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Ford Launches Voice Control of Apps in Car

Ford, which has been trying to fast-forward its automobiles in the digital space, announced today that its 2011 Fiesta model will be the first vehicle in which smartphone apps can be voice-controlled via its in-car synching software.
One issue: Initially, Ford’s SYNC AppLink, downloadable as an upgrade, will work only with Google (GOOG) Android and Research in Motion (RIMM) BlackBerry devices.
As to the more popular iPhone from Apple (AAPL)?
“Ford will introduce AppLink on all SYNC-equipped vehicles next year, as well as provide interoperability with iPhone and other smartphones,” the auto company said in a statement.
Still, anything that stops dodos from fiddling with a smartphone while driving can’t be bad. Ford (F) has been trying mightily to differentiate itself by digitizing its cars.
In December, Ford said it would make the next generation of its SYNC-enabled vehicles into Wi-Fi hotspots, allowing drivers and passengers to connect to the Internet everywhere much more seamlessly in a moving car.
Pandora Internet radio, online talk radio aggregator Stitcher and mobile Twitter client OpenBeak are the first SYNC-enabled mobile applications.
Ford also said it is launching a developers’ network to boost the number of apps that can be used in SYNC-enabled cars.

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wpid 2011 KTM X-Bow R

The rear of the KTM X-Bow R is a 300 hp 2.0-liter TFSI engine in the Audi, with a maximum torque of 400 Nm at the German premium car manufacturer Audi, KTM has chosen one of the most efficient and powerful engines with a cylinder 2 , 0 liter.

2012 Lexus LFA Rear Angle

Lexus LFA is a luxury sports car with a capacity of two passengers. This car is only available in one trim level. Car price of the Lexus LFA MSRP is $ 375, 000.

 
Someday you all will charge wirelessly - phones, cars, calculators graph, all using the same basic technology.

 

As interest in electric vehicles and solar power is on a rise, Michigan-based Duo-Gard Industries decided to develop a new sort of solar-powered charging stations for cars, bikes, scooters, carts and motorcycles.

Honda to Begin Sales of Honda Bicycle Simulator Developed for Traffic Safety Education

This bicycle simulator was initially built for traffic safety education but due to the buzz around the product Honda have decided to bring them onto the Japanese market early next year.

 
Photo of Professor Jay Keasling courtesy of the Lawrence Berkeley Laboratory.

Some might call it luck, some might call it fate. Nevertheless, the day Professor Jay Keasling found out that a plant-based malaria drug called artemisinin was chronically in short supply – that was a very important day.
You see, back in 2000, Dr. Keasling was looking for an organic chemical to be a suitable focus for his research at the University of California-Berkeley into a new field of science known as synthetic biology.
Artemisinin is a fast-acting malaria drug that, when used in a combination therapy to prevent drug resistance, is the current standard treatment for malaria worldwide. Its precursor chemical, amorphadiene synthase, is derived from the sweet wormwood (Artemisia annua), a plant that is not grown in sufficient quantities compared to need. As luck or fate would have it, amorphadiene synthase is in the class of organic chemicals Dr. Keasling believed would be ideal for study. He envisioned synthetic biology techniques creating a high-quality, non-seasonal, economical supply of the target molecule, in this case, an important drug.
Synthetic biology takes genetic engineering to the next level: scientists use parts of DNA to create a new organism or to change what an organism does. In the artemisinin project, Dr. Keasling experimented with introducing the target gene into E. coli bacteria and a type of yeast. Working with the yeast proved to be the better way to go. Dr. Keasling and his team also found a way to alter the metabolic pathway of the yeast. In other words, he made this yeast create the target molecule as the by-product of its fermentation. As it digests the material it is fed (the feedstock), it creates amorphadiene synthase, which can then be converted to artemisinin.
By 2004, Dr. Keasling's lab was showing so much promise in creating amorphadiene synthase on a small scale that the university and a start-up company, Amyris (formed by some of the post-doctoral researchers), were awarded a $42.6 million, five-year grant from the Institute of OneWorld Health (iOWH). The grant, which originated from the Bill and Melinda Gates Foundation , was to perfect the technology for the commercial production of synthetic artemisinin. According to a university spokesman, Dr. Keasling completed his part of the development of the synthetic artemisinin for the university, and the Amyris researchers took over to complete the translation of lab procedures to a process suitable for the larger-scale operations of a drug manufacturer. Amyris completed its assignment in 2010 after partnering with drug maker Sanofi-Aventis in 2008. The iOWH contracted with Sanofi-Aventis to implement the synthetic artemisinin in its commercial production of artemisinin-based combination therapies (ACTs) and provided the company a $10.7 million grant that also originated from the Bill and Melinda Gates Foundation. Sanofi-Aventis is operating on a no profit-no loss basis, and the University of California-Berkeley and Amyris granted a royalty-free license to it for the use of their technology. The projected date for commercial distribution is 2012.
All involved hope that the efforts of these scientists and philanthropists will have a big impact on the deadly toll of malaria in developing countries. This story has many heroes: one is Dr. Victoria Hale, who founded the iOWH to focus on producing drugs and treatments for neglected diseases of the developing world. The iOWH is the first-ever non-profit drug partnering firm in the U.S. that matches neglected diseases with people who can create solutions and people who want to finance the effort. Although Dr. Hale has moved on to her "second generation" non-profit agency focused on women's and children's health problems, the iOWH continues it mission, targeting diarrheal diseases and visceral leishmaniasis in addition to malaria.
A good story should always have a good epilogue. With respect to Amyris, Inc., the company is making progress on adapting a microbially-produced hydrocarbon, Biophene (TM), to a number of uses, including a drop-in replacement for diesel fuel. The company, now headed by John Melo, a former BP executive, has imminent plans for building a facility adjacent to the world's largest sugar cane processor in Brazil. The company, which had attracted significant venture capital, had an IPO last year. According to its CEO, Amyris is generally hopeful regarding cellulose as a future feedstock for the company's fermenting technology platform.
As for Dr. Keasling, he is applying the knowledge and experience gained in developing artemisinin to focus on the metabolic engineering of microorganisms (that is, altering what the microbe produces from what it consumes) to create, for example, a liquid fuel to replace gasoline. His goal is to do this with cheap, resilient, renewable feedstock like tall grass species. Targeting complex sugars found in cellulose (e.g. plant stalks) is much more ambitious than using a simple sugar like corn or sugar cane. To this end, Dr. Keasling was made CEO of the Joint BioEnergy Institute (JBEI, known as "j-bay"), which is one of three bioenergy research centers funded by the U.S. Department of Energy. He is also a faculty scientist with the Lawrence Berkeley National Lab's Physical Biosciences Division and the director of the SyntheticBiologyEngineeringResearchCenter. And while he serves as a professor for Berkeley's bioengineering department and the chemical and biomolecular engineering department, he enjoys the honor of being the Hubbard Howe Jr. Distinguished Professor of Biochemical Engineering.
Considering Dr. Keasling's contribution to synthesizing a potent malaria drug and the progress his lab is making toward synthetic, microbially-generated renewable fuel, one wonders how many of the world's challenges will he take on?

 
"Power density is the Holy Grail of engine design." That is the mantra of Professor Peter Hofbauer, the chairman and chief technical officer of EcoMotors International.
Power density increases when there is more power with less weight. Professor Hofbauer's new opposed-piston opposed-cylinder (opoc) two-stroke engine has unprecedented power density: according to a company spokesman, this breakthrough engine design is 50 percent lighter, is half the size, and is at least 15 percent more efficient in the diesel version now under development. (It can use gasoline, ethanol, diesel – any liquid fuel.) However, EcoMotor's most powerful model to date achieves fuel economy that is 45 percent better than the current, state-of-the-art conventional turbo diesel engines.
Because the opoc(TM) has fewer components (13 versus 40 in an inline-4), it is less expensive to manufacture. Because it is a redesigned standard engine needing no new infrastructure, it can revitalize American manufacturing. Indeed, an EcoMotors handout proclaims, "that means real jobs, real soon."
The opoc(TM) has been in development for eight years, supported by public and private research funding. Professor Hofbauer, a 20-year veteran of Volkswagen, is the founder of EcoMotors, a three-year-old company in suburban Detroit. He explains that the opoc(TM) engine is a hybrid of the boxer engine – the type of flat engine in VW Beetles – and the famous Junkers (pronounced "yoonkers") diesel aircraft engines.
The boxer engine features a central crankshaft and the flat, opposed-cylinder design, but it has cylinder heads and valve train components. The Junkers engine features opposed pistons, but it has parallel crankshafts geared in tandem. In designing the opoc(TM) engine, Professor Hofbauer combined the benefits of the central crankshaft and the opposed cylinder design of the boxer engine with the advantages gained by having opposed pistons sharing a single injection of fuel mixture and eliminating cylinder heads and valve train components. Having two pairs of cylinders as they are laid out in the opoc(TM) engine represents a more balanced design and results in smoother operation.
If one engine with four cylinders is good, wouldn't adding another four be great? Indeed, the EcoMotors engine is designed to be a modular unit that can be teamed with additional units. At present, there are two engine models under development, the EM65 and the larger displacement EM100, and they are each regarded as a power module. Each of them can be paired up with a second unit to double the horsepower. If a vehicle equipped with a dual-module version of the EM100 (for example) is being operated at low speed or on flat terrain, it may not need the additional 325 hp that would be gained from the second module. When more power would be needed, though, that second module would be engaged with an electrically controlled clutch that would essentially shift the engine into a more powerful operating mode much like an automatic transmission. This mechanism would eventually reverse to decouple the second module to return it to more economical operation. EcoMotors terms this "modular cylinder displacement," an obvious enhancement to fuel economy that was promulgated by the EPA more than a decade ago. The spokesman for the company notes that Mercedes, for example, offers a comparable fuel-savings feature by taking half of its engine cylinders offline, but these unfueled cylinders still move and impact operation, if only slightly. With the EcoMotors' clutch, the module is completely detached and has no impact on the drive train. As mentioned previously, the modular cylinder displacement feature for a dual-module configuation of the EM100 makes fuel efficiencies of up to 45 percent attainable.
Another feature that enhances the EcoMotors engine is its electro-mechanical turbo-charger with no lag time in its power boost. This provides the advantage of instantaneous torque that is an appealing feature of electric motors.
Professor Hofbauer owns some of the more than 100 patents that protect the opoc(TM) engine design and the company owns some of them. The patents are for the engine designs and encompass designs using any fuel – gasoline, diesel, or ethanol. At present, EcoMotors is working with Eurocopter, as power density is extremely important in aviation.
It's natural to think of automotive applications when it comes to internal combustion engines, but in fact, the EcoMotors engine design is deliberately versatile, or, as they like to say, "application-agnostic." For those who like specs, the EM100 dual-module engine weighs 296 pounds, is just under 23x42x19 inches, has 325 hp at 3,500 rpm, and a power density of 1.1 hp per lb.
EcoMotors International has some impressive funding partners in Khosla Ventures and Bill Gates, and expects to have engine models ready for production by 2013. While the company has partnered with Eurocopter on one diesel engine project, it is presently consulting and communicating with other manufacturers about prospective partnering projects. Esquire Magazine, which featured the opoc(TM) two-stroke engine as its "Innovation of the Year" in last October's car-of-the-year spread, speculates that the powerful little 40-pound prototype motor – it can power a house – that CEO Don Runkle hauls out of a case when he goes to a meeting may be enough to convince many industry decision-makers "that the Engine That Changes Everything may have finally arrived."
We know Professor Hofbauer believes the challenge of greater power density is specifically his Holy Grail in engine design. For auto executives catering to the American market, that translates to an engine that could power the popular SUVs and light trucks that still accounted for more than half of passenger vehicle sales in 2007. Moreover, in today's economy, jobs in the U.S. auto industry might also be considered the Holy Grail of engine design.
Any way you look at it, though, before you know it, the Holy Grail of engine design may be coming to a showroom near you.

Ford Motor Company has unveiled its all-new Focus Electric - the company's first-ever all-electric passenger car. The zero-CO2-emissions, gasoline-free version of Ford's popular small car is the flagship of the company's growing fleet of hybrid, plug-in hybrid and all-electric vehicles coming to North America and Europe by 2013. "Focus Electric is the flagship of our new family of electrified vehicles, showcasing our commitment to offer consumers choice when it comes to fuel-efficient or fuel-free vehicles," said Derrick Kuzak, Ford group vice president for Global Product Development.
"Its advanced powertrain will deliver significant energy efficiency advantages and zero CO2 emissions without compromising driving enjoyment. And its suite of smart driver information technologies will transform the way customers think about energy usage and their transportation needs."
The Focus Electric will launch in late 2011 and is designed to offer enough range to cover the majority of daily driving habits of Americans. It will offer a mile-per-gallon equivalent better than Chevrolet Volt and competitive with other battery electric vehicles.
A full recharge is expected to take three to four hours at home with the 240-volt charge station -half the charge time of the Nissan Leaf.
Focus Electric introduces new features and technologies - including a unique version of the MyFord Touch driver connect system especially for electric vehicles, a new value charging feature powered by Microsoft and a smartphone app called MyFord Mobile that helps plug-in owners control their vehicles remotely.
The sleek and stylish five-door hatchback leverages Ford's global C-car platform shared by the gasoline and diesel-powered Focus models, which debuted at the 2010 North American International Auto Show and were launched at the Paris Motor Show in September.
Both Focus gasoline and electric variants to be sold in North America will be built at Ford's Michigan Assembly Plant in Wayne, Mich., with production powered in part by one of the largest solar energy generator systems in the state.
For European markets, a decision on where the Focus Electric will be built is currently being finalized.
Focus Electric is one of five new electrified vehicles included in Ford's electrification strategy. Initial deliveries of Transit Connect Electric began in North America at the end of last year and the vehicle will be launched in Europe later in 2011.
A real car Not only is Focus Electric designed to provide outstanding energy efficiency and reliable operation, it also delivers real driving enjoyment. The all-electric powertrain and single-speed transmission provide immediate responsiveness and smooth acceleration when the driver pushes down the accelerator, up to a top speed of 84 mph (136 kph).
Much of Focus Electric's steering, handling and braking feel is shared with the agile, sporty, fuel-powered Focus models upon which it's based, making Focus Electric a dynamic driver's car. At the same time, the absence of a gasoline or diesel engine and outstanding aerodynamics lead to a remarkably quiet, comfortable in-car experience.
"More than any other electric vehicle on the market, Focus Electric loses none of the dynamics and quality of driving a traditional car," said Sherif Marakby, director of Ford's electrification programs and engineering.
"It shares many of the same premium components and features as its gasoline-powered counterpart, while delivering distinct efficiencies and a uniquely exciting driving experience."
Focus Electric offers a host of standard safety and security features including six airbags and electronic traction control, along with hands-free SYNC telephone connectivity and MyKey for North America. Extensive eco-friendly materials, such as bio-foam seat cushions and recycled fabrics also are featured in the vehicle.
Other standard features on Ford Focus Electric for North American customers include a unique execution of MyFord Touch driver connect technology, 15-spoke 17-inch aluminum wheels, a 60/40 split rear bench seat, push button start, AM/FM/CD/MP3 Sony Audio with nine speakers, Sirius Satellite Radio with Travel Link, HD Radio and voice-activated Navigation System.
Plug and play Future owners of the Focus Electric will likely recharge the car's advanced, Ford-engineered lithium-ion battery pack at home on a daily basis, using the recommended 240-volt wall-mounted charge station that will be sold separately or the 120-volt convenience cord that comes with the vehicle.
When plugged in, the Focus Electric onboard charger converts AC power from the electric grid to DC power to charge the liquid-cooled/heated battery pack.
"We're very excited about the potential of Focus Electric in the marketplace. With so many of us accustomed to recharging mobile electronics on a daily basis, we're confident our customers will take to the vehicle recharging process just as easily, because that's exactly what it is - easy," said Nancy Gioia, Ford director of Global Electrification. "Not only have we made the practice of plugging in simple and straightforward, we're working with leading technology companies and the utility industry to make the EV experience empowering and engaging."
An empowering experience Focus Electric owners will be provided with a suite of driver information systems - on-board and off-board - designed to help them manage the recharge process, manage the most eco-friendly route on-board, monitor battery state of charge and maximize energy efficiency to optimize their driving range. This carefully engineered set of tools is designed to give Focus Electric the edge over competitive products, providing new electric vehicle owners the information they need to enjoy all the freedom gas-free driving has to offer.
Among these tools is a unique execution of MyFord Touch driver connect technology. Thoughtfully developed for electric vehicle owners, it offers innovative presentation of vehicle information, such as battery state of charge, distance to charge point, the corresponding range budget and expected range margin. The system's MyView feature allows drivers to access even more vehicle data including the electrical demands of vehicle accessories such as air conditioning, which can impact driving range.
Just as the growing leafy vine of first-generation SmartGauge with EcoGuide represents fuel efficiency in the Ford Fusion Hybrid, the cluster display in Focus Electric uses blue butterflies to represent the surplus range beyond one's charge point destination - the more butterflies there are, the greater the range.
Ford designers were inspired by the phenomenon known as "the butterfly effect," in which a small change, like choosing to drive an electric vehicle, can have an enormous impact. To reinforce the message, at the end of each trip a display screen provides distance driven, miles gained through regenerative braking, energy consumed and a comparative gasoline savings achieved by driving electric.
The cluster is also integrated with the MyFord Touch map-based Navigation System using the vehicle's center stack 8-inch touch screen. After adding their driving destinations, including their next charge point, into the vehicle's Navigation System, the vehicle will coach drivers on how to achieve the desired range - or if travel plans need to be adjusted. The on-board Navigation System provides an EcoRoute option based on characteristics of efficient EV driving.
Remote control Off-board, Focus Electric owners in North America will be able to maintain constant contact with the car anywhere they have mobile phone access using the Ford-developed MyFord Mobile app.
MyFord Mobile is an app that enables access via a smartphone or web-based interface to: + Receive instant vehicle status information
+ Perform key functions remotely
+ Monitor the car's state of charge and current range
+ Get alerts when it requires charging or has finished charging
+ Remotely program charge settings and download vehicle data for analysis
The feature also allows the owner to program the vehicle to use electricity from the grid to heat or cool the battery and cabin while plugged in - called preconditioning. For example, during hot summer months, owners can preprogram the car the evening before to be fully charged - and fully cooled to a particular temperature - by a certain time the following morning. Users can also locate the vehicle with GPS, remotely start the vehicle and remotely lock and unlock the car doors.
Working with MapQuest, MyFord Mobile can communicate charge station and other points of interest to Focus Electric using SYNC's Traffic, Directions and Information (TDI). Turn-by-turn guidance is provided by the in-car map-based Navigation System. Drivers can also get up-to-date charging station information in their vehicle directly through SYNC TDI simply by connecting to SYNC Services.
Value charging The new Focus Electric offers a unique value charging feature, powered by Microsoft, to help owners in the U.S. charge their vehicles at the cheapest utility rates, lowering the cost of ownership.
"Value charging allows our customers to reduce their electricity costs by taking advantage of off-peak or other reduced rates from their utility without a complicated set-up process," said Ed Pleet, manager, Ford Connected Services Organization. "This is a 'set it and forget it' approach for the customer to reduce energy cost."
The tool is designed to help customers avoid unnecessary expense by providing an optimized charge. In the future, these smart charging habits will help utility companies understand and better manage the demands placed upon the electric grid because of electrified vehicles.
Getting charged up Focus Electric owners are likely to handle one of the vehicle's charge cord connectors two or more times each day. That's why Ford worked with supplier Yazaki to provide an industry-standard five-point plug that is ergonomically comfortable to hold as well as durably and distinctively designed.
The plug handle uses a matte-finished black rubber that allows for a comfortable, non-slip grip. The plug head is shielded with a protective glossy white plastic.
When the cord set connector is plugged into the vehicle's charge port, which is conveniently located between the driver's door and front wheel well, it activates a light ring that loops around the port twice in acknowledgement of connectivity.
The light ring then illuminates in quadrants as the vehicle charges. Flashing quadrants represent charge in progress and solid-lit quadrants show stages of charge completion. In the unlikely event of a fault, the entire ring will flash. When the entire ring is solidly lit, the vehicle is fully charged.
Batteries included Focus Electric will be powered by an advanced lithium-ion battery system engineered by Ford in cooperation with supplier LG Chem. The battery system utilizes heated and cooled liquid to help maximize battery life and fuel-free driving range.
Thermal management of lithium-ion battery systems is critical to the success of pure electric vehicles. Focus Electric uses an advanced active liquid cooling and heating system to precondition and regulate the temperature in its larger, more complex lithium-ion battery system.
The active liquid system heats or chills a coolant before pumping it through the battery cooling system. This loop regulates temperature throughout the system against external conditions. On hot days, chilled liquid absorbs heat from the batteries, dispersing it through a radiator before pumping it through the chiller again.
On cold days, heated liquid warms the batteries, gradually bringing the system's temperature to a level that allows it to efficiently accept charge energy and provide enough discharge power for expected vehicle performance.
"Focus Electric is the culmination of years of research and development," said Kuzak. "More importantly, it's the start of an exciting new era for Ford and our customers."

Last Saturday, a blind driver dodged cardboard boxes thrown in front of him while driving a modified Ford Hybrid Escape around the Daytona International Speedway. He had only seconds to react to the obstacles.
"If we just put boxes on the track, people might think we planned the route," said Dennis Hong, whose robotics and mechanisms lab at Virginia Tech modified the cars.
Instead, Hong's team threw boxes from a van so they bounced around. “That shows everyone that their position is random, and that the drivers are really driving,” said Hong.
In addition to avoiding boxes and taking the raceway's turns, the driver, Mark Riccobono, also passed the van.
Fortunately, Riccobono and a second blind driver, Anil Lewis, had done it before.
"The other day, when we got to drive by ourselves, it surpassed any perception of thrilling," Riccobono wrote in an e-mail after a mid-January test run at Virginia International Speedway. Riccobono, who lost his sight at the age of five, is executive director of the National Federation of the Blind's research arm, the Jernigan Institute.
"It's scary and exciting," said Lewis, 46, who lost his sight 21 years ago and thought he would never drive again.
The demonstration at Daytona took place before blind supporters and fans gathered for the Rolex 24 sports car race as part of the National Federation of the Blind's Blind Driver Challenge to develop a car blind people can drive independently.
"We're trying to change people's minds about what blind people can do, and driving is going to change minds," said Lewis, the Federation's communications director. "This is taking it to whole different level."
Riccobono reached speeds of more than 25 mph and did not hit a single box.
Lewis was not worried about a small accident or two. "If it goes off too perfectly, people won't believe its credibility," Lewis said. After all, he explained, the car is a research project and people should expect some failures. Besides, "sighted" drivers have traffic accidents too. Hong had other goals. "I want it to be perfect," he said. "This is a controversial project. I'm getting hundreds of e-mails from people saying, 'You won't believe how much hope this brings to us.' "But I'm also getting hate mail, saying 'Are you insane?'"
Hong understands. In fact, he had doubts until blind drivers tested a prototype.

Development
The National Federation of the Blind announced the Blind Driver Challenge in 2004. Only Virginia Tech responded, and it did not sign up until 2006.
At the time, Hong's lab was developing a driverless car for the DARPA Urban Challenge. Sponsored by the Defense Advanced Research Projects Agency, it called for robot cars to navigate through 60 miles of traffic, lights, stop signs, and obstacles at an old military base. Virginia Tech's upstart team surprised everyone by claiming the $500,000 third prize.
Hong thought he could use a similar approach to build a car for the blind. That was not the Federation's goal.
"They wanted the blind person to make active decisions, and actually drive and control the vehicle," Hong said.
Yet the two vehicles had much in common. Both use similar sensors. A laser light detection and ranging (LIDAR) system identified cars and other obstacles in the road. In addition, two forward-pointing cameras monitored the road as well as lights and stop signs. A GPS system located the car on a map, while an inertial measurement unit tracked the car's speed and direction in case it lost GPS contact.
The vehicles' computers automatically gathered all the sensory information and blended it together to create a model of the car's rapidly changing environment.
In the driverless car, the computer assessed the model, picked out the route, and used the drive-by-wire system to drive the car.
The Blind Driver Challenge vehicle was different. Instead of telling the car how to drive, it had to communicate this information to the driver, who then had to respond accordingly.
Hong's team faced two initial hurdles. First came money. Autonomous cars are expensive, but the Federation offered Hong only $5,000 to get started. He put together a team of 12 undergraduates and they bought a used gasoline-powered dune buggy on eBay for $2,000.
They bought whatever equipment was not donated. The LIDAR made by Hokuyo Automatic Co. was the most expensive component, and ordinarily cost about $8,000.
"Hokuyo originally donated it for another robotics project, but we used it on this," Hong related. "I was afraid to tell them, but when they saw what we did, they became big fans."
Driving By Touch
The second problem was more profound. How could Virginia Tech convey information fast enough to a driver who cannot see? After all, most computers communicate with humans through visual displays. For the blind, that wasn't possible.
Hong started by letting the computer pick the best route and communicate driving information -- fast, slow, right, left, stop -- to the driver.
For the dune buggy, the students built a vest from a massage chair vibrator. Different massage patterns told the driver when to speed up, slow down, or stop. In the Ford Escape, the expanded team of engineers built the vibrator, now branded SpeedStrip, into the driver's seat.
"We're experimenting with straight up-and-down and zigzag patterns, still figuring out which ones are most effective," Hong explained.
The dune buggy's original steering system used a steering wheel that made clicking noises when it turned. The car's computer told the driver how many clicks to turn the wheel. It was awkward, and forced blind drivers to listen to the computer rather than use their hearing to assess their environment.
The Ford Escape, by contrast, uses DriveGrip, a glove with a small vibrating motor on the knuckle of each finger. The more motors that vibrate, the sharper the driver needs to turn.
Finding the right vibration pattern proved a challenge. Hong considered which hand to signal for which turn; whether the motors should vibrate all at once or sequentially; and whether they should turn off suddenly or gradually as the driver completed the turn.
He also had to face the human-in-the-loop problem. An autonomous vehicle is easy for a computer to control because it responds to commands the same way every time.
Humans are another story. Different drivers may interpret the signal to turn hard differently. Even the same driver may respond differently on different days.
This showed up during testing. The computer would define the "road" as an 18 foot wide path on the 30 foot wide racetrack. "If I steered out of that lane, the car would shut down," Lewis recounted. This often happened when cornering.
"Sighted people get a chance to correct their errors," Lewis said. "We asked for the same chance, and when we got it. We got better at staying on the road."
In this case, the solution to the human-in-the-loop was to modify the car's controls so that the driver could learn to adapt to its signals.
The blind drivers and a blind engineer on the Virginia Tech team also suggested cutting off the ends of the DriveGrip gloves, since blind people need touch to sense their environment. They also collaborated on finding the best vibration patterns.
Lewis and Riccobono practiced for a total of seven days during the months before Daytona. Lewis says the Blind Driver Challenge will help blind people stay on the forefront of technology.
"We were worried that the knobs and buttons we used on appliances and phones were going to touch screens. We wanted to make sure there are non-visual interfaces out there for us," Lewis said.
Those interfaces are coming. They are what Hong calls "informational" interfaces. On the Escape, they communicate what is going on outside the car.
One is AirPix, a pad with pressurized air flowing through a grid of pinholes. It works like an air hockey table, but AirPix controls each pinhole's air pulses to form "pictures" that a blind person can view with his or her fingers, like Braille. A similar technology uses a 3-dimensional rubber membrane that changes shape to show road conditions.
The technology is too new to use at Daytona. Yet one day, similar technologies may not only help the blind to drive, but perhaps to navigate streets, use portable computer devices, or view notes from an electronic blackboard.