Popular Mechanics (South Africa)

Your driverless ride is arriving

Hailing a cab will never be the same again

OUTSIDE A LARGE WAREHOUSE in Pittsburgh, in an area along the Allegheny River that was once home to dozens of factories and foundries, but now has shops and restaurant­s, I’m waiting for a different kind of technologi­cal revolution to arrive. I check my phone, look up, and notice it’s already here. A white Ford Fusion, its roof bedazzled with futuristic-looking sensors, is idling nearby. Two people sit up front – one monitoring a computer, the other behind the wheel – but the car is in control. I hop in, press a button on a touch screen, and sit back as the self-driving Uber takes me for a ride.

As we zip out onto the road towards downtown, the car stays neatly in its lane, threading deftly between an oncoming car and parked trucks that stick out into the street. I’ve been in a self-driving car before, but it’s still eerie to watch from the back seat as the steering wheel and pedals move themselves in response to events unfolding on the road around us.

To date, most automated vehicles have been tested on highways in places like California, Nevada and Texas. Pittsburgh, in contrast, features crooked roads, countless bridges, confusing intersecti­ons, and more than its fair share of snow, sleet and rain. As one Uber executive said, if self-driving cars can handle Pittsburgh, they should work anywhere. As if to test this theory, as we turn on to a bustling market street, two pedestrian­s dart on to the road ahead. The car comes to a gentle stop some

distance from them, waiting and then continuing on its way.

A screen in front of the back seat shows the car’s peculiar view of the world: our surroundin­gs rendered in vivid colours and jagged edges. The picture is the product of some of an amazing array of instrument­s arranged all over the vehicle. There are no fewer than seven lasers, including a large spinning lidar unit on the roof; 20 cameras; a highprecis­ion GPS; and a handful of ultrasound sensors. On the screen inside the car, the road looks aqua blue, buildings and other vehicles are red, yellow and green, and nearby pedestrian­s are highlighte­d with what look like little lassos. The screen also indicates how the vehicle is steering and braking, and there’s a button that’ll ask the car to stop the ride any time you want.

This being 2016, Uber has even made it possible for riders to take a selfie from the back seat. Shortly after my ride is over, I receive by e-mail a looping GIF that shows the car’s view of the world and my face grinning in the top-right corner. People on the sidewalk stop and wave while we wait at a traffic light, and a guy driving a pick-up behind us keeps giving the thumbs-up.

My ride is part of the highest-profile test of self-driving vehicles to date, after Uber began letting handpicked customers book rides around Pittsburgh in a fleet of automated taxis. The company, which has already upended the taxi industry with a smartphone app that lets you summon a car, aims to make a significan­t portion of its fleet selfdrivin­g within a matter of years. It’s a bold bet that the technology is ready to transform the way millions of people get around.

But in some ways, it is a bet that Uber has to make. In the first half of this year it lost a staggering $1,27 billion (about R17 billion), mostly because of payments to drivers. Autonomous cars offer “a great opportunit­y for Uber,” says David Keith, an assistant professor at MIT who studies innovation in the automotive industry, “but there’s also a threat that someone else beats them to market.”

Most carmakers, notably Tesla Motors, Audi, Mercedes-Benz, Volvo and General Motors, and even a few big tech companies including Google and (reportedly) Apple, are testing self- self-driving driving vehicles. Tesla cars drive themselves under many circumstan­ces ( (although although the company warns drivers to use the system only on highways and asks them to pay attention and keep their hands on the steering wheel). But despite its formidable competitio­n, Uber might have the best opportunit­y to commercial­ise the technology quickly. Unlike Ford or GM, it can limit automation to the routes it thinks driverless cars can handle at first. And in contrast to Google or Apple, it already has a vast network of taxis that it can make gradually more automated over time.

Uber’s executives have little trouble imagining the upside. With no drivers to split revenues with, Uber could turn a profit. Robot taxis could become so cheap and easy to use that it would make little sense for anyone to actually own a car. Taken to its logical conclusion, automated driving could reprogramm­e transporta­tion itself. Uber is already experiment­ing with food delivery in some cities, and it recently bought Otto, a startup that is developing automated systems for long-haul trucks. Self-driving trucks and vans could ferry goods from fulfillmen­t centres and stores to homes and offices with dizzying speed and efficiency. Shortly before my test ride Andrew Lewandowsk­i, head of Uber’s autonomous operations, a veteran of Google’s self-driving programme, and one of the cofounders of Otto, said: “I really believe that this is the most important thing computers are going to do in the next 10 years.”

Uber is moving quickly. The company created its Advanced Technology Centre, where it’s developing its driverless cars, in February 2015 by hiring a number of researcher­s from the robotics department at nearby Carnegie Mellon University. Using that expertise, Uber developed its self-driving taxis in a little over a year – roughly the amount of time it takes most automakers to redesign an entertainm­ent console.

But is it moving too quickly? Is the technology ready?

ROBO ANCESTORS

For the rest of my time in Pittsburgh, I get around using Ubers controlled exclusivel­y by humans. The contrast is stark. I want to visit CMU’S National Robotics Engineerin­g

Centre (NREC) – part of its Robotics Institute, one of the pioneering research groups involved in developing selfdrivin­g vehicles – to see what its experts think of Uber’s experiment. So I catch a ride with a guy named Brian, who drives a beat-up Hyundai Sonata. Brian says he’s seen several automated Ubers around town, but he can’t imagine a ride in them being as good as one with him. Brian then takes a wrong turn and gets completely lost. To be fair, though, he weaves through traffic just as well as a selfdrivin­g car. Also, when the map on his phone leads us to a bridge that’s closed for repairs, he simply asks a couple of road workers for directions and then improvises a new route. He’s friendly, too, offering to waive the fare and buy me a beer to make up for the inconvenie­nce.

It makes you realise that automated Ubers will offer a very different experience. Fewer wrong turns and overbearin­g drivers, yes, but also no one to help put your suitcase in the trunk or return a lost iphone.

I take a rain check on the beer, say goodbye to Brian, and arrive at NREC’S vast warehouse about 20 minutes late. The building is filled with fascinatin­g robotic prototypes. And if you look carefully, you’ll find some ancestors of today’s automated vehicles. Just inside the entrance, for instance, is Terregator, a six-wheeled robot about the size of a refrigerat­or, with a ring of sensors on top. In 1984, Terregator was among the first robots designed to roam outside of a lab, rolling around CMU’S campus at a few kilometres per hour. And Terregator was succeeded, in 1986, by a heavily modified van called Navlab, one of the first fully computer-controlled vehicles on the road.

Just outside the front door to NREC sits another notable forerunner: a customised Chevy Tahoe filled with computers and decorated with what looks suspicious­ly like an early version of the sensor stack on top of one of Uber’s selfdrivin­g cars. In 2007 this robot, called Boss, won an urban driving contest organised by the US Defence Advanced Research Projects Agency. It was a big moment for automated vehicles, proving that they could navigate ordinary traffic, and just a few years later Google was testing selfdrivin­g cars on real roads.

The three of these CMU robots show how gradualad the progress towards self-driving vehicles was until recently. The hardware and software improved, but the system struggled to make sense of the world a driver sees, in all its rich complexity and weirdness. At NREC, I meet William “Red” Whittaker, a CMU professor who led the developmen­t of Terregator, the first version of Navlab, and Boss. Whittaker says Uber’s new service doesn’t mean the technology is perfected. “Of course it isn’t solved,” he says. “The kinds of things that aren’t solved are the edge cases.”

And there are plenty of edge cases to contend with, including sensors being blinded or impaired by bad weather, bright sunlight, or obstructio­ns. Then there are the inevitable software and hardware failures. But more important, the edge cases involve dealing with the unknown. You can’t program a car for every imaginable situation, so at some stage, you have to trust that it will cope with just about anything that’s thrown at it, using whatever intelligen­ce it has. And it’s hard to be confident about that, especially when even the smallest misunderst­anding, like mistaking a paper bag for a large rock, could lead a car to do something unnecessar­ily dangerous.

Progress has undoubtedl­y picked up in recent years. In particular, advances in computer vision and machine learning have made it possible for automated vehicles to do more with video footage. If you feed enough examples into one of these systems, it can do more than spot an obstacle – it can identify it with impressive accuracy as a pedestrian, a cyclist, or an errant goose.

Still, the edge cases matter. The director of NREC is Herman Herman, a roboticist who grew up in Indonesia, studied at CMU, and has developed automated vehicles for defence, mining and agricultur­e. He believes self-driving cars will arrive, but he raises a few practical concerns about Uber’s plan. “When your Web browser or your computer crashes, it’s annoying, but it’s not a big deal,” he says. “If you have six lanes of highway, there is an autonomous car driving in the middle, and the car decides to make a left turn... well, you can imagine what happens next. It just takes one erroneous command to the steering wheel.”

Another problem Herman foresees is scaling the technology up. It’s all very well having a few driverless cars on the road, but what about dozens, or hundreds? The laser scanners found on Uber’s cars might interfere with one another, he says, and if those vehicles were connected to the cloud, that would require an insane amount of bandwidth. Even something as simple as dirt on a sensor could pose a problem, he says. “The most serious issue of all – and this is a growing area of research for us – is how you verify, how you test an autonomous system to make sure they’re safe,” says Herman.

LEARNING TO DRIVE

For a more hands-on perspectiv­e, I head across town to talk to people actually developing self-driving cars. I visit Raj Rajkumar, a member of CMU’S robotics faculty who runs a lab funded by GM. In the fast-moving world of research into driverless cars, which is often dominated by people in Silicon Valley, Rajkumar might seem a bit old school. Wearing a grey suit, he greets me at his office and then leads me to a basement garage where he’s been working on a prototype Cadillac. The car contains numerous sensors, similar to the ones found on Uber’s cars, but they are all miniaturis­ed and hidden away so that it looks completely normal. Rajkumar is proud of his progress on making driverless cars practical, but he warns me that Uber’s taxis might be raising hopes unreasonab­ly high. “It’s going to take a long time before you can take the driver out of the equation,” he says. “I think people should mute their expectatio­ns.”

Besides the reliabilit­y of a car’s software, Rajkumar worries that a driverless vehicle could be hacked. “We know about the terror attack in Nice, where the terrorist driver was mowing down hundreds of people. Imagine there’s no driver in the vehicle,” he says. Uber says it takes this issue seriously; it recently added two prominent experts on automotive computer security to its team. Rajkumar also warns that fundamenta­l progress is needed to get computers to interpret the real world more intelligen­tly. “We as humans understand the situation,” he says. “We are cognitive, sentient beings. We comprehend, we reason, and we take action. When you have automated vehicles, they are just programmed to do certain things for certain scenarios.”

In other words, the colourful picture I saw in the back of my automated Uber represents a simplistic and alien way of understand­ing the world. It shows where objects are, sometimes with centimetre precision, but there’s no understand­ing what those things really are or what they might do. This is more important than it might sound. An obvious example is how people react when they see a toy sitting in the road and conclude that a child might not be far away. “The additional trickiness is that Uber makes most of its money in urban and suburban locations,” Rajkumar says. “That’s where unexpected situations tend to arrive more often.”

What’s more, anything that goes wrong with Uber’s experiment­al taxi service could have ramificati­ons for the entire industry. The first fatal crash involving an automated driving system, when a Tesla in Autopilot mode failed to spot a large truck on a Florida highway in 2016, has already raised safety questions. Hastily deploying any technology – even one meant to make the roads safer – might easily trigger a backlash. “While Uber has done a great job of promoting this as a breakthrou­gh, it’s still quite a way away, realistica­lly,” says MIT’S Keith. “Novel technologi­es depend on positive word of mouth to build consumer acceptance, but the opposite can happen as well. If there are terrible car crashes attributed to this technology, and regulators crack down, that certainly would moderate people’s enthusiasm.”

I get to experience the reality of the technology’s limits firsthand, about halfway through my ride in Uber’s car, shortly after I’m invited to sit in the driver’s seat. I push a button to activate the automated driving system, and I’m told I can disengage it at any time by moving the steering wheel, touching a pedal, or hitting another big red button. The car seems to be driving perfectly, just as before, but I can’t help noticing how nervous the engineer next to me now is. And then, as we’re sitting in traffic on a bridge, with cars approachin­g in the other direction, the car begins slowly turning the steering wheel to the left and edging out into the oncoming lane. “Grab the wheel,” the engineer shouts.

Maybe it’s a bug, or perhaps the car’s sensors are confused by the wide-open spaces on either side of the bridge. Whatever the case, I quickly do as he says.

I really believe that this is THE MOST IMPORTANT THING computers are going to do in the next 10 years.