Pages

Saturday, August 13, 2011

Stanislas Dehaene on the mental number line

My hypothesis is that number sense qualifies as a biologically determined category of knowledge. I propose that the foundations of arithmetic lie in our ability to mentally represent and manipulate numerosities on a mental “ number line ”, an analogical representation of number ; and that this representation has a long evolutionary history and a specific cerebral substrate. “ Number appears as one of the fundamental dimensions according to which our nervous system parses the external world. Just as we cannot avoid seeing objects in color (an attribute entirely made up by circuits in our occipital cortex, including area V4) and at definite locations in space (a representation reconstructed by occipito-parietal neuronal projection pathways), in the same way numerical quantities are imposed on us effortlessly through the specialized circuits of our inferior parietal lobe. The structure of our brain defines the categories according to which we apprehend the world through mathematics. ” (TNS, p. 245).
Précis of “ The number sense ”
Stanislas Dehaene
INSERM U.334
Service Hospitalier Frédéric Joliot
CEA/DSV
4 Place du Général Leclerc
91401 cedex Orsay
France
The Number Sense: How the Mind Creates Mathematics, Revised and Updated Edition

The Number Sense: How the Mind Creates Mathematics, Revised and Updated Edition

13 comments:

  1. I could hypothesize many things, but is this some grand genetic key to math or the simple realization that this concept is important and schools must ensure that it is taught and understood? If schools do teach the concept, is this a greater hurdle to overcome than every other fundamental concept in math? I'm not big on these things because the assumption is that the problems in math are much more complicated than simple competence.

    What happens in schools that directly teach the concept of a number line? Do these problems disappear? One could claim a genetic cause for almost everything, but the implication is that the issue still exists after a proper introduction to the material. Perhaps the hypothesis is simply that some kids "see" the number line and that some actually have to be directly taught.

    ReplyDelete
  2. I simply don't buy the argument. And I wonder why it's useful?

    Does it mean that people who don't have a numerical sense are genetically inferior?

    Also, how does this impact what you should be doing in the classroom? Wouldn't it make more sense to take a Kumon-like approach and just teach math as we know it in small steps and not worry about some grand genetic scheme? Or take a DI approach and try different ways of teaching and only use what works, and capture that method in a script. Either approach is more effective than starting with a grand genetic theory.

    ReplyDelete
  3. We've discussed this before and I'm not anymore persuaded now. (I should find the post.) I think it's unlikely to be true, since we have overwhelming evidence that our brain structures work with *log* scales, not linear scales. Our ears and eyes feed us data in log scales. Probably our pain scales are log. Our mental impression of how big a number is fits a log scale (which is why we have such a terrible time understanding just how much bigger a trillion is than a billion) too. And in the other direction, for small numbers, it's why we have such trouble understanding the difference between, say, 99% and 99.5%.

    But so what--what if we do organize numbers physically in a cartesian coordinate system? so what? Whether or not it's innate, our Math System organizes numbers in a cartesian coordinate system, so YES, we should teach kids the number line because that's the way we express math.

    ReplyDelete
  4. --http://kitchentablemath.blogspot.com/2011/03/number-sense.html

    we didn't believe it here, either.

    ReplyDelete
  5. our prior conversation about this:

    http://kitchentablemath.blogspot.com/2011/03/number-sense.html

    ReplyDelete
  6. the philosophy-of-mind stuff...
    including but not at all limited to
    the pop-neurology that inexplicably
    grips the minds of so many of
    our contemporaries...
    is mostly irrelevant in considering
    how best to create workable useful
    elementary math curricula.
    we are not mad scientists and
    those children are not skinner's pigeons.
    so mostly i pay it no mind.

    the previous thread
    (teach the # line in 1st grade)
    pointed at wu pointing at the # line
    specifically as a site for refuting the
    there-is-no-alternative-to-the-spiral
    approach to (failing to) teach fractions.

    "you have to be willing to accept
    multiple meanings for it at the outset"
    is... talking for me now not wu...
    a profoundly *anti-mathematical*
    viewpoint. the importance of *definitions*
    in mathematics... *particularly* at the
    elementary level... is almost impossible
    to overstate. you can hide it but you
    can't run from it: it's everywhere and
    it's not going away.

    somebody said something about "rulers"...
    the kind you measure with... upthread
    or in the next one over. looks like maybe
    a good tool for introducing number lines.

    but "somewhere along the line" (as we
    unselfconsciously say having once
    internalized the time-as-moving-point
    model)... and the sooner the better...
    one should forthrightly admit that
    over the generations it's been noticed
    (time and again)
    that by fixing *one* carefully-constructed
    formalization as the *definition*
    of a certain symbol (or phrase or
    what have you) one has *simplified*
    the situation to the point where
    it becomes much *easier* to say
    useful or interesting things about
    that hitherto-only-vaguely-understood
    thing.

    mathphobes are always claiming to
    shy away because something one
    is trying to clarify for them is
    "too complicated" when in my view
    the opposite is actually the case:
    what it actually *is* is "unfamiliar"
    (and that's the way they want it).
    the correct answer to "how do you
    get to carnegie hall" isn't *complicated*
    (or unfamiliar: "practice, practice,
    practice", of course)... but most
    of take it for granted we'll be unable
    to use it despite it's simplicity.
    so they'll drag out some canard
    about perfect-practice-makes-perfect
    and pretend there's something about
    a great performer's *brain* or something.
    hohum.

    ReplyDelete
  7. This comment has been removed by the author.

    ReplyDelete
  8. owen thomas said...
    "but most of [us]
    take it for granted we'll be unable
    to use it despite [its] simplicity."
    yeesh.

    i hope i usually edit my posts
    better than this: two mistakes
    in less than half a sentence.
    if i'm in such a big hurry to
    get somewhere, why am i
    typing out rambles on the
    doggone internet in the first place?

    yay number lines!

    ReplyDelete
  9. Wouldn't it make more sense to take a Kumon-like approach and just teach math as we know it in small steps and not worry about some grand genetic scheme?

    I think Kumon teaches the number line, but I'll have to check.

    ReplyDelete
  10. Looks like Kumon teaches the number line (judging by the Kumon books for sale in bookstores)

    ReplyDelete
  11. I think it's unlikely to be true, since we have overwhelming evidence that our brain structures work with *log* scales, not linear scales

    That's not true for counting.

    Wish to heck I could remember the term for knowing immediately that 3 is different from 2....darn.

    Will try to look it up.

    Where number is concerned, the brain is built to see small, linear numbers correctly and without training. True with animals, too.

    ReplyDelete
  12. Oh!

    Here it is: subitize.
    << Evidence has been given that, up to number 3, human beings link almost immediately objects and their corresponding numbers, without any appearance of counting: we do not need to count, we subitize. >>

    BUT -- after the number 3, we may have a logarithmic number line:

    << Dehaene says the research suggests that a logarithmic number line might be an intuitive mathematical concept, whereas the idea of a linear number line might have to be learned. >>

    http://www.scientificamerican.com/article.cfm?id=a-natural-log

    ReplyDelete