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Inside Honda's ghost town for testing autonomous cars

On the edge of the San Francisco suburb of Concord, California sits a ghost town. Dilapidated buildings and cracked roads are framed by overgrowth and slightly askew street signs. The decommissioned five acre portion of the Concord Naval Weapons Station that once housed military personnel and their families is now home to squirrels, jack rabbits, wild turkeys and Honda's mysterious testing lab for autonomous vehicles. This former town within a Naval base – now dubbed "GoMentum Station" – is the perfect testing ground for Honda's self-driving cars. An almost turn-key solution to the problem of finding somewhere to experiment with autonomous vehicle inside an urban area. Thanks to the GoMentum Station, the automaker has access to 20 miles of various road types, intersections and infrastructure exactly like those found in the real world. Just, you know, without all the people getting in the way. While the faded lane markers and cracked asphalt might initially make it difficult for the car to figure out what's going on around it, that's exactly what you want when training a self-driving system. Many roads in the real world are also in dire need of upkeep. Just because autonomous vehicles are hitting the streets doesn't mean the funding needed to fix all the potholes and faded lane markers will magically appear. The real world doesn't work that way and the robot cars that will eventually make our commutes less of a headache will need to be aware of that. Plus, it's tougher to train a car to drive downtown than to barrel down the highway at 80 miles per hour. A company is going to want to get as much practice as possible. While semi-autonomous driving on the everyone-going-the-same-way-at-a-constant-speed freeway is already a reality, navigating in an urban environment is far more complex. If you've driven on the streets of Los Angeles, San Francisco, New York, Chicago or Seattle you know that driving downtown takes far more concentration than cruising down the interstate. With all that in mind, Honda's tricked out Acura RLX did a good job during an (admittedly very controlled) hands-free demo. It didn't hit either of the pedestrians walking across its path. It stopped at stop signs and even maneuvered around a mannequin situated in the middle of the road. The reality is, watching a car drive around the block and safely avoid stuff is boring. Not to metion, Google has been doing this for a while in the real world.

Honda, Top Gear working on 130-mph lawn mower

We're not even sure they've got a blade of Kentucky Bluegrass to cut, but the folks at Top Gear have gone ahead and started building what will become, if they're successful, the world's fastest lawn mower. Actually, it appears Top Gear is not doing much of the design and assembly work at all, instead having solicited help from experts at Honda and Team Dynamics, which oversees the automaker's touring car efforts.
What the three are working on is a riding lawnmower with a 110-hp engine that can reach 60 miles per hour in four seconds and trim turf at speeds up to 130 mph. If they succeed, such a maximum velocity would put them well ahead of the current record for the world's fastest lawnmower, which is 96.529 mph set by Bobby Cleveland and his Snapper race mower at the Bonneville Salt Flats in September of 2010. Top Gear hasn't said whether or not it will officially go after Cleveland's record, but the build will be featured in an upcoming issue of the Top Gear magazine and is scheduled to be completed by June 17, so we may learn what this maniacal mower's true purpose is then.
According to TG's report on how the build is going, as well as the video of it being fired up (literally) for the first time below, there aren't many actual mower parts left on this machine. What started out as a Honda HF2620 mower now sports wheels and tires from a racing quad, a back axle from a go-kart, a steering rack from a Morris Minor and a 1000cc engine from a Honda VTR1000F sport bike. All that remains from the original mower are the pedals and body panels; even the steel cutting deck has been replaced with a lighter fiberglass version. And blades? This mower will be bladeless, instead using two electric motors to spin lengths of brake cable like a weed whacker.

8 automakers, 15 utilities collaborate on open smart-charging for EVs

We're going to lead with General Motors here. GM is one of eight automakers working with 15 utilities and the Electric Power Research Institute (EPRI) at developing a "smart" plug-in vehicle charging system. Why did we start with GM? Because it's the first automaker whose press release we read that mentioned the other seven automakers. Points for sharing. For the record, the collaboration also includes BMW, Toyota, Mercedes-Benz, Honda, Chrysler, Mitsubishi and Ford. The utilities include DTE Energy, Duke Energy, Southern California Edison and Pacific Gas & Electric. The idea is to develop a so-called "demand charging" system in which an integrated system lets the plug-ins and utilities communicate with each other so that vehicle charging is cut back at peak hours, when energy is most expensive, and ramped up when the rates drop. Such entities say there's a sense of urgency to develop such a system because the number of plug-in vehicles on US roads totals more than 225,000 today and is climbing steadily. There's a lot of technology involved, obviously, but the goal is to have an open platform that's compatible with virtually any automaker's plug-in vehicle. No timeframe was disclosed for when such a system could go live but you can find a press release from EPRI below. EPRI, Utilities, Auto Manufacturers to Create an Open Grid Integration Platform for Plug-in Electric Vehicles PALO ALTO, Calif. (July 29, 2014) – The Electric Power Research Institute, 8 automakers and 15 utilities are working to develop and demonstrate an open platform that would integrate plug-in electric vehicles (PEV) with smart grid technologies enabling utilities to support PEV charging regardless of location. The platform will allow manufacturers to offer a customer-friendly interface through which PEV drivers can more easily participate in utility PEV programs, such as rates for off-peak or nighttime charging. The portal for the system would be a utility's communications system and an electric vehicle's telematics system. As the electric grid evolves with smarter functionality, electric vehicles can serve as a distributed energy resource to support grid reliability, stability and efficiency. With more than 225,000 plug-in vehicles on U.S. roads -- and their numbers growing -- they are likely to play a significant role in electricity demand side management.