The first Tesla I ever saw was stripped down to the chassis, a bare-metal incarnation of the company’s flagship electric Roadster on display at an event in Silicon Valley. Without the need for an internal combustion engine, the two-seater’s petite frame was dominated by a huge battery. My first thought: “This looks like a giant cell phone on wheels.”
As it turns out, I was more right than I realized.
This week, years after that first sighting, Tesla announced plans for what it calls the “Gigafactory,” a 10-million-square-foot plant for making car batteries. The company hopes that the sheer scale of the operation, combined with the inventiveness of its engineers, will bring battery prices down far enough to finally bring its electric cars into the mainstream.
But it’s not just the prospect of a gasoline-free future that has sparked such excitement about the Gigafactory. The same basic lithium-ion tech that fuels Tesla’s cars also runs most of today’s other mobile gadgets, large and small. If Tesla really produces batteries at the scale it’s promising, cars could become just one part of what the company does. One day, Tesla could be a company that powers just about everything, from the phone in your pocket to the electrical grid itself.
Earlier this month, as rumors swirled that Apple might want to buy Tesla, San Francisco Chronicle reported that Tesla CEO Elon Musk had indeed met with the iPhone maker. Musk later confirmed that Tesla and Apple had talked, but he wouldn’t say what about.
Now that Tesla has announced the Gigafactory, Gartner auto industry analyst Thilo Koslowski thinks it would make more sense for Tesla to talk with Apple about something other than an acquisition. “Depending on the capacity of the factory and who the other investors will be, Tesla could start selling its batteries for other products besides cars,” Koslowski tells WIRED. “This could actually mean Tesla might build batteries for Apple.”
Better Batteries for Less Money
To begin erecting its factory, Tesla said it would seek $1.6 billion in debt financing — money that Apple itself could easily supply from its massive cash reserves. In fact, the world’s biggest company could easily put up the money for the entire Gigafactory, which Tesla estimates will ultimately cost between $4 billion and $5 billion. Though industry analysts say the global manufacturing capacity for consumer electronics batteries is already considerable, the economies of scale that Tesla is promising could give Apple access to a whole different level of efficiency, sophistication, and control.
Unlike many parts of the consumer electronics industry, battery-making factories are, in general, highly automated, which means that labor doesn’t factor significantly into production costs. As anyone who has seen Tesla’s car-making robots in action can attest, factory automation is something the company does really, really well. Deep involvement in the project from the start — say, as an investor — could give Apple exactly the kind of intimate involvement with a key supplier that it relishes. This sort of control defines its approach to products. For consumers, that could mean Apple getting better batteries for its devices for less money, just like Tesla wants to do for its cars.
Even if the Gigafactory never makes a battery for a single iPhone, however, its impact on the future of energy storage could be huge. The company says that, once fully operational, the plant will more than double the volume of lithium ion batteries produced in the world today. Sam Jaffe, a battery industry analyst with Navigant Research, says the price drops predicted by Tesla are in line with his firm’s forecasts, and that the cheaper batteries will bring Tesla closer to achieving its primary mission of making a widely affordable electric car, what Tesla is calling its “Gen III” mass market vehicle, or Model E. “The whole point of that model and the whole point of the company was to make that car,” Jaffe says. “It wasn’t to make sports cars or luxury cars. It was to make a family car comparable in price to a gasoline model.”
To reach that mass market, Tesla hopes to be cranking out batteries for 500,000 cars per year by 2020, supported by the Gigafactory. That’s compared to the 35,000 Model S sedans Tesla expects to make this year. Reaching that goal would mean not only a lot more electric cars on the road but a lot more batteries that would need to be replaced. The batteries that power Teslas are a lot like smartphone batteries: Eventually, they start losing their strength. Unlike smartphone batteries, getting down to 60 or 70 percent of their full capacity isn’t just inconvenient. It could leave drivers stranded. Tesla says it plans to fully integrate battery recycling into the Gigafactory’s operations, which could add to the cost savings.
Powering the Grid
But Koslowski says those old batteries could also become part of a robust secondary market. They could, for instance, store energy generated by home solar grids, which can make use of less-than-full strength cells because they don’t have to go anywhere. Already Tesla is supplying battery packs to SolarCity, the solar installer of which Musk serves as chairman, and the company believes that one day its batteries could even serve as backup energy sources for utilities themselves. Bullish Wall Street analysts even predict that, in addition to buttressing the renewable energy grid, Tesla could combine its expertise in cars, batteries, and digital technology to become a leading maker of self-driving vehicles.
Any of this coming to pass, of course, depends on whether the Gigafactory will actually accomplish what Tesla says it will. To bring prices down, battery industry consultant K.M. Abraham says, Tesla will have to figure out how to make its batteries without pushing up costs for component suppliers who would have to increase their output to meet the car maker’s demands. “Unless you come out with new low-cost materials, the battery prices will remain pretty much the same,” says Abraham, who is also a professor of renewable technology at Northeastern University.
Though details from Tesla are scant, a diagram released by the company suggests it does plan to bring as much of the battery making process as possible within the Gigafactory’s walls. Tesla is also pledging to power much of the plant with its own wind and solar energy, a potential testing ground for using its batteries as part of the electrical grid. Diversifying into different uses could be especially crucial if demand for Tesla’s cars doesn’t hit the company’s own projections. Building a factory on such a massive scale is a huge risk if it only makes one thing, but that risk diminishes if Tesla has the ability to use its expertise to make batteries for many uses. If nothing else, Tesla is creating an unprecedented space just to see what’s possible when energy becomes mobile.
“It’s breathtaking, just the sheer size of it,” Jaffe says of the Gigafactory. “This is so beyond anything by comparison.”
Offizielle Ankündigung nächste Woche bei Elektronik-Messe CES in Las Vegas
Google und Audi planen laut einem Zeitungsbericht eine groß angelegte Kooperation. Dabei gehe es darum, dass Unterhaltungs- und Informationssysteme in Audi-Fahrzeugen künftig mit dem Google-Betriebssystem Android laufen, berichtete das „Wall Street Journal“ unter Berufung auf informierte Personen. Der Plan solle kommende Woche auf der Elektronik-Messe CES in Las Vegas vorgestellt werden.
Größeres Projekt
Das Vorhaben sei Teil eines größeren Projekts, das Android im Auto etablieren wolle, hieß es. Weiterer Teilnehmer dieser Allianz sei der Chip-Spezialist Nvidia. Android dominiert im Smartphone-Markt mit einem Marktanteil von zuletzt rund 80 Prozent.
Auch Apple im Auto
Auch Apple arbeitet daran, seine iPhones besser im Auto einzubinden. Seit vergangenem Jahr handelte der Google-Rivale Vereinbarungen für eine vertiefte Integration seiner Geräte und Dienste unter anderem mit General Motors, Daimler und BMW aus.
Carmakers are developing vehicles that have an increasing ability to autonomously drive themselves, potentially reducing accidents and traffic congestion.
A silver BMW 5 Series is weaving through traffic at roughly 120 kilometers per hour (75 mph) on a freeway that cuts northeast through Bavaria between Munich and Ingolstadt. I’m in the driver’s seat, watching cars and trucks pass by, but I haven’t touched the steering wheel, the brake, or the gas pedal for at least 10 minutes. The BMW approaches a truck that is moving slowly. To maintain our speed, the car activates its turn signal and begins steering to the left, toward the passing lane. Just as it does, another car swerves into the passing lane from several cars behind. The BMW quickly switches off its signal and pulls back to the center of the lane, waiting for the speeding car to pass before trying again.Putting your life in the hands of a robot chauffeur offers an unnerving glimpse into how driving is about to be upended. The automobile, which has followed a path of steady but slow technological evolution for the past 130 years, is on course to change dramatically in the next few years, in ways that could have radical economic, environmental, and social impacts.The first autonomous systems, which are able to control steering, braking, and accelerating, are already starting to appear in cars; these systems require drivers to keep an eye on the road and hands on the wheel. But the next generation, such as BMW’s self-driving prototype, could be available in less than a decade and free drivers to work, text, or just relax. Ford, GM, Toyota, Nissan, Volvo, and Audi have all shown off cars that can drive themselves, and they have all declared that within a decade they plan to sell some form of advanced automation—cars able to take over driving on highways or to park themselves in a garage. Google, meanwhile, is investing millions in autonomous driving software, and its driverless cars have become a familiar sight on the highways around Silicon Valley over the last several years.The allure of automation for car companies is huge. In a fiercely competitive market, in which the makers of luxury cars race to indulge customers with the latest technology, it would be commercial suicide not to invest heavily in an automated future. “It’s the most impressive experience we can offer,” Werner Huber, the man in charge of BMW’s autonomous driving project, told me at the company’s headquarters in Munich. He said the company aims to be “one of the first in the world” to introduce highway autonomy.
Thanks to autonomous driving, the road ahead seems likely to have fewer traffic accidents and less congestion and pollution. Data published last year by the Insurance Institute for Highway Safety, a U.S. nonprofit funded by the auto industry, suggests that partly autonomous features are already helping to reduce crashes. Its figures, collected from U.S. auto insurers, show that cars with forward collision warning systems, which either warn the driver about an impending crash or apply the brakes automatically, are involved in far fewer crashes than cars without them.
More comprehensive autonomy could reduce traffic accidents further still. The National Highway Traffic Safety Administration estimates that more than 90 percent of road crashes involve human error, a figure that has led some experts to predict that autonomous driving will reduce the number of accidents on the road by a similar percentage. Assuming the technology becomes ubiquitous and does have such an effect, the benefits to society will be huge. Almost 33,000 people die on the roads in the United States each year, at a cost of $300 billion, according to the American Automobile Association. The World Health Organization estimates that worldwide over 1.2 million people die on roads every year.
Meanwhile, demonstrations conducted at the University of California, Riverside, in 1997 and experiments involving modified road vehicles conducted by Volvo and others in 2011 suggest that having vehicles travel in high-speed automated “platoons,” thereby reducing aerodynamic drag, could lower fuel consumption by 20 percent. And an engineering study published last year concluded that automation could theoretically allow nearly four times as many cars to travel on a given stretch of highway. That could save some of the 5.5 billion hours and 2.9 billion gallons of fuel that the Texas Transportation Institute says are wasted by traffic congestion each year.
If all else fails, there is a big red button on the dashboard that cuts power to all the car’s computers. I practiced hitting it a few times.
But such projections tend to overlook just how challenging it will be to make a driverless car. If autonomous driving is to change transportation dramatically, it needs to be both widespread and flawless. Turning such a complex technology into a commercial product is unlikely to be simple. It could take decades for the technology to come down in cost, and it might take even longer for it to work safely enough that we trust fully automated vehicles to drive us around.
German engineering Much of the hype about autonomous driving has, unsurprisingly, focused on Google’s self-driving project. The cars are impressive, and the company has no doubt insinuated the possibility of driverless vehicles into the imaginations of many. But for all its expertise in developing search technology and software, Google has zero experience building cars. To understand how autonomous driving is more likely to emerge, it is more instructive to see what some of the world’s most advanced automakers are working on. And few places in the world can rival the automotive expertise of Germany, where BMW, Audi, Mercedes-Benz, and Volkswagen are all busy trying to change autonomous driving from a research effort into a viable option on their newest models.
Shortly after arriving in Munich, I found myself at a test track north of the city getting safety instruction from Michael Aeberhard, a BMW research engineer. As I drove a prototype BMW 5 Series along an empty stretch of track, Aeberhard told me to take my hands off the wheel and then issued commands that made the car go berserk and steer wildly off course. Each time, I had to grab the wheel as quickly as I could to override the behavior. The system is designed to defer to a human driver, giving up control whenever he or she moves the wheel or presses a pedal. And if all else fails, there is a big red button on the dashboard that cuts power to all the car’s computers. I practiced hitting it a few times, and discovered how hard it was to control the car without even the power-assisted steering. The idea of the exercise was to prepare me for potential glitches during the actual test drive. “It’s still a prototype,” Aeberhard reminded me several times.
After I signed a disclaimer, we drove to the autobahn outside Munich. A screen fixed to the passenger side of the dashboard showed the world as the car perceives it: three lanes, on which a tiny animated version of the car is surrounded by a bunch of floating blue blocks, each corresponding to a nearby vehicle or to an obstacle like one of the barriers on either side of the road. Aeberhard told me to activate the system in heavy traffic as we rode at about 100 kilometers per hour. When I first flicked the switch, I was dubious about even removing my hands from the wheel, but after watching the car perform numerous passing maneuvers, I found myself relaxing—to my astonishment—until I had to actually remind myself to pay attention to the road.
The car looked normal from the outside. There’s no place on a sleek luxury sedan for the huge rotating laser scanners seen on the prototypes being tested by Google. So BMW and other carmakers have had to find ways to pack smaller, more limited sensors into the body of a car without compromising weight or styling.
Concealed inside the BMW’s front and rear bumpers, two laser scanners and three radar sensors sweep the road before and behind for anything within about 200 meters. Embedded at the top of the windshield and rear window are cameras that track the road markings and detect road signs. Near each side mirror are wide-angle laser scanners, each with almost 180 degrees of vision, that watch the road left and right. Four ultrasonic sensors above the wheels monitor the area close to the car. Finally, a differential Global Positioning System receiver, which combines signals from ground-based stations with those from satellites, knows where the car is, to within a few centimeters of the closest lane marking.
Several computers inside the car’s trunk perform split-second measurements and calculations, processing data pouring in from the sensors. Software assigns a value to each lane of the road based on the car’s speed and the behavior of nearby vehicles. Using a probabilistic technique that helps cancel out inaccuracies in sensor readings, this software decides whether to switch to another lane, to attempt to pass the car ahead, or to get out of the way of a vehicle approaching from behind. Commands are relayed to a separate computer that controls acceleration, braking, and steering. Yet another computer system monitors the behavior of everything involved with autonomous driving for signs of malfunction.
Impressive though BMW’s autonomous highway driving is, it is still years away from market. To see the most advanced autonomy now available, a day later I took the train from Munich to Stuttgart to visit another German automotive giant, Daimler, which owns Mercedes-Benz. At the company’s research and development facility southeast of the city, where experimental new models cruise around covered in black material to hide new designs and features from photographers, I got to ride in probably the most autonomous road car on the market today: the 2014 Mercedes S-Class.
A jovial safety engineer drove me around a test track, showing how the car can lock onto a vehicle in front and follow it along the road at a safe distance. To follow at a constant distance, the car’s computers take over not only braking and accelerating, as with conventional adaptive cruise control, but steering too.
Using a stereo camera, radar, and an infrared camera, the S-Class can also spot objects on the road ahead and take control of the brakes to prevent an accident. The engineer eagerly demonstrated this by accelerating toward a dummy placed in the center of the track. At about 80 kilometers per hour, he took his hands off the wheel and removed his foot from the accelerator. Just when impact seemed all but inevitable, the car performed a near-perfect emergency stop, wrenching us forward in our seats but bringing itself to rest about a foot in front of the dummy, which bore an appropriately terrified expression.
Uncertain road With such technology already on the road and prototypes like BMW’s in the works, it’s tempting to imagine that total automation can’t be far away. In reality, making the leap from the kind of autonomy in the Mercedes-Benz S-Class to the kind in BMW’s prototype will take time, and the dream of total automation could prove surprisingly elusive.
For one thing, many of the sensors and computers found in BMW’s car, and in other prototypes, are too expensive to be deployed widely. And achieving even more complete automation will probably mean using more advanced, more expensive sensors and computers. The spinning laser instrument, or LIDAR, seen on the roof of Google’s cars, for instance, provides the best 3-D image of the surrounding world, accurate down to two centimeters, but sells for around $80,000. Such instruments will also need to be miniaturized and redesigned, adding more cost, since few car designers would slap the existing ones on top of a sleek new model.
Cost will be just one factor, though. While several U.S. states have passed laws permitting autonomous cars to be tested on their roads, the National Highway Traffic Safety Administration has yet to devise regulations for testing and certifying the safety and reliability of autonomous features. Two major international treaties, the Vienna Convention on Road Traffic and the Geneva Convention on Road Traffic, may need to be changed for the cars to be used in Europe and the United States, as both documents state that a driver must be in full control of a vehicle at all times.
Most daunting, however, are the remaining computer science and artificial-intelligence challenges. Automated driving will at first be limited to relatively simple situations, mainly highway driving, because the technology still can’t respond to uncertainties posed by oncoming traffic, rotaries, and pedestrians. And drivers will also almost certainly be expected to assume some sort of supervisory role, requiring them to be ready to retake control as soon as the system gets outside its comfort zone.
Despite the flashy demos, I sometimes detected among carmakers a desire to hit the brakes and temper expectations.
The relationship between human and robot driver could be surprisingly fraught. The problem, as I discovered during my BMW test drive, is that it’s all too easy to lose focus, and difficult to get it back. The difficulty of reëngaging distracted drivers is an issue that Bryan Reimer, a research scientist in MIT’s Age Lab, has well documented (see “Proceed with Caution toward the Self-Driving Car,” May/June 2013). Perhaps the “most inhibiting factors” in the development of driverless cars, he suggests, “will be factors related to the human experience.”
In an effort to address this issue, carmakers are thinking about ways to prevent drivers from becoming too distracted, and ways to bring them back to the driving task as smoothly as possible. This may mean monitoring drivers’ attention and alerting them if they’re becoming too disengaged. “The first generations [of autonomous cars] are going to require a driver to intervene at certain points,” Clifford Nass, codirector of Stanford University’s Center for Automotive Research, told me. “It turns out that may be the most dangerous moment for autonomous vehicles. We may have this terrible irony that when the car is driving autonomously it is much safer, but because of the inability of humans to get back in the loop it may ultimately be less safe.”
An important challenge with a system that drives all by itself, but only some of the time, is that it must be able to predict when it may be about to fail, to give the driver enough time to take over. This ability is limited by the range of a car’s sensors and by the inherent difficulty of predicting the outcome of a complex situation. “Maybe the driver is completely distracted,” Werner Huber said. “He takes five, six, seven seconds to come back to the driving task—that means the car has to know [in advance] when its limitation is reached. The challenge is very big.”
Before traveling to Germany, I visited John Leonard, an MIT professor who works on robot navigation, to find out more about the limits of vehicle automation. Leonard led one of the teams involved in the DARPA Urban Challenge, an event in 2007 that saw autonomous vehicles race across mocked-up city streets, complete with stop-sign intersections and moving traffic. The challenge inspired new research and new interest in autonomous driving, but Leonard is restrained in his enthusiasm for the commercial trajectory that autonomous driving has taken since then. “Some of these fundamental questions, about representing the world and being able to predict what might happen—we might still be decades behind humans with our machine technology,” he told me. “There are major, unsolved, difficult issues here. We have to be careful that we don’t overhype how well it works.”
Leonard suggested that much of the technology that has helped autonomous cars deal with complex urban environments in research projects—some of which is used in Google’s cars today—may never be cheap or compact enough to be employed in commercially available vehicles. This includes not just the LIDAR but also an inertial navigation system, which provides precise positioning information by monitoring the vehicle’s own movement and combining the resulting data with differential GPS and a highly accurate digital map. What’s more, poor weather can significantly degrade the reliability of sensors, Leonard said, and it may not always be feasible to rely heavily on a digital map, as so many prototype systems do. “If the system relies on a very accurate prior map, then it has to be robust to the situation of that map being wrong, and the work of keeping those maps up to date shouldn’t be underestimated,” he said.
Near the end of my ride in BMW’s autonomous prototype, I discovered an example of imperfect autonomy in action. We had made a loop of the airport and were heading back toward the city when a Smart car, which had been darting through traffic a little erratically, suddenly swung in front of me from the right. Confused by its sudden and irregular maneuver, our car kept approaching it rapidly, and with less than a second to spare I lost my nerve and hit the brakes, slowing the car down and taking it out of self-driving mode. A moment later I asked Aeberhard if our car would have braked in time. “It would’ve been close,” he admitted.
Despite the flashy demos and the bold plans for commercialization, I sometimes detected among carmakers a desire to hit the brakes and temper expectations. Ralf Herttwich, who leads research and engineering of driver assistance systems at Mercedes, explained that interpreting a situation becomes exponentially more difficult as the road becomes more complex. “Once you leave the highway and once you go onto the average road, environment perception needs to get better. Your interpretation of traffic situations, because there are so many more of them—they need to get better,” he said. “Just looking at a traffic light and deciding if that traffic light is for you is a very, very complex problem.”
MIT’s Leonard, for one, does not believe total autonomy is imminent. “I do not expect there to be taxis in Manhattan with no drivers in my lifetime,” he said, before quickly adding, “And I don’t want to see taxi drivers out of business. They know where they’re going, and—at least in Europe—they’re courteous and safe, and they get you where you need to be. That’s a very valuable societal role.”
I pondered Leonard’s objections while visiting BMW and Mercedes. I even mentioned some of them to a taxi driver in Munich who was curious about my trip. He seemed far from worried. “We have siebten Sinn—a seventh sense,” he said, referring to the instinctive road awareness a person builds up. As he nipped through the busy traffic with impressive speed, I suspected that this ability to cope deftly with such a complex and messy world could prove useful for a while longer.
Data gathered from Google’s self-driving Prius and Lexus cars shows that they are safer and smoother when steering themselves than when a human takes the wheel, according to the leader of Google’s autonomous-car project.
Chris Urmson made those claims today at a robotics conference in Santa Clara, California. He presented results from two studies of data from the hundreds of thousands of miles Google’s vehicles have logged on public roads in California and Nevada.
One of those analyses showed that when a human was behind the wheel, Google’s cars accelerated and braked significantly more sharply than they did when piloting themselves. Another showed that the cars’ software was much better at maintaining a safe distance from the vehicle ahead than the human drivers were.
“We’re spending less time in near-collision states,” said Urmson. “Our car is driving more smoothly and more safely than our trained professional drivers.”
In addition to painting a rosy picture of his vehicles’ autonomous capabilities, Urmson showed a new dashboard display that his group has developed to help people understand what an autonomous car is doing and when they might want to take over. “Inside the car we’ve gone out of our way to make the human factors work,” he said.
Although that might suggest the company is thinking about how to translate its research project into something used by real motorists, Urmson dodged a question about how that might happen. “We’re thinking about different ways of bringing it to market,” he said. “I can’t tell you any more right now.”
Urmson did say that he is in regular contact with automakers. Many of those companies are independently working on self-driving cars themselves (see “Driverless Cars Are Further Away Than You Think”).
Google has been testing its cars on public roads since 2010 (see “Look, No Hands”), always with a human in the driver’s seat who can take over if necessary.
Urmson dismissed claims that legal and regulatory problems pose a major barrier to cars that are completely autonomous. He pointed out that California, Nevada, and Florida have already adjusted their laws to allow tests of self-driving cars. And existing product liability laws make it clear that a car’s manufacturer would be at fault if the car caused a crash, he said. He also said that when the inevitable accidents do occur, the data autonomous cars collect in order to navigate will provide a powerful and accurate picture of exactly who was responsible.
Urmson showed data from a Google car that was rear-ended in traffic by another driver. Examining the car’s annotated map of its surroundings clearly showed that the Google vehicle smoothly halted before being struck by the other vehicle.
“We don’t have to rely on eyewitnesses that can’t act be trusted as to what happened—we actually have the data,” he said. “The guy around us wasn’t paying enough attention. The data will set you free.”
BMW steigt mit einem Kampfpreis in den Markt für Elektroautos ein und will sein erstes serienmäßiges Elektro- Auto i3 deutlich günstiger anbieten als erwartet. In Deutschland soll der Wagen für 34.950 Euro zu haben sein, in Österreich um 35.700 Euro.
Damit kostet der BMW i3 in etwa so viel wie ein „nackter“ 125d mit Schaltgetriebe.
Zuletzt hatte es geheißen, der i3 werde „deutlich unter 40.000 Euro“ kosten, doch dass es derart deutlich wird, war nicht zu erwarten. Das Auto soll im November auf den deutschen Markt kommen. Die internationale Premiere des BMW i3 wird am 29. Juli 2013 zeitgleich in den Metropolen London, New York und Peking stattfinden.
Service- Paket inkludiert
Das Fahrzeug wird im November 2013 in Österreich eingeführt und hat das BMW Service Inklusive Paket (BSI Paket) für 5 Jahre und 60.000 km inkludiert. Das BSI bündelt die erforderlichen Wartungsarbeiten wie zum Beispiel Service Fahrzeugcheck, Service Bremsflüssigkeit oder Service Mikrofilter.
Die i3- Produktion im Leipziger Werk hat bereits begonnen. Bei der Karosserie setzt BMW komplett auf leichte Materialien wie CFK (kohlefaserverstärkter Kunststoff) und Aluminium, um so das Gewicht der Batterien auszugleichen. Es wurden sogar eigene Verfahren entwickelt, um Karbon kostengünstig in Großserie herzustellen und auch zu reparieren. Vergleichbare Elektroautos in konventioneller Bauweise bringen rund eine halbe Tonne mehr auf die Waage, oft noch mehr, sagt BMW.
Angetrieben wird der BMW i3 von einem 125 kW/170 PS leistenden Elektromotor, der ab der ersten Umdrehung 250 Nm liefert. Die Reichweite gibt der Hersteller mit 130 bis 160 Kilometer an. Für längere Fahrten stellt BMW seinen i- Kunden bei Bedarf ein konventionelles Fahrzeug zur Verfügung. Das Laden an der Haushaltssteckdose dauert acht Stunden, mit einem Schnelllader sind die Akkus nach einer halben Stunde zu 80% voll.
BMW verspricht im Rahmen der Mobilitätsgarantie, leere Akkus unterwegs zumindest teilweise zu füllen, was ab Ankunft des Pannenfahrers 20 Minuten dauern soll. Abgesehen davon: Der i3 ist von Anfang an optional auch mit Range Extender erhältlich, also mit einem 0,6- Liter- Zweizylinder- Benziner, der Strom erzeugt.
The smartphone generation will be perfectly happy not dealing with the expense and hassle of car ownership — why would they when they can order up an autonomous Zipcar with a tap on their iPhone X?
Google Self-Driving Car (photo by Flickr user MarkDoliner, CC Licensed)
Over the past few years, there has been steady progress in the development of self-driving automobiles, and it’s pretty clear that we’re finally on the cusp of this technology going mainstream. As far as I’m concerned, driving is a waste of time, energy, and human life, so I, for one, welcome our autonomous vehicular overlords.
Signs of Change
The assertion that self-driving cars are on the verge of becoming a practical reality may seem a little bold, but the signs are clearly there. For example, California recently legalized autonomous vehicles, making them now legal in three states (Nevada and Florida are the other two). In fact, in relation to this, Bernard Lu, an attorney for the California Department of Motor Vehicles even went so far as to state that “The technology is ahead of the law in many areas” — and that was back in 2010.
Simply put, the technology required to make self-driving cars a reality already exists right now. It’s currently expensive, but the cost will drop as economies of scale kick in.
The Tech Behind It
So what is the tech that makes autonomous vehicles possible? Well, the poster child for self-driving cars is definitely Google’s ongoing Driverless Car project. At last tally, the Google fleet has driven accident-free for over 300,000 miles (480,000 km), making it clear that the concept is completely viable. Each Google Driverless car is equipped with GPS, radar, video cameras, lidar (laser radar), and a lot of real-time computing power. Basic navigation relies on maps and GPS, with live sensor input to react to real-time changes. The entire setup costs about $150,000, which is obviously well beyond the reach of 99% of drivers, but, as mentioned above, this cost will scale down readily.
Another emerging technology that figures prominently in the future of autonomous vehicles is the concept of vehicular communication systems. Obviously vehicle-to-vehicle (V2V) communication and vehicle-to-infrastructure (V2I) communication will make it possible to dynamically route traffic in such a way as to maximize flow and minimize travel times. Say good-bye to traffic jams and road rage, kids.
Why it Will Be Great
In addition to no more traffic jams, self-driving cars promise many other benefits:
Fewer traffic collisions (computers are better than humans at focused, repetitive tasks such as driving)
Increased roadway capacity and reduced traffic congestion (V2V and V2I make dynamic traffic routing possible)
Relief of vehicle occupants from driving chores (you can sleep, watch a movie, read a book, knit a pair of socks, etc. instead of wasting time behind the wheel)
Everyone can enjoy the benefits of travel regardless of their physical abilities, age, or other current restrictions (and, yes, that means no more drunk drivers and innocent victims)
You’ll never need to worry about finding a parking spot close to your destination (the car will drop you off, then go park itself until you signal it back again)
Improved energy efficiency due to minimization of start/stop driving, and elimination of the weight of the unnecessary driver in some circumstances
Car-sharing services like Zipcar will be much more practical
Reduced need for traffic police, red light cameras, and other safety enforcement measures
Cargo transport and delivery vehicles will not need a driver at all
All of the above and more will make the society of the future a very different place than what we’re used to now. That kind of change is likely going to take some adjustment for us older folks, but what about the upcoming generations that will grow up with this? Well, we’re already seeing some signs of a change in attitude there.
The Millennials
Interestingly, the Millennials (people born between 1980 and 2000, approximately) have very different attitudes toward driving than us older folks. In particular, the Millennials are far less interested in drivingthan their parents and grand-parents. There are, of course, plenty of reasons for this attitude, including rising gas costs, an anemic economy, depressed wages, and increasing re-urbanization – none of which is likely to change much in the near future. All of these factors lead to a demographic that is open to the reinvention of vehicular transportation. As Sheryl Connelly, head of global consumer trends at Ford, said, “Young people value access over ownership.”
The smartphone generation will be perfectly happy not dealing with the expense and hassle of car ownership — why would they when they can order up an autonomous Zipcar with a tap on their iPhone X?
Another guaranteed problem is concern about safety. As mentioned before, autonomous vehicles will be far more reliable than human drivers; however, there will inevitably be an accident involving a self-driving car, and the event will be sensationalized by the media. In the end though, the desire to decrease the number of traffic-related fatalities in the world will drive adoption (just for reference, over 30,000 people die each year in vehicle-related deaths in the US alone).
From the GeekDad perspective, the most worrisome thing about autonomous vehicles that I can think of is the possibility of vulnerabilities in the software. We have serious issues with exploits in current operating systems and applications — how much riskier will it be when the compromised computer is rolling along at 60mph? Clearly these systems are going to require a level of security that will embarrass today’s military-grade gear.
Future Consequences
So what are the implications of large-scale adoption of self-driving vehicles? An obvious thought is the corresponding redesign of the road system. Just as we now have commuter lanes, there will undoubtedly be dedicated lanes for driverless vehicles. In fact, eventually the majority of lanes will be reserved for autonomous vehicles, with a few “slow” lanes left over for manually-operated cars and horse-drawn buggies. And if we look even further ahead, eventually it will be illegal to drive a car on public roads.
Another anticipated change relates to the fact that driverless cars need not even be “cars.” Vehicles of the future won’t necessarily just transport humans, so there will likely be a wide spectrum of designs, from large cargo transports to small pizza delivery mini-mobiles. Of course, the technology behind self-driving cars will transfer easily to trains, streetcars, subways, ships, and possibly even aircraft (though that last one makes me a little nervous).
As with any other labor-saving advance in technology, an inevitable consequence of autonomous vehicles will be the elimination of a lot of jobs. Yes, there will be new jobs created to build and service these vehicles, but I’m pretty sure that far more jobs will be eliminated than created. In theory, this should mean that the overall efficiency of the system is increased, and humans will have increased time available to do more valuable work; in practice though, the transition involves a lot of disruption.
Conclusion…
The signs are clear: autonomous vehicles are coming. The technology is already real, and it’s just a matter of scaling down the cost. Once that happens, there will be rapid adoption of driverless automobiles that will result in a complete redefinition of travel. Yes, there are some negatives to this impending transition, but overall, the shift to self-driving vehicles will be a net-positive for society.
Clifford Nass talks about why the automobile is so central to modern life. He discusses the future of autonomous vehicles and describes the human element of auto-mobility.
There is the Google Car Approach and there is the Car Manufacturers Approach.
Originally presented in the Stanford Continuing Studies Program.
Audi präsentierte auf der CES International 2013 die weltweit erste Lizenz für den Betrieb von Computergesteuerten Fahrzeugen.
Die Kooperation zwischen der US-Universität Stanford und Audi mündete bereits vor einigen Monaten in einem Rennwagen, der selbstständig eine vorgegebene Route befährt und darin sicherer als ein menschlicher Rennfahrer rascher auf Bodengegebenheiten und Verkehrssituationen reagieren kann.
Nevada grants Audi the first automaker permit to operate autonomous vehicles on public roads
• Audi gets second-ever license from the state to test Audi piloted driving
• Audi piloted driving and parking technology will be a focus at 2013 CES
• Audi has been an autonomous driving pioneer through work by its Electronics Research Lab in Silicon Valley and Stanford University
Was geschieht mit dem Individualverkehr, wenn Fahrzeuge uns autonom überall hintransportieren, wohin wir wollen?
Die Antwort darauf, beantwortet ein Zitat aus der Kommentarsektion von Spiegel Online:
„Ich lese mit großer Begeisterung diesen Beitrag. Es ist ja schon verschiedentlich über die Versuche, den Staßenverkehr zu automatisieren, berichtet worden, was mich dazu veranlasst hat, ein wenig weiterzudenken.
Was geschieht denn, wenn Autos sich selbsttätig bewegen können? Gibt es dann noch einen Grund, ein eigenes Fahrzeug zu besitzen?
Der Individualverkehr ist ein System, das so vielfach redundant Kapazitäten bereithält, dass dem Systemtheoretiker der Irrsinn dieses Zustandes beispielhaft ist.
Die Abschaffung dieses Systems [Anm. des Individualverkehrs] zugunsten eines Fahrzeugparkes, der von geeigneten Unternehmen vorrätig gehalten wird und auf die jeder gegen Vergütung zugreifen kann (Führerschein? worzu!) birgt wirtschaftliche Vorteile einer solchen Dimension, dass der Privat- PKW verschwinden wird.
Die städtebaulichen Folgen werden ebenso enorm sein.
Das ist eine der aufregendsten Zukunftsvisionen, die ich kenne.“
Weiters – Funktionsweise des Radars:
„Wissen Sie, wie die modernen Radar-Säulen arbeiten? Ein solch modernes Auto hätte natürlich (Radar-)Sensoren. Mit diesen Sensoren könnte es gleichzeitig den Vordermann, alle Autos um das Fahrzeug herum und auch eventuelle Fußgänger und sonstige Objekte um das Fahrzeug einzeln(!!!) beobachten. Das schaffen wir Menschen nicht annähernd. Sobald ein Objekt sich dem zu erwartenden Fahrweg des Fahrzeugs gefährlich nähert, leitet der Computer (Ausweich-)Maßnahmen ein. Der Computer weiß allerdings dann bereits, dass links neben uns ein weiteres Fahrzeug fährt, während der menschliche Autofahrer das erst beim instinktiven Ausweichen feststellt. Außerdem könnte dieses Fahrzeug dann alle nachfahrenden Fahrzeuge über die bevorstehende Notbremsung warnen und so Auffahrunfälle beinahe gänzlich ausschließen.
Automatisches Fahren auf der Autobahn wäre für mich ein Traum. Es würden Tonnen an Kraftstoff und Nerven gespart. Wie oft erlebe ich, dass ich ein Fahrzeug überhole, anschließend von diesem Fahrzeug wiederrum überholt werde um es dann einige Zeit später wieder zu überholen.
Ich fahre jedoch mit Tempomat immer gleichschnell (sofern es der Verkehr erlaubt) und möglichst weit rechts! Dass dann alle gleich langsam fahren müssen, halte ich nicht für notwendig.
Bei wenig Verkehr sollte man seine Wunschgeschwindigkeit wählen können und bei viel Verkehr werden 2 oder 3 Geschwindigkeiten vorgegeben und dann vom Fahrzeug im Verkehrsfluss selbständig gehalten.“
Wifi Direct ist bei jedem Smartphone mit an Bord. Der nachfolgende Artikel erklärt, wie Smartphones in Zukunft intelligent mit Fahrzeugen kommunizieren, um Unfälle zu vermeiden.
„There are plenty of airbags and restraints to keep occupants of most modern cars safe from injury during an accident, and more automakers are deploying driver assistance technology to keep collisions from occurring in the first place – even with pedestrians and others outside the vehicle. Volvo’s pedestrian detection system keeps walkers from inadvertently becoming hood ornaments, and the Swedish brand that’s synonymous with safety has even unveiled a pedestrian airbag.
By developing a system that alerts drivers to the presence of pedestrians, cyclists, road construction workers and others who have a high chance of coming in contact with a moving vehicle, General Motors hopes to reduce the 4,280 pedestrians and 618 bicyclists deaths caused by collisions with motor vehicles in 2010, according to National Highway Traffic Safety Administration. GM researchers are working on technology that will use the Wi-Fi Direct peer-to-peer wireless connection standard to allow smartphones and other connected devices to communicate with cars. Wi-Fi Direct would be integrated with existing driver-assistance systems that use sensor-based object detection to identify pedestrians and others carrying smartphones equipped with a Wi-Fi Direct app that the automaker is also developing.
According to the Wi-Fi Alliance, Wi-Fi Direct has an effective range of just over 200 yards, or roughly more than two football fields. And unlike the type of Wi-Fi you sponge off of at Starbucks, where each user connects to a central access point, Wi-Fi Direct is an ad-hoc network that allows device-to-device connection. “Seven to eight seconds is the amount of time it takes to connect to a Wi-Fi access point,” Donald Grimm, GM’s Global R&D senior researcher of perception and vehicle control systems, told Wired. And even more time if it has to authenticate the user by providing credentials. But with Wi-Fi Direct that time is reduced to one second, according to Grimm, for critical hit-or-miss applications like the one that GM is working on. GM also claims that Wi-Fi Direct has less latency than even cellular networks in order to quickly communicate between two parties on a collision course.
Cars would, of course, first need to be Wi-Fi connected, but that could happen very quickly, according toa report released this week by Strategy Analytics. “Wi-Fi is disrupting the automotive connectivity landscape,” writes the report’s author, Roger Lanctot. “Wi-Fi adoption in cars is rapidly enhancing automotive device connectivity options and applications. The speed, range and volume of data that can be transmitted via Wi-Fi will enable everything from higher quality content distribution in the car and enhanced vehicle diagnostics to inter-vehicle communication.” Lanctot told Wired that he predicts that applications of the latest Wi-Fi and Bluetooth chipsets on smartphones such as Samsung’s Galaxy line-up will prompt automakers to accelerate their in-car Wi-Fi plans, and adds that tier-on suppliers are gearing up to integrate Wi-Fi into automotive systems.
GM is also getting help in setting up a connected-car network from the federal government and by collaborating with its competitors in a pilot program that kicks off next month in Ann Arbor, Michigan to test vehicle-to-vehicle (V2V) and vehicle-to-infrastructure (V2I) communication. “The purpose of the pilot is to gather data on the potential benefits of V2V and V2I technology,” says Grimm. “From that data NHTSA will determine whether to mandate the technology or provide some incentives for car makers to deploy it.”
As for the timing of when pedestrians and others could rely on their smartphones to keep from getting mowed down by careless motorists, Grimm says, “We’re probably looking at five years out, or by the end of the decade. We see that we can extend these applications to include pedestrians, bicyclists and other roadside users.”
The automotive adoption of Wi-Fi Direct could also have side benefits. GM points out that the technology could be used to transfer digital music files or address book information between a home network and a vehicle’s infotainment or navigation system equipped with Wi-Fi Direct. And it could possibly replace Bluetooth as the primary means of device connection in the car – and the compatibility problemsassociated with it. “Wi-Fi Direct uses of the same data transport mechanism as Bluetooth,” GM’s Grimm adds. “And the way you connect to and discover devices is similar to Bluetooth.” Except with Wi-Fi it works more often than not.“
TheIdea – The Innovation Agency 