Alan Kay: Big Ideas are Sometimes Powerful Ideas
From Viewpoints Intelligent Archive
so we
actually are dealing with an academic hour here
and be fitting with our school setting
marvin minsky once said school was the greatest
invention anybody ever came up with to keep
you from staying interested on anything for any reasonable
length of time because of course
it has all these schedules in assembly line movements
and we have one of those today and
I also wanted to leave time for
questions but one of the ways I want to leave time
for questions is to encourage you to ask questions as I
talk so I have no idea how long this
talk is and I am going to stop after
50 minutes and regardless of what what
happened so please don't be
shy ask questions as we go if
you like and because this talk is
not for me but for you
so it's
in a series of ideas which are
somewhat connected I hope so
one contrast
I'd like you to think about is the notion beach of
common sense that
most people take
the world around them as reality I
once came up with
at said technology is anything that happened after
you were born because
the technology that you're born into is
part of your world and it's taken to be normal there and most
internet Prince the Internet is one of the great inventions
of all time not the web but the internet itself
one of the great maybe one of the greatest engineering
feats of all time and
it worked so well that hardly
anybody appreciates it particularly
in computing where they should pay more attention to why
it works so well so here's a
common-sense deduction that
has been made by most
people on the planet for the slightly less
than 200,000 years modern humans have been here
and that is something like a king
natural and normal
extension of the head of the family
hunted leaders
of hunting groups and etc etcetera so
this is just regarded as common sense
and in fact was not regarded as it as an idea
it was just part of the part of the world that people
lived in then in
January 1776 Thomas Paine
wrote a book which he ironically titled common
sense everybody here has heard of Tom Paine's Common Sense
but he had a big idea in it which
was instead of having the King be
the law we can have the law be the king and
what he meant was we can design a much better society
than the what the natural
seeming hereditary monarchy as we can take our
future into our own hands we can come up with a better plan
this is an idea that surfaced
a couple of times in Greece but not
not before not after and
this book
which pain published at his own expense initially
just gave it away had a press run
between six hundred thousand and nine hundred thousand
in six months so
that's a lot by today's standards and
there were 1.5 million non
slaves in the thirteen colonies
back then and so this press run
encompassed somewhere between almost a half
to more than a half of all men women and children in
all 13 colonies so imagine just trying
to reach that number of people today
there is no medium that you could do it with except
with the internet I try
to get sixty percent of
300 million people no
newspaper could do it so
so this is a big idea but
the powerful idea
and this is the distinction I want to make was the
Constitution as a
big idea is kind of an insight and
often insights insights
are wonderful but they're
lightweight they're relatively easy to have compared
to doing something about it so the
Constitution said
we should shape society into a self-organizing
self-correcting shared idea and resource system
and that is a very radical
idea even for today for instance most Americans
have no idea what the design of the
United States was or is it's
imply not taught in schools it's not the way American
history is is taught and
so
most societies on earth haven't
gotten this idea even at the societal level
most human beings on earth don't have this
idea but this is one of these powerful ideas
that makes qualitative
differences in almost every
area of life and it's related to an even
bigger set of ideas so
another common sense
whoops
another another
common sense notion which is
actually with most Americans today according to the surveys
I've seen which is the world is pretty much as it seems
so we this
is what our nervous systems are set up to do we're
basically weren't set up by nature to think
we're set up by nature to cope and so
primary mechanism is whatever environment we
find ourselves in so the answer anthropologists
know that you can take a child at
birth from any culture on the planet and take
on the planet that child will grow up as
a member of that culture you took it too that's
because humans are rather more similar
than they are different we have about 300
traits that anthropologists have identified
that seem to be quite genetic including
things like language having culture telling stories
and those mechanisms
get embodied with the
local varieties of those and so the
reality you grow up within the language you
grew up with is the language and
the reality of the culture you you're born in Q
so
now this big ideas
have been had a number of times in history I happen to like the
Talmud version of it
we see things not as they are but as we are
so this is a bit I'd love to know
what actually
happened to the person who came up with this
idea did they take it to its logical conclusion
considering and
was interesting that was published in this Talmud is part
of the commentary
but this is one
of the great big ideas of all time this
is a really hard one because it
completely relative izes what's
going on however it's not a powerful idea
but had numerous
times and
powerful idea came in
the 17th century and you
could point to a number of people and you could point to various
societies but
17th century has a has a perfect
atomic
bomb place where science started
because we had Galileo
and Kepler and maybe Copernicus
beforehand and a few other people but in fact
when Newton did
the Principia he actually revolutionized
human thought and it's probably the largest leap in human
thought of this kind that we know of historically
this is why most scientists
think of Newton as being the greatest scientist
and he was almost the first scientist and
not just in
relative terms but in absolute terms the amount
of distance he was able to cover not just
in terms of knowledge but in terms of about look and
the powerful idea of science
is not so easy to state everything
else comes out pretty nicely as slogans and
there's more to science than just
this but this is one half of it which
is science is not about knowledge as
niels bohr said science is not there to tell
us about the universe is what most people think
most non-scientists most kids in school
are taught what is called science
as in roughly the same way they learn religion in
when they go to church or
synagogue or mosque but
in what science is at all it's not about knowledge
it's about relating the
stuff we can do and can't do in here
all the things that we can do with
our representational systems to stuff
out there that we can't get to directly because
everything we do is filtered through our nervous
systems as filtered through our culture's is
filtered for through the the difficulties
we have with making relationships
about things and this was not an
easy idea to have we'll
see in a bit but
what's happened in the last 400 years in
many many dimensions
has been more than has happened
in the rest of the 200,000 years and you
know the cliche that
most scientists 90 more
of all the scientists who ever lived you're alive today
and most of the things that
are happening today and some
of the problems and some of the solutions to those problems
are all caused this by different way
and much is made
particularly in the pop culture of
bringing bright
this is because pop
culture's or cultures without a lot
of developed knowledge basically
live by their wits and so you out
with each other and you
compete at the level of width but
imagine being born with an IQ
of 500 who knows how
smart leonardo was let's
just no 203 who because
those figures don't what does IQ me in any
way but let's just say hey suppose
you're just a hell of a lot smarter than anybody who ever lived
but you were born in 10,000 BC
how far you going to get so
you can probably out wit everybody around you before
they burn you at the stake
but in fact Leonardo
who we know is very very bright could
not invent a single engine
for any of the vehicles that he designed so
he's famous for designing things that look
like planes and things that maybe look like helicopters
and I'll and they're wonderful and he did a lot
hings but he couldn't make a single goddamn one of
them work that is and that's
because he wasn't smart enough to think himself out
of the era he had been born into as
far as we know if nobody has the closest person who's ever
thought himself out of the era he was born into his
Newton so
you have this odd paradox
that whoops sorry that
Henry Ford who is not nearly as smart as
Leonardo just happened to be born in the right time and
so he did revolutionize one
of the areas that Leonardo wanted to revolutionize
by being able
to do adaptive engineering and a little
invention to the stuff that was already around
so his knowledge was
processed knowledge and this was very powerful and what
was the difference between these two these
two guys was this
change of outlook that Newton
was one of the promulgate errs of
so one of the ways I
when I talked to grabs grad students
or children I say well knowledge
is silver but outlook is
gold our
world is built on changes of outlook that was what the
Constitution was that was what Tom Paine did
and that's what science did and
IQ is led
because there is no
we know of no developed field knowledge in
which you can get by with just talent there's
no developed sport in which you can get by with
just talent and some of the most
difficult sports have been
excelled in by people who are not as athletic
so for instance Chris effort
as an example who is not a particularly athletic
tennis player but man that you know
how to work and so she got very very
good at it and most things have
this thing an Outlook also
tells you what kind of knowledge to
go after because of course every group
in history had a zillion amount of not you going to the
Australian outback without a
native Australian there
to help you you're going to die whereas for
them is just a walk in the park because
everything is food they know how to get water and
it's there just they know where the dangers are they
it's no big deal so every group
has lots of knowledge the real thing to think about is
what kind of knowledge is that what's the quality
level what's the level of flexibility what can you
you do with it and these outlook
changes are more pine Steiners another
one so about a hundred years ago
something
that Newton in a
slightly different Einstein was quite sure that
Newton if he lived longer and had not
been put in had a head
of the Treasury in England that Newton would have actually
come up with a theory of relativity I don't
know whether he could have could have actually
done that because but Newton
didn't know that
he thought it was ridiculous that his equations
had action at a distance
so he said so in letters as just
that nobody could measure well enough
and what they did measure the
gravitational forces seem to
transmit instantly but
from Newton standpoint that was ridiculous
okay so that was
the first section so the second section is to look at
children can actually do under ideal conditions and
this is not easy to find so
a couple of these things are results of
just dealing with hundreds
and hundreds of teachers over more than 40
years and in this case this was an
accident because we were working in the fourth
and fifth grades in the school and of course I started
wandering around the school and I happen to poke my
nose into first grade and
what I saw was quite shocking
to me i should mention I have a
degree in mathematics and another one in molecular biology
as well as the computer science degrees
so when I walked into this math this first grade classroom
and SAT there for a few minutes
I gradually realize
that this teacher was doing real math with
first graders not school
math but real math the real deal and
as I got to know her Julia nishijima was her name
I found she was that
she have not taken any math in college but
she was like one of these musician friends you
might have who was just a natural musician she
was a net she just saw the world in terms of math and
her outlook was in the world of the
kindergarten and first grade child so
over a couple of years I saw some
most amazing things I've ever seen in any classroom at any age
this one was done after the kids have been there for
about three months and the school
is a busing school in LA and what
that means is that the children in order
to induce the parents
to get on the that have
their children but if you think about bus driving
a car in LA as ridiculous so
let's put our children on buses twice
twice a day to
try and deal with some of the racial imbalance
problems and but
they did and there was
interesting inducements to get the parents to do that but
the law was that for each of the busing
schools had to have the same demographic
as the city as a whole so
these busing schools were the perfect place for doing
educational experiments because the city
forty-five percent Hispanic until you have forty-five
percent Hispanic kids in there and
just down the line in these schools so
here's the thing she
had and this is not unlike a lot of the things
that she did with the kids so this one
was fine to shape you like a square diamond
a triangle a trapezoid and
make a progression
of shapes just using these shapes
so next
larger size next larger size next larger size and trapezoids
are coarser are a tricky but
so 30 kids in the class and
they all pick
the ones that they like they all did did something and
then she did something
that seems a little strange to me which was to have
him now go from these easy to handle wouldn't
manipulatives to cutting
out the same shapes out of cardboard so I asked
her afterwards why she did this and she said well little
kids are always jumping to conclusions and this
part now that they've done the thing I want them to think about
it so this part slows them down so the idea here
is make a we're going to make a little thing to free to take
home to your parents to show what what
you're doing and so here's one of them and
Laura in here
on this sheet she wrote down what she
noticed that the first diamond
here took one diamond the total number of diamonds
was one and then she had to add three
more diamonds to get the next
diamond shape and the total was four and then she had to add
five to get the next one the total number of tiles
was nine and she could see
that she was adding to each time
it's get the first column and then
up you can see
she wasn't quite sure what six times six was
but she knew the square numbers
up to five times five
then she worked this all out so this is her sheet
then the teacher
julia had
kids all bringing their projects up to the front of the room
there it is
kids
look to each other's projects and they looked at the little
tables and they went holy shit
technical term
because everybody had filled
same table regardless of what the shapes were the
growth laws were the same so
this was hugely exciting I was there
I just happened to be there that day and
I'm looking at this stuff with tears running down my because
this is one of the best mathematical
things I've ever seen done in any classroom at any age and
some of you
are we'll
have some mathematical background and
realize what the kids were doing is actually
deriving to
differential laws one
is the differential law for smooth progressions
sometimes called linear progressions
that's that first column and
of course if they used instead of using two
they used one it would have a different growth
but it would still be smooth and linear
they could use three or they could use 3.5 so
basic ideas are just adding the same
thing in there and in math that's
called the first order differential equation if it were
in a continuous space like we like
to teach in school but for the kids this is the screen
and there's a math for that its
a math we don't teach but it's called a
first order differential discreet relationship
and the second one is
all the square numbers
it's a quadratic one so this is
called the second order differential discreet
relationship and it's built on the first an important
thing here is that virtually everything
in high school physics and most things in your first physics
course in college can be handled with no more
mathematics than this this is
actually the real basis of the calculus
wind using in high school and college his
calculus has nothing to do with algebra even
though it's cloaked in algebra for historical
reasons most Mountain mathematicians did not realize this
what calculus is is actually an idea
quite separate from the symbology that's
used on so
and of course the kids could calculate with this
so the
little rule they had was you start with
one piece and then you add to the new new pieces column
add to each time and then you
add from that column to
the total column to get the next one and
a few if you act it out you get something like this
so you start off with ones and
you do a plus two to get
the next guy there and then you take that guy and the preceding
guy to gets the next guy in okay
so that's called a second
order differential machine
and
it just happens to be what
Babbage member Babbage what
did Babbage do then the invented computer so first
hing he did was to actually make a machine for computing
exactly those numbers and it
was just he did it so you could compute seven stages
of them because again in mathematical
terms this is a way of computing all of the values
of all of the polynomials of up to a certain
order and Babbage did it because when he was
a kid he was 19 or 20 there
were so many errors in his mathematical
tables booked in the early 1800s he
screwed across the room and he said to his friend
herschel who became a great astronomer he
said I wish to god these calculations have been executed
by steam meaning
gee whiz people make
so many mistakes we can build a machine to just
compute all its math we can
machine to compute all this duck so
that's what this teacher intuited from
these kids and now let's take a look at
relationship
to the world that you're more familiar with and
going to do is go through this thing again and just watch
where the points
are and I've drawn a line through
the curves are so start
off again so there's the ones
okay there's
a3 and a4
so you can see the quadratic one is growing very quickly now
it's next one will be out of sight there
the difference here is pretty interesting because
this way of looking at
it is simply not what you do in first grade because
the looking at
all the values at once which is the way classical mathematics
likes to look at them
in this case requires multiplication
so even in the simple
guy you have to multiply the slope
times X
to get each succeeding y as you go through
there and you have to square you
have a squared term to get the quadratic so so this
way takes it completely out of the child's world and yet the
idea and the capturing
of what change is actually is more fundamental
than the algebraic way of looking at it
because we've made a machine we
don't have to solve in equations we can generate the answers
so
in other words we can mechanically in calculus terms
we can mechanically integrate these things
instead of symbolically having to integrate them and it just changes
everything round this was see more paper
it's great insight not this particular example but
another one this this is an example I did
but the basic idea is if you have a machine that
can help you do the integration then all
of a sudden you can chop ten years and change
outlook to teaching
real math in terms that are built into human beings
so one of the reasons and it happened science
thinks of math this way
because
scientists are lazy mathematicians that's
because it takes so much energy to deal with the real world that
you don't want to spend a lot of time messing around with
mathematics so everything in science is
done by just adding things together and these additions
are quantities that are called vectors you've heard
of those but there are fairly simple generalizations
of what numbers are so this
whole area is incredibly fruitful for
dealing even with very young children
and of course we have computers
so we can do things
with them based on these ideas
and we're used to using computers
in school not for this stuff we're
used to using it to imitate paper
in fact
it's expensive paper with a little bit of magic
in their pay a little extra money and we can run a movie
in our book and we
can go look at something in a library that spread
out over the entire world rather than going down the
hall to do it but by and large pretty
much every use of computing in most schools particularly
in elementary schools is to do what business
people do with their computers which is not to use them for
anything interesting it's basically automating the past
but if
take a look at what computers actually are so
we can get our selves a little
paint palette here
and I'll
make a little car
and obviously
i'm not using powerpoint here but
you can think about this as a teacher as to whether
you would
when you're trying to help
children with examples and stuff you
kind of would like to just be able to
make things on
the fly because you do have a dynamic medium
this has been one of the hardest idea
is to make happen because people
okay I've got my little car and
the thing that's understandable it's sort of a graphical
object and I'll just call it a car here
and but I can also look inside it and here's
something that's a little less usual for
instance here's cars heading it's
where the car is pointing and if I click
over here and start changing the angle you
can see it's changing the car and conversely if
you look over where it says heading and notice
what happens when I change it
so here I have a visual representation where
the car is pointing and here i have a symbolic 1 and
similarly I have little behaviors car
turn by five car 4 by 15 and
those of you tried logo you recognize these are standard
logo ones if I want to make a little script
to take advantage
of these I can just pull out some tiles and
now I've got my car going and maybe
I'll get it to go 10 at a pop
okay so
in fact that I can steer
my car so for instance if i
want to make the car go straight i can take it down to
zero that's a big one for kids go
the other direction turned it in the negative direction
so very young children just
get a sense of concrete
magnitudes and numbers but
driving a car this way is a little bit like kissing your sister
so what you really want to do is make a steering
wheel so we'll paint another
little drawing
and these drawings were all the same entities and
when I look inside this wheel I
see the same thing and
if I turn this wheel
can see the number going up and
negative and stuff and if you remember the number
i put in here determine
which way the car was going which direction
to turn and how much so it's kind of a invitation
to take the name of those
the turn numbers coming out of the wheel
and just dropping it into the script here and
now as I change the wheel
we can see that
the car is turning by whatever the wheels heading
is so here's an interesting thing to think about
if you've ever had trouble with teaching children about variables
a child who learns variables this
way learns it the first time and forever
it's not the variables are hard for
children it's just that the way they're taught is completely
unseated yes
oh this so this is called squeaky
toys if you go to squeak LAN
org runs on every it's
free
yes that was so both of these the
scratch was not the media lab
and was also done on top of squeak so
scratch and e toys or to scratch
was done kind of four teenage
after school kids as
a media thing they're both relatively similar
and you can both do a lot of the same things here
so the basic idea
here is that you're trying
to situate a
motivation if I want to I
to drive this car with a steering wheel and
the fact that the number is coming
out of the steering wheel are going to be different and so it makes sense to have
them name and this script
icking over and over again so this could hardly be simpler
and one other little
thing is the car is a little difficult to control
here and so
to the kids will want it why don't you just put a gear and a
gear here being for example dividing
the number coming out by three
now you have to turn
the way the wheel much further in order to get the same influence
on the car so most 5th graders
have no idea why they should ever learn how to multiply or divide
because in the world that they're taught in school
math they're taught it's not about scaling
it's about solving other kinds of problems but
in the world of science and
engineering it's not about scaling
not about
multiplying as we as
we generally do but it's about scaling things okay
so let
me try another little idea on you i'm going
to make a little script here so
i'm going to set cars speed to 30 and
i'm
going to
set say
increase the cars
horizontal position by cars speed each time
so if I just do this
or if I just let it go
stop
so does does everybody see that
this is that
first column that the six-year-olds did
what I'm
increasing is the position
where they are so the
car is doing a uniform
speed and these little dots i'm
dropping help us see the uniformity of it but
what if i say okay instead
of instead of doing that what
if I okay
look at this one really carefully now what if I increase this by 30
each time alright so the speed is going to start off
0 36 d all
right so now the speed is growing and
then I'm going to whatever
that has grown to i'm going to then bump the car ahead
right so you see this is the two columns
so the car is going to go exponentially
so if i go do
it cow
and this gives us a visual way of
thinking about acceleration because the
distance between those two dots is the distance
travel per unit time and the distance travel
per unit time is the speed
right so many so much distance
per tick 30 miles per hour
and so what's happening here is we can see
accelerating and the fifth graders love to
know that the term for this is acceleration
okay we have a question yes I
know
your your commentary is focusing on math
but my question has
to do with the kids response to reading
and writing or reading and typing in this case do
you find that the kids
are more do they get the transference from being able
to use this high place and I try that after
yeah
that's a good question though
reason I'm hurrying along here is I'm
going to be cut out regardless of how interesting this talk is
it's going to end at 10 minutes to
the hour okay let's move
so I want the only comment here
is does everybody
see that what you're doing on the
computer can't be science but
is only math that you can't do
science on a computer
why
eah
I can simulate any goddamn thing I
want on a computer I can live up one side
and down the other so it's just all math is is
a story that's consistent but
he problem is the degrees of freedom in in any reasonable
human language are larger than those the universe has
and so this is this is why the Greeks
quite invent science except maybe Archimedes
and the reason is they thought God was a mathematician and
thought if they started off with self-evident
first principles that they could just
deduce the universe the same way God did
could be true because that this is a
lot of physicists think this might
be true I doubt it so
let's take a look let's look at the kids in the world now
so you're a bunch of objects objects that
you think will fall to the earth at the same
okay
oh do not pay any attention to
what anybody else the grapefruit now
you two levels of shot put sponge balls
are a couple
sleep janet
is up on the roof because
stopwatches by
the way to do it but
when do you really not go
together so put a sponge ball
okay I think we should do the shot
right and the sub ball because
they're two totally different ways and if
you drop them at the same time but they'll drop
at the same speed drop
okay so
if you do this so Aristotle
did not ask any children when
he came up with the wrong theory of this he
just deduced it using
a using a wrong a common-sense way of thinking about
what's actually going on but we found that one
child in 30 roughly so if you if
you have a class of 30 kids
you've got an excellent chance that one child will do what that little girl
did which is to pull the Galileo and just
cut to the chase and say hey wait
a minute that's
the I'm already in the
place
where all I have to do is just listen and of course the
scaffolding in the Leaning Tower of Pisa was
what Galileo listen to it was under repair at
that time so
but that's
quality could call that a big idea
however
can also do something
a little bit more here so we
take a video these
might look like funny video frames but video is just
part of the objects that these this language deals
with so we can make the frames convenient to take every fifth frame
you can stack them sideways or
you can stack them like this if
you look at this what do you think the kids say
when they see that pattern
acceleration four months later
so four months previously they did the horizontal
thing with the car four months later remember the
visual path what kind of acceleration
so well
let's measure
so we measure from the bottom of one
guy and so we can just use these little
translucent rectangles to do it
pre-measured these so
i don't have to fiddle while I'm rushed
for time as it is but then the cool thing
is i can just stack these up
like
okay what do you think these
things mean what are these
these are the differences
between the speed at each time tick
right each rectangle is the speed at
each time tick in i'm doing a visual subtraction
there and what i'm showing is their progressive if I just subtract
hem off they're all the same what kind of acceleration is
that acceleration
so the kids immediately write this
little script right here
let's listen to Tyrone here
and to make sure that I was
doing it just right I got
a magnifier which would help me
so I figure out if the size was just
right after I'd done that I would
go and click on the little basic
category button and then a little mini
would pop up and one
of the categories would be geometry so I click on that and
here it has many things have
to do with the size and shape of
the rectangle so
I would see with the Heidi I kept
going along the process until I
had them all lined up with their height i subtracted
the smaller ones height from the big one to see
if there was a kind of pattern anywhere there
could help me I'm not as this worked so
in order to show that it was working
i decided to leave a doc copy so that it
would show if the ball was really the exact right speed Henry
simulated ball is tracking the movie
this is how he's showing that his model
is in accord with the real world at
least two within a pixel so what you got here so
here's something to think about lily and mcdermott of
Washington is a physicist who looks at college kids seventy
percent of all college kids including science majors
in this country fail to understand Galilean
gravity that's what this is ninety
percent of the children going doing it
this way actually derive the equations
themselves actually make the simulations from scratch
themselves and show within
the limits of the accuracy hear
that their model is an
accord with physical reality and in fact the difference
between Galilean gravity 14
feet above the ground and Newtonian gravity is only one part
in a million and so we can think of get
Galileo is very lucky that
he couldn't measure that one part
in a million or he would have been very confused right
this way had to be done first before the
Newtonian way hat okay so let me I think I'm
getting to the point where I have to finish up
so
let's think about serious stuff now
e
live inside of systems and we are systems so
it's a nice unification through all of the
sciences engineering and art
so if you're going to make up a middle school science
curriculum for say the eighth grade I would
not pick a science like biology but I pick
a uniform unifying rubric
like systems and I teach all of different Sciences
the systems aspect of those and
use mathematics to deal with those
things and my romantic ideal
would be the planet is in trouble and we need to learn
how to save it
and
what we've got going in general is
something like this if you hit
this mystery object with a hammer it
returns to equilibrium but if
I raise it up far enough it
doesn't come back
so
what we got here
the most systems
are like this the equilibrium
they have is actually dynamically
stable but not statically stable so
if you just tap this thing
it won't do anything but if
tap it enough to get it passed its center of mass bunk
and
thing to understand here is that's
that's what we're doing so what we're doing is stressing
the earth and
little bits of stress like
burning the river in Cleveland can
be fixed up in large amounts of stress
can topple the system and think
about systems is when they get toppled they
don't stop but it's in a new state
now and it's going to resist
getting it back it could so
for instance when the climate has toppled in the past
aken between ten thousand a hundred thousand
and five hundred thousand years to restore all
of those numbers are a lot larger than our lifetime
okay
let me just try it
so
what we've seen here is a Jerry
Bruner idea but I've tried to show you
is that the
most important idea here is that you have to heed the level of
development of the person you're trying to teach and
if you know yourself like it doesn't
make sense for a non mathematician to try and teach math to
a six-year-old it just doesn't
because the six the
six-year-old doesn't think in the same way as a teenager or an
doesn't if you want to teach real math you
have to be a mathematician or have a mathematician
in the loop because the mathematicians job is to figure out what
kind of real math is within the wheelhouse
of the six-year-old
that's really the job
so discovery learning so
here's the thing we have two poles in the United States back to
basics and discovery learning
both of this both these are absolute
vs it
so it's very complicated going into a meeting with
educators because they tend to polarize long those and you
know any scientist and mathematician guys think Oh No
and the
the joke here is about discovery learning is is
whoops is the teacher
saying oh no they're discovering the wrong things why
are they discovering the wrong things well consider
our 200,000 years on the planet
we had to go almost all the
way to the present to just do agriculture Greece was
only 2,500 years ago that was modern math and
real science was just 400 years ago
think about that the
u.s. know a stable
dynamically stable democratic government
is only a few hundred years old these ideas are
not easy so what you need is a guide
so
it's not Hillary climbing Everest it's Tenzing
and Hillary and
sure we'd love to have Socrates and Fineman
as guides but these guys don't
scale this is one of the problems with school
books are great because you can get some
of Fineman and Socrates but
I used books a lot but I needed to have
real teacher that teacher had something libraries didn't
have which is a table full of junk you could make things and learn things with
libraries should have
these but they don't know that they should and I have
my dad who is a physiologist to ask questions of
so what we're thinking about
today is what
kind of use could we make
out of the computer since it has booked like properties
but it also is active enough to
be able to sense what the user is doing
so here's a simple
thing that's very popular guitar hero
so the interesting thing
about guitar hero is that people
don't have to go to school to learn how to play it like
most video games
now the bug with this is that
real guitar I used to be a professional guitar
player jazz guitar it's just
like a thousand times harder than guitar hero guitar hero
is it like simple drumming if
you ever tried drumming is very like
just having a snare and a high hat
and that's tricky enough if
you've ever tried it you have to get a couple of things going it's tricky
you can think it's the entire world because
this trick Ian of itself and there's all these great sounds
coming out but it's absolutely a snare and a delusion and
most here's the prediction most schools
States are going to wind up using computers in
classrooms to do a form of guitar hero
for most of the important subjects
because most teachers in
the united states are not guitar players
alright so this is a huge
problem and yet
without
replacing humans it's
absolutely possible to make some
a fantastic tutoring system for learning any level
of guitar playing at any level
without having to have a human in the loop that's what's interesting
you don't get everything you get with
a human but you get about ninety-five
stuff that you need to be able to do anyway you
can do it and that's what
I want you to think about is not replacing teachers
here but to listen
to our smarter than the average President as
talked to the National Academy last spring he
gets it the
only way we're ever going to get enough science
savvy knowledge into schools is to help
existing teacher with media that understand
the science as children can practice it
this is going to be a revolution
going to happen over the next year and it is a grand challenge it's
as difficult as the challenge that we faced
40 years ago where the challenge was everybody
should have a personal computer pervasively network worldwide
and
we have the funding for it and
we were able to invent it now several billion
people have it and it's time to use the computers
for what they're really good for what
do you think thank you very much
