-
Every single one of us will lose
-
or has already lost something
we rely on every single day.
-
I am of course talking about our keys.
-
(Laughter)
-
Just kidding.
-
What I actually want to talk about is one
of our most important senses: vision.
-
Every single day we each lose
a little bit of our ability
-
to refocus our eyes
-
until we can't refocus at all.
-
We call this condition presbyopia,
-
and it affects two billion
people worldwide.
-
That's right, I said billion.
-
If you haven't heard of presbyopia,
-
and you're wondering,
"Where are these two billion people?"
-
here's a hint before
I get into the details.
-
It's the reason why people wear
reading glasses or bifocal lenses.
-
I'll get started by describing
the loss in refocusing ability
-
leading up to presbyopia.
-
As a newborn, you would have
been able to focus
-
as close as six and a half centimeters,
-
if you wished to.
-
By your mid-20s, you have about
half of that focusing power left.
-
10 centimeters or so,
-
but close enough that you never
notice the difference.
-
By your late 40s though,
-
the closest you can focus
is about 25 centimeters,
-
maybe even farther.
-
Losses in focusing ability
beyond this point
-
start affecting near-vision
tasks like reading,
-
and by the time you reach age 60,
-
nothing within a meter
radius of you is clear.
-
Right now some of you
are probably thinking,
-
that sounds bad but he means
you in a figurative sense,
-
only for the people that actually
end up with presbyopia.
-
But no, when I say you, I literally mean
that every single one of you
-
will someday be presbyopic
if you aren't already.
-
That sounds a bit troubling.
-
I want to remind you that presbyopia
has been with us for all of human history
-
and we've done a lot
of different things to try and fix it.
-
So to start, let's imagine
that you're sitting at a desk, reading.
-
If you were presbyopic,
-
it might look a little
something like this.
-
Anything close by,
like the magazine, will be blurry.
-
Moving on to solutions.
-
First, reading glasses.
-
These have lenses
with a single focal power
-
tuned so that near objects
come into focus.
-
But far objects
necessarily go out of focus,
-
meaning you have to constantly
switch back and forth
-
between wearing and not wearing them.
-
To solve this problem
-
Benjamin Franklin invented
what he called "double spectacles."
-
Today we call those bifocals,
-
and what they let him do
was see far when he looked up
-
and see near when he looked down.
-
Today we also have progressive lenses
which get rid of the line
-
by smoothly varying the focal power
from top to bottom.
-
The downside to both of these
-
is that you lose field of vision
at any given distance,
-
because it gets split up
from top to bottom like this.
-
To see why that's a problem,
-
imagine that you're climbing
down a ladder or stairs.
-
You look down to get
your footing but it's blurry.
-
Why would it be blurry?
-
Well, you look down
and that's the near part of the lens,
-
but the next step was past arm's reach,
-
which for your eyes counts as far.
-
The next solution I want to point out
is a little less common
-
but comes up in contact lenses
or LASIK surgeries,
-
and it's called monovision.
-
It works by setting up
the dominant eye to focus far
-
and the other eye to focus near.
-
Your brain does the work
of intelligently putting together
-
the sharpest parts from each eye's view,
-
but the two eyes see
slightly different things,
-
and that makes it harder
to judge distances binocularly.
-
So where does that leave us?
-
We've come up with a lot of solutions
-
but none of them quite restore
natural refocusing.
-
None of them let you
just look at something
-
and expect it to be in focus.
-
But why?
-
Well, to explain that
-
we'll want to take a look
at the anatomy of the human eye.
-
The part of the eye that allows us
to refocus to different distances
-
is called the crystalline lens.
-
There are muscles surrounding the lens
that can deform it into different shapes,
-
which in turn changes its focusing power.
-
What happens when someone
becomes presbyopic?
-
It turns out that
the crystalline lens stiffens
-
to the point that it doesn't
really change shape anymore.
-
Now, thinking back
on all the solutions I listed earlier,
-
we can see that they all have
something in common with the others
-
but not with our eyes,
-
and that is that they're all static.
-
It's like the optical equivalent
of a pirate with a peg leg.
-
What is the optical equivalent
of a modern prosthetic leg?
-
The last several decades have seen
the creation and rapid development
-
of what are called "focus-tunable lenses."
-
There are several different types.
-
Mechanically-shifted Alvarez lenses,
-
deformable liquid lenses
-
and electronically-switched,
liquid crystal lenses.
-
Now these have their own trade-offs,
-
but what they don't skimp on
is the visual experience.
-
Full-field-of-view vision that can be
sharp at any desired distance.
-
OK, great. The lenses we need
already exist.
-
Problem solved, right?
-
Not so fast.
-
Focus-tunable lenses add a bit
of complexity to the equation.
-
The lenses don't have any way of knowing
what distance they should be focused to.
-
What we need are glasses
-
that, when you're looking far,
far objects are sharp,
-
and when you look near,
-
near objects come into focus
in your field of view,
-
without you having to think about it.
-
What I've worked on
these last few years at Stanford
-
is building that exact intelligence
around the lenses.
-
Our prototype borrows technology
from virtual and augmented reality systems
-
to estimate focusing distance.
-
We have an eye tracker that can tell
what direction our eyes are focused in.
-
Using two of these, we can
triangulate your gaze direction
-
to get a focus estimate.
-
Just in case though,
to increase reliability,
-
we also added a distance sensor.
-
The sensor is a camera
that looks out at the world
-
and reports distances to objects.
-
We can again use your gaze direction
to get a distance estimate
-
for a second time.
-
We then fuse those two distance estimates
-
and update the focus-tunable
lens power accordingly.
-
The next step for us was
to test our device on actual people.
-
So we recruited about 100 presbyopes
and had them test our device
-
while we measured their performance.
-
What we saw convinced us right then
that autofocals were the future.
-
Our participants could see more clearly,
they could focus more quickly
-
and they thought it was an easier
and better focusing experience
-
than their current correction.
-
To put it simply, when it comes to vision,
-
autofocals don't compromise
like static corrections in use today do.
-
But I don't want to get ahead of myself.
-
There's a lot of work
for my colleagues and me left to do.
-
For example, our glasses are a bit --
-
(Laughter)
-
bulky, maybe?
-
And one reason for this
is that we used bulkier components
-
that are often intended
for research use or industrial use.
-
Another is that we need
to strap everything down
-
because current eye-tracking algorithms
don't have the robustness that we need.
-
So moving forward,
-
as we move from a research
setting into a start-up,
-
we plan to make future autofocals
-
eventually look a little bit more
like normal glasses.
-
For this to happen,
we'll need to significantly improve
-
the robustness
of our eye-tracking solution.
-
We'll also need to incorporate smaller
and more efficient electronics and lenses.
-
That said, even with
our current prototype,
-
we've shown that today's
focus-tunable lens technology
-
is capable of outperforming
traditional forms of static correction.
-
So it's only a matter of time.
-
It's pretty clear that in the near future,
-
instead of worrying about which pair
of glasses to use and when,
-
we'll be able to just focus
on the important things.
-
Thank you.
-
(Applause)
closed TED
