We have incredible potential.
But how much do we really know
about what are the most effective ways
for us to extract this potential?
To overcome obstacles?
To reach our goals?
To change as we need
to change along the way?
To learn? To evolve?
I'm a professor of computer science,
and my area of research
is quantum computation.
Those are computers that don't exist yet.
But imagine computers
that will take one second
to solve certain computational tasks
that the fastest
supercomputer in the world
will take zillions of years to solve.
Thousands of researchers
all over the world are now trying
to build those computers,
and also trying to understand
what you will be able to do with them
if and when we manage to build them.
I deal with difficult challenges
on a daily basis.
I'm really interested
in trying to find ways
to overcome obstacles, and learning,
which are more effective.
Now, during my career
I've had ups and downs.
I was fortunate enough to have
a very, very successful PhD.
But immediately after my PhD,
I went into this numb period
in which nothing seemed to actually work,
even though I was putting
a lot of effort into it.
My friend came to me and told me
"Dorit, you've painted
a very beautiful picture in your PhD.
But you're putting in too much effort.
Maybe it's time to let go, sign it up,
and move on to the next picture."
And he was right; I was clinging
to it with all my might.
I was applying a lot of force.
That's one way of applying force.
But we do that all the time
in many, many different contexts
and many variations.
Imagine yourself opening a drawer.
You try to open it.
It doesn't open.
It's stuck.
What do you do?
You try harder.
And if it doesn't work,
you try even harder.
It might even break.
You tell yourself
you have to finish an exercise,
so you force yourself to do it.
You want to go on a diet,
you force yourself to do it.
You need to finish this book
that's been lying
near your bed for a month,
you force yourself to do it.
I'm not saying that as a criticism,
it's just an observation.
We see this all around us,
it's something very natural for us to do,
and that's what we've probably
been told to do
many times when we were very young.
But we lose a lot
from this forceful approach.
We lose a lot in quality.
We lose our sensitivity, our creativity.
Imagine a kid who hates mathematics
and is forced to do
a mathematical exercise.
It's not a very pretty
sight to see, right?
It's not inspiring.
It's as if some other part
of his brain has taken over him,
and it's doing the job
but it's doing it very, very poorly.
But there's a different kind
of thinking and learning
which is much more connected to ourselves,
and much more attentive,
and of a much higher quality -
something which is much more connected,
much more attentive;
it's more sensitive and more creative.
I want to give you an experience
of such a learning and thinking process
which is not forced.
I'm holding a glass of water
here in front of you,
and I'm going to rotate
this glass around itself
without spilling the water, and without
detaching my hand from the glass.
Here, watch me do it.
Good, worked the first time.
Now I have a question for you.
How many times did the glass
rotate around itself?
I'll let you watch me do it again.
Watch carefully.
Okay.
It doesn't matter;
the answer doesn't matter.
The point is that my question - if you're
curious and intrigued by the movement -
my question triggered some spontaneous
thinking process inside you
that was unforced.
It was something
connected to your curiosity
and something that came from within.
The answer, by the way, is two.
I'm looking for ways to maintain
those kind of qualities -
sensitivity, creativity -
those connections within us,
not only with such simple exercises,
but also in front of the hardest obstacles
that we want to overcome.
For that matter, let me
move on to my other passion.
I've done body-mind methods for years.
I practice tai chi,
king fu, yoga, Feldenkrais.
One day, my kung fu teacher came to me,
it was while I was doing this kick.
And he told me,
"Dorit, pay attention to how
you return your leg back from the kick."
Now, actually, I never even knew
I'm returning my leg back from the kick.
It always seemed to me like my kick
ended with my leg up in the air,
and the rest didn't exist.
And then it occurred to me,
it's exactly how I operate in life.
I throw myself into challenges,
and then I don't care about
how I come back from them.
What we do with our physical body,
our physical patterns,
are actually intimately connected
to how we interact with life in general.
I want to give you four principles
I've extracted from body-mind methods.
And those principles, I think,
are very useful for overcoming obstacles
and learning in general
while maintaining your sensitivity,
and creativity, and capabilities,
even in front of very difficult obstacles.
Now, those principles don't only apply
to physical movement,
I think they apply to overcoming
challenges in general.
In fact, they also apply
to my scientific research
and for learning mathematics.
I'm going to give you an example
coming from a Feldenkrais lesson
and extract the principles
from it one by one.
I'm just taking Feldenkrais as an example;
I could have taken other
body-mind methods as well,
but this is a particularly
illuminating example.
You see here my Feldenkrais
teacher, Eilat Almagor,
and she's giving a lesson
to a child called Yuval.
Yuval came to the lesson with some kind
of asymmetry in the way he's sitting.
He finds it difficult to lean
on his left sitting bone.
He leans on his right sitting bone.
That means that he can't take his right
leg to the right, like that, while sitting
because he can't lift
his right sitting bone.
By the end of the lesson, however,
Yuval actually brings his right leg
to the right on his own.
I want to give you the key steps
of what's going on in the lesson,
and walk you through those key steps,
and extract the principles one by one.
(Video) Dorit Aharonov: Eilat starts
by working with Yuval's
right sitting bone.
Now this might seem counterintuitive
because Yuval already knows
how to lean on his right sitting bone.
(On stage) DA: You might think
that this means
that he will actually move
further to the right.
And indeed, a little bit later,
he does move further to the right.
First principle:
Start within your comfort zone,
and make it even more comfortable.
The next thing that Eilat does,
is now that Yuval
is very comfortable with where he is,
she inserts one little new ingredient
into his scenario.
She just lets him feel that he can
be supported in his left sitting bone.
But this is done within his comfort zone.
She just picks one
little thing to add to it.
Pick a challenge which
is interesting, within your reach,
not too easy, not too hard.
The next thing that Eilat does
might look a bit weird.
She lifts Yuval up in the air
and lets him fall,
and she does it from various directions.
Now what she actually does,
is she takes him away
from what he has just learned,
to lean on both his sitting bones,
and lets him know that he can return back
to what he just learned
from different directions.
Third principle:
Move away from your desired goal,
and come back to it
from different directions.
Now, you might have noticed
that during the whole time,
Yuval continues to play,
and do various things, and move.
It's all happening
within his comfort zone.
He integrates everything
that he's learning into his own life.
Fourth and last principle:
Play with it, connect it
to everything you know,
make it your own.
A little bit later, Yuval takes his leg
to the right on his own.
The movement has already become his own.
I want to repeat those four principles.
Start within your comfort zone
and make it even more comfortable.
Second principle:
Not too easy, not too hard:
Pick an interesting challenge
within your reach.
Third principle:
Move away from your desired goal,
and come back to it from different angles.
Fourth principle:
Play with it, connect it,
make it your own.
Okay, now these principles,
they're effective, as you've seen,
in the context of movement.
But I find them to be very, very effective
also in other contexts.
And in particular,
in my scientific research,
and in the context
of mathematics in general.
Now, I want to give you an example
of how to use those principles
in the context of mathematics,
in the context of a small riddle.
Once upon a time, there was a queen.
The queen ruled her island because
she was the only one on the island
who knew how to do the following trick.
She had two cubes;
each cube had six faces,
and on each face,
there is a digit written.
Now, what she knew
how to do with those cubes
is she knew how to represent
all dates in the month with those cubes.
Now, this is a bit confusing because
there are only six faces on each cube,
and there are ten digits to write on them,
so how did she do that?
I want to solve this riddle with you
using the principles that I've just shown,
and I'll have this place here
at the top corner of the screen
where the principle
that we're now using will be written.
So that you can keep track of it.
We start with what we need to do.
We need to write six digits on each cube
so I make space for those digits,
six for each cube.
Now let's start
with a very, very small step.
Let's just write the first date - 01.
So we need a 0 on the first cube,
and we need a 11 on the second cube
so we do that.
Well that was easy enough,
so let's continue this way.
We can also write 02, 03, 04, 05.
Okay, but we can't continue like that
for all dates that start with 0,
there's just not enough room
in the right cube.
So now we see that we can
identify a simple goal
that is still something interesting
that we don't know how to do.
Let's try to represent
all the dates that start with 0 -
the left-most column.
We see that we can't just do that
with just one 0 on one cube,
but if we add one 0 on the right cube,
then you can combine it
with all the digits
by putting all the other digits
on the left cube.
So now we are done with the left column.
But we can take this idea of having
0 on both cubes to the next column.
We can solve now for the next column
which consists of all numbers
that start with 1,
by just putting 1 on both cubes.
We can do that because we have more room,
we add a 1 to the left cube,
and now we have 1 on both cubes
and we can do all combinations
with all the other digits.
So that's fine for the second column.
Now we want to do the third column.
So if we can put 2 on both cubes,
that would be great,
but we don't have more room.
So now what do we do?
Well, we use the next principle,
and we make a deliberate mistake.
We move away from our target and we add 2,
even though we don't have room for that.
Maybe we can correct for it later.
Okay, so now we have 2 on the left cube,
and you can check that
you can now write all the 20s,
and you can also see
that you can write 30 and 31.
Great, but now we have
seven digits on the left cube.
So how do we correct for that?
I need all the digits on the left cube,
so what do I do?
Now I want to use the fourth principle:
I want to play with it.
So let's get serious with playing.
I brought here with me
two colorful cubes from that island,
and I want to play with them.
I'm going to play with them,
and I can write here -
they're going to break, actually -
okay, I have a 2 here;
I can write 20-something.
Let's see.
I can write 21.
I can write 27.
I can write 26.
29!
Right, I can also write 29.
Aha, you've got it already.
I don't need the 6 and 9.
And that's the solution.
Now, you might be thinking,
"Hmm, is this all it takes
to be a quantum computer scientist?
Just rotate colorful cubes
and lift your right and left
sitting bone once in a while,
and follow your butt once in a while?"
Well, the answer is...
honestly, yes.
Now seriously, I strongly believe
that all scientific discoveries,
great or small,
can be boiled down
to a very small, little step
of maybe a twist or a rotation
around what you thought before,
or looking at things
from a different angle,
or making an unexpected connection.
And playing with it
will reveal those things.
And this is exactly what we're doing now
in the area of quantum computation.
In this area, we are actually at the state
of Yuval in the beginning of the lesson.
We don't know yet
how to build those computers.
And we don't know yet
what we will be able to do with them,
if and when they're built.
But what we're doing is,
we start within our comfort zone,
we look around to see
where we can expand it,
where we can find challenges
within our reach
that are still interesting,
and once we find them
and manage to get them,
we try to understand it further,
we try to go back and forth
in order for it to be reliable.
We try to fall on it
from different directions,
and we keep continuing to play.
And that is something
that has already been very useful,
even without reaching
our goals, our big goals,
we already found very,
very interesting things
and many new areas have been opened,
and many new connections,
just by this approach.
Do you have a goal in your life
that you haven't managed to move
or make progress on for a long time?
I invite you to check - maybe...
maybe...
you're putting just too much energy
in a direction that you expect
things to move.
And maybe by reducing the amount of force
and letting it move in other directions,
you might find yourself
in a different place
which could be very close
to where you are now,
but it will be a different place
from which things will look different.
I find that resisting the temptation
of using the forceful approach
is a lifelong process of awareness,
but I think it's worthwhile
because you gain your sensitivity,
your creativity, your liveliness,
in front of difficult obstacles.
And even if you don't reach
what you wanted,
well, you reach other places
which could be as interesting.
Thank you for listening.
(Applause)
(Whistles)
(Cheers)