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Re: [xmca] a minus times a plus

I'm generally sympathetic to these points, which sound like they come from a teacher's direct experience.
Up to the very end, where I think that it is a little too easy to blame the success of our rivals (popular, youth, and commercial mass culture) for our own failures.
Yes, there is not much in our (American) public culture that lauds learning, education, knowledge, academic achievement, intellectual curiosity, etc. And without that it is a lot harder for teachers to Make the Case for anything in the curriculum.
But I would see popular culture only as a competitor for attention and for a sense of what is valued, not as in any way directly impeding students' ability to learn.
Along the lines of the argument I offered in a previous posting, we could see a number of domains of implicitly similar (or at least mutually supportive) cultural practices that are to a large extent (but never wholly) mutually opposed or contrasting (cf. heteroglossia, this is a more general heteropraxia). We are quite familiar with this notion in the case of say class-based subcultural practices, where we know that the contrasts are not inherent and necessary ones, but tend to be sociological constructions, ways of maintaining boundaries, privileges, identities, etc. That tends I think to be true of the relationship between academic or school culture and media/popular/ youth culture. Neither really wants to have much to do with the other.
But work such as Jim Gee's on video games, or Rebecca Black and many others on fan fiction and amateur music and video production, does I think show pretty convincingly that popular/youth culture, especially appropriations of mass culture for our own purposes and in the terms- of-value of our own communities, represents significant and valuable learning, some of which carries considerable academic and potential professional relevance. What is dismaying is that this other educational world is much more successful than schools are, and as Gee has argued, even puts into practice a lot of our own best pedagogical strategies, which in schools we tend to sacrifice to political expedience. 

JAY.

Jay Lemke
Professor
Educational Studies
University of Michigan
Ann Arbor, MI 48109
www.umich.edu/~jaylemke




On Jul 8, 2009, at 5:24 PM, larry smolucha wrote:



Thoughts from Francine Smolucha
on teaching math:

Learning math occurs within a discourse on
"Why do I have to know this?"

Like all discourse this is a situated discourse,
occuring within a classroom or as a one to one interaction
(with either a live person or with a media intermediary such as a
book or computer tutorial.)

A discourse analysis would reveal these typical lines of discourse:

Question: Why do I have to know this?"

(1) Because some authority figure said so/
    because I said so/ because the school board said so/
    because the state mandates it/ because the oppressive
    colonial/capitalist school system mandates it . . . .

(2) Because it is on the test/ the unit test/the final exam/
    the state achievement test/the college entrance exam/
    the scholarship qualifying exam

(3) Because this is what kids your age are expected to know/
    in our school/school district/state or in other countries.

(4) Because you need to know this in order to get a good job.
(Do you really? Will you ever need to know this as an adult?)

(5) Because you will use it in everyday life?
(Really?????)

(6) Because you are exercising your brain/math is mental exercise
for your brain just like push-ups build up your muscles/ math is
a type of mental gymnastics.
(7) Because I learned it, your father/mother learned it/ your grandfather 
learned it/that is how our family bettered itself (economically).
(8) Because you will receive a token/a cookie/a smiley face sticker/ . . . .. (or because failure will be punished with a poor grade, being grounded, etc.) 

One key factor here is whether the discourse takes place between
significant others. If the teacher is not a significant other for the
learner, the teacher's words are tuned out. If the learner is not a
significant other for the teacher, the teacher is mouthing platitudes.

Some of these arguments for learning math turn into slippery slopes.

(1) If the state is imposing this on us let us rise up and
over throw the oppressive government system. Then we don't have to learn math.
(4) If I need to know math in order to get a job or a good job, how come people who know a lot of math are out of work (can't find a job/a decent job)? 
Usually, we are talking about people who the learner knows personally
like Dad or Mom or an Uncle.
(5) Not even all elementary school math is used in the everyday life of an 
adult, much less a child.
Making the Case for Math is crucial in learning math because it motivates 
the learner to put continual effort into a challenging course of study
(a course of study that does not often provide immediate tangible
rewards.) A formal part of teacher education in math should be helping the future teacher develop a effective/versatile discourse style for Making the Case for Math.
How about Making the Case for Learning History? Making the Case for Learning Grammar? 
As well as, Making the Case for Learning Science.

Making the Case for Learning to Read and Write is another matter.
If the cultural system values these academic skills, the teacher's job is much simpler. If the cultural system undermines the development of cognitive ability, the teacher has to create a sub-culture, counter-culture, an alternative culture. In Western cultures, for example, the incessant mindless rhythms of pop/hip-hop music and video games, and the hyper arousal cycle associated with them, undermines the brain's 
ability to concentrate and be able to think.


























To: xmca@weber.ucsd.edu
Subject: RE: [xmca] a minus times a plus
From: ERIC.RAMBERG@spps.org
Date: Tue, 7 Jul 2009 08:25:18 -0500

Those interested in this discussion please take the time to read what
Sylvia Scribner's research has to offer.

http://lchc.ucsd.edu/Histarch/jaap84v6n1-2.PDF

Hope people find this as helpful as I have.

eric




"A.Bakker" <A.Bakker@fi.uu.nl>
Sent by: xmca-bounces@weber.ucsd.edu
07/07/2009 06:59 AM
Please respond to "eXtended Mind, Culture, Activity"
To: <ablunden@mira.net>, "'eXtended Mind, Culture,Activity'" 
<xmca@weber.ucsd.edu>
       cc:
       Subject:        RE: [xmca] a minus times a plus
Interesting discussion! Let me dwell on two projects in response to Jay 
and
Andy.

1. what kind of math do we need at work?

We have analyzed the mathematical knowledge required in 239
intermediate-level professions (think of service engineering, florist, baker, low level analyst in science labs, builders, car mechanics, salary administration, secretarial work, hairdresser etc). Some of these do not have to do any calculations at all (butcher in a factory just selecting 
good
and bad parts of meat), but the vast majority of professions face simple arithmetic, geometry (area, volume), data handling and risk, and sometimes formulas. Even at the lowest level of education, lab analysts face some 
high-level statistics (F-test, t-test, correlation etc) in method
validation, precision of instruments etc.
Although there is some truth in Andy's comments, this analysis gives a 
more
nuanced image. Moreover, there is more than math at work and in daily
life:
math required for higher-level education. Vocational students without
enough
mathematical and scientific baggage have trouble getting through their higher vocational education (nursing, teaching, management etc). however, 
I
should note that our Dutch school system differs drastically from the
American one because our vocational education is big (60% of the students) 
and starts early (pre-vocational education at age 12).

2. basing science units on authentic practices
Indeed, many math and science problems at school are not very realistic. 
It
is in fact quite hard to design good ones. Over the past years we have 
tried
to base educational units on authentic practices in which science or math 
is
used (with activity theory in mind as well). We have 'translated'
authentic
goals to learner goals, adapted ways of working and knowledge required to 
be
manageable to students (grade 10-12). The idea was to use meaningful
relationships between goals, tools, knowledge etc in outside-school
practice
as sources of inspiration for school units. Although we have had some
success, there are still many challenges in designing good units - even if we allow the learning goals to be drastically different from the Standards (say: insight into health and nutrition rather than say DNA, evolution, 
cell
biology...).
So I agree with Jay that content is a major problem, but even then we have 
a
lot of work to do in terms of designing good alternatives.

Chevallard has written interesting papers on didactic transposition,
adapting knowledge as used in the 'real world' to school situations. He describes a contradiction that cannot be resolved completely: education promises to prepare kids for their future and for society. At the same 
time,
education cannot really fulfil its promise. What students learn is often something that teachers can easily test. Chevallard argues that the main 
reason that we still teach math and science is NOT that they are so
useful,
but they can be rolled out nicely in stages over the school grades and can be tested in objective ways. A lot of things that are very useful to learn do not make it to the curricula, simply because they are so hard to teach 
and test (medicine, psychology, sociology, social skills etc.)

Arthur Bakker


-----Original Message-----
From: xmca-bounces@weber.ucsd.edu [mailto:xmca-bounces@weber.ucsd.edu ] 
On

Behalf Of Andy Blunden
Sent: dinsdag 7 juli 2009 13:30
To: eXtended Mind, Culture, Activity
Subject: Re: [xmca] a minus times a plus

Your key claims are beyond challenge Jay; you can get by
perfectly well in all aspects of life without mathematics,
apart from a basic understanding of the notion of quantity
and some elementary arithmetic, except for a very small
group of professions. It has annoyed me, this need to invent
pseudo-problems that seem to demand mathematics, to
"justify" the need to learn maths. It seems to me that it is
requirement to pass maths exams to gain entry to a very wide
range of jobs etc., which is the only real motivation for most.

But can you tell me, is there no evidence that going through
the process of learning maths in some way benefits the mind?
in the same way that (as I understand it) learning to read
and write has a permanent and effect on how people think?
that mathematics is a kind of mental gymnastics.

Andy

Jay Lemke wrote:
Thank, Ivan, for responding in part to some of my concerns re teaching 
math-as-math in schools.

It's a big, old debate in education whether we should teach ideas,
concepts, and disciplines as abstract systems, in the hopes they can 
then be used as tools to think with ... or whether that usually

doesn't
work, puts kids off from the subject, and it's better to let concepts appear more naturally in the context of real-world problems, issues, 
activities which are not about math or science, but in which

math-using

and science-using activities and practices can play a helpful part.

The academic, and intellectual answer, as part of a cultural and
institutional tradition, is that we cheat students out of the power of 
math and science if we don't give them the systems of abstract

concepts,

and that other approaches tend to degenerate into second-rate
practicalism that avoids theory, critique, alternatives, creativity, etc. My own view, after a long time participating in, observing, and 
trying to analyze the teaching of science, and to a lesser degree
mathematics, is that the powerful systematic conceptual tools are a

very

advanced stage of membership in one or more very specialized
communities, and are simply not of much use to most people.
Maybe my view is a bit extreme. But I think it remains true that it is 
not just a failure to find the magic method of teaching that is the
problem with math-as-math and science-as-science in the curriculum. It 
is the content itself. Or, really, the lack of content, the lack of
engagement with real life activities that are meaningful and important 
to the students, in the modern math and science curricula. And I do

not

see the solution as inventing clever artificial problems and topics

that
seem to be relevant to real-life, but which are in fact just excuses 
to

do more math-as-math and science-as-science.

A mathematician or a scientist can find, show you, highlight, apply
their conceptual tools to nearly anything. Some reasonable level of
abstract awareness of those tools can emerge from encountering, in

some

detail and depth, several domains and examples or projects in which

the
concepts have been highlighted for their usefulness (and that includes usefulness for critical thinking, for imagining alternatives --- not just for engineering practical constructions or solutions). But this comes at the end of a long learning process, and almost as a kind of 
side-effect, and not at the beginning or as the primary purpose or
goal-of-activity.
There is math and science in jumping jacks and football, in mountain climbing, in raising a pet or growing some food, in figuring the cost 
of
better garbage collection in the neighborhood, in organizing a block party, in understanding when to go to the hospital or what counts as 
evidence in a court case. It might be better to say that there are
issues of quantity and degree, of probability and risk, of nutrition 
and

cause and effect in all these domains and phenonena, and that the
workarounds and tricks and mnemonics and practical methods accumulated 
across them all tend to implicate some more general strategies ---

which
we could just tell you, but then the odds are you wouldn't understand 
or

remember or know how to use them for yourself.

I am not talking here about advanced levels of education, but about
introductory ones ... up to about the age of 15 or 17, or up to the
point at which interest and possibility tend to focus students toward some preferred specialization. Then the balance shifts, again not all 
the way toward abstract disciplines (as, for example, medical

education
has struggled to sort out for a long time now), but a bit more toward the justification of more emphasis on theoretical learning, as part of 
membership in a specialist community of knowers/doers.

What are the practical situations in which you need to multiply a

minus
times a plus? not textbook imaginaries, but for real? If you had some broad and in-depth knowledge about such a situation, would it then be 
so
hard to make sense of how signed numbers multiply there? And how far a 
step is it, and how necessary a step for all to take, from an

induction

from several such well-understood situations to the pure

mathematicians'

abstract arguments about how signed numbers multiply everywhere, or
really, nowhere??

JAY.



Jay Lemke
Professor
Educational Studies
University of Michigan
Ann Arbor, MI 48109
www.umich.edu/~jaylemke




On Jun 30, 2009, at 6:50 PM, Ivan Rosero wrote:


Here's a familiar exhortation:
"We need as many engineers as possible. As there is a lack of them, 
invite
to this study, persons of about 18 years, who have already studied

the

necessary sciences. Relieve the parents of taxes and grant the

scholars

sufficient means."

According to my brief cyber-sphere search, these are the words of

Emperor

Constantine.
So, anyway, we all know what road that empire took. I doubt it was 
lack of
engineers though :) So, given the very similar verbiage spilling out 
of NSF
these days, I agree with Jay, perhaps slowing down and taking a

minute

or

two to rethink this wouldn't be bad at all.
If I read you correctly Jay, one big worry you have is that we don't 
end up
reifying mathematics (in the sense Constantine seems to be doing with 
engineering) in the frustration we experience with our almost

complete

failure in teaching it.

It reminds me of mountain-climbing.  For me at least, this is one

hell

of a
difficult sport, and the few times I've ever participated, it has

been

a

real big struggle to get to the top.  And we're talking Mt.

Washington,

a

measly ~6000 ft peek.  Anyway, I struggle, sweat, almost pass-out,

and

finally I'm there.  It is AWESOME, the joy is overwhelming.  20

minutes
later, as my muscles cool down and my adrenaline levels-off, I stare 
down

the thing and feel a creeping dread, even if the way down is many

times

easier than the way up.
This story can go in many directions from here, as many as there are 
people
who have made it (oh, God, this is cheesy) mountain-top.  They are

not

universally happy stories however.
I DO think it is useful to know some mathematics and have a host of scientific concepts to think with and through at our disposal. None 
of this
is Bad (or Good for that matter) in and of itself. The Purpose, of 
course,
is what is at issue.

ZPDs are value agnostic.  Mike and his team at LCHC are currently
attempting
to create ZPDs that can instill basic arithmetic in kids whose daily 
(and

arguably far stronger) ZPDs pull them in many other (sometimes

directly
opposite) directions. Some of those ZPDs, however, are not in direct 
conflict with math.  That is my hunch, or assumption.  The task,

then,

is

perhaps a bit simpler than creating new ones.

Is it simpler to find and then piggy-back on, ZPDs that contain
kernels of
arithmetic in them?  Susan Goldin-Meadow has pretty convincing
evidence that
specific motor activity can not only presage basic arithmetic, but

can

even
aid in its acquisition. So, might not Jay's concern (if I read him 
right)
that mathematics (and the whole lot of techno-science) becomes
surreptitiously reified in our frustrated attempts to teach it be
addressed
from a different direction?

Jumping-jacks anyone?

Ivan

On Sat, Jun 27, 2009 at 11:00 PM, Andy Blunden <ablunden@mira.net>

wrote:



I hope people won't mind if I continue to pick the brains of this
list on
the problem of my niece's progress in maths, or lack of it.

It seems that the suggestion last time - that Marissa may have

missed

important lessons while on holiday - may explain her poor

performance

last
year in maths, even though maths has always been her weak subject.. 
She has
caught up a bit but she is still badly behind.
It seems that the issue Mike has raised also applies: she is getting 
homework that seem to presume she know things that in fact she
doesn't. The
only other negative in her school reports is that she doesn't
participate in
class discussion or ask questions when she doesn't understand

something.
I presume the hesitancy about speaking up is probably the cause of 
failure
to correct her maths problems and the teachers giving her homework 
she

doesn't understand.
She is now 15 and her maths homework is also beyond her father! :) 
and the
crisis of the transition from childhood to adulthood around this

age,

makes
it impossible for the father to get Marissa talk about it to him, or 
engage
Marissa in games of 20 Questions or something to lead her to the

joys

of
asking others. Discussion over the dinner table is apparently also 
unconducive to her participation.

Does anyone have any ideas? I've run out of suggestions. I could
probably
help if I was there, but I'm 1000 km away.

Andy

Mike Cole wrote:


SO glad you are interested in this, Jay.
I have just made contact with Karen Fuson who has, lucky for us,
"retired"
from Northwestern and moved nearby. She is away for a week or so
but then we are getting together. This is a problem that just may 
be

tractable, theoretically interesting for sure, attractive of

experience

collaborators,
and god knows, of practrical importance to lots of kids.

mike

On Sun, Jun 7, 2009 at 3:27 PM, Jay Lemke <jaylemke@umich.edu>

wrote:


Yes, Mike and F.K., these are very disturbing issues. Both that

what

we
think we want to teach seems to depend on deeper (e.g. 4000- year 
deep)
knowledge than it's realistic to expect most people to learn (or 
want to
learn), and that how we teach even the most practical bits of
mathematics
(like 15 minus 8) seems to have gone so wrong that it's hard to

know

where
to start, especially for those we have most systematically failed. 
We do indeed need to not give up. But we also need, I think, to

admit

that
it's time to seriously re-think the whole of the what, why, and

how

of
education. Math is a nice place to focus because at least some of 
it

seems
universally agreed to be useful by almost everyone, because
professional
mathematicians and most people, including teachers and mathematics educators, seem to hold radically different views about what the 
subject
is,
and because success in teaching it, measured in almost any way, is 
pretty
near the bottom of the heap.
Yes, we can find somewhat better ways to teach the same stuff, but 
maybe
it's the stuff itself (the content of the curriculum, viewed not 
just as
information, but as activity) that needs to be rethought? along
with the
ethics and efficacy of who decides.

No matter how many times you multiply a minus by any number of

pluses,

you
still get a minus.

JAY.

Jay Lemke
Professor
Educational Studies
University of Michigan
Ann Arbor, MI 48109
www.umich.edu/~jaylemke




On Jun 6, 2009, at 6:12 PM, Mike Cole wrote:

Hi Foo Keong-- It is so generous of you to even try to explain!

And

your
question re math seems to me
relevant to other areas of knowledge as well when you ask, "Can we 
condensefour thousand years of
human development into an easily digestible four minutes for
learners."

Could we consider four years, just for whole numbers? Davydov
starts with
Algebra as the gateway arithmetic. Jean Schmittau, Peter Moxhay

and

others
believe his method of introducing youngesters to math has some

extra

power.
As I understand it, others on xmca are dubious and look to other 
sources
of
difficulty. Karen Fuson, in her article on "developing

mathematical

power
ins whole number operations" focuses on introducing number

operations

through very simple, familiar, imaginable,
events where exchange is involved.
Its odd to me experiencing the cycle of time, the "coming back to 
the

beginning and recognizing it
for the first time" that is happening for me right now with

arithmetic

and
early algebra. The source
is quite practical with social significance: the unbridgable gap 
the

children I work with face between
what their teachers are teaching about (say) subtraction (2005-118 
is my
current keystone example)
trying to get their kids to learn that the first step is to

subtract

8

from
15 and know enough to treat the
second zero as a 9. But the child, even understanding that the

task

the
teacher is focused on is
disabled because when asked 15-8 the answer =3 and only

painstaking
attention to the problem set up with fingers and subtracting one 
by

one,
with full compliance and even eagerness by the child, brings
her to 7.

Now suppose this phenomenon is ubiquitous, affects 100's of
thousands of
children, and is heavily correlated with social class.

Then ....  ??? ....
I think my frustration is probably equivalent to yourse in
intensity, but
the quality is of a somewhat different nature.
mike
On Sat, Jun 6, 2009 at 3:11 AM, Ng Foo Keong <lefouque@gmail.com > 
wrote:
I was trained in mathematics at the University of Cambridge (UK) 

for my undergraduate studies, concentrating more on pure

mathematics (including algebra).  I am able to roll out a

rigorous abstract proof of why "minus times minus" is a "plus",

using only the basic axioms of real numbers (actually you only

need a few of those axioms).
However, abstract proofs aren't likely to be useful for non- math 

specialists and struggling neophyte learners of algebra.  in

order to pull off such a proof, or even just to understand just
the few lines of proof, you almost need to be a mental masochist. 

Who likes to go through mental torture?


Can we condense four thousand years of human development of
mathematical understanding into an easily digestible four minutes 

for learners?


thus the huge gulf of understanding still persists.  that's why

as an educator, i feel so useless being unable to help other

people.   :-(


F.K.




2009/6/4 Mike Cole <lchcmike@gmail.com>:
I am currently reading article by Fuson suggestion by Anna Sfard 
on

whole
number operations. I also need to study Anna's paper with exactly 
this


example in it. Not sure what moment of despair at deeper

understanding


hit

me. Now that I am done teaching and have a whole day to

communicate


things

are looking up!! Apologies for doubting I could have deep
understanding

of
why minus x minus = plus and minus x plus = minus. At present my
understanding remains somewhat bifurcated. The former is negation 
of

a
negation as david kel long ago suggested, linking his suggestion 
to


Anna's

comognition
approach. The second I think more of in terms of number line and 

multiplication as repeated addition.

Perhaps the two will coalesce under your combined tutelage.

mike


And member book links are coming in. Nice.

mike


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