to the 1931 National
League season, fly balls that bounced over or through the outfield fence
were home runs! All batted balls that cleared or went through the fence on the fly or that were hit more than 250 feet in the air and cleared or went through the fence after a bounce in fair territory
were counted as home runs. After the rule change the batter was
awarded second base and these were called "automatic doubles"
(ground-rule doubles are ballpark-specific rules) and are covered by rule 6.09(d)-(h) in the MLB Rule Book."
Change the rules, change the results. Could you add fruits as 2+2? Or just the same kind of fruit? Three clouds; three pebbles; three goats; three thoughts; three
olives; when you take away clouds, pebbles, goats, thoughts, olives,
then what do you have left? The concept of threeness! Each such ....ness
is an integer..." But an "integer" is an idea, it is a "construct," which students should learn to decide is either useful or not useful. Do we count "the number of people on the earth" (US Census is at odds with other counters) or measure the cumulative carbon footprint? (and what system of maths do we use to do that?).
Toss this into the mix... "three clouds"? the sky is full of water vapor, where does one cloud start and another stop? Is a three day old pygmy goat the same as an adult mountain goat? This "integer" idea, "threeness," what does it mean and how can we use it?
Toss this into the mix... "three clouds"? the sky is full of water vapor, where does one cloud start and another stop? Is a three day old pygmy goat the same as an adult mountain goat? This "integer" idea, "threeness," what does it mean and how can we use it?
New York's Polo Grounds, an interesting field made for interesting stats. |
Now, how many home runs did Babe Ruth hit? How many home runs did Lou Gehrig hit? But wait,
"With the exception of a couple of months at the
start of the 1920 season, from 1906 to 1930 the foul lines were
"infinitely long": A fly ball over the fence had to land in fair territory (as determined by the infinitely long foul lines), or be fair when last seen by the umpire, in order to be a home run. In other words, a fly ball that went over the fence in fair territory
but "hooked" around the foul pole (if there was a foul pole) was ruled a
foul ball." How many home runs did Babe Ruth hit? How many home runs did Lou Gehrig hit?
So, the rules matter, and the rules are changeable - assuming you can make the right argument. And this is creative magic which infiltrates everything, from the music you listen to to how that classroom window frames the world beyond. Years ago I taught an Intro to Architecture course at Pratt Institute. I'd take my students to the corner of 53rd Street and Park Avenue in Manhattan, and we'd look. To the southwest was Charles McKim's 1916 Racquet and Tennis Club, to the northwest the 1952 Gordon Bunshaft Lever House, to the southeast Mies van der Rohe's incredible 1958 Seagram's Building - three absolute architectural masterpieces. The fourth corner, the northwest, is occupied by "399 Park Avenue," a 1961 structure by Carson Lundin, Kahn and Jacobs. It is an awful building, by just about anyone's standards.
So, the rules matter, and the rules are changeable - assuming you can make the right argument. And this is creative magic which infiltrates everything, from the music you listen to to how that classroom window frames the world beyond. Years ago I taught an Intro to Architecture course at Pratt Institute. I'd take my students to the corner of 53rd Street and Park Avenue in Manhattan, and we'd look. To the southwest was Charles McKim's 1916 Racquet and Tennis Club, to the northwest the 1952 Gordon Bunshaft Lever House, to the southeast Mies van der Rohe's incredible 1958 Seagram's Building - three absolute architectural masterpieces. The fourth corner, the northwest, is occupied by "399 Park Avenue," a 1961 structure by Carson Lundin, Kahn and Jacobs. It is an awful building, by just about anyone's standards.
We'd spend a long time standing on that corner trying to figure this out, and eventually, we'd get to maths and ratios and Fibonacci and the Golden Mean. 0, 1, 1, 2, 3, 5, 8, 13, 21, 34, 55, 89, 144... Because it is that concept of ratio - embraced in three of those structures, ignored in the fourth - that so much of human comfort with proportion occurs. Europeans called it, "the divine proportion." Why? well, here you would seem to have a year long project which might carry your students anywhere and everywhere in mathematics.
Architects, artists, Wall Street traders, even, yeah, that student ID card or credit card in your pocket... What makes this "the divine proportion"? |
OK, that's one route. Another, hinted at near the top, is Coding. Coding is not just that mix of logic and creativity which is essential to maths, but it has a "real" feel. You don't get things "right" or "wrong," they work or they don't work.
Bring coding into your classrooms. Here's one simple free tool called Notepad++ which we have on our MITS Freedom Sticks. But better, take a look at student coding efforts around the world, from Mozilla's Hackasaurus to Ireland's CoderDojo and Scratch for Kinect which are all bringing kids into this in a big way.
Bring coding into your classrooms. Here's one simple free tool called Notepad++ which we have on our MITS Freedom Sticks. But better, take a look at student coding efforts around the world, from Mozilla's Hackasaurus to Ireland's CoderDojo and Scratch for Kinect which are all bringing kids into this in a big way.
As Stephen Howell (above) says, this is very different than working in that Steve Jobs iOS world where you buy the solutions you need in life. This is using the heart of mathematics to build your own world. Starting simply, kids get interested, they gain competence, they dig behind the curtains - something Jobs and Apple have never permitted - and they move deeper and deeper into what, eventually, begins to look like a much more engaging version of our curriculum. Eventually those Scratch programming kids will be building their own Lego blocks, teaching each other how to do it, challenging each other, and, yes, becoming the builders of that "next world."
So please, take the way you currently teach mathematics apart. Become a mathematics educator instead of a curriculum teacher. It might make all the difference in the future of your students.
- Ira Socol
So please, take the way you currently teach mathematics apart. Become a mathematics educator instead of a curriculum teacher. It might make all the difference in the future of your students.
- Ira Socol
next: changing rooms
Great post as always Ira. It has given me plenty to think about. I have been using coding in my Maths class over the last while with great success and have found that it has helped my Computer Science students connect with Math in a way that I haven't seen before.
ReplyDeleteMath was something for me to get past instead of appreciating. If I had been taught math in a way that wasn't drudgery maybe today I would have been a physicist as well as a poet. I hate it when schools implicitly or explicitly categorize kids as one kind of kid or another.
ReplyDeleteIn high school I took a go at your own pace Algebra class. The Math teachers were actually good, ie, they knew their stuff. But not one of them took me aside and said, "whoa, this isn't a race," or maybe I would have better than a "D."
I realize now, in teaching our younger daughter math that I really can do problems in my head. I do not want her feeling the same way I did. Math as a chore.
When I went to college, my family pressured me to be a Business major. I took Business Calculus Much to my surprise, I got a C. Why then would I get a D in Algebra and a C in Calculus? That, to me, pardon the pun, never added up. I do think that K-12 teachers owe it to students like me to do a better job at engaging us. Who knows? Maybe I would have studied optics, which is something that enthralled me when I was in high school instead of being yet another English major.