On roads Retroreflection (sometimes called retroflection) is used on
road surfaces,
road signs,
vehicles, and
clothing (large parts of the surface of special
safety clothing, less on regular coats). When the headlights of a car illuminate a retroreflective surface, the reflected light is directed towards the car and its driver (rather than in all directions as with diffuse
reflection). However, a
pedestrian can see retroreflective surfaces in the dark only if there is a light source directly between them and the reflector (e.g., via a flashlight they carry) or directly behind them (e.g., via a car approaching from behind). "
Cat's eyes" are a particular type of retroreflector embedded in the road surface and are used mostly in the UK and parts of the
United States. Corner reflectors are better at sending the light back to the source over long distances, while spheres are better at sending the light to a receiver somewhat off-axis from the source, as when the light from
headlights is reflected into the driver's
eyes. Retroreflectors can be embedded in the road (level with the road surface), or they can be raised above the road surface.
Raised reflectors are visible for very long distances (typically 0.5–1
kilometer or more), while sunken reflectors are visible only at very close ranges due to the higher angle required to properly reflect the light. Raised reflectors are generally not used in areas that regularly experience snow during winter, as passing
snowplows can tear them off the roadways. Stress on roadways caused by cars running over embedded objects also contributes to accelerated wear and
pothole formation. Retroreflective road paint is thus very popular in
Canada and parts of the United States, as it is not affected by the passage of snowplows and does not affect the interior of the roadway. Where weather permits, embedded or raised retroreflectors are preferred as they last much longer than road paint, which is weathered by the elements, can be obscured by sediment or rain, and is ground away by the passage of vehicles.
For signs on highway signs and pavement markings For traffic signs and vehicle operators, the light source is a vehicle's headlights, where the light is sent to the traffic sign face and then returned to the vehicle operator. Retroreflective traffic sign faces are manufactured with glass beads or prismatic reflectors embedded in a base sheeting layer so that the face reflects light, therefore making the sign appear more bright and visible to the vehicle operator under darkened conditions. According to the United States
National Highway Traffic Safety Administration (NHTSA), the Traffic Safety Facts 2000 publication states the fatal crash rate is 3-4 times more likely during nighttime crashes than daytime incidents. A misconception many people have is that retroreflectivity is only important during night-time travel. However, in recent years, more states and agencies require that headlights be turned on in inclement weather such as rain and snow. According to the United States
Federal Highway Administration (FHWA): Approximately 24% of all vehicle accidents occur during adverse weather (rain, sleet, snow and fog). Rain conditions account for 47% of weather-related accidents. These statistics are based on 14-year averages from 1995 to 2008. The FHWA's
Manual on Uniform Traffic Control Devices requires that signs be either illuminated or made with retroreflective sheeting materials, and though most signs in the U.S. are made with retroreflective sheeting materials, they degrade over time. Until now, there has been little information available to determine how long the retroreflectivity lasts. The MUTCD now requires that agencies maintain traffic signs to a set of minimum levels but provide a variety of maintenance methods that agencies can use for compliance. The minimum retroreflectivity requirements do not imply that an agency must measure every sign. Rather, the new MUTCD language describes methods that agencies can use to maintain traffic sign retroreflectivity at or above the minimum levels. In
Canada,
aerodrome lighting can be replaced by appropriately colored retroreflectors, the most important of which are the white retroreflectors that delineate the runway edges, and must be seen by aircraft equipped with landing lights up to 2 nautical miles away.
Ships, boats, emergency gear Retroflective tape is recognized and recommended by the International Convention for the Safety of Life at Sea (
SOLAS) because of its high reflectivity of both light and
radar signals. Application to
life rafts, personal flotation devices, and other safety gear makes it easy to locate people and objects in the water at night. When applied to boat surfaces it creates a larger
radar signature—particularly for fiberglass boats, which produce very little radar reflection on their own. It conforms to International Maritime Organization regulation, IMO Res. A.658 (16) and meets U.S. Coast Guard specification 46 CFR Part 164, Subpart 164.018/5/0. Examples of commercially available products are 3M part numbers 3150A and 6750I, and Orafol Oralite FD1403.
Surveying In
surveying, a retroreflector—usually referred to as a
prism—is normally attached on a
surveying pole and is used as a target for
distance measurement, for example, a
total station. The instrument operator or robot aims a
laser beam at the retroreflector. The instrument measures the propagation time of the light and converts it to a distance. Prisms are used with survey and 3D point monitoring systems to measure changes in horizontal and vertical position of a point. Two prisms may also serve as targets for
angle measurements, using total stations or simpler
theodolites; this usage, reminiscent of the
heliotrope, does not involve retroreflection per se, it only requires visibility by means of any source of illumination (such as the sun) for direct sighting to the center of the target prism as seen from the optical instrument.
In space On the Moon Astronauts on the
Apollo 11,
14, and
15 missions left retroreflectors on the
Moon as part of the
Lunar Laser Ranging Experiment. The
Soviet Lunokhod 1 and
Lunokhod 2 rovers also carried smaller arrays. Reflected signals were initially received from
Lunokhod 1, but no return signals were detected from 1971 until 2010, at least in part due to some uncertainty in its location on the Moon. In 2010, it was found in
Lunar Reconnaissance Orbiter photographs and the retroreflectors have been used again. ''Lunokhod 2's'' array continues to return signals to Earth. Even under good viewing conditions, only a single reflected photon is received every few seconds. This makes the job of filtering laser-generated photons from naturally occurring photons challenging.
Vikram lander of
Chandrayaan-3 left Laser Retroreflector Array (LRA) instrument supplied by
NASA's
Goddard Space Flight Center as part of international collaboration with
ISRO. On 12 December 2023,
Lunar Reconnaissance Orbiter was successfully able to detect transmitted laser pulses from Vikram lander.
On Mars A similar device, the
Laser Retroreflector Array (LaRA), has been incorporated in the Mars
Perseverance rover. The retroreflector was designed by the
National Institute for Nuclear Physics of Italy, which built the instrument on behalf of the
Italian Space Agency. - LaRA - (artwork)
In satellites Many
artificial satellites carry retroreflectors so they can be tracked from
ground stations. Some satellites were built solely for laser ranging.
LAGEOS, or Laser Geodynamics Satellites, are a series of scientific research satellites designed to provide an orbiting laser ranging benchmark for geodynamical studies of the Earth. There are two LAGEOS spacecraft: LAGEOS-1 (launched in 1976), and LAGEOS-2 (launched in 1992). They use cube-corner retroreflectors made of fused silica glass. As of 2020, both LAGEOS spacecraft are still in service. Three
STARSHINE satellites equipped with retroreflectors were launched beginning in 1999. The
LARES satellite was launched on February 13, 2012. (See also:
List of laser ranging satellites.) Other satellites include retroreflectors for orbit calibration and orbit determination, such as in
satellite navigation (e.g., all
Galileo satellites, most
GLONASS satellites,
IRNSS satellites,
BeiDou,
QZSS, and two
GPS satellites) as well as in
satellite gravimetry (
GOCE)
satellite altimetry (e.g.,
TOPEX/Poseidon,
Sentinel-3). Retroreflectors can also be used for inter-satellite laser ranging instead of ground-tracking (e.g.,
GRACE-FO). The
BLITS (Ball Lens In The Space) spherical retroreflector satellite was placed into orbit as part of a September 2009 Soyuz launch by the
Federal Space Agency of Russia with the assistance of the
International Laser Ranging Service, an independent body originally organized by the
International Association of Geodesy, the
International Astronomical Union, and international committees. The ILRS central bureau is located at the United States'
Goddard Space Flight Center. The reflector, a type of
Luneburg lens, was developed and manufactured by the Institute for Precision Instrument Engineering (IPIE) in Moscow. The mission was interrupted in 2013 after a collision with
space debris.
Free-space optical communication Modulated retroreflectors, in which the reflectance is changed over time by some means, are the subject of research and development for
free-space optical communications networks. The basic concept of such systems is that a low-power remote system, such as a sensor mote, can receive an optical signal from a base station and reflect the modulated signal back to the base station. Since the base station supplies the optical power, this allows the remote system to communicate without excessive power consumption. Modulated retroreflectors also exist in the form of modulated phase-conjugate mirrors (PCMs). In the latter case, a "time-reversed" wave is generated by the PCM with temporal encoding of the phase-conjugate wave (see, e.g., SciAm, Oct. 1990, "The Photorefractive Effect," David M. Pepper,
et al.). Inexpensive corner-aiming retroreflectors are used in user-controlled technology as optical datalink devices. Aiming is done at night, and the necessary retroreflector area depends on aiming distance and ambient lighting from street lamps. The optical receiver itself behaves as a weak retroreflector because it contains a large, precisely focused
lens that detects illuminated objects in its focal plane. This allows aiming without a retroreflector for short ranges.
Other uses Retroreflectors are used in the following example applications: • In common (non-SLR) digital cameras, the sensor system is often retroreflective. Researchers have used this property to demonstrate a system to prevent unauthorized photographs by detecting digital cameras and beaming a highly focused beam of light into the lens. • In movie screens to allow for high brilliance under dark conditions. •
Digital compositing programs and
chroma key environments use retroreflection to replace traditional lit backdrops in composite work as they provide a more solid color without requiring that the backdrop be lit separately. • In Longpath-
DOAS systems retroreflectors are used to reflect the light emitted from a lightsource back into a telescope. It is then spectrally analyzed to obtain information about the trace gas content of the air between the telescope and the retro reflector. •
Barcode labels can be printed on retroreflective material to increase the range of scanning up to 50 feet. • In a form of
3D display; where a
retro-reflective sheeting and a set of projectors is used to project stereoscopic images back to user's eye. The use of
mobile projectors and
positional tracking mounted on user's spectacles frame allows the illusion of a hologram to be created for
computer generated imagery. • Flashlight fish of the family
Anomalopidae have natural retroreflectors. See
tapetum lucidum. • High-visibility clothing, especially in the
construction industry. ==History==