Can Cars Drive Themselves—And Should They?

Will cars really be able to drive themselves without human operators? Should they? And are they good business investments? Everyone is searching for answers.

Autonomous vehicle technology has reached a point where no automaker can ignore it. Every major auto maker is racing to develop and perfect autono­mous vehicles, believing that the market for them could one day reach trillions of dollars. Companies such as Ford, General Motors, Nissan, Mercedes, Tesla, and others have invested billions in autono­mous technology research and development. Ford in­vested $1 billion in AI firm Argo AI, and GM bought a self-driving car startup called Cruise. Ford has set a goal of producing a self-driving car with no pedals by 2021. Ride-hailing companies like Uber and Lyft believe driverless cars that eliminate labor costs are key to their long-term profitability. Cars that drive themselves have been on the road in select loca­tions in California, Arizona, Michigan, Paris, London, Singapore, and Beijing. Waymo, the company that emerged from Google’s self-driving car project, pre­dicts that by 2020 its fleet of self-driving Jaguars will make as many as one million trips per day.

A car that is supposed to take over driving from a human requires a very powerful computer system that must process and analyze large amounts of data generated by myriad sensors, cameras, and other devices to control and adjust steering, accelerating, and braking in response to real-time conditions. Key technologies include:

Sensors: Self-driving cars are loaded with sensors of many different types. Sensors on car wheels measure car velocity as it drives and moves through traffic. Ultrasonic sensors measure and track positions of line curbs, sidewalks, and objects very close to the car.

Cameras: Cameras are needed for spotting things like lane lines on the highway, speed signs, and traffic lights. Windshield-mounted cameras create a 3-D image of the road ahead. Cameras behind the rear-view mirror focus on lane markings. Infrared cameras pick up infrared beams emitted from head­lamps to extend vision for night driving.

Lidars: Lidars are light detection and ranging de­vices which sit on top of most self-driving cars.

A lidar fires out millions of laser beams every sec­ond, measuring how long they take to bounce back. The lidar takes in a 360-degree view of a car’s sur­roundings, identifying nearby objects with an accu­racy up to 2 centimeters. Lidars are very expensive and not yet robust enough for a life of potholes, ex­treme temperatures, rain, or snow.

GPS: A global positioning system (GPS) pinpoints the car’s macro location, and is accurate to within 1.9 meters. Combined with reading from tachom­eters, gyroscopes, and altimeters, it provides initial positioning.

Radar: Radar bounces radio waves off of objects to help see a car’s surroundings, including blind spots, and is especially helpful for spotting big metallic ob­jects, such as other vehicles.

Computer: All the data generated by these tech­nologies needs to be combined, analyzed, and turned into a robot-friendly picture of the world, with in­structions on how to move through it, requiring almost supercomputer-like processing power. Its soft­ware features obstacle avoidance algorithms, predic­tive modeling, and “smart” object discrimination (for example, knowing the difference between a bicycle and a motorcycle) to help the vehicle follow traffic rules and navigate obstacles.

Machine Learning, Deep Learning, and Computer Vision Technology: The car’s computer system has to be “trained” using machine intelligence and deep learning to do things like detect lane lines and identify cyclists, by show­ing it millions of examples of the subject at hand. Because the world is too complex to write a rule for every possible scenario, cars must be able to “learn” from experience and figure out how to navigate on their own.

Maps: Before an autonomous car takes to the streets, its developers use cameras and lidars to map its territory in extreme detail. That information helps the car verify its sensor readings, and it is key for any vehicle to know its own location.

Self-driving car companies are notorious for over­hyping their progress. Should we believe them? At this point, the outlook for them is clouded.

In March 2018, a self-driving Uber Volvo XC90 operating in autonomous mode struck and killed a woman in Tempe, Arizona. Since the crash, Arizona has suspended autonomous vehicle testing in the state, and Uber is not renewing its permit to test self-driving cars in California. The company has also stopped testing autonomous cars in Pittsburgh and Toronto and it’s unclear when it will be revived. Even before the accident, Uber’s self-driving cars were having trouble driving through construction zones and next to tall vehicles like big truck rigs. Uber’s drivers had to intervene far more frequently than drivers in other autonomous car projects.

The Uber accident raised questions about whether autonomous vehicles were even ready to be tested on public roads and how regulators should deal with this. Autonomous vehicle technology’s defenders pointed out that nearly 40,000 people die on U.S. roads every year, and human error causes more than 90 percent of crashes. But no matter how quickly self-driving proliferates, it will be a very long time before the robots can put a serious dent in those numbers and convince everyday folks that they’re better off letting the cars do the driving.

While proponents of self-driving cars like Tesla’s Elon Musk envision a self-driving world where al­most all traffic accidents would be eliminated, and the elderly and disabled could travel freely, most Americans think otherwise. A Pew Research Center survey found that most people did not want to ride in self-driving cars and were unsure if they would make roads more dangerous or safer. Eighty-seven percent wanted a person always behind the wheel, ready to take over if something went wrong.

There’s still plenty that needs to be improved before self-driving vehicles could safely take to the road. Autonomous vehicles are not yet able to op­erate safely in all weather conditions. Heavy rain or snow can confuse current car radar and lidar systems—autonomous vehicles can’t operate on their own in such weather conditions. These vehicles also have trouble when tree branches hang too low or bridges and roads have faint lane markings. On some roads, self-driving vehicles will have to make guid­ance decisions without the benefit of white lines or clear demarcations at the edge of the road, including Botts’ Dots (small plastic markers that define lanes). Botts’ Dots are not believed to be effective lane­marking for autonomous vehicles.

Computer vision systems are able to reliably rec­ognize objects. What remains challenging is “scene understanding’—for example, the ability to determine whether a bag on the road is empty or is hiding bricks or heavy objects inside. Although autonomous vehicle vision systems are now capable of picking out traffic lights reliably, they are not always able to make correct decisions if traffic lights are not working. This requires experience, intuition, and knowing how to cooperate among multiple vehicles. Autonomous vehicles must also be able to recognize a person moving alongside a road, determine whether that person is riding a bicycle, and how that person is likely to respond and behave.

All of that is still difficult for an autonomous vehicle to do right now. Chaotic environments such as congested streets teeming with cars, pedestrians, and cyclists are especially difficult for self-driving cars to navigate.

Driving a car to merge into rapidly flowing lanes of traffic is an intricate task that often requires eye contact with oncoming drivers. How can autono­mous vehicles communicate with humans and other machines to let them know what they want to do? Researchers are investigating whether electronic signs and car-to-car communication systems would solve this problem. There’s also what’s called the “trolley problem”: In a situation where a crash is unavoidable, how does a robot car decide whom or what to hit? Should it hit the car coming up on its left or a tree on the side of the road?

A less advanced version of autonomous vehicle technology is already on the market. Cadillac Super Cruise, Nissan ProPilot Assist, and Tesla Autopilot are capable of keeping a car in its lane and a safe dis­tance from other cars, allowing the “driver’ behind the wheel to take hands off the wheel, provided that person keeps paying attention and is ready to take control if needed. These less-advanced systems can’t see things like stopped fire trucks or traffic lights.

But humans haven’t made good driving backups be­cause their attention tends to wander. At least two Tesla drivers in the U.S. have died using the system. (One hit a truck in 2016, another hit a highway barrier in 2018.) There is what is called a “handoff problem.” A semi-autonomous car needs to be able to determine what its human “driver” is doing and how to get that person to take the wheel when needed.

And let’s not forget security. A self-driving car is es­sentially a collection of networked computers and sen­sors linked wirelessly to the outside world, and it is no more secure than other networked systems. Keeping systems safe from intruders who want to crash or wea- ponize cars may prove to be the greatest challenge con­fronting autonomous vehicles in the future.

Self-driving cars require new ecosystems to sup­port them, much as today’s cars are dependent on garages, gasoline stations, and highway systems.

New roads, highways, and automotive supply chains will have to be rebuilt for self-driving cars. The big auto makers that build millions of cars a year rely on complex, precise interaction among hundreds of companies, including automotive component suppli­ers and the services to keep cars running. They need dealers to sell the cars, gas pumps or charging sta­tions to fuel them, body shops to fix them, and park­ing lots to store them. Manufacturers of autonomous vehicles need to rethink interactions and processes built up over a century. The highway infrastructure will need to change over time to support autonomous vehicles. Waymo has partnered with Avis to take care of its fleet of driverless minivans in Arizona, and it’s working with a startup called Trov to insure their pas­sengers. GM is retooling one of its plants to produce Chevrolet Bolts without steering wheels or pedals.

A computer-driven car that can handle any situ­ation as well as a human under all conditions is decades away at best. Many analysts expect the first deployment of self-driving technology will be robot taxi services operating in limited conditions and areas, so their operators can avoid particularly tricky intersections and make sure everything is mapped in fine detail. The Boston Consulting Group predicts that 25 percent of all miles driven in the U.S. by 2030 may be by shared self-driving vehicles. To take a ride, you’d probably have to use predetermined pickup and drop-off points, so your car can always pull over safely and legally. The makers of self-driving cars will be figuring out how much to charge so they can recoup their research and development costs, but not so much as to dissuade potential riders. They’ll strug­gle with regulators and insurance companies over what to do in the inevitable event of a crash.

Some pundits predict that in the next few decades, driverless technology will add $7 trillion to the global economy and save hundreds of thousands of lives.

At the same time, it could devastate the auto indus­try along with gas stations, taxi drivers, and truck­ers. People might stop buying cars because services like Uber using self-driving cars would be cheaper. This could cause mass unemployment of taxi drivers and large reductions in auto sales. It would also cut down the need for many parking garages and parking spaces, freeing up valuable real estate for other pur­poses. More people might decide to live further from their workplaces because autonomous vehicles linked to traffic systems would make traffic flow more smoothly and free riders to work, nap, or watch video while commuting. Some people will prosper. Most will probably benefit, but many will be left behind. Driverless technology is estimated to change one in every nine U.S. jobs, although it will also create new jobs. Another consideration is that the tremendous investment in autonomous vehicles, estimated to be around $32 billion annually, might be better spent on improving public transportation systems like trains and subways. Does America need more cars in sprawling urban areas where highways are already jammed?

The accidents self-driving cars have experienced so far point to the need to create a dependable stan­dard for measuring reliability and safety. In 2018, twenty-nine states have enacted legislation regulat­ing autonomous vehicles, with a few states requiring a safety driver always be in the car ready to take con­trol. U.S. federal regulators have delayed formulat­ing an overarching set of self-driving car standards, leaving a gap for the states to fill. The federal gov­ernment is only now poised to create its first law for autonomous vehicles. This law is similar to Arizona’s and would allow hundreds of thousands of driverless cars to be deployed within a few years and would re­strict states from putting up hurdles for the industry.

Source: Laudon Kenneth C., Laudon Jane Price (2020), Management Information Systems: Managing the Digital Firm, Pearson; 16th edition.

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