- Automotive lighting
The lighting system of a motor vehicle consists of lighting and signalling devices mounted or integrated to the front, sides, rear, and in some cases the top of the motor vehicle. The purpose of this system is to provide illumination for the driver to operate the vehicle safely after dark, to increase the conspicuity of the vehicle, and to display information about the vehicle's presence, position, size, direction of travel, and driver's intentions regarding direction and speed of travel.
Colour of light emitted
The colour of light emitted by vehicle lights is largely standardised by longstanding convention, first codified in the 1949 Vienna Convention on Road Traffic and later specified in the 1968 United Nations Convention on Road Traffic. Generally, but with some regional exceptions, lamps facing rearward must emit red light, lamps facing sideward and all turn signals must emit amber light, lamps facing frontward must emit white or selective yellow light, and no other colours are permitted except on emergency vehicles.
Forward illumination is provided by high- ("main", "full", "driving") and low- ("dip", "dipped", "passing") beam headlamps, which may be augmented by auxiliary fog lamps, driving lamps, and/or cornering lamps.
Dipped beam (low beam, passing beam, meeting beam)
Dipped-beam (also called low, passing, or meeting beam) headlamps provide a light distribution to give adequate forward and lateral illumination without blinding other road users with excessive glare. This beam is specified for use whenever other vehicles are present ahead. The international ECE Regulations for headlamps specify a beam with a sharp, asymmetric cutoff preventing significant amounts of light from being cast into the eyes of drivers of preceding or oncoming cars. Control of glare is less strict in the North American Society of Automotive Engineers (SAE) beam standard contained in FMVSS / CMVSS 108.
Main beam (high beam, driving beam, full beam)
Main-beam (also called high, driving, or full beam) headlamps provide an intense, centre-weighted distribution of light with no particular control of glare. Therefore, they are only suitable for use when alone on the road, as the glare they produce will dazzle other drivers. International ECE Regulations permit higher-intensity high-beam headlamps than are allowed under North American regulations
"Driving lamp" is a term deriving from the early days of nighttime driving, when it was relatively rare to encounter an opposing vehicle. Only on those occasions when opposing drivers passed each other would the dipped or "passing" beam be used. The full beam was therefore known as the "driving beam", and this terminology is still found in international ECE Regulations, which do not distinguish between a vehicle's primary (mandatory) and auxiliary (optional) upper/driving beam lamps. The "driving beam" term has been supplanted in North American regulations by the functionally descriptive term "auxiliary high-beam lamp". They are most notably fitted on rallying cars, and are occasionally fitted to production vehicles derived from or imitating such cars. They are common in countries with large stretches of unlit roads, or in regions such as the Nordic countries where the period of daylight is short during winter. Many countries regulate the installation and use of driving lamps. For example, in Russia each vehicle may have no more than three pairs of lights including the original-equipment items, and in Paraguay, auxiliary driving lamps must be off and covered with opaque material when the vehicle is circulating in urban areas.
Rallye and off-road lamps
Vehicles used in rallying, off-roading, or at very high speeds often have extra lamps to broaden and extend the field of illumination in front of the vehicle. On off-road vehicles in particular, these additional lamps are sometimes mounted along with forward-facing lights on a bar above the roof, which protects them from road hazards and raises the beams allowing for a greater projection of light forward.
Front fog lamps
Front fog lamps provide a wide, bar-shaped beam of light with a sharp cutoff at the top, and are generally aimed and mounted low. They may be either white or selective yellow. They are intended for use at low speed to increase the illumination directed towards the road surface and verges in conditions of poor visibility due to rain, fog, dust or snow. As such, they are often most effectively used in place of dipped-beam headlamps, reducing the glareback from fog or falling snow, although the legality varies by jurisdiction of using front fog lamps without low beam headlamps.
Use of the front fog lamps when visibility is not seriously reduced is often prohibited (for example in the United Kingdom), as they can cause increased glare to other drivers, particularly in wet pavement conditions, as well as harming the driver's own vision due to excessive foreground illumination.
The respective purposes of front fog lamps and driving lamps are often confused, due in part to the misconception that fog lamps are necessarily selective yellow, while any auxiliary lamp that makes white light is a driving lamp. Automakers and aftermarket parts and accessories suppliers frequently refer interchangeably to "fog lamps" and "driving lamps" (or "fog/driving lamps"). In most countries, weather conditions rarely necessitate the use of fog lamps, and there is no legal requirement for them, so their primary purpose is frequently cosmetic. They are often available as optional extras or only on higher trim levels of many cars. Studies have shown that in North America more people inappropriately use their fog lamps in dry weather than use them properly in poor weather.
On some models, white "cornering lamps" provide extra lateral illumination in the direction of an intended turn or lane change. These are actuated in conjunction with the turn signals, though they burn steadily, and they may also be wired to illuminate when the vehicle is shifted into reverse gear, as is done on many Saabs and Corvettes. North American technical standards contain provisions for front cornering lamps as well as for rear cornering lamps. Cornering lamps have traditionally been prohibited under international ECE Regulations, though provisions have recently been made to allow them as long as they are only operable when the vehicle is travelling at less than 40 kilometres per hour (about 25 mph).
Police cars, emergency vehicles, and those competing in road rallies are sometimes equipped with an auxiliary lamp, sometimes called an alley light, in a swivel-mounted housing attached to one or both a-pillars, directable by a handle protruding through the pillar into the vehicle. Until the mid-1940s, these spot lamps could be found as standard equipment on expensive cars.[which?] Until the mid-1960s, they were commonly offered by automakers as model-specific accessory items. Spot lamps are used to illuminate signs, house numbers, and people. Spot lights can also be had in versions designed to mount through the vehicle's roof. In some countries, for example in Russia, spot lights are allowed only on emergency vehicles or for off-road driving.
Conspicuity, signal and identification lights
Conspicuity devices are the lamps and reflectors that make a vehicle conspicuous and visible with respect to its presence, position, direction of travel, change in direction or deceleration. Such lamps may burn steadily, blink, or flash, depending on their intended and regulated function.
Front position lamps (parking lamps, standing lamps)
Nighttime standing-vehicle conspicuity to the front is provided by "front position lamps", known as "parking lamps" or "parking lights" in North America, and "front sidelights" in British English. Despite the UK term, these are not the same as the sidemarker lights described below. The front position lamps may emit white or amber light in North America; elsewhere in the world they must emit only white light. Colloquial city light terminology for front position lamps derives from the practice, formerly adhered to in cities like Moscow, London and Paris, of driving at night in built-up areas using these low-intensity lights rather than headlamps. It is now illegal in many countries to drive a vehicle with parking lamps illuminated, unless the headlamps are also illuminated. The UK briefly required Dim-Dip lights, described below, in an attempt to optimise the level of light used at night in built-up areas.
Since the late 1960s, front position lamps have been required to remain illuminated even when the headlamps are on, to maintain the visual signature of a dual-track vehicle to oncoming drivers in the event of headlamp burnout. Front position lamps worldwide produce between 4 and 125 candelas.
In Germany, the StVZO (Road Traffic Licensing Regulations) calls for a different function also known as parking lamps: With the vehicle's ignition switched off, the operator may activate a low-intensity light at the front (white or amber) and rear (red) on either the left or the right side of the car. This function is used when parking in narrow unlit streets to provide parked-vehicle conspicuity to approaching drivers. This function, which is optional under ECE and US regulations, is served passively and without power consumption in North America by the mandatory sidemarker retroreflectors.
Daytime running lamps
Some countries permit or require vehicles to be equipped with daytime running lamps (DRL). These may be functionally-dedicated lamps, or the function may be provided by, e.g., the low beam or high beam headlamps, the front turn signals, or the front fog lamps, depending on local regulations. In ECE Regulations, a functionally-dedicated DRL must emit white light with an intensity of at least 400 candelas on axis and no more than 1200 candelas in any direction. Most countries applying ECE Regulations permit low beam headlamps to be used as daytime running lamps. Canada, Sweden, Norway, Slovenia, Finland, Iceland, and Denmark require hardwired automatic DRL systems of varying specification depending on the specific country. DRLs are permitted in many countries where they are not required, but prohibited in other countries not requiring them.
In North America, daytime running lamps may produce up to 7,000 candelas, and can be implemented as high-beam headlamps running at less-than-rated voltage. This has provoked a large number of complaints about glare.
Front, side, and rear position lamps are permitted, required or forbidden to illuminate in combination with daytime running lamps, depending on the jurisdiction and the DRL implementation. Likewise, according to jurisdictional regulations, DRLs mounted within a certain distance of turn signals are permitted or required to extinguish or dim down to parking lamp intensity individually when the adjacent turn signal is operating.
U.K. regulations briefly required vehicles first used on or after 1 April 1987 to be equipped with a dim-dip device or special running lamps, except such vehicles as comply fully with ECE Regulation 48 regarding installation of lighting equipment. A dim-dip device operates the low beam headlamps (called "dipped beam" in the UK) at between 10% and 20% of normal low-beam intensity. The running lamps permitted as an alternative to dim-dip were required to emit at least 200 candela straight ahead, and no more than 800 candela in any direction. In practice, most vehicles were equipped with the dim-dip option rather than the running lamps.
The dim-dip systems were not intended for daytime use as DRLs. Rather, they operated if the engine was running and the driver switched on the parking lamps (called "sidelights" in the UK). Dim-dip was intended to provide a nighttime "town beam" with intensity between that of the parking lamps commonly used at the time by British drivers in city traffic after dark, and dipped (low) beams; the former were considered insufficiently intense to provide improved conspicuity in conditions requiring it, while the latter were considered too glaring for safe use in built-up areas. The UK was the only country to require such dim-dip systems, though vehicles so equipped were sold in other Commonwealth countries with left-hand traffic.
In 1988, the European Commission successfully prosecuted the UK government in the European Court of Justice, arguing that the UK requirement for dim-dip was illegal under EC directives prohibiting member states from enacting vehicle lighting requirements not contained in pan-European EC directives. As a result, the UK requirement for dim-dip was quashed. Nevertheless, dim-dip systems remain permitted, and while such systems are not presently as common as they once were, dim-dip functionality was fitted on many new cars well into the 1990s.
Sidemarker lights and reflectors
In North America, amber front and red rear sidemarker lamps and retro-reflectors are required. The law initially required lights or retroreflectors on vehicles made after 1 January 1968. This was amended to require lights and retroreflectors on vehicles made after 1 January 1970. These side-facing devices make the vehicle's presence, position and direction of travel clearly visible from oblique angles. The lights are wired so as to illuminate whenever the vehicles' parking and taillamps are on, including when the headlamps are being used. Front amber sidemarkers in North America may or may not be wired so as to flash in sync with the turn signals. Sidemarkers are permitted outside North America, but not required. If installed, they are required to be brighter and visible through a larger horizontal angle than US sidemarkers, they may not flash, and they must be amber at the front and rear unless the rear sidemarker is incorporated into the main rear lamp cluster, in which case it may be red or amber. Some Japanese, European, British and US-brand vehicles have sidemarkers in Europe and other countries where they are not required.
Turn signals — formally called "directional indicators" or "directional signals", and informally known as "directionals", "blinkers", "indicators" or "flashers" — are signal lights mounted near the left and right front and rear corners of a vehicle, and sometimes on the sides, used to indicate to other drivers that the operator intends a lateral change of position (turn or lane change). Electric turn signal lights were devised as early as 1907. The modern turn signal was patented in 1938 and was later offered by most major automobile manufacturers. Today, turn signals are required on all vehicles that are driven on public roadways in most countries. Alternative systems of hand signals were used earlier, and they are still common for bicycles. Hand signals are also sometimes used when regular vehicle lights are malfunctioning.
Some cars from the 1920s to 1950s used retractable semaphores called trafficators rather than flashing lights. They were commonly mounted high up behind the front doors and swung out horizontally. However, they were fragile and could be easily broken off and also had a tendency to stick in the closed position.
As with all vehicle lighting and signalling devices, turn signal lights must comply with technical standards that stipulate minimum and maximum permissible intensity levels, minimum horizontal and vertical angles of visibility, and minimum illuminated surface area to ensure that they are visible at all relevant angles, do not dazzle those who view them, and are suitably conspicuous in conditions ranging from full darkness to full direct sunlight.
Side turn signals
In most countries outside North America, cars must be equipped with side-mounted turn signal repeaters to make the turn indication visible laterally rather than just to the front and rear of the vehicle. These are permitted, but not required in North America. As an alternative in North America, the front amber sidemarker lights may be wired to flash with the turn signals, but this also is not mandatory. In recent years, many automakers have been incorporating side turn signal devices into the sideview mirror housings, rather than mounting them on the vehicle's fenders. One of the first vehicles so equipped was the Mercedes-Benz R170. There is evidence to suggest these mirror-mounted turn signals may be more effective than fender-mounted items.
Electrical connection and switching
Turn signals are required to blink on and off, or "flash", at a steady rate of between 60 and 120 blinks per minute (Although some operate slower than this). International regulations require that all turn signals activated at the same time (i.e., all right signals or all left signals) flash in simultaneous phase with one another; North American regulations also require simultaneous operation, but permit sidemarkers wired for side turn signal functionality to flash in opposite-phase. Worldwide regulations stipulate an audiovisual tell-tale indicator when the turn signals are activated; this usually takes the form of one combined or separate left and right green indicator lights on the vehicle's instrument cluster, and a cyclical "tick-tock" noise generated electromechanically or electronically. It is also required that audio and/or visual warning be provided to the vehicle operator in the event of a turn signal's failure to light. This warning is usually provided by a much faster- or slower-than-normal flash rate, visible on the dashboard indicator, and audible via the faster tick-tock sound.
Turn signals are in almost every case activated by means of a horizontal lever (or "stalk") protruding from the side of the steering column, though some vehicles have the lever mounted instead to the dashboard. The outboard end of the stalk is pushed clockwise to activate the right turn signals, or anticlockwise for the left turn signals. This operation is intuitive; for any given steering manoeuvre, the stalk is pivoted in the same direction as the steering wheel must be turned. In virtually all left-hand drive cars, the signal stalk is on the left side of the column. In right-hand drive cars, the signal stalk may be on either side. If the vehicle's wipers are controlled by a stalk on the opposite side from the signal stalk, a driver unaccustomed to the vehicle may inadvertently activate the wrong control.
Virtually all vehicles (except many motorcycles and commercial semi-tractors) have a turn indicator self-cancelling feature that returns the lever to the neutral (no signal) position as the steering wheel approaches the straight-ahead position after a turn has been made. Depending on the configuration of the steering and self-cancelling systems, large-radius turns may not involve enough steering wheel movement to trip the turn signal switch back to the neutral position automatically. However, if the self-cancelling system is configured to avoid this, it may tend to cancel the turn signal prematurely in response to normal steering wheel movement before and during common turns. Beginning in the late 1960s, indicating for a lane change was facilitated by the addition of a spring-loaded momentary signal-on position just shy of the left and right detents. The signal operates for however long the driver holds the lever partway towards the left or right turn signal detent. Some recent vehicles have an automatic lane-change indication feature; tapping the lever partway towards the left or right signal position and immediately releasing it causes the applicable turn indicators to flash three to five times.
Many transit buses, such as those in New York, have, since at least the 1950s, had turn signals activated by floor-mounted momentary-contact footswitches on the floor near the driver's left foot (on left-hand drive buses). The foot-activated signals allow bus drivers to keep both hands on the steering wheel while watching the road and scanning for passengers as they approach a bus stop. New York City Transit bus drivers, among others, are trained to step continuously on the right directional switch while servicing a bus stop, to signal other road users they are intentionally dwelling at the stop, allowing following buses to skip that stop. This method of signalling requires no special arrangements for self-cancellation or passing.
Turn signal colour
Until the early 1960s, most front turn signals worldwide emitted white light and most rear turn signals emitted red. Amber front turn signals were voluntarily adopted by the auto industry in the USA for most vehicles beginning in the 1963 model year, though front turn signals were still legally permitted to emit white light until FMVSS 108 took effect for the 1968 model year, whereupon amber became the only permissible front turn signal colour. Presently, almost all countries outside North America require that all front, side and rear turn signals produce amber light. In North America the rear signals may be amber or red. American regulators and other proponents of red rear turn signals have historically asserted there is no proven safety benefit to amber signals, though it has been recognised since the 1960s that amber turn signals are more quickly spotted than red ones. International proponents of amber rear signals say they are more easily discernible as turn signals, and U.S. studies in the early 1990s demonstrated improvements in the speed and accuracy of following drivers' reaction to stop lamps when the turn signals were amber rather than red. A 2008 U.S. study by the National Highway Traffic Safety Administration (NHTSA) suggests vehicles with amber rear signals rather than red ones are up to 28% less likely to be involved in certain kinds of collisions, and a 2009 NHTSA study determined there is a significant overall safety benefit to amber rather than red rear turn signals.
There is some evidence that turn signals with colourless clear lenses and amber bulbs may be less conspicuous in bright sunlight than those with amber lenses and colourless bulbs.
The amber bulbs commonly used in turn signals with colourless lenses are no longer made with cadmium glass, since cadmium was banned because of its toxicity by various regulations worldwide, including the European RoHS directive. Amber glass made without cadmium is relatively costly, so most amber bulbs are now made with clear glass dipped in an amber coating. Some of these coatings are not as durable as the bulbs themselves; with prolonged heat-cool cycles, the coating may flake off the bulb glass, or its colour may fade. This causes the turn signal to emit white light rather than the required amber light. The international regulation on motor vehicle bulbs requires manufacturers to test bulbs for colour endurance. However, no test protocol or colour durability requirement is specified. Discussion is ongoing within the Groupe des Rapporteurs d'Éclairage, the UNECE working group on vehicular lighting regulation, to develop and implement a colour durability standard. Rather than using an amber bulb, some signal lamps contain an inner amber plastic enclosure between a colourless bulb and the colourless outer lens. With the development of high power amber LED lights, it is possible that filament bulbs for turn signals will be made obsolete within a few years.
Sequential turn signals
Sequential turn signals are a feature on some cars whereby multiple lights that produce the rear turn signal do not all flash on and off in phase. Rather, the horizontally arrayed lamps are illuminated sequentially: the innermost lamp lights and remains illuminated, the next outermost lamp lights and remains illuminated, followed by the next outermost lamp and so on until the outermost lamp lights briefly, at which point all lamps extinguish together and, after a short pause, the cycle begins again. The visual effect is one of outward motion in the direction of the intended turn or lane change. This implementation has generally been found only on American cars that use combination red rear stop and turn signal lamps.
Sequential turn signals were factory fitted to Ford Thunderbirds built between 1965 and 1971, inclusive, to Mercury Cougars between 1967 and 1973, to Shelby Mustangs between 1967 and 1970, to 1969 Imperials (division of Chrysler Corp), to the JDM 1971 Nissan Cedric, and to current Ford Mustangs. The system is costly and complex relative to standard turn signals, and no other production cars were so equipped.
Two different systems were employed. The earlier, fitted to the 1965 through 1968 Ford-built cars, was electro-mechanical, featuring an electric motor driving, through reduction gearing, a set of three slow-turning cams. These cams would actuate switches to turn on the lights in sequence so long as the turn signal switch was set. This system was complicated and prone to failure, and the units no longer function in many surviving cars. Later Ford cars and the 1969 Imperial used a transistorised control module with no moving parts.
FMVSS 108 has been officially interpreted as requiring all turn signal lights to illuminate simultaneously. However, the 2010 and newer Ford Mustangs are equipped with sequential turn signals.
Rear position lamps (tail lamps)
Night time vehicle conspicuity to the rear is provided by "rear position lamps" (also called "taillamps" or "tail lamps", "taillights" or "tail lights"). These are required to produce only red light, and to be wired such that they are lit whenever the front position lamps are illuminated—including when the headlamps are on. Rear position lamps may be combined with the vehicle's stop lamps, or separate from them. In combined-function installations, the lamps produce brighter red light for the stop lamp function, and dimmer red light for the rear position lamp function. The tail and stop light functions may be produced separately and/or by a dual-intensity lamp.
Regulations worldwide stipulate minimum intensity ratios between the bright (stop) and dim (tail) modes, so that a vehicle displaying rear position lamps will not be mistakenly interpreted as showing stop lamps, and vice versa.
Stop lamps (brake lights)
Red steady-burning rear lights, brighter than the rear position lamps, are activated when the driver applies the vehicle's brakes. These are called "stop lamps", or, colloquially, "brake lights". They are required to be fitted in multiples of two, symmetrically at the left and right edges of the rear of every vehicle. Outside North America, the range of acceptable intensity for a stop lamp containing one light source (e.g. bulb) is 60 to 185 candelas. In North America, the acceptable range for a single-compartment stop lamp is 80 to 300 candelas.
Centre High Mount Stop Lamp (CHMSL)
In North America since 1986, in Australia and New Zealand since 1990, and in Europe since 1998, a central brake lamp, mounted higher than the vehicle's left and right brake lamps and called a "Centre High Mount Stop Lamp (CHMSL)", is also required. The CHMSL (pronounced //) is also sometimes referred to as the "centre brake lamp", the "third brake light", the "eye-level brake lamp", the "safety brake lamp", or the "high-level brake lamp". The CHMSL may produce light by means of a single central filament bulb, a row or cluster of filament bulbs or LEDs, or a strip of Neon tube.
The CHMSL is intended to provide a deceleration warning to following drivers whose view of the vehicle's left and right stop lamps is blocked by interceding vehicles. It also helps to disambiguate brake vs. turn signal messages in North America, where red rear turn signals identical in appearance to stop lamps are permitted, and also can provide a redundant stop light signal in the event of a stop lamp malfunction.
The CHMSL is generally required to illuminate steadily and not permitted to flash, though U.S. regulators granted Mercedes-Benz a temporary, limited exemption to the steady-light requirement so as to evaluate whether a flashing CHMSL provides an emergency stop signal that effectively reduces the likelihood of a crash.
On passenger cars, the CHMSL may be placed above the back glass, affixed to the vehicle's interior just inside the back glass, or it may be integrated into the vehicle's deck lid or into a spoiler. Other specialised fitments are sometimes seen; the Jeep Wrangler and Land Rover Freelander have the CHMSL on a stalk fixed to the spare wheel carrier. Trucks, vans and commercial vehicles sometimes have the CHMSL mounted to the trailing edge of the vehicle's roof. The CHMSL is required by regulations worldwide to be centred laterally on the vehicle, though ECE R48 permits lateral offset of up to 15 cm if the vehicle's lateral centre is not coincident with a fixed body panel, but instead separates movable components such as doors. The Renault Master van, for example, uses a laterally offset CHMSL for this reason. The height of the CHMSL is also regulated, in absolute terms and with respect to the mounting height of the vehicle's conventional left and right stop lamps. Depending on the left and right lamps' height, the lower edge of the CHMSL may be just above the left and right lamps' upper edge.
The 1952 Volkswagen Bus was equipped with a center-mounted brake light in addition to the two conventional brake lights. The 1968 - 1971 Ford Thunderbird could be ordered with optional supplemental high-mounted stop and turn signal lights integrated into the left and right interior trim surrounding the backglass. The Oldsmobile Toronado from 1971 to 1978, and the Buick Riviera from 1974 to 1976 had similar dual high-mounted supplemental stop/turn lights as standard equipment; these were located on the outside of the vehicle below the bottom of the backglass. This type of configuration was not widely adopted at the time. Auto and lamp manufacturers in Germany experimented with dual high-mount supplemental stop lamps in the early 1980s, but this effort, too, failed to gain wide popular or regulatory support.
Early studies involving taxicabs and other fleet vehicles found that a third stop lamp reduced rear-end collisions by about 50%. The lamp's novelty probably played a role, since today the lamp is credited with reducing collisions by about 5%.
In 1986, the United States National Highway Traffic Safety Administration and Transport Canada mandated that all new passenger cars have a CHMSL installed. A CHMSL was required on all new light trucks and vans starting in 1994. CHMSLs are so inexpensive to incorporate into a vehicle that even if the lamps prevent only a few percent of rear end collisions they remain a cost-effective safety feature.
Emergency Stop Signal (ESS)
Toyota, Mercedes-Benz, Volvo, and BMW have released vehicles equipped to convey a special light signal when the vehicle is braked rapidly and severely. This is officially referred to as "Emergency Stop Signal", and ECE Regulation 48 calls for the lamps providing the ESS to flash at 4 Hz when a passenger car decelerates at greater than 6 m/s2 or a truck or bus decelerates at greater than 4 m/s2. Mercedes vehicles flash the stop lamps for the ESS, while vehicles from the Volkswagen Group of manufacturers (VW, Audi, SEAT & Skoda) flash the hazard flashers.
Other methods of severe-braking indication have also been implemented; some Volvo models make the stop lamps brighter, and some BMWs have "Adaptive Brake Lights" that effectively increase the size of the stop lights under severe braking by illuminating the tail lamps at brighter-than-normal intensity. As long as the brighter-than-normal stop lamps are within the regulated maximum intensity for stop lamps in general, this kind of implementation does not require specific regulatory approval since the stop lamps are under all conditions operating in accord with the general regulations on stop lamps.
The idea behind such emergency-braking indicator systems is to catch following drivers' attention with special urgency. However, there remains considerable debate over whether the system offers a measurable increase in safety performance. To date, studies of vehicles in service have not shown any significant such improvement. The systems used by BMW, Volvo, and Mercedes differ not only in operational mode (growing vs. intensifying vs. flashing, respectively), but also in such parameters as deceleration threshold of activation. Data are being collected and analyzed in an effort to determine how such a system might be implemented to maximise a safety benefit, if such a benefit can be realised with visual emergency braking displays. An experimental study at the University of Toronto  has tested stop lights which gradually and continuously grow in illuminated area with increasing vehicle deceleration rate (i.e., increasing brake application pressure).
One potentially problematic factor in the implementation of flashing stop lamps in North America is that North American regulations permit flashing stop lamps to be used in lieu of separate rear turn signal and hazard warning lamps.
Rear fog lamps
In Europe and other countries adhering to ECE Regulation 48, vehicles must be equipped with one or two bright red "rear fog lamps" (or "fog taillamps"), which serve as high-intensity rear position lamps to be energised by the driver in conditions of poor visibility to enhance vehicle conspicuity from the rear. The allowable range of intensity for a rear fog lamp is 150 to 300 candelas, which is within the range of a U.S. stop lamp. For this reason, some European vehicles imported to the United States have their rear fog lamps wired as stop lamps, since their European-specification stop lamps may not be sufficiently intense to comply with U.S. regulations, and in North America rear fog lamps are not required equipment. However, they are permitted, and are found almost exclusively on European-brand vehicles in North America — Audi, Jaguar, Mercedes, MINI, Land Rover, Porsche, Saab and Volvo provide functional rear fog lights on their North American models. The final generation Oldsmobile Aurora also had dual rear fog lights installed in the rear bumper as standard equipment.
Most jurisdictions permit rear fog lamps to be installed either singly or in pairs. If a single rear fog is fitted, most jurisdictions require it to be located at or to the driver's side of the vehicle's centreline — whichever side is the prevailing driver's side in the country in which the vehicle is registered. This is to maximise the sight line of following drivers to the rear fog lamp. In many cases, a single reversing lamp is mounted on the passenger side of the vehicle, positionally symmetrical with the rear fog. If two rear fog lamps are fitted, they must be symmetrical with respect to the vehicle's centreline. Proponents of twin rear fog lamps say two lamps provide vehicle distance information not available from a single lamp. Proponents of the single rear fog lamp say dual rear fog lamps closely mimic the appearance of illuminated stop lamps (which are mandatorily installed in pairs), reducing the conspicuity of the stop lamps' message when the rear fogs are activated. To provide some safeguard against rear fog lamps being confused with stop lamps, ECE R48 requires a separation of at least 10 cm between the closest illuminated edges of any stop lamp and any rear fog lamp.
To provide illumination to the rear when backing up, and to warn adjacent vehicle operators and pedestrians of a vehicle's rearward motion, each vehicle must be equipped with at least one rear-mounted, rear-facing reversing lamp (or "backup light"). These are currently required to produce white light by U.S. and international ECE regulations. However, some countries have at various times permitted amber reversing lamps. In Australia and New Zealand, for example, vehicle manufacturers were faced with the task of localising American cars originally equipped with combination red stop/turn signal lamps and white reversing lamps. Those countries' regulations permitted the amber rear turn signals to burn steadily as reversing lamps, so automakers and importers were able to combine the (mandatorily amber) rear turn signal and (optionally amber) reversing lamp function, and so comply with the regulations without the need for additional lighting devices. Both countries presently require white reversing lamps, so the combination amber turn/reverse lamp is no longer permitted on new vehicles. The U.S. state of Washington presently permits reversing lamps to emit white or amber light.
Rear registration plate lamp
The rear registration plate is illuminated by a white lamp designed to light the surface of the plate without creating white light directly visible to the rear of the vehicle; it must be illuminated whenever the position lamps are lit.
On large vehicles
Large vehicles such as trucks and buses are in many cases required to carry additional lighting devices beyond those required on passenger vehicles. The specific requirements vary according to the regulations in force where the vehicle is registered and/or operated.
In North America, vehicles over 2,032 mm (80 inches) wide must be equipped with three amber front and three red rear identification lamps spaced between 6 and 12 inches apart at the center of the front and rear of the vehicle, as high as practicable. The front identification lamps are typically mounted atop the cab of vehicles that do not have a flat-nose design. This type of identification lamp can also be found on road trains in Australia.
In North America, vehicles over 2,032 mm (80 inches) wide must be equipped with left and right amber front and red rear clearance lights to indicate the overall width of the vehicle. These must be amber at the front, red at the rear, and mounted as high as practicable.
End outline marker lamps
ECE Regulations require large vehicles to be equipped with left and right white front and red rear end outline marker lamps, which serve a purpose similar to that of the American clearance lamp.
Intermediate sidemarker lamps & reflectors
North American regulations require large vehicles to be equipped with left and right amber sidemarker lights and reflectors mounted midway between the front and rear sidemarkers.
Rear overtake lights
Until about the 1970s in France, Spain, Morroco, and possibly other countries, many commercial vehicles and some soviet road trains from "Sovtransavto" had a green light mounted on the rear offside. This could be operated by the driver to indicate that it was safe for the following vehicle to overtake.
Emergency warning devices
Also called "hazards", "hazard warning flashers", "hazard warning lights", "4-way flashers", or simply "flashers". International regulations require vehicles to be equipped with a control which, when activated, flashes the left and right directional signals, front and rear, all at the same time and in phase. This function is meant to indicate a hazard such as a vehicle stopped in or near moving traffic, a disabled vehicle, a vehicle moving substantially slower than the flow of traffic such as a truck climbing a steep grade, or the presence of stopped or slow traffic ahead on a high speed road. Sometimes, they are used in severe fog conditions. Operation of the hazard flashers must be from a control independent of the turn signal control, and an audiovisual tell-tale must be provided to the driver. In vehicles with a separate left and right green turn signal tell-tale on the dashboard, both left and right indicators may flash to provide visual indication of the hazard flashers' operation. In vehicles with a single green turn signal tell-tale on the dashboard, a separate red tell-tale must be provided for hazard flasher indication. Because the hazard flasher function operates the vehicle's left and right turn signals, a left or a right turn signal function cannot be provided while the hazard flashers are operating.
Red rear sidemarker retroreflectors on Ford F-series trucks without (top) and with (bottom) direct illumination
"Retroreflectors" (also "reflex reflectors") produce no light of their own, but rather reflect incident light back towards its source, e.g., another driver's headlight. They are regulated as automotive lighting devices, and specified so as to account for the separation between a vehicle's headlamps and its driver's eyes. Thus, vehicles are conspicuous even when their electrically powered lighting system is off or disabled. Regulations worldwide require each vehicle to be equipped with rear-facing red retroreflectors. Since 1968 North American regulations also require side-facing retroreflectors, amber in front and red in the rear. Sweden, South Africa and other countries have at various times required white front-facing retroreflectors.
Multicolour auxiliary signals
Some jurisdictions, such as the US states of Oregon and Idaho, permit vehicles to be equipped with auxiliary rear signal systems displaying green light when the accelerator is depressed, yellow light when the vehicle is coasting, and red light when the brake is depressed. Such systems have in the past been sold as aftermarket accessories, but are today seldom seen in traffic.
Research and development
The US National Highway Traffic Safety Administration, among other bodies, has commissioned studies of these and many other vehicle signal systems and configurations, in an effort to determine the most promising avenues and best practices for enhanced crash avoidance via optimised vehicle conspicuity and signal lighting systems.
Most cars have at least one "dome light" (UK, courtesy light) located in or near the ceiling of the passenger compartment, to provide illumination by which to fasten seatbelts and enter or exit the car. These often have an option to switch on when the front (or any) passenger doors are opened. Many vehicles have expanded this feature, causing the overhead interior light to remain on after all doors are closed, allowing passengers to fasten seat belts with added illumination. The extended lighting cycle usually ends when the vehicles ignition has begun, or a gradual reduction in light emitted after a couple of minutes if the car isn't started, called "theater" lighting. Interior lighting has been added on some vehicles at the bottom edge of the dashboard, which illuminate the floor for front passengers (which are referred to in the US as "courtesy lights"), or underneath the front seats at the rear, to illuminate the floor for rear seat passengers. This type of convenience lighting approach is also sometimes used to illuminate interior or exterior door handles, exterior step running boards, or electric window switches.
LED light sources are beginning to appear increasingly as interior convenience lights in various locations as the technology becomes more widely used, especially with finely focused lighting on console control surfaces and in cabin storage areas.
There may be additional map lights that are aimed at specific passenger positions, that allow for reading without particular glare distraction to the driver. Some vehicles have "approach lighting" (puddle lights) integrated into the exterior mirrors or lower edges of the doors, as well as activating interior lighting, that is activated via key fob. Many cars have lights in the trunk (or boot), the engine compartment, and the glovebox and other storage compartments.
Most instruments and controls on a dashboard in modern vehicles are illuminated in some fashion when the headlamps are turned on, and the intensity of light can be adjusted by the driver for comfort. Saabs feature an aerospace technologies-derived "night panel" function which shuts off all interior illumination save for the speedometer (unless attention is called to a critical situation on another gauge) to improve the driver's night vision.
On service vehicles
Emergency vehicle lights
Emergency vehicles such as fire engines, ambulances, police cars, snow-removal vehicles and tow trucks are usually equipped with intense warning lights of particular colours. These may be motorised rotating beacons, xenon strobes, or arrays of LEDs. The prescribed colours differ by jurisdiction; in most countries, blue and/or red special warning lamps are used on police, fire, and medical-emergency vehicles. In North America and some other jurisdictions, amber lights are for tow trucks, private security personnel, construction vehicles, and other nonofficial special-service vehicles, while volunteer firefighters use red, blue, or green, depending on jurisdiction. In the UK, doctors may use green warning lamps. Special warning lights, usually amber, are also sometimes mounted on slow vehicles such as mobile cranes, excavators, tractors, and even mobility scooters in certain conditions.
Taxicabs are distinguished by special lights according to local regulations. They may have an illuminated "Taxi" sign, a light to signal that they are ready to take passengers or off duty, and/or an emergency panic light the driver can activate in the event of a robbery to alert passersby to call the police.
Construction and technology
Incandescent light bulbs
Traditionally, an tungsten incandescent light bulb has been the light source used in all of the various automotive signalling and marking lamps. Typically, bulbs of 21 to 27 watts, producing 280 to 570 lumens (22 to 45 mean spherical candlepower) are used for stop, turn, reversing and rear fog lamps, while bulbs of 4 to 10 W, producing 40 to 130 lm (3 to 10 mscp) are used for tail lamps, parking lamps, sidemarker lamps and side turn signal repeaters. These bulbs typically have either a metal bayonet base or a plastic or glass wedge base for the physical and electrical interface with the lamp socket.
Tungsten-halogen light bulbs are a very common light source for headlamps and other forward illumination functions. Some recent-model vehicles use small halogen bulbs for exterior signalling and marking functions, as well. The first halogen lamp approved for automotive use was the H1, which was introduced in Europe in 1962.
The devices popularly called "Xenon headlamps" are formally known as high-intensity discharge, or HID lamps.
Xenon is currently the lamp used in single-source lighting systems being developed for automotive use. In these systems, a single light source sends light via optical fibers to wherever it is needed in the automobile. This development, known as distributive lighting, is already appearing in the interior lighting features, for example the Ford Mustang's interior lighting. In an expanded system, the light could be channeled to the side mirrors for example, which would act as forward driving lights that could be made to swivel in position with the car as it turns. The headlight pattern would not be limited to individual overlapping beams, but could be channeled by electronic controls of the fiber optics to provide optimum visibility over an extended range of driving conditions including fog, dust or snow. Individual lamps would not be needed, just a mounting point for the optical fibers running back to the single light source and computer controlled for colour, intensity and continuity.
Neon lamp tubes were introduced into widespread production for the CHMSL on the 1995 Ford Explorer, and notable later uses included the 1998 Lincoln Mark VIII, with a neon tube spanning the width of the trunk decklid, and the BMW Z8, which made extensive use of neon. Numerous concept cars have included neon lamp features, from such manufacturers as Volvo. Hella offered an aftermarket neon CHMSL in the late 1990s.
The linear packaging of the neon light source lends itself to the linear packaging favored for many CHMSL installations, and neon lights offer the same nearly instant rise time benefit as LEDs. However, neon tubes require an expensive and relatively power-hungry ballast (power supply unit), and as a result, neon lights have not found significant long-term popularity as sources of light for automotive signaling.
Light emitting diodes (LED)
LEDs are being used with increasing frequency in automotive lamps. They offer very long service life, extreme vibration resistance, and can permit considerably shallower packaging compared to most bulb-type assemblies. LEDs also offer a significant safety performance benefit when employed in stop lights, for when power is applied they rise to full intensity approximately 200 milliseconds (0.2 seconds) faster than incandescent bulbs. This fast rise time not only improves the attentional conspicuity of the stop lamp, but also provides following drivers with increased time in which to react to the appearance of the stop lamps.
LEDs were first applied to automotive lighting in Centre High Mount Stop Lamps (CHMSL), beginning in the late 1980s. Adoption of LEDs for other signal functions on passenger cars has been slow, but is beginning to increase with demand for the technology and related styling updates. The 2007 Audi R8 sports car uses two strips of optically-focused high-intensity LEDs for its Daytime Running Lamps. Optional on the R8 in ECE markets is the world's first LED headlamp made by AL-Automotive Lighting. The low and high beams along with the position (parking) lamp and front turn signal are all realised with LEDs. The Lexus LS 600h features LED low beam, position and sidemarker lamps in North America, and the 2009 Cadillac Escalade Platinum uses LEDs for the low and high beams, as well as for the position and sidemarker lamps.
The commercial vehicle industry has rapidly adopted LEDs for virtually all signaling and marking functions on trucks and buses, because in addition to the fast rise time and concomitant safety benefit, LEDs' extremely long service life reduces vehicle downtime. Almost all commercial vehicles use exterior lighting devices of standardised format and fitment, which has cost-reduced and sped the changeover.
LED lamps have been proven to be a feasible alternative to traditional light sources for flashing beacon lights on vehicles such as maintenance trucks. Previously, traditional light sources required the engine to continue running to ensure that the battery would not get worn out if the lights were to be used for more than a few hours. The energy-efficient nature of the LED source allows the engine to remain turned off but the light to continue to flash.
Variable-intensity signal lamps
Internationalised ECE regulations explicitly permit vehicle signal lamps with intensity automatically increased during bright daylight hours when sunlight reduces the effectiveness of the stop lamps, and automatically decreased during hours of darkness when glare could be a concern. Both US and ECE regulations contain provisions for determining the minimum and maximum acceptable intensity for lamps that contain more than a single light source.
- Automotive lamp types
- Daytime running lamp
- Twilight Sentinel
- Federal Motor Vehicle Safety Standard 108
- Florence Lawrence - inventor of the first turn and stop signals
- Hidden headlamps
- Lighting-up time
- National Highway Traffic Safety Administration (NHTSA)
- Turn indicator stalk
- Windscreen wiper
- World Forum for Harmonization of Vehicle Regulations
- ^ 1949 Vienna Convention on Road Traffic, lighting prescriptions
- ^ "U.N. Convention on Road Traffic (1968)" (PDF). http://www.fileden.com/files/2009/9/30/2589169//road1968.pdf. Retrieved 2011-05-14.
- ^ a b PDF (313 KB)
- ^ a b PDF (843 KB)
- ^ a b c d e f g h i j k l m n o p q r s t u v w PDF (2.00 MB)
- ^ Rumar, Kåre (2000). Relative merits of the U.S. and ECE high-beam maximum intensities and of two- and four-headlamp systems. UMTRI. http://hdl.handle.net/2027.42/49438.
- ^ ECE R113, "Motor vehicle headlamps emitting a symmetrical passing beam or a driving beam or both and equipped with filament lamps"
- ^ "SAE Standard J581, "Auxiliary Upper Beam Lamps"". Sae.org. http://www.sae.org/technical/standards/J581_200407. Retrieved 2010-11-24.
- ^ Reglamento General de Tránsito-Asunción, Artículo 180 (General Traffic Regulations-Asuncion, Article 180 — Spanish language)
- ^ "SAE Standard J583, "Front Fog Lamps"". Sae.org. 2005-09-08. http://www.sae.org/technical/standards/J583_200509. Retrieved 2010-11-24.
- ^ ECE R19, "Front Fog Lamps, Part 1"
- ^ ECE R19, "Front Fog Lamps, Part 2"
- ^ "What Are Fog Lamps Really For?". Daniel Stern Lighting. http://www.danielsternlighting.com/tech/lights/fog_lamps/fog_lamps.html. Retrieved 14 August 2006.
- ^ Sivak, M.; Flannagan, M.J.; Traube, E.C.; Hashimoto, H.; Kojima, S. (1997) (paper, PDF). Fog Lamps: Frequency of Installation and Nature of Use. SAE 970657. Society of Automotive Engineers. http://www.sae.org/technical/papers/970657. Retrieved 14 August 2006.
- ^ a b c d e f g h i j k l m n o p q r s t u v w x y z ECE R48, "Installation of lighting and light-signalling devices on motor vehicles"
- ^ "SAE Standard J852, "Front Cornering Lamps for Use on Motor Vehicles"". Sae.org. http://www.sae.org/technical/standards/J852_200104. Retrieved 2010-11-24.
- ^ "SAE Standard J1373, "Rear Cornering Lamps for Use on Motor Vehicles Less than 9.1 m in Overall Length"". Sae.org. http://www.sae.org/technical/standards/J1373_200605. Retrieved 2010-11-24.
- ^ "E/ECE/324" (PDF). http://www.unece.org/trans/main/wp29/wp29regs/r119e.pdf. Retrieved 2010-11-24.
- ^ "Sidelight definition". Ldoceonline.com. http://www.ldoceonline.com/dictionary/sidelight. Retrieved 2010-11-24.
- ^ a b "Microsoft Word - 660-redMTr.doc" (PDF). http://www.swov.nl/rapport/R-2003-28.pdf. Retrieved 2010-11-24.
- ^ Reid, J.A. (1978). "LILAC--Low Intensity Large Area City light" (Hardcopy). International Technical Conference on Experimental Safety Vehicles: 675–80. http://mirlyn.lib.umich.edu/F/?func=direct&doc_number=005472646&local_base=UMTRI_PUB. Retrieved 18 July 2009.
- ^ "SAE Standard J222:Parking Lamps (Front Position Lamps)". Sae.org. 2006-12-11. http://www.sae.org/technical/standards/J222_200612. Retrieved 2010-11-24.
- ^ "StVZO §51c Parkleuchten, Park-Warntafeln" (PDF). http://www.axperts.de/WebRoot/Store16/Shops/61480327/487D/C182/0AE1/2134/2A5C/C0A8/28BA/36F7/StVZO.pdf. Retrieved 2010-11-24.
- ^ "ECE Regulation 87, Revision 2: Daytime running lamps" (PDF). http://www.unece.org/trans/main/wp29/wp29regs/r087r2e.pdf. Retrieved 2010-11-24.
- ^ "NHTSA Docket 3319 for DRL Glare Complaints". DOT Docket Management System. US Department of Transportation. 9 January 1998. http://dms.dot.gov/search/searchResultsAdvanced.cfm?docketNumber=3319&searchType=document. Retrieved 14 August 2006.
- ^ "NHTSA Docket 4124, Rulemaking to Reduce DRL Glare (aborted), with public complaints". DOT Docket Management System. US Department of Transportation. 7 August 1998. http://dms.dot.gov/search/searchResultsAdvanced.cfm?docketNumber=4124&searchType=document. Retrieved 14 August 2006.
- ^ a b c Gaynor, Mark. "UK Dim-Dip Running Lights Regulatory History". D. Stern. http://dastern.torque.net/techdocs/dimdip.html. Retrieved 14 August 2006.
- ^ I.l.p.e.. "Memorandum submitted by the Institution of Public Lighting Engineers". D. Stern. http://dastern.torque.net/techdocs/DimDip2.html. Retrieved 14 August 2006.
- ^ a b Kahane, Charles J. (1983-07). "An Evaluation of Side Marker Lamps For Cars, Trucks, and Buses". DOT HS 806 430. Washington, DC: National Highway Traffic Safety Administration. http://www.nhtsa.dot.gov/Cars/rules/regrev/evaluate/806430.html. Retrieved 18 July 2009.
- ^ "Flashing Sidemarker Lamps". Daniel Stern Lighting. 12 December 2002. http://www.danielsternlighting.com/tech/markerflash/markerflash.html. Retrieved 14 August 2006.
- ^ "Upgraded Mazda Axela On Sale in Japan" (Press release). Mazda. 22 November 2005. http://www.webcitation.org/5yuFFQhSR. Retrieved 22 December 2006.
- ^ U.S. Patent 912,831
- ^ U.S. Patent 2,122,508
- ^ Flannagan, M.J.; Reed, M.P. (2005) (paper, PDF). Geometric Visibility of Mirror-Mounted Turn Signals. Ref 2005-01-0449. Society of Automotive Engineers. http://www.sae.org/technical/papers/2005-01-0449. Retrieved 14 August 2006.
- ^ a b "NHTSA official interpretation of FMVSS 108 in re sequential turn signals". Isearch.nhtsa.gov. 1988-09-01. http://isearch.nhtsa.gov/files/00473.ztv.html. Retrieved 2010-11-24.
- ^ Ronald Cuomo (June 2003). "Talking Technical: Bus Directional/Signals Lights (PDF)" (PDF). The Leader - Department of Buses newsletter (New York: New York City Transit Authority Department of Buses): 7. http://retiree.nyct.com/newsletrs/l0603.pdf. Retrieved 12 July 2008.
- ^ Popular Science magazine, April 1962, p. 70
- ^ Popular Mechanics magazine, August 1962, pp. 70, 182
- ^ Rockwell, T. H., Safford, R. R. (1969): An evaluation of rear-end signal system characteristics in night driving, pp. 12-13, 17, 33, 41-42
- ^ Allen, M. J. (1964): Misuse of red light on automobiles, pp 2-3
- ^ Popular Science magazine, June 1961, p. 40
- ^ a b Hitzemeyer, E.G.; Wilde, H.; Ellenburger, D (1977) (paper). What Color Should Rear Turn Signals Be?. Society of Automotive Engineers. http://www.sae.org/technical/papers/770812.
- ^ Taylor, G.W.; Ng, W.K. (1981) (paper). Measurement of Effectiveness of Rear-Turn-Signal Systems in Reducing Vehicle Accidents From An Analysis of Actual Accident Data. Ref # 810192. Society of Automotive Engineers. http://www.sae.org/technical/papers/810192.
- ^ [Effects of Turn-Signal Colour on Reaction Times to Brake Signals "Umtri 60502"] (journal article). Ergonomics (UMTRI, Taylor & Francis) 40 (1): 62–68. 1997-01. doi:10.1080/001401397188378. Effects of Turn-Signal Colour on Reaction Times to Brake Signals. Retrieved 14 August 2006.
- ^ Van Iderstine, Richard (4 November 2004). "Washington Post Online". Vehicle Lighting (Washington Post). http://www.washingtonpost.com/wp-dyn/articles/A37484-2004Nov9.html. Retrieved 14 August 2006.
- ^ D'orleans, G. (1997) (paper). World Harmonization and Procedures for Lighting and Signaling Products. Society of Automotive Engineers. http://www.sae.org/technical/papers/970913.
- ^ PDF (527 KB)
- ^ Allen, Kirk (2009) (PDF). The Effectiveness of Amber Rear Turn Signals for Reducing Rear Impacts. National Highway Traffic Safety Administration. http://www-nrd.nhtsa.dot.gov/Pubs/811115.PDF.
- ^ Sivak, M.; Schoettle, B.; Flannagan, M. J.; Minoda, T. (1998) (paper). [Effectiveness of clear-lens turn signals in direct sunlight umtri 98926]. UMTRI # 98926. UMTRI. Effectiveness of clear-lens turn signals in direct sunlight.
- ^ PDF (114 KB)
- ^ PDF (1.78 MB)
- ^ PDF (76.4 KB)
- ^ "NHTSA official interpretation of FMVSS 108 in re simultaneity of lamp illumination". Isearch.nhtsa.gov. 1988-09-01. http://isearch.nhtsa.gov/files/3157o.html. Retrieved 2010-11-24.
- ^ "2010 MUSTANG Reviews Industry Expert Review". fordvehicles.com. http://www.fordvehicles.com/cars/mustang/reviews/review-details/?id=148. Retrieved 7 July 2009.
- ^ "What are LED taillights?". Ask.cars.com. 16 September 2008. http://ask.cars.com/2008/09/what-are-led-ta.html. Retrieved 1 May 2009.
- ^ UN Regulation 7: Front and rear position lamps, stop lamps and end-outline marker lamps
- ^ UK MOT vehicle inspection manual
- ^ SAE J586: Stop Lamps for Vehicles Less Than 2032mm in Width
- ^ a b "New Zealand vehicle inspection requirements manual, sec. 4". Ltsa.govt.nz. http://www.ltsa.govt.nz/certifiers/virm-in-service/general-04-v3a5.pdf. Retrieved 2010-11-24.
- ^ India vehicle safety standards
- ^ "NHTSA denial of petition for flashing CHMSL". Regulations.justia.com. http://regulations.justia.com/view/12906/. Retrieved 2010-11-24.
- ^ "NHTSA explication of requirement for stop lamps to burn steadily". http://www.regulations.gov/fdmspublic/ContentViewer?objectId=090000648031b2f8&disposition=attachment&contentType=pdf. Retrieved 2010-11-24.
- ^ NHTSA grants MBUSA limited permission for flashing CHMSL
- ^ Gaudean, George J (1996-12). Motor Vehicle Lighting. SAE International. ISBN 978-1560917533.
- ^ a b [http://automotivemileposts.com/autobrevity/highlevelrearlamps.html Automotive Mile Posts: High Level Rear Lamps[
- ^ 1968 Ford Thunderbird optional equipment
- ^ Popular Mechanics, October 1970: "'71 Cars: GM's Family Movers"
- ^ Burghoff, Wilhelm; et al (1999). 100 Years of Hella : From a Lamp Workshop to Global Supplier to the Automobile Industry (1899-1999). Management Board of Hella KG Hueck & Co.. ISBN B000JP6DB6.
- ^ a b Kahane, Charles J. and Hertz, Ellen (1998). "NHTSA Technical Report Number DOT HS 808 696: The Long-Term Effectiveness of Center High Mounted Stop Lamps in Passenger Cars and Light Trucks". http://www.nhtsa.dot.gov/cars/rules/regrev/evaluate/808696.html. Retrieved 26 April 2006.
- ^ "The All-New Volvo S80" (PDF). Volvo Cars of North America. Archived from the original on 18 March 2007. http://web.archive.org/web/20070318042224/http://www.volvocars.us/NR/rdonlyres/3067E89B-F748-4121-95CD-DE7A95190ED1/38998/MY07S80US.pdf. Retrieved 25 March 2007.
- ^ NHTSA analysis of flashing central 3rd stop light ideas, U.S. Federal Register, 1st page[dead link]
- ^ PDF (653 KB)
- ^ "NHTSA response to MBUSA petition". http://www.regulations.gov/fdmspublic/ContentViewer?objectId=09000064802afc33&disposition=attachment&contentType=pdf. Retrieved 2010-11-24.
- ^ "RCW 46.37.100: Color of clearance lamps, side marker lamps, back-up lamps, and reflectors". Apps.leg.wa.gov. http://apps.leg.wa.gov/RCW/default.aspx?cite=46.37.100. Retrieved 2010-11-24.
- ^ "ECE Regulation 4:Illumination of Rear Registration Plates of Motor Vehicles" (PDF). http://www.unece.org/trans/main/wp29/wp29regs/r004r2a3e.pdf. Retrieved 2010-11-24.
- ^ "SAE J910:Hazard Warning Signal Switch". Sae.org. 1988-10-01. http://www.sae.org/technical/standards/J910_198810. Retrieved 2010-11-24.
- ^ "SAE J1690:Flashers". Sae.org. 1996-08-01. http://www.sae.org/technical/standards/J1690_199608. Retrieved 2010-11-24.
- ^ "Oregon Revised Statutes, 2007". Law. Oregon State Legislature. http://landru.leg.state.or.us/ors/816.html#816.160. Retrieved 9 November 2008.
- ^ State of Idaho. "Idaho Statutes". Law. State of Idaho. http://www3.state.id.us/cgi-bin/newidst?sctid=490090021.K. Retrieved 9 November 2008.
- ^ National Highway Traffic Safety Administration, Virginia Tech Transportation Institute. [Avoidance/2002/Task 1 Report.pdf "Enhanced Rear Lighting And Signaling Systems: Literature Review and Analyses of Alternative System Concepts"] (PDF). US Department of Transportation. Avoidance/2002/Task 1 Report.pdf. Retrieved 9 September 2010.
- ^ Bullough, John; Nicholas P Skinner (2009-12). "Evaluation of Light-Emitting Diode Beacon Light Fixtures" (PDF). Lighting Research Center - Rensselaer Polytechnic Institute. http://www.nysdot.gov/divisions/engineering/technical-services/trans-r-and-d-repository/LRCBeaconReport.pdf. Retrieved 5 June 2010.
- ^ "The Long and Lighted Road: Lighting and Driving | Lighting Futures | Programs | LRC". Lrc.rpi.edu. http://www.lrc.rpi.edu/programs/futures/lf-auto/. Retrieved 2010-11-24.
- ^ "Designing Advanced Automotive Illumination Systems". Ptbmagazine.com. http://www.ptbmagazine.com/NOV99/ptb.1199auto.html. Retrieved 2010-11-24.
- ^ "First Full-LED Headlamp for Audi R8". germancarscene.com. http://germancarscene.com/2008/05/30/first-full-led-headlamp-for-the-audi-r8/. Retrieved 12 July 2008.
- ^ Bullough, J. D. and N. P. Skinner. 2009. Evaluation of Light-Emitting Diode Beacon Light Fixtures [report to the New York State Department of Transportation]. Albany, NY: New York State Department of Transportation. See online at: www.rpi.edu/programs/transportation/projects/LEDbeacon.asp [accessed 28 May 2010]
- Sidemarkers, flashing and non-flashing
- Turn signal patent, issued 1909
- Car Lights Flash Warning Signals 1951 article on first Hazard Flashers
Automotive design Part of the Automobile series BodyCompartmentsOther Exterior
equipmentLightingLegal and other
equipmentBackup camera • Boost gauge • Buzzer • Carputer • Electronic instrument cluster • Fuel gauge • Global Positioning System and Automotive navigation system • Head-up display • Idiot light • Malfunction Indicator Lamp • Night vision • Odometer • Radar detector • LIDAR detector • Speedometer • Tachometer • Trip computerControlsTheft deterrenceOther
Portal • Category
Wikimedia Foundation. 2010.
Look at other dictionaries:
Automotive Lighting — Reutlingen GmbH Tipo Filial de Magneti Marelli Fundación 1999 Sede Reutlingen … Wikipedia Español
Automotive Lighting — Reutlingen GmbH Rechtsform Gesellschaft mit beschränkter Haftung Gründung 1999 … Deutsch Wikipedia
Automotive Lighting — AL Automotive Lighting a été créée en 1999 suite à une coentreprise entre le groupe italien Magneti Marelli division Eclairage et l allemand Robert Bosch GmbH (K2 Lighting division). AL Automotive Lighting modifier … Wikipédia en Français
Lighting — Not to be confused with lightning. For other uses, see lighting (disambiguation). Low intensity lighting and haze in a concert hall allows laser effects to be visible … Wikipedia
Automotive Components Holdings — Automotive Components Holdings, LLC (ACH) is a wholly owned subsidiary of Ford Motor Company, formed by the 2005 transfer of 17 automotive components factories and 6 research, testing, and other facilities from Visteon Corporation to Ford Motor… … Wikipedia
Automotive battery — 12 V, 40 Ah Lead acid car battery An automotive battery is a type of rechargeable battery that supplies electric energy to an automobile. Usually this refers to an SLI battery (starting, lighting, ignition) to power the starter motor … Wikipedia
Automotive navigation system — A taxi equipped with GPS navigation device An automotive navigation system is a satellite navigation system designed for use in automobiles. It typically uses a GPS navigation device to acquire position data to locate the user on a road in the… … Wikipedia
Automotive molding — Chevrolet C/K with Body side molding Automotive molding (or car body molding) are decorative and protective moldings on the car body. The term applies both to the detail and the material. Car moldings include side body molding, lower body molding … Wikipedia
Automotive design terminology — A glossary of terms as relating to automotive design.Some terms may be found at car body style. NOTOC 0 9;1 box form: A categorization based on overall form design using rough rectangle volumes. In the case of the 1 box, it is a single continuous … Wikipedia
Emergency vehicle lighting — refers to any of several visual warning devices, which may be known as light bars or beacons, fitted to a vehicle and used when the driver wishes to convey to other road users the urgency of their journey, to provide additional warning of a… … Wikipedia