How to pronounce "laps"

Translator: Morton Bast Reviewer: Thu-Huong Ha

So, how many of you have ever

gotten behind the wheel of a car

when you really shouldn't have been driving?

Maybe you're out on the road for a long day,

and you just wanted to get home.

You were tired, but you felt you could drive a few more miles.

Maybe you thought,

I've had less to drink than everybody else,

I should be the one to go home.

Or maybe your mind was just entirely elsewhere.

Does this sound familiar to you?

Now, in those situations, wouldn't it be great

if there was a button on your dashboard

that you could push, and the car would get you home safely?

Now, that's been the promise of the self-driving car,

the autonomous vehicle, and it's been the dream

since at least 1939, when General Motors showcased

this idea at their Futurama booth at the World's Fair.

Now, it's been one of those dreams

that's always seemed about 20 years in the future.

Now, two weeks ago, that dream took a step forward,

when the state of Nevada granted Google's self-driving car

the very first license for an autonomous vehicle,

clearly establishing that it's legal for them

to test it on the roads in Nevada.

Now, California's considering similar legislation,

and this would make sure that the autonomous car

is not one of those things that has to stay in Vegas.

(Laughter)

Now, in my lab at Stanford, we've been working on

autonomous cars too, but with a slightly different spin

on things. You see, we've been developing robotic race cars,

cars that can actually push themselves to the very limits

of physical performance.

Now, why would we want to do such a thing?

Well, there's two really good reasons for this.

First, we believe that before people turn over control

to an autonomous car, that autonomous car should be

at least as good as the very best human drivers.

Now, if you're like me, and the other 70 percent of the population

who know that we are above-average drivers,

you understand that's a very high bar.

There's another reason as well.

Just like race car drivers can use all of the friction

between the tire and the road,

all of the car's capabilities to go as fast as possible,

we want to use all of those capabilities to avoid

any accident we can.

Now, you may push the car to the limits

not because you're driving too fast,

but because you've hit an icy patch of road,

conditions have changed.

In those situations, we want a car

that is capable enough to avoid any accident

that can physically be avoided.

I must confess, there's kind of a third motivation as well.

You see, I have a passion for racing.

In the past, I've been a race car owner,

a crew chief and a driving coach,

although maybe not at the level that you're currently expecting.

One of the things that we've developed in the lab --

we've developed several vehicles --

is what we believe is the world's first

autonomously drifting car.

It's another one of those categories

where maybe there's not a lot of competition.

(Laughter)

But this is P1. It's an entirely student-built electric vehicle,

which through using its rear-wheel drive

and front-wheel steer-by-wire

can drift around corners.

It can get sideways like a rally car driver,

always able to take the tightest curve,

even on slippery, changing surfaces,

never spinning out.

We've also worked with Volkswagen Oracle,

on Shelley, an autonomous race car that has raced

at 150 miles an hour through the Bonneville Salt Flats,

gone around Thunderhill Raceway Park in the sun,

the wind and the rain,

and navigated the 153 turns and 12.4 miles

of the Pikes Peak Hill Climb route

in Colorado with nobody at the wheel.

(Laughter)

(Applause)

I guess it goes without saying that we've had a lot of fun

doing this.

But in fact, there's something else that we've developed

in the process of developing these autonomous cars.

We have developed a tremendous appreciation

for the capabilities of human race car drivers.

As we've looked at the question of how well do these cars perform,

we wanted to compare them to our human counterparts.

And we discovered their human counterparts are amazing.

Now, we can take a map of a race track,

we can take a mathematical model of a car,

and with some iteration, we can actually find

the fastest way around that track.

We line that up with data that we record

from a professional driver,

and the resemblance is absolutely remarkable.

Yes, there are subtle differences here,

but the human race car driver is able to go out

and drive an amazingly fast line,

without the benefit of an algorithm that compares

the trade-off between going as fast as possible

in this corner, and shaving a little bit of time

off of the straight over here.

Not only that, they're able to do it lap

after lap after lap.

They're able to go out and consistently do this,

pushing the car to the limits every single time.

It's extraordinary to watch.

You put them in a new car,

and after a few laps, they've found the fastest line in that car,

and they're off to the races.

It really makes you think,

we'd love to know what's going on inside their brain.

So as researchers, that's what we decided to find out.

We decided to instrument not only the car,

but also the race car driver,

to try to get a glimpse into what was going on

in their head as they were doing this.

Now, this is Dr. Lene Harbott applying electrodes

to the head of John Morton.

John Morton is a former Can-Am and IMSA driver,

who's also a class champion at Le Mans.

Fantastic driver, and very willing to put up with graduate students

and this sort of research.

She's putting electrodes on his head

so that we can monitor the electrical activity

in John's brain as he races around the track.

Now, clearly we're not going to put a couple of electrodes on his head

and understand exactly what all of his thoughts are on the track.

However, neuroscientists have identified certain patterns

that let us tease out some very important aspects of this.

For instance, the resting brain

tends to generate a lot of alpha waves.

In contrast, theta waves are associated with

a lot of cognitive activity, like visual processing,

things where the driver is thinking quite a bit.

Now, we can measure this,

and we can look at the relative power

between the theta waves and the alpha waves.

This gives us a measure of mental workload,

how much the driver is actually challenged cognitively

at any point along the track.

Now, we wanted to see if we could actually record this

on the track, so we headed down south to Laguna Seca.

Laguna Seca is a legendary raceway

about halfway between Salinas and Monterey.

It has a curve there called the Corkscrew.

Now, the Corkscrew is a chicane, followed by a quick

right-handed turn as the road drops three stories.

Now, the strategy for driving this as explained to me was,

you aim for the bush in the distance,

and as the road falls away, you realize it was actually the top of a tree.

All right, so thanks to the Revs Program at Stanford,

we were able to take John there

and put him behind the wheel

of a 1960 Porsche Abarth Carrera.

Life is way too short for boring cars.

So, here you see John on the track,

he's going up the hill -- Oh! Somebody liked that --

and you can see, actually, his mental workload

-- measuring here in the red bar --

you can see his actions as he approaches.

Now watch, he has to downshift.

And then he has to turn left.

Look for the tree, and down.

Not surprisingly, you can see this is a pretty challenging task.

You can see his mental workload spike as he goes through this,

as you would expect with something that requires

this level of complexity.

But what's really interesting is to look at areas of the track

where his mental workload doesn't increase.

I'm going to take you around now

to the other side of the track.

Turn three. And John's going to go into that corner

and the rear end of the car is going to begin to slide out.

He's going to have to correct for that with steering.

So watch as John does this here.

Watch the mental workload, and watch the steering.

The car begins to slide out, dramatic maneuver to correct it,

and no change whatsoever in the mental workload.

Not a challenging task.

In fact, entirely reflexive.

Now, our data processing on this is still preliminary,

but it really seems that these phenomenal feats

that the race car drivers are performing

are instinctive.

They are things that they have simply learned to do.

It requires very little mental workload

for them to perform these amazing feats.

And their actions are fantastic.

This is exactly what you want to do on the steering wheel

to catch the car in this situation.

Now, this has given us tremendous insight

and inspiration for our own autonomous vehicles.

We've started to ask the question:

Can we make them a little less algorithmic

and a little more intuitive?

Can we take this reflexive action

that we see from the very best race car drivers,

introduce it to our cars,

and maybe even into a system that could

get onto your car in the future?

That would take us a long step

along the road to autonomous vehicles

that drive as well as the best humans.

But it's made us think a little bit more deeply as well.

Do we want something more from our car

than to simply be a chauffeur?

Do we want our car to perhaps be a partner, a coach,

someone that can use their understanding of the situation

to help us reach our potential?

Can, in fact, the technology not simply replace humans,

but allow us to reach the level of reflex and intuition

that we're all capable of?

So, as we move forward into this technological future,

I want you to just pause and think of that for a moment.

What is the ideal balance of human and machine?

And as we think about that,

let's take inspiration

from the absolutely amazing capabilities

of the human body and the human mind.

Thank you.

(Applause)