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binocular

 
Dictionary: bin·oc·u·lar   (bə-nŏk'yə-lər, bī-) pronunciation
 
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binocular
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binocular
pair of binoculars
(Precision Graphics)
adj.
  1. Relating to, used by, or involving both eyes at the same time: binocular vision.
  2. Having two eyes arranged to produce stereoscopic vision.
n.

An optical device, such as a pair of field glasses or opera glasses, designed for simultaneous use by both eyes and consisting of two small telescopes joined with a single focusing device. Often used in the plural.

binocularity bin·oc'u·lar'i·ty (-lăr'ĭ-tē) n.
binocularly bin·oc'u·lar·ly adv.
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How Products are Made: How is a binocular made?
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Background

Modern binoculars consist of two barrel chambers with an objective lens, eyepiece, and a pair of prisms inside. The prisms reflect and lengthen the light, while the objective lenses enhance and magnify images due to stereoscopic vision.

History

Man has been experimenting with glass since its advent sometime around 3500 B.C. These experiments soon became known for their ocular implications. The designs of early optical instruments, like the telescope, were not recorded. It is assumed that these instruments were studied and perfected by Galileo Galilei. Early binoculars were actually called binocular telescopes, and are thought to be based on Galileo's discoveries and designs of prisms.

Early telescopic lenses were full of bubbles and other imperfections. They were also slightly green due to the iron content in the glass. Polishing techniques were crude, and although lenses were of good quality in the center, the peripheral shape was poor resulting in a restricted aperture. As telescopes were improved, binoculars evolved. The first patent application for binocular telescopes was filed early in the seventeenth century by Jan Lippershey in present day Holland. Lippershey primarily used quartz crystal, which is hard to manipulate. The first hand-held binocular originated in 1702 with Johann Zahn's small binocular of two tubes with a lithe connection.

A patent application submitted in 1854 by Ignatio Porro began the use of the modern prism binocular called the Porro prism erecting system. This optical system consisted of an objective lens and ocular lens (eyepiece) with two facing, right angle prisms arranged to invert and correct the orientation of the image. The two most commonly used prism systems are the porro prism and the roof prism design. The roof system uses prisms positioned one over the other resulting in a more compact design.

An other major breakthrough occurred in 1894 when Carl Zeiss, a German optical specialist, developed binoculars with convex lenses and delta prisms to correct the inverted image. In a porro design, the light is bent in a "Z" shape before reaching the eye, allowing the distance between the eyepiece and the objective lens to be compacted. This enables the size and weight of binoculars to be reduced.

Reductions in the weight of the binoculars occurred with the use of aluminum or polycarbonate housings instead of the heavier metal alloys used in pre-civil war binoculars. Performance of smaller and larger binoculars has improved with the introduction of coatings to render the lenses non-reflective and reduce the amount of scattered light. The quality of prisms has also improved over the years, resulting in a reduction of the bubbling effect of optical glass. In the early 1970s, nitrogen filled, waterproof binoculars were developed. A decade later the arrival of infrared transmitters capable of seeing in the dark further transformed binocular technology. Variable magnification models were also developed allowing the user to adjust the level of magnification.

Raw Materials

Early binocular models had brass housing covers and were relatively heavy and expensive to produce. Subsequent leather or hard rubber covers were replaced in Germany during the World War I by a cover of black lacquered cardboard. Galvanized steel replaced the heavier brass in the housing covers. In the 1930s, nearly all of the metal parts of the service glasses were made of aluminum to save brass and reduce the weight.

Modern-day binocular tubes are primarily made out of aluminum coated with silicon or a leather-like material called gutta-percha. The lenses and prisms are made from glass and coated with an anti-reflective coating.

Design

With the exception of the optical glass and some rubber seals, the majority of binocular component parts can be manufactured using a Computer Assisted Design and Manufacturing (CAD/CAM) system that downloads the designs to a variety of Computer Numerically Controlled (CNC) devices (multi-axis mill turn and milling machines as well as vertical and horizontal machining centers, lathes, etc.). Using CAD software provides both drawing, dimensioning, and visualization capabilities. These lead to improvements in the binoculars final design.

The Manufacturing
Process

  1. The lens material is poured into a lens mold, which has a spherical curved bottom. This results in a lens that is about 4 in (10.2 cm) in diameter and 1-1.5 in (2.4-3.8 cm) thick.
  2. The lenses are then removed from the molds and cut into specific pieces using a diamond saw to create the optical lenses.
  3. The lenses are placed into the grinding machine and polished.
  4. After they have been carefully machined, the lenses are anodized to reduce reflections in vacuum tanks. The more coatings applied, the less light absorbed.
  5. The ocular lenses (nearest the eyes) are also molded and carefully polished by auto-polish machines after which they are centered on diamond turning machines and finally cleaned by running through several different solvents in automated machinery.
  6. The objective lenses, those furthest from the eyes, are molded and then polished with polishing machines.
  7. These components are then manually assembled into a die cast body, which is often made from aluminum.
  8. Using a technique called physical vapor deposition, the optics are placed into a "plasma machine" and coated with dielectric coatings. The coatings are essential for high performance.
  9. The optics are then inspected and tested for clarity and defects using lasers in specially designed particulate free rooms.
  10. Next, the rod shaped prisms are cut by lasers into three-sided shapes depending on the type of prism being manufactured (i.e., roof prisms or porro prisms).
  11. The prisms are coated with dielectric materials (metal oxides) by physical vapor deposition inside a vacuum chamber.
  12. When all these components are assembled on a belt assembly line, the final assembly station collimates the binocular by hand, making the left side exactly parallel to the right, so only one image will be seen at a time.
  13. The binocular housing is then covered with a substance called gutta-percha, which looks like leather but is more durable and flexible. This covering is applied by hand using an adhesive and may be coated with a protective rubber covering.
  14. On the assembly line bare metal housing covers are covered with plastic or rubber.
  15. The prisms are placed by hand inside the binocular casing and manually screwed in place.
  16. The objective lenses are held in place by a metal or plastic ring and the eyepiece is fitted with a rubber eyecap.
  17. The focusing lenses are placed in the housing with screws mounted by hand.
  18. Waterproof binoculars must have orings at every orifice, be purged with nitrogen (injected through a seal), and sealed. The final step would be the packing of binoculars in cases with neck straps, most cases today being of a canvas-like material.

Quality Control

Binoculars that have been hermetically sealed (waterproof) and nitrogen charged (fogproof) are tested underwater. Most binoculars will withstand water immersion at 16.4(5 m) for five minutes. Both barrels of a binocular need to be optically parallel for the image to merge into one perfect circle and are carefully checked for alignment.

Byproducts/Waste

Lenses and prisms that have defects such as scratches or cracks are either discarded and melted down to be molded again, or they are recycled. If the casing is damaged during production, it is also either remolded or recycled.

The Future

Binoculars continue to advance with new technology. Their ability to see further with better focusing techniques enables the consumer to use the product for a wider variety of tasks. Binoculars are now tending to use the same stabilizing method used in video cameras that automatically stabilizes the prism system so that the image remains steady to the viewer. Some binoculars are also coming equipped with night scope vision. This would enable the consumer to see objects that are far away even at night. Technological advancements are continually made on these specialty binoculars, which are primarily used by the military or for surveillance.

Where to Learn More

Books

Bell, Louis. The Telescope. McGraw-Hill Book Company, Inc., 1922.

Von Rohr, Moritz. Die Binokularen Instrumente. Berlin: Springer, 1920.

Other

The United States Patent Office Web Page. November 2001. <http://www.uspto.gov/patft>.

Van Helden, Albert. The Telescope. 1995. November 2001. <http://es.rice.edu/ES/humsoc/GalileoiThings/telescope.html>.

[Article by: Bonny McClain]


 
Sci-Tech Encyclopedia: Binoculars
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Optical instruments consisting of a parallel pair of matched telescopes, used to extend the range of stereoscopic vision to far distances. Each half of a binocular consists of a telescope objective, a prism for inverting the image, and an eyepiece (see illustration). See also Eyepiece; Stereoscopy; Vision.

Modern prism binocular. (<i>Bausch and Lomb Optical Co</i>.)
Modern prism binocular. (Bausch and Lomb Optical Co.)

The characteristics of a binocular are stated by using a pair of numbers, such as 7 × 50 (seven by fifty), where the first number is the magnifying power of the binocular and the second is the diameter of the objective of the binocular in millimeters.

Since a lens forms an inverted image, the straight-through combination of an objective and eyepiece would provide an inverted field of view to the eye, as in an astronomical telescope. Almost all binoculars use prisms with an odd number of reflecting surfaces to invert the image correctly. The choice of prisms must also provide for the adjustment in pupil separation by having the optical axes on either side of the prism displaced but parallel. The most frequently used prism is a Porro prism, which is a combination of two 45°–90° prisms. These lead to a bulky mechanical construction, so that many modern binoculars use straight-through prisms. See also Mirror optics; Optical prism.

Binoculars require some ability to change the separation between the eyepiece and the objective to provide focusing to accommodate different object distances and possible refractive errors in the eye. Most binoculars provide for a joint focus adjustment of both tubes with one eye having an additional focus range to compensate for users who have differing refractive errors in each eye. Another optical feature often available in binoculars is a variable magnification or zoom system. See also Zoom lens.

Selection of binoculars should be made with some consideration of the intended use. A larger objective will permit use of the binoculars at lower light levels. However, binoculars with larger-diameter objectives and higher powers are heavier and less convenient to use. The jitter produced while holding the binoculars will be magnified by the binocular, so that very high power binoculars usually require a stable support, such as a tripod, to be used properly. A modest power such as 6 is usually more comfortable than a high power such as 10.

Opera glasses are a type of low-power binoculars which use simpler optics. The use of a negative lens as an eyepiece, as in a Galilean telescope, limits the power and the field of view but permits a lighter and less expensive instrument.

 
Britannica Concise Encyclopedia: binoculars
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Optical instrument for providing a magnified view of distant objects, consisting of two similar telescopes, one for each eye, mounted on a single frame. In most binoculars, each telescope has two prisms, which reinvert the inverted image provided by the eyepiece of each telescope. Light rays travel along a folded path inside the telescopes, so the instrument has a shorter overall length. The prisms also provide better depth perception at greater distances, by allowing the two objectives (object lenses) to be set farther apart than the eyepieces. Binocular eyepieces are often fitted to microscopes or other optical instruments.

For more information on binoculars, visit Britannica.com.

 
Columbia Encyclopedia: binocular
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binocular, small optical instrument consisting of two similar telescopes mounted on a single frame so that separate images enter each of the viewer's eyes. As with a single telescope, distant objects appear magnified, but the binocular has the additional advantage that it substantially increases the range of depth perception of the viewer because the magnified images are seen with both eyes. The frame of a binocular is usually hinged to permit adjustment of the distance between the telescopes. Focusing can be done by means of a wheel on the central axis between the telescopes; turning the wheel changes the distance from the objective lenses of the telescopes to the eyepieces. Separate focusing of each telescope from the eyepiece may be provided in some types of binocular. The term binocular now usually refers to the prism binocular, in which light entering each telescope through its objective lens is bent first one way and then the other by a pair of prisms before passing through one or more additional lenses in the eyepiece. The prisms aid in reducing the length of the instrument and in enhancing the viewer's depth perception by increasing the distance between the objective lenses. Other types of binocular include the opera glass and the field glass; both use Galilean telescopes, which do not employ prisms and which usually have less magnifying power than the telescopes in prism binoculars. A binocular is often specified by an expression such as “7×35” or “8×50”—the first number indicates how many times the binocular magnifies an object and the second number is the diameter of either objective lens in millimeters. The size of an objective lens is a measure of how much light it can gather for effective viewing.

Bibliography

See J. T. Kozak, Deep-Sky Objects for Binoculars (1988).

 
Veterinary Dictionary: binocular
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1. pertaining to both eyes.
2. having two eyepieces, as in a microscope.

  • b. field — the field of vision, simultaneously received by both eyes. Varies between animal species, depending on the placement of the eyes in the skull. Widest in the cat (90°), 60–70° in the horse and 15° in poultry.
    Field of vision of predatory animals. By permission from Aspinall V, O'Reilly M, Introduction to Veterinary Anatomy and Physiology, Butterworth Heinemann, 2004
 
Boating Encyclopedia: Binoculars
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Learning what the numbers mean; the classic boat size
The basic rule concerning binoculars is that every boat should carry two pairs: a good expensive pair for your use only, and another inexpensive pair for visitors who keep changing the focus and won’t put the strap around their neck.The classic choice for boat binoculars is 7x50—that is, sevenfold magnification and front lenses 50 mm (2 in.) in diameter. Any greater magnification is counterproductive on a small boat with a lively motion, causing dancing, erratic views in the eyepiece. The larger the front lenses, the better, because they admit more light; 7x50 mm binoculars are good night glasses and will help you locate objects almost invisible to the naked eye at dusk and afterward.Special image-stabilizing binoculars powered by batteries that use software technology permit magnifications of as much as 14 times, but are not commonly found on small boats because of their expense and extra weight. The same applies to even more expensive night scopes—a spin-off of military applications—that electronically enhance minute amounts of existing light. They don’t magnify as much as ordinary night glasses do, but they certainly paint clear pictures of objects you would never otherwise see at night.

 
Wikipedia: Binoculars
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A typical Porro prism binocular design

Binocular telescopes, or binoculars (also known as field glasses), are two identical or mirror-symmetrical telescopes mounted side-by-side and aligned to point accurately in the same direction, allowing the viewer to use both eyes (binocular vision) when viewing distant objects. Most are sized to be held using both hands, although there are much larger types.

Unlike a monocular telescope, a binocular gives users a three-dimensional image: the two views, presented from slightly different viewpoints to each of the viewer's eyes, produce a merged view with depth perception. There is no need to close or obstruct one eye to avoid confusion, as is usual with monocular telescopes.

Contents

Optical design

Galilean binoculars

Galilean binoculars

Almost from the invention of the telescope in the 17th century the advantages of mounting two of them side by side for binocular vision seems to have been explored.[1] Most early binoculars used Galilean optics; that is they used a convex objective and a concave eyepiece lens. The Galilean design has the advantage of presenting an erect image but has a narrow field of view and is not capable of very high magnification. This type of construction is still used in very cheap models and in opera glasses or theater glasses.

Prism binoculars

Roof-prism binoculars.

An improved image and higher magnification can be achieved in a construction binoculars employing Keplerian optics, where the image formed by the objective lens is viewed through a positive eyepiece lens (ocular). This configuration has the disadvantage that the image is inverted. There are different ways of correcting these disadvantages.

Porro prism binoculars

Double Porro prism design

Named after Italian optician Ignazio Porro who patented this image erecting system in 1854 and later refined by makers like Carl Zeiss in the 1890s,[1] binoculars of this type use a Porro prism in a double prism Z-shaped configuration to erect the image. This feature results in binoculars that are wide, with objective lenses that are well separated but offset from the eyepieces. Porro prism designs have the added benefit of folding the optical path so that the physical length of the binoculars is less than the focal length of the objective and wider spacing of the objectives gives better sensation of depth.

Abbe-Koenig "roof prism" design

Roof prism binoculars

Binoculars using roof prisms may have appeared as early as the 1870s in a design by Achille Victor Emile Daubresse.[2][3] Most roof prism binoculars use either the Abbe-Koenig prism (named after Ernst Karl Abbe and Albert Koenig and patented by Carl Zeiss in 1905) or Schmidt-Pechan prism (invented in 1899) designs to erect the image and fold the optical path. They have objective lenses that are approximately in line with the eyepieces.

Relative advantages of porro prism and roof prism binoculars

Roof-prisms designs create an instrument that is narrower and more compact than Porro prisms. There is also a difference in image brightness. Porro-prism binoculars will inherently produce a brighter image than roof-prism binoculars of the same magnification, objective size, and optical quality, because the roof-prism design employs silvered surfaces that reduce light transmission by 12% to 15%. Roof-prisms designs also require tighter tolerances as far as alignment of their optical elements (collimation). This adds to their expense since the design requires them to use fixed elements that need to be set at a high degree of collimation at the factory. Porro prisms binoculars occasionally need their prism sets to be re-aligned to bring them into collimation. The fixed alignment in roof-prism designs means the binoculars normally won't need re-collimation.[4]

Optical parameters

 This section may contain original research or unverified claims. Please improve the article by adding references. See the talk page for details. (April 2009)
Parameters listed on the prism cover plate describing a 7 power magnification binocular with a 50 mm Objective diameter and a 372-foot Field of view at 1000 yards.

Binoculars are usually designed for the specific application for which they are intended. Those different designs create certain optical parameters (some of which may be listed on the prism cover plate of the binocular). Those parameters are:

Magnification — The ratio of the focal length of the eyepiece divided into the focal length of the objective gives the linear magnifying power of binoculars (sometimes expressed as "diameters"). A magnification of factor 7, for example, produces an image as if one were 7 times closer to the object. The amount of magnification depends upon the application the binoculars are designed for. Hand-held binoculars have lower magnifications so they will be less susceptible to shaking. A larger magnification leads to a smaller field of view.

Objective diameter – The diameter of the objective lens determines how much light can be gathered to form an image. It is usually expressed in millimeters.

It is customary to categorize binoculars by the magnification × the objective diameter; e.g. 7×50.

Field of view — The field of view of a binocular is determined by its optical design. It is usually notated in a linear value, such as how many feet (meters) in width will be seen at 1,000 yards (or 1,000 m), or in an angular value of how many degrees can be viewed.

Exit pupil — Binoculars concentrate the light gathered by the objective into a beam, the exit pupil, whose diameter is the objective diameter divided by the magnifying power. For maximum effective light-gathering and brightest image, the exit pupil should equal the diameter of the fully dilated iris of the human eye— about 7 mm, reducing with age. If the cone of light streaming out of the binocular is larger than the pupil it is going into, any light larger than the pupil is wasted in terms of providing information to the eye. In daytime use the human pupil is typically dilated about 3 mm, which is about the exit pupil of a 7x21 binocular. A much larger 7x50 binocular will produce a cone of light bigger than the pupil it is entering, and this light will, in the day, be wasted. It is therefore seemingly pointless to carry around a larger instrument.

However, a larger exit pupil makes it easier to put the eye where it can receive the light: anywhere in the large exit pupil cone of light will do. This ease of placement helps avoid vignetting, which is a darkened or obscured view that occurs when the light path is partially blocked. And, it means that the image can be quickly found which is important when looking at birds or game animals that move rapidly. A narrow exit pupil binocular may also be fatiguing because the instrument must be held exactly in place in front of the eyes to provide a useful image. Finally, many people use their binoculars at dusk, in overcast conditions, and at night, when their pupils are larger. Thus the daytime exit pupil is not a universally desirable standard. For comfort, ease of use, and flexibility in applications, larger binoculars with larger exit pupils are satisfying choices even if their capability is not fully used by day.

Eye relief — Eye relief is the distance from the rear eyepiece lens to the exit pupil or eye point[5]. It is the distance the observer must position his or her eye behind the eyepiece in order to see an unvignetted image. The longer the focal length of the eyepiece, the greater the eye relief. Binoculars may have eye relief ranging from few millimeters to 2.5 centimeters or more. Eye relief can be particularly important for eyeglass wearers. The eye of an eyeglass wearer is typically further from the eye piece which necessitates a longer eye relief in order to still see the entire field of view. Binoculars with short eye relief can also be hard to use in instances where it is difficult to hold them steady.

Optical coatings

Anti-reflective coatings

Main article: Anti-reflective coating
U.S. Navy binocular

Since a binocular can have 16 air-to-glass surfaces, with light lost at every surface, optical coatings can significantly affect image quality. When light strikes an interface between two materials of different refractive index (e.g., at an air-glass interface), some of the light is transmitted, some reflected. In any sort of image-forming optical instrument (telescope, camera, microscope, etc.), ideally no light should be reflected; instead of forming an image, light which reaches the viewer after being reflected is distributed in the field of view, and reduces the contrast between the true image and the background. Reflection can be reduced, but not eliminated, by applying optical coatings to interfaces. Each time light enters or leaves a piece of glass; about 5% is reflected back. This "lost" light bounces around inside the binocular, making the image hazy and hard to see. Lens coatings effectively lower reflection losses, which finally results in a brighter and sharper image. For example, 8x40 binoculars with good optical coatings will yield a brighter image than uncoated 8x50 binoculars. Light can also be reflected from the interior of the instrument, but it is simple to minimize this to negligible proportions. Contrast is also improved by good coating due to the partial elimination of internal reflections.

A classic lens-coating material is magnesium fluoride; it reduces reflections from 5% to 1%. Modern lens coatings consist of complex multi-layers and reflect only 0.25% or less to yield an image with maximum brightness and natural colors.

Roof prism phase correction coating

In binoculars with roof prisms multiple internal reflections in a roof prism cause a polarization-dependent phase-lag of the transmitted light, in a manner similar to a Fresnel rhomb.

The light path through the roof prism is split in two paths that reflect on either side of the roof ridge. One half of the light reflects from roof surface 1 to roof surface 2. The other half of the light reflects from roof surface 2 to roof surface 1. During any reflection, including total internal reflection inside a prism, unpolarized light becomes partially polarized. During subsequent reflections the direction of this polarization vector is changed but it is changed differently for each path in a manner similar to a Foucault pendulum. When the light following the two paths are recombined the polarization vectors of each path do not coincide. The angle between the two polarization vector called the phase shift, or the geometric phase, or the Berry phase.

In a roof prism without a phase correcting coating interference between the two paths with different geometric phase results in a varying intensity distribution in the image reducing apparent contrast and resolution compared to a porro prism erecting system. This effect can be seen in the elongation of the Airy disk[6] in the same direction as the crest of the roof.

The unwanted interference effects are suppressed by vapour depositing a special dielectric coating known as a phase-correction coating or P-coating on the roof surfaces of the roof prism. This coating corrects for the difference in geometric phase between the two paths so both have effectively the same phase shift and no interference degrades the image.

Binoculars using either a Schmidt-Pechan roof prism or a Abbe-Koenig roof prism benefit from phase coatings. Porro prism binoculars do not recombine beams after following two paths with different phase and so do not benefit from a phase coating.

Roof prism metallic mirror coating

Main article: Mirror

In binoculars that use a Schmidt-Pechan roof prism some surfaces of the roof prism must be mirror coated for efficient reflection since the light is incident at one of the glass-air boundaries at an angle less than the critical angle so total internal reflection does not occur. Without a mirror coating most of that light would be lost. Typically an aluminum mirror coating (reflectivity of 87% to 93%) or silver mirror coating (reflectivity of 95% to 98%) is used.

In older binocular designs silver mirror coatings were used but these coatings oxidized and lost reflectivity over time in unsealed binoculars. Aluminum mirror coatings were used in later unsealed designs because it did not tarnish even though it has a lower reflectivity than silver. Modern binocular designs use either aluminum or silver. Silver is used in modern high-quality designs as modern binoculars are sealed and nitrogen or argon filled so the silver mirror coating doesn't tarnish in an inert atmosphere.[7]

Porro prism binoculars and roof prism binoculars using the Abbe-Koenig roof prism do not use mirror coatings because these prisms reflect with 100% reflectivity using total internal reflection in the prism.

Roof prism dielectric mirror coating

Main article: Dielectric mirror

A dielectric coating on a Schmidt-Pechan roof prism causes the prism surfaces to act as a dielectric mirror. The non-metallic dielectric reflective coating is formed from several multilayers of alternating high and low refractive index materials deposited on the roof prism's reflective surfaces. Each single multilayer reflects a narrow band of light frequencies so several multilayers, each tuned to a different color, are required to reflect white light. This multi-multilayer coating increases reflectivity from the prism surfaces by acting as a distributed Bragg reflector. A well-designed dielectric coating can provide a reflectivity of more than 99% across the visible light spectrum. This reflectivity is much improved compared to either an aluminum mirror coating (87% to 93%) or silver mirror coating (95% to 98%).

Porro prism binoculars and roof prism binoculars using the Abbe-Koenig roof prism do not use dielectric coatings because these prisms reflect with very high reflectivity using total internal reflection in the prism rather than requiring a mirror coating.

Marketing terms used to denote coatings

The presence of any coatings is typically denoted on binoculars by the following terms:

  • coated optics: one or more surfaces are anti-reflective coated with a single-layer coating.
  • fully coated: all air-to-glass surfaces are anti-reflective coated with a single-layer coating. Plastic lenses, however, if used, may not be coated[citation needed].
  • multi-coated: one or more surfaces have anti-reflective multi-layer coatings.
  • fully multi-coated: all air-to-glass surfaces are anti-reflective multi-layer coated.
  • phase-coated or P-coating: the roof prism has a phase-correcting coating
  • aluminum-coated: the roof prism mirrors are coated with an aluminum coating. The default if a mirror coating isn't mentioned.
  • silver-coated: the roof prism mirrors are coated with a silver coating
  • dielectric-coated: the roof prism mirrors are coated with a dielectric coating

Mechanical design

Focusing and adjustment

Binoculars to be used to view objects that are not at a fixed distance must have a focusing arrangement. Traditionally, two different arrangements have been used to provide focus. Binoculars with "independent focus" require the two telescopes to be focused independently by adjusting each eyepiece, thereby changing the distance between ocular and objective lenses. Binoculars designed for heavy field use, such as military applications, traditionally have used independent focusing. Because general users find it more convenient to focus both tubes with one adjustment action, a second type of binocular incorporates "central focusing", which involves rotation of a central focusing wheel. In addition, one of the two eyepieces can be further adjusted to compensate for differences between the viewer's eyes (usually by rotating the eyepiece in its mount). Because the focal change effected by the adjustable eyepiece can be measured in the customary unit of refractive power, the diopter, the adjustable eyepiece itself is often called a "diopter." Once this adjustment has been made for a given viewer, the binoculars can be refocused on an object at a different distance by using the focusing wheel to move both tubes together without eyepiece readjustment.

Binocular with internal elements visible

There are also "focus-free" or "fixed-focus" binoculars. They have a depth of field from a relatively large closest distance to infinity, and perform exactly the same as a focusing model of the same optical quality (or lack of it) focused on the middle distance.

Zoom binoculars, while in principle a good idea, are generally considered not to perform very well. The problem is that it is very difficult to coordinate the magnification for both eyes precisely. When the magnification is not perfectly matched, the user's eyes and brain will try to compensate. After sustained viewing, this can cause eye strain and fatigue. The sharper the optics are, the more precise matching is needed, so successful zoom binoculars tend to be of lower optical quality.

Most modern binoculars have hinged-telescope construction that enables the distance between eyepieces to be adjusted to accommodate viewers with different eye separation. This adjustment feature is lacking on many older binoculars.

Image stabilization

Shake can be much reduced, and higher magnifications used, with binoculars using image-stabilization technology. Parts of the instrument which change the position of the image may be held steady by powered gyroscopes or by powered mechanisms driven by gyroscopic or inertial detectors, or may be mounted in such a way as to oppose and damp the effect of shaking movements. Stabilization may be enabled or disabled by the user as required. These techniques allow binoculars up to 20× to be hand-held, and much improve the image stability of lower-power instruments. There are some disadvantages: the image may not be quite as good as the best unstabilized binoculars when tripod-mounted, stabilized binoculars also tend to be more expensive and heavier than similarly specified non-stabilised binoculars.

Alignment

Well-collimated binoculars, when viewed through human eyes and processed by a human brain, should produce a single circular, apparently three-dimensional image, with no visible indication that one is actually viewing two distinct images from slightly different viewpoints. Departure from the ideal will cause, at best, vague discomfort and visual fatigue, but the perceived field of view will be close to circular anyway. The cinematic convention used to represent a view through binoculars as two circles partially overlapping in a figure-of-eight shape is not true to life.

Misalignment is remedied by small movements to the prisms, often by turning screws accessible without opening the binoculars, or by adjusting the position of the objective via eccentric rings built into the objective cell. Alignment is usually done by a professional although instructions for checking binoculars for collimation errors and for collimating them can be found on the Internet.

Applications

 This section may contain original research or unverified claims. Please improve the article by adding references. See the talk page for details. (April 2009)

General use

People in Orchid, Florida use binoculars for birdwatching.

Hand-held binoculars range from small 3 x 10 Galilean opera glasses, used in theaters, to glasses with 7 to 12 diameters magnification and 30 to 50 mm objectives for typical outdoor use. Porro prism models predominate although bird watchers and hunters tend to prefer, and are prepared to pay for, the lighter but more expensive roof-prism models.

Many tourist attractions have installed pedestal-mounted, coin-operated binoculars to allow visitors to obtain a closer view of the attraction. In the United Kingdom, 20 pence often gives a couple of minutes of operation, and in the United States, one or two quarters gives between one-and-a-half to two-and-a-half minutes.

Coin-operated binocular

Range Finding

Many binoculars have range finding reticle (scale) superimposed upon the view. This scale allows the distance to the object to be estimate if the objects height is known (or estimatable). The common mariner 7 x 50 binocular have these scales with the angle between marks equal to 5 mil[8]. One mil is equivalent to the angle between the top and bottom of an object one meter in height at a distance of 1000 meters.

Therefore to estimate the distance to an object that is a known height the formula is:

\mathrm{D}= \frac{OH}{Mil}X 1000

where:

  • D is the Distance to the object in meters.
  • OH is the known Object Height.
  • Mil is the height of the object in number of Mil.


With the typical binocular 5 mil scale (each mark is 5 mil), a lighthouse that is 3 marks high that is known to be 120 meters tall is 8000 meters distance.

\mathrm{8000 m}= \frac{120 m}{15 mil}X 1000

Military

Binoculars have a long history of military use. Galilean designs were widely used up to the end of the 19th century when they gave way to porro prism types. Binoculars constructed for general military use tend to be more heavily ruggedized than their civilian counterparts. They generally avoid more fragile center focus arrangements in favor of independent focus, which also makes for easier, more effective weatherproofing. Prism sets in military binoculars may have redundant aluminized coatings on their prism sets to guarantee they don’t lose their reflective qualities if they get wet. Military binoculars of the Cold War era were sometimes fitted with passive sensors that detected active IR emissions, while modern ones usually are fitted with filters blocking laser beams. Further, binoculars designed for military usage may include a stadiametric reticle in one ocular in order to facilitate range estimation.

Naval ship binocular

There are binoculars designed specifically for civilian and military use at sea. Hand held models will be 5× to 7× but with very large prism sets combined with eyepieces designed to give generous eye relief. This optical combination prevents the image vignetting or going dark when the binocular is pitching and vibrating relative to the viewer's eye. Large, high-magnification models with large objectives are also used in fixed mountings.

Very large binocular naval rangefinders (up to 15 meters separation of the two objective lenses, weight 10 tons, for ranging World War II naval gun targets 25 km away) have been used, although late-20th century technology made this application redundant.

Astronomical

Binoculars are widely used by amateur astronomers; their wide field of view making them useful for comet and supernova seeking (giant binoculars) and general observation (portable binoculars). Some binoculars in the 70 mm and larger range remain useful for terrestrial viewing; true astronomical binocular designs (often 90 mm and larger) typically dispense with prisms for correct image terrestrial viewing in order to maximize light transmission. Such binoculars also have removable eyepieces to vary magnification and are typically not designed to be waterproof or withstand rough field use.

Ceres, Neptune, Pallas, Titan, and the Galilean moons of Jupiter are invisible to the naked eye but can readily be seen with binoculars. Although visible unaided in pollution-free skies, Uranus and Vesta require binoculars for easy detection. 10×50 binoculars are limited to an magnitude of +10 to +11 depending on sky conditions and observer experience. Asteroids like Interamnia, Davida, Europa and, unless under exceptional conditions Hygiea, are too faint to be seen with commonly sold binoculars. Likewise too faint to be seen with most binoculars are the planetary moons except the Galileans and Titan, and the dwarf planets Pluto and Eris. Among deep sky objects, open clusters can be magnificent, such as the bright double cluster (NGC 869 and NGC 884) in the constellation Perseus, and globular clusters, such as M13 in Hercules, are easy to spot. Among nebulae, M17 in Sagittarius and the North American nebula (NGC 7000) in Cygnus are also readily viewed.

15x70 binocular.

Of particular relevance for low-light and astronomical viewing is the ratio between magnifying power and objective lens diameter. A lower magnification facilitates a larger field of view which is useful in viewing large deep sky objects such as the Milky Way, nebula, and galaxies, though the large exit pupil means some of the gathered light is wasted. The large exit pupil will also image the night sky background, effectively decreasing contrast, making the detection of faint objects more difficult except perhaps in remote locations with negligible light pollution. Binoculars geared towards astronomical uses provide the most satisfying views with larger aperture objectives (in the 70 mm or 80 mm range). Astronomy binoculars typically have magnifications of 12.5 and greater. However, many of the objects in the Messier Catalog and other objects of eighth magnitude and brighter are readily viewed in hand-held binoculars in the 35 to 40 mm range, such as are found in many households for birding, hunting, and viewing sports events. But larger binocular objectives are preferred for astronomy because the diameter of the objective lens regulates the total amount of light captured, and therefore determines the faintest star that can be observed. Due to their high magnification and heavy weight, these binoculars usually require some sort of mount to stabilize the image. A magnification of ten (10x) is usually considered the most that can be held comfortably steady without a tripod or other mount.

Much larger binoculars have been made by amateur telescope makers, essentially using two refracting or reflecting astronomical telescopes, with mixed results. A very large professional instrument, although not one that would normally be called binoculars, is the Large Binocular Telescope in Arizona, USA, which produced its "First Light" image on October 26, 2005. The LBT comprises two 8-meter reflector telescopes. While not intended to be held to the eyes of a viewer, it uses two telescopes to view the same object, giving higher resolving power than a single instrument of the same light-gathering power, and allowing interferometric use.

Manufacturers

Some notable binocular manufacturers as of 2008. Sorted in alphabetical order:

  • Bausch & Lomb (USA) – has not made binoculars since 1976, when they licensed their name to Bushnell, Inc., who made binoculars under the Bausch & Lomb name until the license expired, and was not renewed, in 2005.
  • Brunton, Inc. (USA)
  • Bushnell Corporation (USA)
  • Canon Inc. (Japan) – I.S. series: porro variants?
  • Celestron
  • Fujinon (Japan) – FMTSX, FMTSX-2, MTSX series: porro.
  • Leica Camera (Germany) – Ultravid, Duovid, Geovid: all are roof prism.
  • Leupold & Stevens, Inc. (USA)
  • Meade Instruments (USA)– Glacier (roof prism), TravelView (porro), CaptureView (folding roof prism), and Astro Series (roof prism)
  • Minox
  • Nikon Corporation (Japan) – EDG Series, High Grade series, Monarch series, RAII, Spotter series: roof prism; Prostar series, Superior E series, E series, Action EX series: porro.
  • Pentax Corporation (Japan) – DCFED/SP/XP series: roof prism; UCF series: inverted porro; PCFV/WP/XCF series: porro.
  • Swarovski Optik[9]
  • Vixen (telescopes) (Japan) – Apex/Apex Pro: roof prism; Ultima: porro.
  • Vortex Optics (USA)
  • Zeiss (Germany) – FL, Victory, Conquest: roof prism; 7×50 BGAT/T porro, 15×60 BGA/T porro, discontinued.

See also

Notes

  1. ^ a b Europa.com — The Early History of the Binocular
  2. ^ groups.google.co.ke
  3. ^ photodigital.net — rec.photo.equipment.misc Discussion: Achille Victor Emile Daubresse, forgotten prism inventor
  4. ^ Astronomy Hacks By Robert Bruce Thompson, Barbara Fritchman Thompson, chapter 1, page 34
  5. ^ "Introduction to Optics 2nd ed.", pp.141-142, Pedrotti & Pedrotti, Prentice-Hall 1993
  6. ^ http://www.zbirding.info/zbirders/blogs/sing/archive/2006/08/09/189.aspx
  7. ^ http://www.zbirding.info/Truth/prisms/prisms.htm
  8. ^ Binoculars.com — Marine 7 x 50 Binoculars. Bushnell
  9. ^ www.regionhall.at - The Swarovski story

References

External links

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Translations: Binocular
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Dansk (Danish)
adj. - binokular
n. - kikkert, prismekikkert

idioms:

  • binocular vision    samsyn

Nederlands (Dutch)
(mv) verrekijker, (mv) toneelkijker, binoculair

Français (French)
adj. - binoculaire
n. - jumelles

idioms:

  • binocular vision    vision binoculaire

Deutsch (German)
adj. - (Phys) binokular, zweiäugig
n. - Fernglas, Fernrohr, Doppelfernrohr, Feldstecher

idioms:

  • binocular vision    binokulare Sicht

Ελληνική (Greek)
n. - διόφθαλμο, (πληθ.) κιάλια

idioms:

  • binocular vision    διόφθαλμη όραση

Italiano (Italian)
binocolo

idioms:

  • binocular vision    visione binoculare

Português (Portuguese)
n. - binóculo (m)

idioms:

  • binocular vision    visão (f) binocular

Русский (Russian)
бинокль

idioms:

  • binocular vision    бинокулярное зрение

Español (Spanish)
adj. - binocular
n. - gemelos, binoculares

idioms:

  • binocular vision    visión binocular

Svenska (Swedish)
n. - kikare

中文(简体)(Chinese (Simplified))
双眼的, 双眼用的, 双筒望远镜, 双目显微镜

idioms:

  • binocular vision    双眼的视力, 双眼视觉

中文(繁體)(Chinese (Traditional))
adj. - 雙眼的, 雙眼用的
n. - 雙筒望遠鏡, 雙目顯微鏡

idioms:

  • binocular vision    雙眼的視力, 雙眼視覺

한국어 (Korean)
adj. - 두 눈의
n. - 쌍안경 , 쌍안 현미경

日本語 (Japanese)
adj. - 両眼の, 両眼用の
n. - 双眼鏡, 双眼顕微鏡

idioms:

  • binocular vision    両眼視, 両眼立体視

العربيه (Arabic)
‏(الاسم) ذو عينين, منظار, ناظور‏

עברית (Hebrew)
adj. - ‮של שתי העיניים‬
n. - ‮ברבים: משקפת‬

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