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2016 Technology of the Year Finalist: Audi Virtual Cockpit

The heart of most infotainment systems is a touchscreen in the center console. In many systems, some information can be sent to the gauge cluster in slightly redacted form – stripped-down navigation commands, basic audio info, that sort of thing. To get the full story, the driver has to take their eyes off the road and look to the middle of the dashboard. Audi's Virtual Cockpit, in essence, ditches the center screen and places all that information in the gauge cluster. The high-resolution TFT screen is just over a foot wide, and it has two main modes: Classic view, and Infotainment view. Classic looks like many other traditional TFT gauge clusters, with large traditional gauges and the ability to display a decent amount of information in the space in-between. Go into Infotainment view, and the gauges shrink and head to the lower corners, freeing up a much larger amount of real estate for, say, the nav system map. The gauges also get out of the way when utilizing the menu, entering a destination, or that sort of thing. The four main modes are standard stuff. Virtual Cockpit will show you navigation, media, phone, and trip computer information in large or small formats. You interact with Virtual Cockpit with a familiar MMI wheel-type controller in the center console, like in many other Audis, or with buttons and a scroll/push wheel on the left side of the steering wheel. Climate control functions are handed by physical controls cleverly integrated in the center three vents. It takes a lot of processing power to make all this work as well as it does, and that's handled by NVIDIA's Tegra 3 processor – a quad-core processor usually seen in tablets and smartphones. The system is quick and responsive, and we found the high-resolution screen to be impressively sharp. If there's a downside, it's that Virtual Cockpit doesn't leave an opportunity for a passenger to step in and, say, enter a destination or change the radio station without altering what's right in front of the driver. It could be inconvenient at best, distracting at worst, to have the nav system directions you're trying to follow suddenly be superseded by the audio menu. Adding a small secondary screen for the passenger could be one fix; a connected companion smartphone app another. In the meantime, it's an impressive implementation of a clever idea.

Audi Q2 is coming soon to a city center near you

For a company that exploded into modern consciousness through its Quattro all-wheel-drive technology, delivering a crossover with just two-wheel drive could be a big leap for Audi. While some models offer all-wheel drive, Audi will deliver the entry-level versions of its all-new segment-stealing Q2 baby crossover SUV with just front-wheel drive. All Q2 models will run as front-wheel-drive cars most of the time anyway, with the all-wheel drive doled out by an electronically controlled, multi-plate differential. Fitted as standard only to the range-topping 2.0-liter petrol and diesel models, and optional on the 1.4-liter petrol and less-powerful 2.0-liter diesel models, the system only moves torque to the rear axle when the front end has run out of grip. Looking past which wheels are driven, there are more reasons to be positive than negative about the Q2. First, where the Prologue concept was the first car from new(ish) design boss Marc Lichte to wear an Audi badge, the Q2 will be his first production model. No more sausages cut to different lengths, he insists, and you can tell he means it when you look at the huge, chamfered cut they've taken out of the top of the doors at the tornado line. Designed and conceived for a younger, more urban audience than any Audi before it, the Q2 will also deliver buyers a full Mini-style level of individualization for its five-seat cabin. View 47 Photos Audi will launch the car with six different engines and the teasing promise of plug-in hybrid power "one day" in its life cycle. At 13.7 feet long, the Q2 is 7.67 inches shorter than the Q3 and far lighter, too. At just 2,657 pounds, it's light enough that Audi felt comfortable giving it a 114-horsepower, 1.0-liter, three-cylinder engine as its entry powerplant. From there, Q2 buyers can step up to a 1.4-liter, turbocharged four-cylinder engine with direct injection, variable valve timing and lift, and cylinder-on-demand technology, with 148 hp. The top petrol-powered variant will have the 2.0-liter, four-cylinder turbo motor, with both direct and indirect fuel injection and 190 hp. A 114-hp version of the 1.6-liter, four-cylinder turbodiesel provides the step-in point to the diesel range (in Europe, anyway), followed by a 148- and 190-hp versions of the 2.0-liter turbodiesel.

Watch Stanford's self-driving Audi hit the track

Sending a self-driving race car around a track with nobody inside seems pointless – there's no driver to enjoy the ride, and the car certainly isn't getting a thrill out of it. But the students performing research with Stanford University's Audi TTS test rig "Shelley" (not to be confused with Audi's own self-driving race cars) are getting a kick out of the numbers generated by the machine. "A race car driver can use all of a car's functionality to drive fast," says Stanford Professor Chris Gerdes. "We want to access that same functionality to make driving safer." The teams push the car to speeds over 120mph and the computers have executed lap times nearly as fast as professional drivers. However, they also spend a lot of time maneuvering at 50 to 75 mph, the speeds where accidents are most likely to happen. That way, the students can figure out how to incorporate braking, throttle and maneuvering to develop new types of automatic collision avoidance algorithms. Better technology, for instance, could have saved Google from a recent slow-speed accident where its vehicle was struck by a bus. During race days, students break into teams to perform different types of research. "Once you get to the track, things can go differently than you expect. So it's an excellent lesson of advanced planning," says Gerdes. In the latest rounds of testing, for instance, one PhD student developed emergency lane-change algorithms, while another recorded a skilled human driver in an attempt to convert his behavior into a driving algorithm. The main goal, of course, is to prepare students for something they may not have expected -- an automotive industry that is adopting self-driving technology at breakneck speeds. This article by Steve Dent originally ran on Engadget, the definitive guide to this connected life. Green Audi Technology Coupe Autonomous Vehicles Racing Vehicles Performance Videos racecar research