You're driving home from a weekend vacation. It's late at night, and the winding two-lane road has no streetlights. You approach a curve at 40 mph -- slow enough to make the turn, but too fast to stop suddenly if you need to. What's waiting there, just beyond the range of your headlights? A stalled car? A deer..?
With adaptive headlights, there's no guessing game. The lights turn their beams around each bend in the road, giving you a better view of what's ahead. Improved night driving isn't a trivial matter -- over 46 percent of fatal accidents in 2006 occurred at night, a number much higher than the proportion of driving done at night
Standard headlights shine straight ahead, no matter what direction the car is moving. When going around curves, they illuminate the side of the road more than the road itself. Adaptive headlights react to the steering, speed and elevation of the car and automatically adjust to illuminate the road ahead. When the car turns right, the headlights angle to the right. Turn the car left, the headlights angle to the left. This is important not only for the driver of the car with adaptive headlights, but for other drivers on the road as well. The glare of oncoming headlights can cause serious visibility problems. Since adaptive headlights are directed at the road, the incidence of glare is reduced.
A car with adaptive headlights uses electronic sensors to detect the speed of the car, how far the driver has turned the steering wheel, and the yaw of the car. Yaw is the rotation of the car around the vertical axis -- when a car is spinning, for example, its yaw is changing. The sensors direct small electric motors built into the headlight casing to turn the headlights. A typical adaptive headlight can turn the lights up to 15 degrees from center, giving them a 30-degree range of movement
The sensors in an adaptive headlights system prevent the lights from turning when they don't need to. If the car isn't moving or is moving in reverse, the adaptive headlights won't activate. This helps keep the lights from inadvertently blinding other drivers.
Most adaptive headlights systems also include a self-leveling system. Self-leveling headlights have an additional level sensor that determines if the car is tilted forward or back. For example, if a car is driving over a large bump, when the front of the car hits the bump, it lifts up. Standard headlights would briefly point up into the sky until the rear of the car moved over the bump and the car returned to a level position. You may have noticed this if a car driving behind you at night passed over a bump, such as a railroad crossing. The other car's headlights would flash briefly, as if the driver had blinked his or her high beams at you. This is actually the car's headlights temporarily pointing up and into your eyes instead of down at the road. With a self-leveling system, electric servomotors react to the level sensor and keep the headlights aimed down at the road, no matter the position of the car.
Headlights of the Future:
Auto designers are developing several innovations in headlight technology that should appear on production models in the next few years. Adaptive brake lights will allow you to see more than just the car in front of you applying the brakes. You'll also know how hard the driver is applying the brakes, giving you a good indication of trouble ahead or how much you yourself need to slow down. These brake systems will light up like normal brake lights under normal braking conditions. However, when someone presses on the brakes hard to make a more sudden stop, the brake lights shine more brightly. The lighting is progressive -- when someone really stomps on the brakes, the very brightest brake light comes on, while lesser degrees of braking force result in brightness in between "normal" and "full stop."
Single-source fiber-optic lights: could revolutionize auto lighting by allowing for a wider variety of lighting options and optimal lighting configurations. A single-source system uses one light located somewhere in the inner workings of the car. Fiber-optic strands then carry the light to wherever it's needed. Instead of two headlights, a car could have a wide light-emitting pattern on the front. The fiber optics could be manipulated by small motors to allow even more versatile adaptive lighting. The drawback for the time being is that the fiber optics lose a lot of the light's intensity as they carry it, so a very bright single-source is needed.
With adaptive headlights, there's no guessing game. The lights turn their beams around each bend in the road, giving you a better view of what's ahead. Improved night driving isn't a trivial matter -- over 46 percent of fatal accidents in 2006 occurred at night, a number much higher than the proportion of driving done at night
Standard headlights shine straight ahead, no matter what direction the car is moving. When going around curves, they illuminate the side of the road more than the road itself. Adaptive headlights react to the steering, speed and elevation of the car and automatically adjust to illuminate the road ahead. When the car turns right, the headlights angle to the right. Turn the car left, the headlights angle to the left. This is important not only for the driver of the car with adaptive headlights, but for other drivers on the road as well. The glare of oncoming headlights can cause serious visibility problems. Since adaptive headlights are directed at the road, the incidence of glare is reduced.
A car with adaptive headlights uses electronic sensors to detect the speed of the car, how far the driver has turned the steering wheel, and the yaw of the car. Yaw is the rotation of the car around the vertical axis -- when a car is spinning, for example, its yaw is changing. The sensors direct small electric motors built into the headlight casing to turn the headlights. A typical adaptive headlight can turn the lights up to 15 degrees from center, giving them a 30-degree range of movement
The sensors in an adaptive headlights system prevent the lights from turning when they don't need to. If the car isn't moving or is moving in reverse, the adaptive headlights won't activate. This helps keep the lights from inadvertently blinding other drivers.
Self-leveling Systems :
Most adaptive headlights systems also include a self-leveling system. Self-leveling headlights have an additional level sensor that determines if the car is tilted forward or back. For example, if a car is driving over a large bump, when the front of the car hits the bump, it lifts up. Standard headlights would briefly point up into the sky until the rear of the car moved over the bump and the car returned to a level position. You may have noticed this if a car driving behind you at night passed over a bump, such as a railroad crossing. The other car's headlights would flash briefly, as if the driver had blinked his or her high beams at you. This is actually the car's headlights temporarily pointing up and into your eyes instead of down at the road. With a self-leveling system, electric servomotors react to the level sensor and keep the headlights aimed down at the road, no matter the position of the car.
Headlights of the Future:
Auto designers are developing several innovations in headlight technology that should appear on production models in the next few years. Adaptive brake lights will allow you to see more than just the car in front of you applying the brakes. You'll also know how hard the driver is applying the brakes, giving you a good indication of trouble ahead or how much you yourself need to slow down. These brake systems will light up like normal brake lights under normal braking conditions. However, when someone presses on the brakes hard to make a more sudden stop, the brake lights shine more brightly. The lighting is progressive -- when someone really stomps on the brakes, the very brightest brake light comes on, while lesser degrees of braking force result in brightness in between "normal" and "full stop."
Single-source fiber-optic lights: could revolutionize auto lighting by allowing for a wider variety of lighting options and optimal lighting configurations. A single-source system uses one light located somewhere in the inner workings of the car. Fiber-optic strands then carry the light to wherever it's needed. Instead of two headlights, a car could have a wide light-emitting pattern on the front. The fiber optics could be manipulated by small motors to allow even more versatile adaptive lighting. The drawback for the time being is that the fiber optics lose a lot of the light's intensity as they carry it, so a very bright single-source is needed.
awesome dude
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