The work on Singapore
Math Figured Out for Parents, which is my book about exactly that, is
proceeding very nicely, and I thought I'd give a bit of progress report here.
For those of you who like the social commentary essays or want me to talk about
my science fiction writing, all things in time—I'm trying to maintain a
rotation. I'm not a brand. I'm trying not to become one. I'm probably going to
be something other than a brand, and when I become that, I'll pretend I became
it on purpose.
Meanwhile, in my non-brandish kind of way:
Quick catch-up on what this is about: the Singapore Math system was developed in that
nation in the 1980s, and has undergone continual development and improvement
since that time. In the international math achievement rankings, the top 5-6
nations for the last few years have consistently been places that adopted
Singapore Math a decade or more previously (as you might expect, students who
start out in Singapore Math reap more benefit than those who have to cross over
when they're older). Almost entirely because of those international statistics,
many high-achievement-oriented charter schools in the United States have tried
to adopt Singapore Math in the last few years, with varying degrees of success.
Some mostly-affluent public school districts are in the early process of
adoption, and a few of the charter systems that are dedicated to raising
student achievement in low income students and/or students of color are
exploring it as well.
Even if your kid's school is not going to Singapore
Math directly, it's going to get closer to it. The incoming Common Core math
standards have borrowed some material from Singapore Math. Furthermore, the
necessity of teaching to the test in the present climate of No Child Left
Behind plus Common Core standards has caused the main Singapore Math publisher
in the United States to bring out a line of Singapore Math books which are
"aligned with the standards." *
Singapore Math is better math for elementary students, but it can't be adopted by
just handing the teachers copies of the new textbooks and telling them to stay
a chapter ahead. That's the main thing I'll be talking about later on in this
piece—why it's better and why it's also hard to implement. For some parents
trying to help kids with homework, it is somewhere between terrifying,
confusing, and enraging.
Hence my project: a book that figures out this
Singapore Math thing for parents. By figuring out, I mean several different
things:
•figuring out why your kid's school is changing to
Singapore Math, or might, or should
•figuring out how Singapore Math is going to make
your kid much more math-proficient; there's a reason it works, and a reason it
works better than approaches you may
be more familiar with
•figuring out why they do that**
•figuring out how to help your kid with homework
and
•figuring out whether your kid is actually getting
the benefits of Singapore Math, or just being pushed through a different set of
worksheets.***
One way to my conclusion: reading and theory. Lately I've been polishing and clarifying that
first part, about how Singapore Math is the better way to teach math. Since to
write it, I have to understand it myself, much of my recent reading has been in
understanding the deep reasoning that underlies Singapore Math, and the
fundamental problems with the alternatives.
The tradition of arguing about how kids ought to
learn math goes back at least to Reverend Thomas Vowler Short in 1840, accelerating into a full-blown uproar by the turn
of the twentieth century. **** So lately my research reading has been devoted
to getting caught up enough to say something reasonably intelligent (or at
least excusably not-stupid) in the long-running discussion about how people in
general and kids in particular ought to learn mathematics. I've read a great
number of highly influential books that only experts have ever heard of—sometimes
feel like I'm reading the secret history of elementary school.
Where it has all led me is to a much deeper
conviction that:
• the Singapore Mathematics methods are flat-out
the best system ever devised for teaching mathematics to students whose
abilities are in the range from about one standard deviation below to about two
standard deviations above average, which embraces about 80% of all math
students.
•Singapore Math is better for a reason that is
subtle, complex, and, to use a scary word, deep—not as in "deep
philosophy" but as in "deeply embedded."
Another way to my conclusion: practical experience.
In the last few months, this
has also been confirmed by personal experience. My wife is a reading and math
intervention specialist; she helps kids who are having reading or math problems
get back on track before they fall too far behind. She has a tutoring business
on the side which is usually booked up with a waiting list, and since my math
background goes a good deal further than hers, and she gets occasional calls
from parents who are mainly worried about math, she started working me in to
cover math tutoring on more advanced subjects, as another pair of eyes while
she was administering diagnostics, and in general to help out on math
interventions.
Naturally enough, since I've been spending months
understanding what's up with Singapore Math, I reached for that toolbox, and
I've been delighted with the results. I'm a reasonably good tutor—I know the
math, I know the educational theory, I get along with children, I have a large
bag of tricks for getting the math and the kid onto better terms with each
other. But with the Singapore Math concepts and approaches, I'm a much better
tutor, and kids who once seemed hopelessly blocked are moving ahead fast enough
to eventually catch up with and pass their classmates. (It's also a major kick
to hear them say, "I like
math," sometimes in a tone of astonishment, or, to quote one of them
directly, "It's math but it's actually kind of cool.") I've said for
many years that the ability to use math well is a basic human gift like poetry,
dance, music, storytelling, drawing, dressing well, making small talk, coding,
or cooking, something kids should be able to do competently and confidently,
and appreciate intelligently, by the time they grow up.
In the short run, I'm taking on much more tutoring
work. As I coach more kids through their personal math walls, I learn vastly
more about how Singapore Math works at the level where ultimately any system of
math instruction has to work: in the mind of the individual kid. I'll end up
with a better book because of that.
But in the longer run, here's what I've really
learned between the reading and the tutoring experience: Singapore Math is the one system of math instruction that really
understands and uses the deep relationship between procedural proficiency and
conceptual understanding.
The meeting of theory and practice: why Singapore
Math is really better.
Quick definitions: procedural proficiency is the ability to execute an algorithm
quickly and accurately; it's quite literally know-how. If you can do a long
division of a 4-digit number into a 9-digit number, keeping the decimal point where
it belongs, out to 6 digits of accuracy, in less than 2 minutes, you are more
procedurally proficient at long division than about 95% of American adults (and
about as procedurally proficient as a run-of-the-mill Japanese adult, or a top-of-the-first-quartile
Singaporean). There are several components to procedural proficiency: knowing
which algorithm goes with which problem, remembering all the steps correctly, and
executing each step quickly and accurately. If you know how to hand-extract an
nth root, you're more procedurally proficient than someone who only knows how
to hand-extract a square root. If you know four ways to find the roots of a
quadratic equation in one variable******, you're more procedurally proficient
than the guy who only knows the quadratic formula. If you know the inside-out
pattern for multiplying two-digit numbers, but you sometimes reverse the inside
and outside products, you are less procedurally proficient than the person who
never does. If you've got multi-digit lattice multiplication down cold but have to
stop and count out any time there's an eight or a seven, you're less proficient
than the person who knows the whole multiplication table.
For our purposes here, procedural proficiency
applies to any procedure and any problem. Whether a student is doing division
of whole numbers by counter-rectangles (a method which especially irritates
some parents) or by short division (most parents don't even know there's such a
thing nowadays), if he's doing it quickly and reliably, he's procedurally
proficient at it. If a student always checks to see whether the coefficients of
x1 add up to zero and uses the trivial ±√c/a when they do, that's a
procedurally proficient decision even if he doesn't know the quadratic formula.
Conceptual
understanding is being able to
make a simple mathematical argument about why an algorithm works, why a thing
is true, or in general, "why." If, off the top of your head and
without having to think about it, you can quickly and clearly explain why, to
divide a fraction by a fraction, you invert the divisor and multiply, you've
got conceptual understanding. If you can prove the Pythagorean theorem or that
there's an infinite number of primes, you have conceptual understanding of
those ideas, no matter how slowly you use the Pythagorean algorithm to find the
diagonal of a rectangle or how difficult you find it to do a simple
factorization.
Traditional methods: going really fast till you
sock into that wall. Those two
concepts are the heart and soul of why teaching mathematics has been such a
thorny problem, ever since Reverend Short first made a good guess on the
subject. Young kids love patterns, rhythms, repetition, and so forth and learn
them very easily (consider clapping games, nursery rhymes, songs like
"B-I-N-G-O," games like hopscotch and jacks, just to start with, or
just wait till you're on a city bus next to a little kid who has a favorite
commercial jingle s/he sings over and over).
So the traditional method of instruction, learning
highly patterned algorithms (write this here, put that there, cross that out
and write the next highest, etc.) produces very quick, easy procedural
proficiency. Nearly every adult who has math trouble (which is, truthfully,
most Americans) will tell you sadly that they "loved math" or
"were good at math" up till
... and that up till is almost always
some point where the fading memory of a maturing brain was no longer able to
keep all the patterns straight, or the patterns became too complex (think how
much more complicated long division is than two-digit addition), or there just
wasn't any reliable pattern any more. Usually the same people will tell you
they loved math but hated word problems, which is something like loving playing
scales on the clarinet but hating music, or loving counting out the box step
but hating to go dancing.
Mary Boole seems to have been the first person to
figure out and articulate clearly that if kids learn it algorithms exclusively
as aconceptual patterns for manipulating meaningless symbols, they will inevitably
hit some wall later. When that happens, if they don't have the tool of
referring to the underlying principles and concepts, they're done; they can go
no further. Some few kids are lucky enough that they acquired concepts all
along (very often on their own, by simply enjoying playing with numbers); those
are the ones we think are "naturally good at math." Other kids,
driven by one kind of necessity or another (wrath of parents, lure of a career,
etc.) begin belated and partial conceptual learning, and get enough of it to go
on for a while, at least until they hit the limits of their conceptual learning
skills. And the great majority just declare themselves "not good at
math" and give up, spending the rest of their lives evading situations
that math could make easier.*******
Now, a good math teacher in the early grades has
always been able to point out concepts as the students progressed. A stack of
blocks, by not getting any taller or shorter when blocks are moved around
within it, beautifully illustrates the commutative and associative principles
(whether they're called by that name or not). The number of tiles on the floor
doesn't change whether you stand on the west or the north side, and that can
teach the commutative principle for multiplication. But there have also always
been too many teachers out there who just wanted to get done with the
worksheet, and whose answer to "Why?" was "Because you don't
want to stay in from recess."
So essentially, the traditional style of teaching
math has been shown, under all sorts of conditions, for a good hundred years
and more, to produce early procedural proficiency but expose many students to a
later conceptual block. You get more kids who can make change quickly but fewer
who can go to engineering school. And when they hit the blocks, it's painful
and frustrating and most of them come away hating math.
Reforms: don't go there, there's a wall; or here's
a key, so why do you need a lock?
Naturally enough, reformers who wanted to fix the hitting the wall problem either tried to avoid the hitting, or tried to avoid the wall, i.e. most reform math movements involved either:
1. simplifying and dumbing down math so that kids can learn a basic set of patterns and let it go at that (never a very good option and a disaster in the 21st century when so much of the better part of the job market requires math)
1. simplifying and dumbing down math so that kids can learn a basic set of patterns and let it go at that (never a very good option and a disaster in the 21st century when so much of the better part of the job market requires math)
2.
teaching
conceptual understanding as an alternative. That's what New Math, inquiry-based
math, and several other systems try to do.
That
second idea makes sense on the surface; if the reason little Sammy can't grasp
fractions is that s/he only knows multiplication and division as procedures,
teach them to him/her as concepts in the first place.
But as is
well-known, in practice this leads to kids who can define the cardinality of a
set but can't figure it out without resort to their fingers. Concept-heavy math
education often fails to lead to procedural proficiency; worse yet, because the
concepts are ungrounded in any experience, the students seem to know them only
as names, and not to be able to apply them or see what they refer to. If we
were producing calculus wizards who couldn't make change, we might live with
that by automating change-making or training change-specialists; but the
embarrassing truth for conceptualists has been that without a procedural base,
people don't seem to acquire the concepts either.
So there's
the dilemma: emphasize procedural proficiency and lose large parts of every
cohort to frustration and despair when they don't have the conceptual basis to
go on. Emphasize conceptual understanding and lose even larger parts of every
cohort to learned helplessness and a propensity to name things but not be able
to work with them.
Where
Singapore Math is really a revolution. The mathematicians (Singapore has some superb ones) and the
educational psychologists (ditto) looked at the problem something like this:
Procedural proficiency approaches are focused on
manipulating symbols quickly and accurately. Conceptual understanding
approaches are focused on connecting meanings accurately. But a student can
only really know for sure that a procedure is accurate if s/he understands the
concept behind it, and a concept isn't really understood till
the student sees it happening.
In short,
procedures are what concepts mean about,
and concepts are the things that govern and
allow us to remember procedures. It's
a dialog.
Concepts are how we remember procedures. The last few decades of memory research have shown
that memories are not recordings, but a set of cues from which we structure and
rebuild a narrative, visualization, or other coherent thing we need to refer
to. If you're truly procedurally proficient, you know that already; if your
mind slips for a moment while doing long division, the concept that explains
why you multiply and then subtract (and go back a step if the partial remainder
is larger than the divisor) is there in your memory too, ready to activate if
you do something in the wrong order or get stuck.
Also, procedural proficiency is essential before
the next level of concept can be learned effectively. A student who can
only add by counting forward has to do far too much work for a 7-year-old
memory (which is highly accurate and retentive but works in tiny chunks) to be
able to also grasp multiplication. There are only so many processors and
registers available, and they have limited capacity; to grasp higher concepts,
lower ones have to be automated. Let me give you three very fast analogies:
1)
You control
where you point your eyes (high level concepts about your environment) but you
usually leave depth of focus "automatic" and you have no choice at
all about whether to see with your rods or cones. If you had to decide how to
balance the signals coming in from your eyes, you couldn't see at all.
2)
If you've ever
watched a young kid learning to play baseball, you know there's not much use
telling him/her "The play's at first" until s/he knows that a
"play" is "a situation into which you should throw the ball,"
and all that's useless until s/he can throw a ball somewhere reasonably close to
first base. The concept of a "play" is meaningless until the kid is actually someone who can play the game as a player who can throw into a play.
3)
A college
science instructor friend tells me that he has to coach students to read every
formula and equation (many of them seem to think that stuff is just decoration
and the meaning is in the words around it), and strongly urges them to solve
each one for all the variables. If they can easily see that F=ma implies m=F/a and a=F/m, and keep
all those in mind as they read on, he figures they'll probably make it, though
not as easily as the students who didn't need to be told. If they don't see
much relation between those three, or think of them as three separate facts, he
suggests they change majors to "something words-only."
And there's the great thing with Singapore Math.
There's a structured pathway from concept to procedure to higher concept to
more complex procedure to even higher concept, on and on; the concepts are not
just window-dressing and decor to keep the smart students from getting bored
with algorithms. Nor are the algorithms mere passing examples of the
to-be-admired concepts. It's understood that the ground for a concept has to be
prepared with procedures that have become largely automatic—you can't have an a-ha!
where everything clicks if the pieces of it can't move fast enough to click.
And it's equally understood that the focus for a procedure has to be on
implementing a concept; a kid who is chanting "four times nine equals
thirty-six" needs to be thinking of what "times" and
"equals" mean every time he chants it.
What great teachers have always done anyway, Singapore Math is built around. So unlike any other system, Singapore Math doesn't
try to "emphasize the really important thing, which is" {procedures,
concepts}. It builds in that vital alternation, that you acquire the concept to
help remember the procedure that will allow you to see the next concept that
will enable you to remember/construct/apply the next procedure, over and over—like
a person walking forward on two feet instead of spinning in a circle around a
stationary foot, or a climber going hand over hand, not limited to the height
of the first handhold.
And as a corollary, Singapore Math training
materials make it clear that we acquire procedures by procedural methods (i.e.
practice, including both repetition and variation, or to use the dreadfully
old-fashioned words, drills and exercises). We acquire concepts by conceptual
methods (inquiry, pattern-finding, reasoning, extrapolation, and so forth). And we join procedures to concepts, and
concepts to procedures, and move on.
Contemplate that phrase, if you will. And we join procedures to concepts, and
concepts to procedures, and move on.
How's it work in practice? Let me take an example
I've now seen three times: some kids cling to very simple but time-consuming
procedures like counting up to add, counting down to subtract, or counting by
factors to multiply (e.g. to multiply 8X5 they tick off 5,10,15,20,25,30,35,40
under their breath as they pop up eight fingers in sequence). In each case, it
turned out that one reason the kid did this was because s/he thought the
construction caused the answer to be right—in other words, the equal sign did
not express that 8X5, 5X8, 10X4, and 40 were all the same number. Rather, the
equals sign was a command to "calculate now," and 8X5 would not be 40
until you calculated it.
I found that out by slowly walking them through
their mental process, until I confirmed that for them, calculation was what
made the result true, rather than a procedure for finding the truth.
The cure was then to demonstrate, in up to a dozen
different ways, what = actually means—that 8X5 is not "how you make
40" but "another name for 40." Once they saw that, they also saw
that 40 could be right without doing the calculation—and with a bit of
salesmanship on my part, that it would be much easier to just know that when
you needed it (just as it's easier to get a pizza if you know it's called a
pizza, rather than to say, "I want you to make me a circle of dough and
put cheese and a mixture of spiced crushed tomatoes on top of it, then heat the
oven ..." every time).
Then, pushing them to remember every single time what the math facts meant, so that they would know when and where to use those
automatic bits of knowledge, we worked out a mutually agreed on plan and
timetable for memorization. They all did it faster than expected/required. And
the next step was that we used their newfound procedural proficiency to start
exploring the next concept up the ladder ... from which would flow more
procedures, with which they would be able to understand more concepts.
One last thing: tutoring students almost always
move on, as they catch up with regular students or as they become secure in
running ahead of their classmates. The biggest thing they take with them from
that dose of Singapore Math, I hear, is that once they have that model of how
to learn math, they can apply it whether their teacher does so consciously or
not. They have, in short, acquired the ability to learn mathematics—really learn real mathematics—whether
the teacher is good or not. And if knowledge is power, that's the very source
of power.
§
* quick translation of that for those of you who
don't read American educationese fluently: the order and timing of mathematical
topics from Singapore Math has been partly copied into the new guidelines
(Common Core) that many schools are adopting. (Feel free to insert several
hours of reading up about politics of Common Core right here, if you insist. Go
ahead, I can wait. I've done it myself. I'll even feel some sympathy for you
after you're done). In general, the international version of Singapore Math far
exceeds what Common Core asks for, so within the Common Core process, Singapore
Math has been a force for higher standards and against dumbing-down. No Child
Left Behind is a Bush administration holdover law that the Obama Administration
has found useful as a tool against underperforming schools, and so has not
given it up despite heavy pressure from their close political allies, the
teacher's unions. NCLB is a system in which poor student performance on
standardized tests makes schools liable to pressure and sanctions that can go
as far as reallocating their funds or students to the point of closing them
down. Many terrified school boards and school administrators therefore insist
that any curriculum be "aligned with the standards" by which they
mean an exhaustive list of "right here on this page is where we teach the
third graders the material they'll need to correctly answer the type of
question that a specific standard requires." Because Singapore Math is
generally more advanced at comparable ages than the standard American math
curriculum, most of the "alignment" consists of verifying that by the
time students are tested on any topic, they'll already have been taught it;
almost no material has had to be added, and little existing material has had to
be moved earlier. This checklist/bookkeeping process seems to have produced
little or no actual change from international Singapore math, but it's probably
been very successful at selling new editions of the old textbooks.
** for many different values of that. In general, Singapore Math presents the material in an order
and manner that has sound reasons in educational psychology, mathematical
rigor, and preparation for more advanced work—often in all three. For obvious
reasons, though, this isn't always explained in student textbooks, and
sometimes even the teacher may not be clear on it, especially in the many
places where Singapore Math is being thrown at them on the "stay a chapter
ahead" basis. For most parents with kids in Singapore Math, there seems to
be an occasional that, as in,
"Well, she seems to be learning math, and I see why they have her do most
of it, but what is that about?"
Hence, a whole section of the book dedicated to thats.
*** subject for a future blog. I think most of us
realize that a really good math teacher can use many of the not-very-good
textbooks and materials on the market, and still really teach math to most or
all of the kids in the room, by supplementing, emphasizing, or sometimes
teaching against the materials. Unfortunately, underprepared, mathphobic,
rigid, insecure, or otherwise weak math teachers can also use a great
curriculum to baffle, confuse, frustrate, and turn off a whole roomful of kids.
Some teachers who are being handed Singapore Math to teach are being thrown in
over their heads, and it really doesn't matter whether they're in over their
heads because they aren't getting enough support, didn't get enough
preparation, never learned the underlying math, or just hate math. Whoever's
fault that is, it's the kids who pay the price. So that section of the book
will be about making sure that if your kids' school is wise enough to offer
them Singapore Math, what they get is actually Singapore Math.
**** see, for example, the surprisingly
modern-sounding arguments in Mary Boole's Lectures
on the Logic of Arithmetic (1903) or John Dewey's The Psychology of Number (1895).
***** and you gosh-danged well should, too.
******* subject for another future blog after I do
some more research: it is extremely well established that illiterate adults
have an enormous number of tricks for not getting caught being unable to read
(getting other people to fill out forms for them, sticking to restaurants and
canned goods that have pictures of the food, listening to class discussion and
repeating things other students have said, saying they forgot their glasses and
asking someone to read the text to them, etc.) There are probably as many
tricks, and as clever tricks, for innumerates, but they are probably used much
more often. Unlike illiterates, however, I suspect that there are many, many
more innumerates who just live with being cheated, pay too much, having to use
trial and error, etc.
