Tim Holtz

Bronze Folding Antique Binoculars Leather Case Old Opera Glasses Eye 1857 Retro

Description: Folding Binoculars with Leather Case These Bronze Folding Binoculars come with a Leather Case The case has an image of a ship and the words "R & J Beck Ltd" "London 1857 No. 7964387" and "Made for Royal Navy" Just twist the handle to open them and press the top to fold them down The dimensions are 11cm x 8 cm x 2.3 cm or 4.3" x 3.1" x 1" They weight 255 grams 9 ounces In Very Good Condition for their age All My Auctions Start at a Penny...With No Reserve..If your the only bidder you win it for 1p....Grab a Bargain!!!! Sorry about the poor quality photos. They don't do the item justice. A lot of my buyers tell me the coin looks better in real life than in my photos A wonderful item for anyone who likes The Binoculars It would be a super addition to any collection, excellent display, practical piece or authentic period prop. Comes from a pet and smoke free home Sorry about the poor quality photos. They don't do the item justice which looks a lot better in real life All my Auctions Bidding starts a a penny with no reserve...An Amazing Keepsake and Would Make a Perfect Gift I have a lot of Historical Memorabilia on Ebay so Check out my other items! Bid with Confidence - Check My Almost 100% Positive Feedback from over 30,000 Satisfied Check out my other items! All Payment Methods in All Major Currencies Accepted. Be sure to add me to your favourites list! All Items Dispatched within 24 hours of Receiving Payment. Thanks for Looking and Best of Luck with the Bidding!! I have sold items to coutries such as Afghanistan * Albania * Algeria * American Samoa (US) * Andorra * Angola * Anguilla (GB) * Antigua and Barbuda * Argentina * Armenia * Aruba (NL) * Australia * Austria * Azerbaijan * Bahamas * Bahrain * Bangladesh * Barbados * Belarus * Belgium * Belize * Benin * Bermuda (GB) * Bhutan * Bolivia * Bonaire (NL) * Bosnia and Herzegovina * Botswana * Bouvet Island (NO) * Brazil * British Indian Ocean Territory (GB) * British Virgin Islands (GB) * Brunei * Bulgaria * Burkina Faso * Burundi * Cambodia * Cameroon * Canada * Cape Verde * Cayman Islands (GB) * Central African Republic * Chad * Chile * China * Christmas Island (AU) * Cocos Islands (AU) * Colombia * Comoros * Congo * Democratic Republic of the Congo * Cook Islands (NZ) * Coral Sea Islands Territory (AU) * Costa Rica * Croatia * Cuba * Curaçao (NL) * Cyprus * Czech Republic * Denmark * Djibouti * Dominica * Dominican Republic * East Timor * Ecuador * Egypt * El Salvador * Equatorial Guinea * Eritrea * Estonia * Ethiopia * Falkland Islands (GB) * Faroe Islands (DK) * Fiji Islands * Finland * France * French Guiana (FR) * French Polynesia (FR) * French Southern Lands (FR) * Gabon * Gambia * Georgia * Germany * Ghana * Gibraltar (GB) * Greece * Greenland (DK) * Grenada * Guadeloupe (FR) * Guam (US) * Guatemala * Guernsey (GB) * Guinea * Guinea-Bissau * Guyana * Haiti * Heard and McDonald Islands (AU) * Honduras * Hong Kong (CN) * Hungary * Iceland * India * Indonesia * Iran * Iraq * Ireland * Isle of Man (GB) * Israel * Italy * Ivory Coast * Jamaica * Jan Mayen (NO) * Japan * Jersey (GB) * Jordan * Kazakhstan * Kenya * Kiribati * Kosovo * Kuwait * Kyrgyzstan * Laos * Latvia * Lebanon * Lesotho * Liberia * Libya * Liechtenstein * Lithuania * Luxembourg * Macau (CN) * Macedonia * Madagascar * Malawi * Malaysia * Maldives * Mali * Malta * Marshall Islands * Martinique (FR) * Mauritania * Mauritius * Mayotte (FR) * Mexico * Micronesia * Moldova * Monaco * Mongolia * Montenegro * Montserrat (GB) * Morocco * Mozambique * Myanmar * Namibia * Nauru * Navassa (US) * Nepal * Netherlands * New Caledonia (FR) * New Zealand * Nicaragua * Niger * Nigeria * Niue (NZ) * Norfolk Island (AU) * North Korea * Northern Cyprus * Northern Mariana Islands (US) * Norway * Oman * Pakistan * Palau * Palestinian Authority * Panama * Papua New Guinea * Paraguay * Peru * Philippines * Pitcairn Island (GB) * Poland * Portugal * Puerto Rico (US) * Qatar * Reunion (FR) * Romania * Russia * Rwanda * Saba (NL) * Saint Barthelemy (FR) * Saint Helena (GB) * Saint Kitts and Nevis * Saint Lucia * Saint Martin (FR) * Saint Pierre and Miquelon (FR) * Saint Vincent and the Grenadines * Samoa * San Marino * Sao Tome and Principe * Saudi Arabia * Senegal * Serbia * Seychelles * Sierra Leone * Singapore * Sint Eustatius (NL) * Sint Maarten (NL) * Slovakia * Slovenia * Solomon Islands * Somalia * South Africa * South Georgia (GB) * South Korea * South Sudan * Spain * Sri Lanka * Sudan * Suriname * Svalbard (NO) * Swaziland * Sweden * Switzerland * Syria * Taiwan * Tajikistan * Tanzania * Thailand * Togo * Tokelau (NZ) * Tonga * Trinidad and Tobago * Tunisia * Turkey * Turkmenistan * Turks and Caicos Islands (GB) * Tuvalu * U.S. Minor Pacific Islands (US) * U.S. Virgin Islands (US) * Uganda * Ukraine * United Arab Emirates * United Kingdom * United States * Uruguay * Uzbekistan * Vanuatu * Vatican City * Venezuela * Vietnam * Wallis and Futuna (FR) * Yemen * Zambia * Zimbabwe and major cities such as Tokyo, Yokohama, New York City, Sao Paulo, Seoul, Mexico City, Osaka, Kobe, Kyoto, Manila, Mumbai, Delhi, Jakarta, Lagos, Kolkata, Cairo, Los Angeles, Buenos Aires, Rio de Janeiro, Moscow, Shanghai, Karachi, Paris, Istanbul, Nagoya, Beijing, Chicago, London, Shenzhen, Essen, Düsseldorf, Tehran, Bogota, Lima, Bangkok, Johannesburg, East Rand, Chennai, Taipei, Baghdad, Santiago, Bangalore, Hyderabad, St Petersburg, Philadelphia, Lahore, Kinshasa, Miami, Ho Chi Minh City, Madrid, Tianjin, Kuala Lumpur, Toronto, Milan, Shenyang, Dallas, Fort Worth, Boston, Belo Horizonte, Khartoum, Riyadh, Singapore, Washington, Detroit, Barcelona,, Houston, Athens, Berlin, Sydney, Atlanta, Guadalajara, San Francisco, Oakland, Montreal, Monterey, Melbourne, Ankara, Recife, Phoenix/Mesa, Durban, Porto Alegre, Dalian, Jeddah, Seattle, Cape Town, San Diego, Fortaleza, Curitiba, Rome, Naples, Minneapolis, St. Paul, Tel Aviv, Birmingham, Frankfurt, Lisbon, Manchester, San Juan, Katowice, Tashkent, Fukuoka, Baku, Sumqayit, St. Louis, Baltimore, Sapporo, Tampa, St. Petersburg, Taichung, Warsaw, Denver, Cologne, Bonn, Hamburg, Dubai, Pretoria, Vancouver, Beirut, Budapest, Cleveland, Pittsburgh, Campinas, Harare, Brasilia, Kuwait, Munich, Portland, Brussels, Vienna, San Jose, Damman , Copenhagen, Brisbane, Riverside, San Bernardino, Cincinnati and AccraThe History of BinocularsEver wondered how binoculars came to be? We step back in time to see who invented them and why. Find out all about binoculars in today’s history lesson.What are binoculars?Binoculars are two telescopes attached side-by-side and aligned to focus in the same direction or an optical instrument with a lens for each eye that is used for viewing distant objects. They are also known as field glasses which provides a magnified view of distant objects. If you’re curious about just how they work, then don’t miss our guide to the science behind them. Common uses of binocularsA binocular is a device that comes handy when watching your favorite games while at the rear, watching birds, hunting and lots more. The less expensive a binocular is, the more people purchase them and enjoy the capabilities they have because this optical instrument lets you see details from a distant location. When were binoculars invented?It took about 5,000 years for glass to be able to be shaped into a lens for the first telescope. The scientist, Galileo Galilei was introduced to astronomy using a telescope. He was the first to see the craters on the moon, discover sunspots, the four moons around Jupiter and the rings surrounding Saturn. The telescope dealt with limited magnification as well as a narrow field of focus. Hans Lippershey, an experienced eyeglass maker from Holland, was not the first to assemble a device like a telescope but he was credited with the invention as he was the first to make the new device widely known. who-invented-binoculars Later, Sir Isaac Newton announced that there was a new telescope design whereby a curved mirror was used to receive light and reflect it back to a point of focus instead of glass lenses. This reflector telescope designed by Newton paved way for other telescope concepts to be used to magnify objects. It was after the first 300 years of telescopes being in existence that binoculars finally evolved. Then it was a binocular telescope that had two small prismatic telescopes fused together. This was when Hans Lippershey sought a 30-year patent that would allow him to have exclusive manufacturing rights of his instruments in 1608 that the official in charge, who had never seen a telescope before, asked him to build a binocular version of it. Lippershey announced the first binocular on December 8th, 1608 and then after it passed inspection, two more (made using optics made from quartz crystals) were created. The early binoculars were made with glass lenses and Galilean optics. These optics were named after Galilei Galileo for the progress he made over early telescopes. Galilean binoculars had an inverted eyepiece and a curved lens or mirror that received light from the focused object when viewed and focused the light rays to produce the real image. Though the elements in the binocular gave it the ability to produce a right-side-up image, one of its faults was that it produced a narrow field of vision and had a low magnification. As you know, a binocular is the conjoining of two telescopes side-by-side and can be treated similar to a telescope. You should know that a binocular makes visual perception easy while presenting a three-dimensional image of the focused object. Check out this post to see how we actually perceive depth of field. Some of the links below are affiliate links, meaning, at no additional cost to you, we may make a commission if you click through and make a purchase. Recommended Reading: Don’t miss our guide to the leading kids’ binoculars. So who really invented binoculars?There was speculation about the invention of binoculars in 1608 and 1609 when it was announced. Galilei Galileo was the first man to introduce the telescope. An experienced eyeglass maker from Holland, Hans Lippershey was the first to be credited and acknowledged as having assembled an instrument like the telescope that allows users to use both eyes to view distant objects. He made the invention widely known. When Lippershey gained a 30-year patent that would have given him mutually exclusive rights to his invention, a bureaucrat in charge of approvals requested that he produce a telescope with two eyepiece and optics of quartz. The instrument was completed, and it received approval in 1608. But the patent rights weren’t granted to Lippershey based on the fact that other people were already aware of the invention. binoculars-on-carpet Some scholars had their doubts as regards the new invention while others had praise for Lippershey. Louise Bell speculated that the new instrument had a power of 3 or 4 times with an objective of an inch-and-one-half or less in diameter. Henry King, another authority on the history of the telescope, agreed with Bell as he said that quartz was more difficult to work with and the so the request for crystal optics was mainly because of the low quality of optical glasses in that period. During the civil war, a Robert Tolles made available a supply of field glasses which Henry Fitz and Alvan Clark each used to produce a binocular. Though in February 1865, the Clark glass was tested, but only one device was completed by the end of the war. History has it that none of these binoculars currently exist. Then came Ignatio Porro with prisms in binoculars. The modern prism binocular started with his 1854 Italian patent for a prism-erecting system. In the 1860s, monoculars that used the same prism configuration with the modern porro prism binoculars were produced through work he did Paris with Jean Georges Hofmann, who was a German optician. Other makers of porro-prism optics include the companies Nachet in 1875, Emil Busch in 1865 and Boulanger in 1859. Some manufacturers made prism binoculars that were a combination of low-quality of glasses and optical designs that were unrefined, and their production techniques resulted in a failed venture. It is unknown if any of those binoculars survived. Ernst Abbe, a German optical designer showcased a prism telescope at the Vienna Trade Fair in 1873. The invention was designed using Porro’s ideas but without the knowledge of the previous work. Abbe wanted to cement the prisms initially, but he put it on hold in order to develop the theoretical basis of the modern microscope. He was associated with Otto Schott, a glassmaker, and Carl Zeiss, an instrument maker and this resulted in quite a series of innovations by the German optical industry. As history records, in 1894, the first quality binoculars with a modern design were sold and it was a result of the optical designs of Ernst Abbe teamed with the production abilities Carl Zeiss brought to the binocular industry. Take a look at our guide to binocular maintenance to see how you can prolong the life and maintain the performance of your favorite bird watching tool. You don’t want to miss our guide to the top spotting scopes for every budget either. You can see it here. Stay tuned for lots more at Stealthy Ninjas over the coming weeks. We’ll be reviewing the top binoculars for various activities in the near future. Binoculars or field glasses are two refracting telescopes mounted side-by-side and aligned to point in the same direction, allowing the viewer to use both eyes (binocular vision) when viewing distant objects. Most binoculars are sized to be held using both hands, although sizes vary widely from opera glasses to large pedestal-mounted military models. Unlike a (monocular) telescope, binoculars give users a three-dimensional image: each eyepiece presents a slightly different image to each of the viewer's eyes and the parallax allows the visual cortex to generate an impression of depth. Optical designs Galilean 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. The Galilean design is also used in low magnification binocular surgical and jewelers' loupes because they can be very short and produce an upright image without extra or unusual erecting optics, reducing expense and overall weight. They also have large exit pupils, making centering less critical, and the narrow field of view works well in those applications.[2] These are typically mounted on an eyeglass frame or custom-fit onto eyeglasses. Keplerian An improved image and higher magnification are achieved in binoculars employing Keplerian optics, where the image formed by the objective lens is viewed through a positive eyepiece lens (ocular). Since the Keplerian configuration produces an inverted image, different methods are used to turn the image the right way up. Erecting lenses In aprismatic binoculars with Keplerian optics (which were sometimes called "twin telescopes"), each tube has one or two additional lenses (relay lens) between the objective and the eyepiece. These lenses are used to erect the image. The binoculars with erecting lenses had a serious disadvantage: they are too long. Such binoculars were popular in the 1800s (for example, G.& S. Merz models). The Keplerian "twin telescopes" binoculars were optically and mechanically hard to manufacture, but it took until the 1890s to supersede them with better prism-based technology.[3][4] Prism Optical prisms added to the design enabled the display of the image the right way up without needing as many lenses, and decreasing the overall length of the instrument, typically using Porro prism or roof prism systems.[5][6] The Italian optical inventor of optical instruments Ignazio Porro worked during the 1860s with Hofmann in Paris to produce monoculars using the same prism configuration used in modern Porro prism binoculars. At the 1873 Vienna Trade Fair German optical designer and scientist Ernst Abbe displayed a prism telescope with two cemented Porro prisms. The optical solutions of Porro and Abbe were theoretically sound, but the employed prism systems failed in practice primarily due to insufficient glass quality.[7][1] Porro Double Porro prism design Porro prism binoculars are named after Ignazio Porro, who patented this image erecting system in 1854. The later refinement by Ernst Abbe and his cooperation with glass scientist Otto Schott and instrument maker Carl Zeiss resulted in 1894 in the commercial introduction of improved 'modern' Porro prism binoculars by the Carl Zeiss company.[1] Binoculars of this type use a pair of Porro prisms in a Z-shaped configuration to erect the image. This results in wide binoculars, with objective lenses that are well separated and offset from the eyepieces, giving a better sensation of depth. 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. Porro prism binoculars were made in such a way to erect an image in a relatively small space, thus binoculars using prisms started in this way. Porro prisms require typically within 10 arcminutes (1/6 of 1 degree) tolerances for alignment of their optical elements (collimation) at the factory. Sometimes Porro prisms binoculars need their prisms set to be re-aligned to bring them into collimation.[8] Good-quality Porro prism design binoculars often feature about 1.5 millimetres (0.06 in) deep grooves or notches ground across the width of the hypotenuse face center of the prisms, to eliminate image quality reducing abaxial non-image-forming reflections.[9] Porro prism binoculars can offer good optical performance with relatively little manufacturing effort and as human eyes are ergonomically limited by their interpupillary distance the offset and separation of big (60+ mm wide) diameter objective lenses and the eyepieces becomes a practical advantage in a stereoscopic optical product. In the early 2020s, the commercial market share of Porro prism-type binoculars had become the second most numerous compared to other prism-type optical designs.[10] There are alternative Porro prism-based systems available that find application in binoculars on a small scale, like the Perger prism that offers a significantly reduced axial offset compared to traditional Porro prism designs .[11][12] Roof Schmidt–Pechan "roof" prism design Abbe–Koenig "roof" prism design Roof prism binoculars may have appeared as early as the 1870s in a design by Achille Victor Emile Daubresse.[13][14] In 1897 Moritz Hensoldt began marketing pentaprism based roof prism binoculars.[15] Most roof prism binoculars use either the Schmidt–Pechan prism (invented in 1899) or the Abbe–Koenig prism (named after Ernst Karl Abbe and Albert König and patented by Carl Zeiss in 1905) designs to erect the image and fold the optical path. They have objective lenses that are approximately in a line with the eyepieces.[16] Binoculars with roof prisms have been in use to a large extent since the second half of the 20th century. Roof prism designs result in objective lenses that are almost or totally in line with the eyepieces, creating an instrument that is narrower and more compact than Porro prisms and lighter. There is also a difference in image brightness. Porro prism and Abbe–Koenig roof-prism binoculars will inherently produce a brighter image than Schmidt–Pechan roof prism binoculars of the same magnification, objective size, and optical quality, because the Schmidt-Pechan roof-prism design employs mirror-coated surfaces that reduce light transmission. In roof prism designs, optically relevant prism angles must be correct within 2 arcseconds (1/1,800 of 1 degree) to avoid seeing an obstructive double image. Maintaining such tight production tolerances for the alignment of their optical elements by laser or interference (collimation) at an affordable price point is challenging. To avoid the need for later re-collimation, the prisms are generally aligned at the factory and then permanently fixed to a metal plate.[17] These complicating production requirements make high-quality roof prism binoculars more costly to produce than Porro prism binoculars of equivalent optical quality and until phase correction coatings were invented in 1988 Porro prism binoculars optically offered superior resolution and contrast to non-phase corrected roof prism binoculars.[16][17][18][19] In the early 2020s, the commercial offering of Schmidt-Pechan designs exceeds the Abbe-Koenig design offerings and had become the dominant optical design compared to other prism-type designs.[20] Alternative roof prism-based designs like the Uppendahl prism system composed of three prisms cemented together were and are commercially offered on a small scale.[21][22] Common optical systems and their practical effect on binoculars housing shapes Binoculars diagram showing a Porro prism design Binoculars diagram showing a Porro prism design Porro prism binoculars, with distinctive eyepiece/objective axis offset Porro prism binoculars, with distinctive eyepiece/objective axis offset Binoculars diagram showing a Schmidt–Pechan roof prism design Binoculars diagram showing a Schmidt–Pechan roof prism design Binoculars diagram showing an Abbe–Koenig roof prism design Binoculars diagram showing an Abbe–Koenig roof prism design Roof prism binoculars, with the eyepiece in line with the objective Roof prism binoculars, with the eyepiece in line with the objective The optical system of modern binoculars consists of three main optical assemblies:[23] Objective lens assembly. This is the lens assembly at the front of the binoculars. It gathers light from the object and forms an image at the image plane. Image orientation correction assembly. This is usually a prism assembly that shortens the optical path. Without this, the image would be inverted and laterally reversed, which is inconvenient for the user. Eyepiece lens assembly. This is the lens assembly near the user's eyes. Its function is to magnify the image. Although different prism systems have optical design-induced advantages and disadvantages when compared, due to technological progress in fields like optical coatings, optical glass manufacturing, etcetera, differences in the early 2020s in high-quality binoculars practically became irrelevant. At high-quality price points, similar optical performance can be achieved with every commonly applied optical system. This was 20–30 years earlier not possible, as occurring optical disadvantages and problems could at that time not be technically mitigated to practical irrelevancy. Relevant differences in optical performance in the sub-high-quality price categories can still be observed with roof prism-type binoculars today because well-executed technical problem mitigation measures and narrow manufacturing tolerances remain difficult and cost-intensive. Optical parameters Parameters listed on the prism cover plate describing 7 power magnification binoculars with a 50 mm objective diameter and a 372 foot (113.39 m) field of view at 1,000 yards (914.4 m) Binoculars are usually designed for specific applications. These different designs require certain optical parameters which may be listed on the prism cover plate of the binoculars. Those parameters are: Magnification Given as the first number in a binocular description (e.g., 7×35, 10×50), magnification is the ratio of the focal length of the objective divided by the focal length of the eyepiece. This gives the magnifying power of binoculars (sometimes expressed as "diameters"). A magnification factor of 7, for example, produces an image 7 times larger than the original seen from that distance. The desirable amount of magnification depends upon the intended application, and in most binoculars is a permanent, non-adjustable feature of the device (zoom binoculars are the exception). Hand-held binoculars typically have magnifications ranging from 7× to 10×, so they will be less susceptible to the effects of shaking hands.[24] A larger magnification leads to a smaller field of view and may require a tripod for image stability. Some specialized binoculars for astronomy or military use have magnifications ranging from 15× to 25×.[25] Objective diameter Given as the second number in a binocular description (e.g., 7×35, 10×50), the diameter of the objective lens determines the resolution (sharpness) and how much light can be gathered to form an image. When two different binoculars have equal magnification, equal quality, and produce a sufficiently matched exit pupil (see below), the larger objective diameter produces a "brighter" [a][26][27] and sharper image.[28][29] An 8×40, then, will produce a "brighter" and sharper image than an 8×25, even though both enlarge the image an identical eight times. The larger front lenses in the 8×40 also produce wider beams of light (exit pupil) that leave the eyepieces. This makes it more comfortable to view with an 8×40 than an 8×25. A pair of 10×50 binoculars is better than a pair of 8×40 binoculars for magnification, sharpness and luminous flux. Objective diameter is usually expressed in millimeters. It is customary to categorize binoculars by the magnification × the objective diameter; e.g., 7×50. Smaller binoculars may have a diameter of as low as 22 mm; 35 mm and 50 mm are common diameters for field binoculars; astronomical binoculars have diameters ranging from 70 mm to 150 mm.[25] Field of view The field of view of a pair of binoculars depends on its optical design and in general is inversely proportional to the magnifying power. 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 The small exit pupil of a 25×30 telescope and large exit pupils of 9×63 binoculars suitable for use in low light Binoculars concentrate the light gathered by the objective into a beam, of which its diameter, the exit pupil, is the objective diameter divided by the magnifying power. For maximum effective light-gathering and brightest image, and to maximize the sharpness,[26] the exit pupil should at least equal the diameter of the pupil of the human eye: about 7 mm at night and about 3 mm in the daytime, decreasing with age. If the cone of light streaming out of the binoculars is larger than the pupil it is going into, any light larger than the pupil is wasted. In daytime use, the human pupil is typically dilated about 3 mm, which is about the exit pupil of a 7×21 binocular. Much larger 7×50 binoculars will produce a (7.14 mm) cone of light bigger than the pupil it is entering, and this light will, in the daytime, be wasted. An exit pupil that is too small also will present an observer with a dimmer view, since only a small portion of the light-gathering surface of the retina is used.[26][30] For applications where equipment must be carried (birdwatching, hunting), users opt for much smaller (lighter) binoculars with an exit pupil that matches their expected iris diameter so they will have maximum resolution but are not carrying the weight of wasted aperture.[29] 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, especially in large field of view binoculars, vignetting, which brings to the viewer an image with its borders darkened because the light from them 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, or for a seafarer on the deck of a pitching vessel or observing from a moving vehicle. Narrow exit pupil binoculars also may 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 dawn, at dusk, in overcast conditions, or 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 satisfactory choices even if their capability is not fully used by day. Twilight factor and relative brightness Before innovations like anti-reflective coatings were commonly used in binoculars, their performance was often mathematically expressed. Nowadays, the practically achievable instrumentally measurable brightness of binoculars rely on a complex mix of factors like the quality of optical glass used and various applied optical coatings and not just the magnification and the size of objective lenses. The twilight factor for binoculars can be calculated by first multiplying the magnification by the objective lens diameter and then finding the square root of the result. For instance, the twilight factor of 7×50 binoculars is therefore the square root of 7 × 50: the square root of 350 = 18.71. The higher the twilight factor, mathematically, the better the resolution of the binoculars when observing under dim light conditions. Mathematically, 7×50 binoculars have exactly the same twilight factor as 70×5 ones, but 70×5 binoculars are useless during twilight and also in well-lit conditions as they would offer only a 0.14 mm exit pupil. The twilight factor without knowing the accompanying more decisive exit pupil does not permit a practical determination of the low light capability of binoculars. Ideally, the exit pupil should be at least as large as the pupil diameter of the user's dark-adapted eyes in circumstances with no extraneous light.[31] A primarily historic, more meaningful mathematical approach to indicate the level of clarity and brightness in binoculars was relative brightness. It is calculated by squaring the diameter of the exit pupil. In the above 7×50 binoculars example, this means that their relative brightness index is 51 (7.14 × 7.14 = 51). The higher the relative brightness index number, mathematically, the better the binoculars are suited for low light use.[32] Eye relief Eye relief is the distance from the rear eyepiece lens to the exit pupil or eye point.[33] 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 potential eye relief. Binoculars may have eye relief ranging from a few millimeters to 25 mm or more. Eye relief can be particularly important for eyeglasses wearers. The eye of an eyeglasses wearer is typically farther from the eye piece which necessitates a longer eye relief in order to avoid vignetting and, in the extreme cases, to conserve 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. Eyeglasses wearers who intend to wear their glasses when using binoculars should look for binoculars with an eye relief that is long enough so that their eyes are not behind the point of focus (also called the eyepoint). Else, their glasses will occupy the space where their eyes should be. Generally, an eye relief over 16 mm should be adequate for any eyeglass wearer. However, if glasses frames are thicker and so significantly protrude from the face, an eye relief over 17 mm should be considered. Eyeglasses wearers should also look for binoculars with twist-up eye cups that ideally have multiple settings, so they can be partially or fully retracted to adjust eye relief to individual ergonomic preferences.[34] Close focus distance Close focus distance is the closest point that the binocular can focus on. This distance varies from about 0.5 to 30 m (2 to 98 ft), depending upon the design of the binoculars. If the close focus distance is short with respect to the magnification, the binocular can be used also to see particulars not visible to the naked eye. Eyepieces Main article: Eyepiece Binocular eyepieces usually consist of three or more lens elements in two or more groups. The lens furthest from the viewer's eye is called the field lens or objective lens and that closest to the eye the eye lens or ocular lens. The most common Kellner configuration is that invented in 1849 by Carl Kellner. In this arrangement, the eye lens is a plano-concave/ double convex achromatic doublet (the flat part of the former facing the eye) and the field lens is a double-convex singlet. A reversed Kellner eyepiece was developed in 1975 and in it the field lens is a double concave/ double convex achromatic doublet and the eye lens is a double convex singlet. The reverse Kellner provides 50% more eye relief and works better with small focal ratios as well as having a slightly wider field.[35] Wide field binoculars typically utilize some kind of Erfle configuration, patented in 1921. These have five or six elements in three groups. The groups may be two achromatic doublets with a double convex singlet between them or may all be achromatic doublets. These eyepieces tend not to perform as well as Kellner eyepieces at high power because they suffer from astigmatism and ghost images. However they have large eye lenses, excellent eye relief, and are comfortable to use at lower powers.[35] Field flattener lens High-end binoculars often incorporate a field flattener lens in the eyepiece behind their prism configuration, designed to improve image sharpness and reduce image distortion at the outer regions of the field of view.[36] Mechanical design Focus and adjustment Independent focusing binoculars as used by the British military Porro type, external eyepiece bridge central-focusing binoculars with a rotating diopter on the right eyepiece allowing to adjust refractive differences between the viewer's left and right eyes Binoculars have a focusing arrangement which changes the distance between eyepiece and objective lenses or internally mounted lens elements. Normally there are two different arrangements used to provide focus, "independent focus" and "central focusing": Independent focusing is an arrangement where the two telescope tubes are focused independently by adjusting each eyepiece. Binoculars designed for harsh environmental conditions and heavy field use, such as military or marine applications, traditionally have used independent focusing. Central focusing is an arrangement which involves rotation of a central focusing wheel to adjust both telescope tubes together. 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 dioptre, the adjustable eyepiece itself is often called a dioptre. 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 adjust both tubes together without eyepiece readjustment. Central focusing binoculars can be further subdivided into: External focusing, which focuses binoculars by moving the eyepieces, where the volume of the binoculars always changes. During this process, external air and also small dust particles and moisture can be drawn into or pressed out of the binoculars. It is hard to seal or waterproof such systems and in case the eyepieces are moved by a central focuser shaft and external eyepiece arms bridge construction, this construction can (accidentally) get bent/deformed that can result in disabling misalignment. Internal focusing, which focuses binoculars by moving internal mounted optical lenses located between the objective lens group and the prism assembly – or rarely located between the prism assembly and eyepiece lens assembly[22][37] – within the housing without changing the volume of the binoculars. The addition of a focusing lens reduces the light transmission of the optical system contained in the telescope tube somewhat. Internal focusing is generally considered the mechanically more robust central focusing solution and with the help of an appropriate seal like O-rings air and moisture ingress can be prevented, to make binoculars fully waterproof.[38] With increasing magnification, the depth of field – the distance between the nearest and the farthest objects that are in acceptably sharp focus in an image – decreases. The depth of field reduces quadratic with the magnification, so compared to 7× binoculars, 10× binoculars offer about half (7² ÷ 10² = 0.49) the depth of field. However, not related to the binoculars optical system, the user perceived practical depth of field or depth of acceptable view performance is also dependent on the accommodation ability (accommodation ability varies from person to person and decreases significantly with age) and light conditions dependent effective pupil size or diameter of the user's eyes. There are "focus-free" or "fixed-focus" binoculars that have no focusing mechanism other than the eyepiece adjustments that are meant to be set for the user's eyes and left fixed. These are considered to be compromise designs, suited for convenience, but not well suited for work that falls outside their designed hyperfocal distance range (for hand held binoculars generally from about 35 m (38 yd) to infinity without performing eyepiece adjustments for a given viewer).[39] Binoculars can be generally used without eyeglasses by myopic (near-sighted) or hyperopic (far-sighted) users simply by adjusting the focus a little farther. Most manufacturers leave a little extra available focal-range beyond the infinity-stop/setting to account for this when focusing for infinity.[citation needed] People with severe astigmatism, however, will still need to use their glasses while using binoculars. Some binoculars have adjustable magnification, zoom binoculars, such as 7-21×50 intended to give the user the flexibility of having a single pair of binoculars with a wide range of magnifications, usually by moving a "zoom" lever. This is accomplished by a complex series of adjusting lenses similar to a zoom camera lens. These designs are noted to be a compromise and even a gimmick[40] since they add bulk, complexity and fragility to the binocular. The complex optical path also leads to a narrow field of view and a large drop in brightness at high zoom.[41] Models also have to match the magnification for both eyes throughout the zoom range and hold collimation to avoid eye strain and fatigue.[42] These almost always perform much better at the low power setting than they do at the higher settings. This is natural, since the front objective cannot enlarge to let in more light as the power is increased, so the view gets dimmer. At 7×, the 50mm front objective provides a 7.14 mm exit pupil, but at 21×, the same front objective provides only a 2.38 mm exit pupil. Also, the optical quality of a zoom binocular at any given power is inferior to that of a fixed power binocular of that power. Interpupillary distance Binoculars with adjustable interpupillary distance set for about 63 mm Most modern binoculars are also adjustable via a hinged construction that enables the distance between the two telescope halves to be adjusted to accommodate viewers with different eye separation or "interpupillary distance (IPD)" (the distance measured in millimeters between the centers of the pupils of the eyes). Most are optimized for the interpupillary distance (typically about 63 mm) for adults. Interpupillary distance varies with respect to age, gender and race. The binoculars industry has to take IPD variance (most adults have IPDs in the 50–75 mm range) and its extrema into account, because stereoscopic optical products need to be able to cope with many possible users, including those with the smallest and largest IPDs.[43] Children and adults with narrow IPDs can experience problems with the IPD adjustment range of binocular barrels to match the width between the centers of the pupils in each eye impairing the use of some binoculars.[44][45] Adults with average or wide IPDs generally experience no eye separation adjustment range problems, but straight barreled roof prism binoculars featuring over 60 mm diameter objectives can dimensionally be problematic to correctly adjust for adults with a relatively narrow IPDs.[46] Anatomic conditions like hypertelorism and hypotelorism can affect IPD and due to extreme IPDs result in practical impairment of using stereoscopic optical products like binoculars. Alignment The two telescopes in binoculars are aligned in parallel (collimated), to produce a single circular, apparently three-dimensional, image. Misalignment will cause the binoculars to produce a double image. Even slight misalignment will cause vague discomfort and visual fatigue as the brain tries to combine the skewed images.[47] Alignment is performed by small movements to the prisms, by adjusting an internal support cell or by turning external set screws, or by adjusting the position of the objective via eccentric rings built into the objective cell. Unconditional aligning (3-axis collimation, meaning both optical axes are aligned parallel with the axis of the hinge used to select various interpupillary distance settings) binoculars requires specialized equipment.[8] Unconditional alignment is usually done by a professional, although the externally mounted adjustment features can usually be accessed by the end user. Conditional alignment ignores the third axis (the hinge) in the alignment process. Such a conditional alignment comes down to a 2-axis pseudo-collimation and will only be serviceable within a small range of interpupillary distance settings, as conditional aligned binoculars are not collimated for the full interpupillary distance setting range. Image stability Some binoculars use image-stabilization technology to reduce shake at higher magnifications. This is done by having a gyroscope move part of the instrument, or by powered mechanisms driven by gyroscopic or inertial detectors, or via a mount designed 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. Housing Binoculars housings can be made of various structural materials. Old binoculars barrels and hinge bridges were often made of brass. Later steel and relatively light metals like aluminum and magnesium alloys were used, as well as polymers like (fibre-reinforced) polycarbonate and acrylonitrile butadiene styrene. The housing can be rubber armored externally as outer covering to provide a non-slip gripping surface, absorption of undesired sounds and additional cushioning/protection against dents, scrapes, bumps and minor impacts.[48][49] Optical coatings Main article: Optical coating Binoculars with red-colored multicoatings Because a typical binocular has 6 to 10 optical elements [50] with special characteristics and up to 20 atmosphere-to-glass surfaces, binocular manufacturers use different types of optical coatings for technical reasons and to improve the image they produce. Lens and prism optical coatings on binoculars can increase light transmission, minimize detrimental reflections and interference effects, optimize beneficial reflections, repel water and grease and even protect the lens from scratches. Modern optical coatings are composed of a combination of very thin layers of materials such as oxides, metals, or rare earth materials. The performance of an optical coating is dependent on the number of layers, manipulating their exact thickness and composition, and the refractive index difference between them.[51] These coatings have become a key technology in the field of optics and manufacturers often have their own designations for their optical coatings. The various lens and prism optical coatings used in high-quality 21st century binoculars, when added together, can total about 200 (often superimposed) coating layers.[52] Anti-reflective Main article: Anti-reflective coating A quarter-wavelength (λ) thick anti-reflection coating, which leads to destructive interference Anti-reflective interference coatings reduce light lost at every optical surface through reflection at each surface. Reducing reflection via anti-reflective coatings also reduces the amount of "lost" light present inside the binocular which would otherwise make the image appear hazy (low contrast). A pair of binoculars with good optical coatings may yield a brighter image than uncoated binoculars with a larger objective lens, on account of superior light transmission through the assembly. The first transparent interference-based coating Transparentbelag (T) used by Zeiss was invented in 1935 by Olexander Smakula.[53] A classic lens-coating material is magnesium fluoride, which reduces reflected light from about 4% to 1.5%. At 16 atmosphere to optical glass surfaces passes, a 4% reflection loss theoretically means a 52% light transmission (0.9616 = 0.520) and a 1.5% reflection loss a much better 78.5% light transmission (0.98516 = 0.785). Reflection can be further reduced over a wider range of wavelengths and angles by using several superimposed layers with different refractive indices. The anti-reflective multi-coating Transparentbelag* (T*) used by Zeiss in the late 1970s consisted of six superimposed layers. In general, the outer coating layers have slightly lower index of refraction values and the layer thickness is adapted to the range of wavelengths in the visible spectrum to promote optimal destructive interference via reflection in the beams reflected from the interfaces, and constructive interference in the corresponding transmitted beams. There is no simple formula for the optimal layer thickness for a given choice of materials. These parameters are therefore determined with the help of simulation programs. Determined by the optical properties of the lenses used and intended primary use of the binoculars, different coatings are preferred, to optimize light transmission dictated by the human eye luminous efficiency function variance. Maximal light transmission around wavelengths of 555 nm (green) is important for obtaining optimal photopic vision using the eye cone cells for observation in well-lit conditions. Maximal light transmission around wavelengths of 498 nm (cyan) is important for obtaining optimal scotopic vision using the eye rod cells for observation in low light conditions. As a result, effective modern anti-reflective lens coatings consist of complex multi-layers and reflect only 0.25% or less to yield an image with maximum brightness and natural colors.[54] These allow high-quality 21st century binoculars to practically achieve at the eye lens or ocular lens measured over 90% light transmission values in low light conditions. Depending on the coating, the character of the image seen in the binoculars under normal daylight can either look "warmer" or "colder" and appear either with higher or lower contrast. Subject to the application, the coating is also optimized for maximum color fidelity through the visible spectrum, for example in the case of lenses specially designed for bird watching.[55][56][57] A common application technique is physical vapor deposition of one or more superimposed anti-reflective coating layer(s) which includes evaporative deposition, making it a complex production process.[58] Phase correction Beam path at the roof edge (cross-section); the P-coating layer is on both roof surfaces In binoculars with roof prisms the light path is split into two paths that reflect on either side of the roof prism 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. If the roof faces are uncoated, the mechanism of reflection is Total Internal Reflection (TIR). In TIR, light polarized in the plane of incidence (p-polarized) and light polarized orthogonal to the plane of incidence (s-polarized) experience different phase shifts. As a consequence, linearly polarized light emerges from a roof prism elliptically polarized. Furthermore, the state of elliptical polarization of the two paths through the prism is different. When the two paths recombine on the retina (or a detector) there is interference between light from the two paths causing a distortion of the Point Spread Function and a deterioration of the image. Resolution and contrast significantly suffer. These unwanted interference effects can be suppressed by vapor depositing a special dielectric coating known as a phase-correction coating or P-coating on the roof surfaces of the roof prism. To approximately correct a roof prism for polychromatic light several phase-correction coating layers are superimposed, since every layer is wavelength and angle of incidence specific.[59] The P-coating was developed in 1988 by Adolf Weyrauch at Carl Zeiss.[60] Other manufacturers followed soon, and since then phase-correction coatings are used across the board in medium and high-quality roof prism binoculars. This coating suppresses the difference in phase shift between s- and p- polarization so both paths have the same polarization and no interference degrades the image.[61] In this way, since the 1990s, roof prism binoculars have also achieved resolution values that were previously only achievable with Porro prisms.[62] The presence of a phase-correction coating can be checked on unopened binoculars using two polarization filters.[60] Dielectric phase-correction prism coatings are applied in a vacuum chamber with maybe thirty or more different superimposed vapor coating layers deposits, making it a complex production process. Binoculars using either a Schmidt–Pechan roof prism, Abbe–Koenig roof prism or an Uppendahl roof prism benefit from phase coatings that compensate for a loss of resolution and contrast caused by the interference effects that occur in untreated roof prisms. Porro prism and Perger prism binoculars do not split beams and therefore they do not require any phase coatings. Metallic mirror Main article: Mirror In binoculars with Schmidt–Pechan or Uppendahl roof prisms, mirror coatings are added to some surfaces of the roof prism because the light is incident at one of the prism's 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. Roof prism aluminum mirror coating (reflectivity of 87% to 93%) or silver mirror coating (reflectivity of 95% to 98%) is used.[63][64] In older 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 they did not tarnish even though they have a lower reflectivity than silver. Using vacuum-vaporization technology, modern designs use either aluminum, enhanced aluminum (consisting of aluminum overcoated with a multilayer dielectric film) or silver.[65] Silver is used in modern high-quality designs which are sealed and filled with nitrogen or argon to provide an inert atmosphere so that the silver mirror coating does not tarnish.[66] Porro prism and Perger prism binoculars and roof prism binoculars using the Abbe–Koenig roof prism configuration do not use mirror coatings because these prisms reflect with 100% reflectivity using total internal reflection in the prism rather than requiring a (metallic) mirror coating. Dielectric mirror Main article: Dielectric mirror Diagram of a dielectric mirror. Thin layers with a high refractive index n1 are interleaved with thicker layers with a lower refractive index n2. The path lengths lA and lB differ by exactly one wavelength, which leads to constructive interference. Dielectric coatings are used in Schmidt–Pechan and Uppendahl roof prisms to cause the prism surfaces to act as a dielectric mirror. This coating was introduced in 2004 in Zeiss Victory FL binoculars featuring Schmidt–Pechan prisms. Other manufacturers followed soon, and since then dielectric coatings are used across the board in medium and high-quality Schmidt–Pechan and Uppendahl roof prism binoculars. The non-metallic dielectric reflective coating is formed from several multilayers of alternating high and low refractive index materials deposited on a prism's reflective surfaces. The manufacturing techniques for dielectric mirrors are based on thin-film deposition methods. A common application technique is physical vapor deposition which includes evaporative deposition with maybe seventy or more different superimposed vapor coating layers deposits, making it a complex production process.[67] This multilayer coating increases reflectivity from the prism surfaces by acting as a distributed Bragg reflector. A well-designed multilayer dielectric coating can provide a reflectivity of over 99% across the visible light spectrum.[68] This reflectivity is an improvement compared to either an aluminium mirror coating or silver mirror coating. Porro prism and Perger prism binoculars and roof prism binoculars using the Abbe–Koenig roof prism do not use dielectric coatings because these prisms reflect with 100% reflectivity using total internal reflection in the prism rather than requiring a (dielectric) mirror coating. Terms All binoculars 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.[69] 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. The presence of optical high transmittance crown glass offering relatively low refractive index (≈1.52) and low dispersion (with Abbe numbers around 60) is typically denoted on binoculars by the following terms:[70] BK7 (Schott designates it as 517642. The first three digits designate its refractive index [1.517] and the last three designate its Abbe number [64.2]. Its critical angle is 41.2°.) BaK4 (Schott designates it as 569560. The first three digits designate its refractive index [1.569] and the last three designate its Abbe number [56.0]. Its critical angle is 39.6°.) Roof prisms only phase-coated or P-coating: the roof prism has a phase-correcting coating aluminium-coated: the roof prism mirrors are coated with an aluminium 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 Accessories Binoculars with eyepieces resting on a rainguard all connected by a neck strap Deer hunters using binoculars harnesses suitable for prolonged carrying Common accessories for binoculars are: neck and shoulder straps for carrying binocular harnesses (sometimes combined with an integrated field case) to distribute weight evenly for prolonged carrying field carrying cases/side bags binoculars storage/travel cases rainguards for protecting the eyepieces outer lenses (tethered) lens caps for protecting the objectives outer lenses cleaning kits to carefully remove dirt from lenses and other surfaces tripod adapters Applications General use Trinovid 8×20 C folded for storage[71] Trinovid 8×20 C expanded for use Compact binoculars with double bridge Tower Optical coin-operated binocular tower viewers Hand-held binoculars range from small 3 × 10 Galilean opera glasses, used in theaters, to glasses with 7 to 12 times magnification and 30 to 50 mm diameter objectives for typical outdoor use. Compact or pocket binoculars are small light binoculars suitable for daytime use. Most compact binoculars feature magnifications of 7× to 10×, and objective diameter sizes of a relatively modest 20 mm to 25 mm, resulting in small exit pupil sizes limiting low light suitability. Roof prim designs tend to be narrower and more compact than equivalent Porro prism designs. Thus, compact binoculars are mostly roof prism designs. The telescope tubes of compact binoculars can often be folded closely to each other to radically reduce the binocular's volume when not in use, for easy carriage and storage. Many tourist attractions have installed pedestal-mounted, coin-operated binocular tower viewers to allow visitors to obtain a closer view of the attraction. Land surveys and geographic data collection Although technology has surpassed using binoculars for data collection, historically these were advanced tools used by geographers and other geoscientists. Field glasses still today can provide visual aid when surveying large areas. Bird watching Birdwatching is a very popular hobby among nature and animal lovers; a binocular is their most basic tool because most human eyes cannot resolve sufficient detail to fully appreciate and/or study small birds.[72] To be able to view birds in flight well rapid moving objects acquiring capability and depth of field are important. Typically, binoculars with a magnification of 8× to 10× are used, though many manufacturers produce models with 7× magnification for a wider field of view and increased depth of field. The other main consideration for birdwatching binoculars is the size of the objective that collects light. A larger (e.g. 40–45mm) objective works better in low light and for seeing into foliage, but also makes for a heavier binocular than a 30–35mm objective. Weight may not seem a primary consideration when first hefting a pair of binoculars, but birdwatching involves a lot of holding up the binoculars while standing in one place. Careful shopping is advised by the birdwatching community.[73] Hunting Hunters commonly use binoculars in the field as a way to observe distant game animals. Hunters most commonly use about 8× magnification binoculars with 40–45mm objectives to be able to find and observe game in low light conditions.[74] European manufacturers produced and produce 7×42 binoculars with good low light performance without getting too bulky for mobile use like extended carrying/stalking and much bigger bulky 8×56 and 9×63 low-light binoculars optically optimized for excellent low light performance for more stationary hunting at dusk and night. For hunting binoculars optimized for observation in twilight, coatings are preferred that maximize light transmission in the wavelength range around 460-540 nm.[75][76][77][46][78] Range finding Some binoculars have a range finding reticle (scale) superimposed upon the view. This scale allows the distance to the object to be estimated if the object's height is known (or estimable). The common mariner 7×50 binoculars have these scales with the angle between marks equal to 5 mil.[79] 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: D = O H Mil × 1000 D={\frac {OH}{{\text{Mil}}}}\times 1000 where: D D is the Distance to the object in meters. O H OH is the known Object Height. Mil {\text{Mil}} is the angular height of the object in number of Mil. With the typical 5 mil scale (each mark is 5 mil), a lighthouse that is 3 marks high and known to be 120 meters tall is 8000 meters distant. 8000 m = 120 m 15 mil × 1000 8000{\text{m}}={\frac {120{\text{m}}}{15{\text{mil}}}}\times 1000 Military Vector series laser rangefinder 7×42 binoculars can measure distance and angles and also features a 360° digital compass and class 1 eye safe filters German U.D.F. 7×50 blc U-boat binoculars (1939–1945)[80] 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 rugged than their civilian counterparts. They generally avoid 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. One variant form was called "trench binoculars", a combination of binoculars and periscope, often used for artillery spotting purposes. It projected only a few inches above the parapet, thus keeping the viewer's head safely in the trench. Military binoculars can and were also used as measuring and aiming devices, and can feature filters and (illuminated) reticles.[81][82] 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 used as weapons. Further, binoculars designed for military usage may include a stadiametric reticle in one eyepiece in order to facilitate range estimation.[83] Modern binoculars designed for military usage can also feature laser rangefinders, compasses, and data exchange interfaces to send measurements to other peripheral devices.[84] 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 radar and laser range finding technology made this application mostly redundant.[citation needed] Marine 7×50 marine binoculars with dampened compass US Naval ship 'Big eyes' 20×120 binoculars in fixed mounting There are binoculars designed specifically for civilian and military use under harsh environmental conditions at sea. Hand held models will be 5× to 8× magnification, 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 binoculars are pitching and vibrating relative to the viewer's eyes due to a vessel's motion.[85] Marine binoculars often contain one or more features to aid in navigation on ships and boats. Hand held marine binoculars typically feature:[86] Sealed interior: O-rings or other seals prevent air and moisture ingress. Nitrogen or argon filled interior: the interior is filled with 'dry' gas to prevent internal fogging/tarnishing of the optical surfaces. As fungi can not grow in the presence of an inert or noble gas atmosphere, it also prevents lens fungus formation. Independent focusing: this method aids in providing a durable, sealed interior. Reticle scale: a navigational aid which uses a horizon line and a vertical scale for measuring the distance of objects of known width or height – sometimes an important navigational aid. Compass: A compass bearing projected in the image. Dampening helps to read the compass bearing on a moving ship or boat. Floating strap: some marine binoculars float on water, to prevent sinking. Marine binoculars that do not float are sometime supplied with or provided by the user as an aftermarket accessory with a strap that will function as a flotation device. Mariners also often deem an adequate low light performance of the optical combination important, explaining the many 7×50 hand held marine binoculars offerings featuring a large 7.14 mm exit pupil, which corresponds to the average pupil size of a youthful dark-adapted human eye in circumstances with no extraneous light. Civilian and military ships can also use large, high-magnification binocular models with large objectives in fixed mountings. Astronomical 25 × 150 binoculars adapted for astronomical use Binoculars are widely used by amateur astronomers; their wide field of view makes them useful for comet and supernova seeking (giant binoculars) and general observation (portable binoculars). Binoculars specifically geared towards astronomical viewing will have larger aperture objectives (in the 70 mm or 80 mm range) because the diameter of the objective lens increases the total amount of light captured, and therefore determines the faintest star that can be observed. Binoculars designed specifically for astronomical viewing (often 80 mm and larger) are sometimes designed without prisms in order to allow maximum light transmission. Such binoculars also usually have changeable eyepieces to vary magnification. Binoculars with high magnification and heavy weight usually require some sort of mount to stabilize the image. A magnification of 10x is generally considered the practical limit for observation with handheld binoculars. Binoculars more powerful than 15×70 require support of some type. Much larger binoculars have been made by amateur telescope makers, essentially using two refracting or reflecting astronomical telescopes. 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 the Milky Way and large nebulous objects (referred to as deep sky objects) such as the nebulae and galaxies. The large (typical 7.14 mm using 7×50) exit pupil [objective (mm)/power] of these devices results in a small portion of the gathered light not being usable by individuals whose pupils do not sufficiently dilate. For example, the pupils of those over 50 rarely dilate over 5 mm wide. The large exit pupil also collects more light from the background sky, effectively decreasing contrast, making the detection of faint objects more difficult except perhaps in remote locations with negligible light pollution. Many astronomical objects of 8 magnitude or brighter, such as the star clusters, nebulae and galaxies listed in the Messier Catalog, are readily viewed in hand-held binoculars in the 35 to 40 mm range, as are found in many households for birding, hunting, and viewing sports events. For observing smaller star clusters, nebulae, and galaxies binocular magnification is an important factor for visibility because these objects appear tiny at typical binocular magnifications.[87] A simulated view of how the Andromeda Galaxy (Messier 31) would appear in a pair of binoculars Some open clusters, 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 America Nebula (NGC 7000) in Cygnus are also readily viewed. Binoculars can show a few of the wider-split binary stars such as Albireo in the constellation Cygnus. A number of Solar System objects that are mostly to completely invisible to the human eye are reasonably detectable with medium-size binoculars, including larger craters on the Moon; the dim outer planets Uranus and Neptune; the inner "minor planets" Ceres, Vesta and Pallas; Saturn's largest moon Titan; and the Galilean moons of Jupiter. Although visible unaided in pollution-free skies, Uranus and Vesta require binoculars for easy detection. 10×50 binoculars are limited to an apparent magnitude of +9.5 to +11 depending on sky conditions and observer experience.[88] 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. Other difficult binocular targets include the phases of Venus and the rings of Saturn. Only binoculars with very high magnification, 20x or higher, are capable of discerning Saturn's rings to a recognizable extent. High-power binoculars can sometimes show one or two cloud belts on the disk of Jupiter, if optics and observing conditions are sufficiently good. Binoculars can also aid in observation of human-made space objects, such as spotting satellites in the sky as they pass. List of binocular manufacturers There are many companies that manufacturer binoculars, both past and present. They include: Barr and Stroud (UK) – sold binoculars commercially and primary supplier to the Royal Navy in WWII. The new range of Barr & Stroud binoculars are currently made in China (Nov. 2011) and distributed by Optical Vision Ltd. Bausch & Lomb (US) – 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. BELOMO (Belarus) – both porro prism and roof prism models manufactured. Bresser (Germany) Bushnell Corporation (US) Blaser – Premium binoculars[89] Canon Inc (Japan) – I.S. series: porro variants Celestron Docter Optics (Germany) – Nobilem series: porro prisms Fujinon (Japan) – FMTSX, FMTSX-2, MTSX series: porro I.O.R. (Romania) Kazan Optical-Mechanical Plant (KOMZ) (Russia) – manufactures a variety of porro prism models, sold under the trade name Baigish Kowa (Japan) Krasnogorsky Zavod (Russia) – both porro prism and roof prism models, models with optical stabilizers. The factory is part of the [[Rostec#Shvabe Holding[43]|Shvabe Holding Group]] Leica Camera (Germany) – Noctivid, Ultravid, Duovid, Geovid, Trinovid: most are roof prism, with a few high end porro prism examples Leupold & Stevens, Inc (US) Meade Instruments (US) – Glacier (roof prism), TravelView (porro), CaptureView (folding roof prism) and Astro Series (roof prism). Also sells under the name Coronado. Meopta (Czech Republic) – Meostar B1 (roof prism) Minox Nikon (Japan) – EDG, High Grade, Monarch, RAII, and Spotter series: roof prism; Prostar, Superior E, E, and Action EX series: porro; Prostaff series, Aculon series Olympus Corporation (Japan) Pentax (Japan) – DCFED/SP/XP series: roof prism; UCF series: inverted porro; PCFV/WP/XCF series: porro Sill Optics (Optolyth brand) [de] (Germany) – both porro prism and roof prism models[90] Steiner-Optik (in German) (Germany)[91] PRAKTICA (United Kingdom) for birdwatching, sightseeing, hiking, camping. Sunagor (Japan) Swarovski Optik[92] Takahashi Seisakusho (Japan) Tasco Vixen (telescopes) (Japan) – Apex/Apex Pro: roof prism; Ultima: porro Vivitar (US) Vortex Optics (US) Zeiss (Germany) – FL, Victory, Conquest: roof prism; 7×50 BGAT/T: porro, 15×60 BGA/T: porro, discontinued See also Anti-fog Binoviewer Globe effect Lens List of telescope types Monocular Optical telescope Spotting scope Tower viewer Notes "brightness" refers here to luminous flux on the retina and not to the photometrical definition of brightness: with the hypothesis of the match exit pupil, the (photometrical) brightness of the magnified scene (the illuminance of the retina) is the same (with an ideal lossless binoculars) as the one perceived by the naked eye in the same ambient light conditions, according to the conservation of luminance in lossless optical systems. 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Archived from the original on 2015-11-01. Retrieved 2022-05-24. "Image of a Uppendahl prism system used in Leitz Wetzlar, Trinovid 7×42B binoculars. The first Trinovid series featuring a Uppendahl prism system was made until 1990". 18 October 2012. Archived from the original on 2022-07-21. Retrieved 2022-07-21. PROPERTIES AND PERFORMANCE OF THE NEW LEICA TRINOVID 7X35B (=HERE NAMED RETROVID) COMPARED WITH OLDER LEITZ-LEICA TRINOVIDS AND WITH BINOCULARS FROM BECK, FOTON AND THE NEW KOWA 6,5X32. February 2020 by Dr. Gijs van Ginkel Binocular Lens And Prism Glass Clifford E. Swartz, Back-of-the-envelope Physics, JHU Press – 2003, page 73 Martin Mobberley, Astronomical Equipment for Amateurs, Springer Science & Business Media – 2012, pp. 53–55 "G. F. Lothian, Optics and its uses, Van Nostrand Reinhold Company, 1975, p. 37". Born, M.; Wolf, E. (1970). "Principles of Optics" (fifth ed.). Pergamon Press. pp. 188–190. Alan R. 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US Patent US3484149A Center focusing prism binocular and reticle "Binocular Basics". Archived from the original on 2022-02-28. Retrieved 2022-07-31. "Self Focusing Binoculars, Fixed Focus & Individual Focus Binoculars". Archived from the original on 2022-05-31. Retrieved 2022-05-13. Dunne, Pete (2003). Pete Dunne on Bird Watching: the how-to, where-to, and when-to of birding. Houghton Mifflin Harcourt. p. 54. ISBN 9780395906866. Archived from the original on 2016-12-27. Retrieved 2016-10-10. Harrington, Philip S. (2011). Star Ware: The Amateur Astronomer's Guide to Choosing, Buying, and Using. John Wiley & Sons. p. 54. ISBN 9781118046333. Archived from the original on 2016-12-27. Retrieved 2016-10-10. Tonkin, Stephen (2007). Binocular Astronomy: The Patrick Moore Practical Astronomy Series. Springer Science & Business Media. p. 46. ISBN 9781846287886. Archived from the original on 2016-12-28. Retrieved 2016-10-10. "Variation and extrema of human interpupillary distance, Neil A. Dodgson, University of Cambridge Computer Laboratory, 15 J. J. Thomson Avenue, Cambridge, UK CB3 0FD" (PDF). Archived (PDF) from the original on 2022-08-18. Retrieved 2022-04-20. "thebinocularsite.com — A Parent's Guide to Choosing Binoculars for Children". Archived from the original on June 6, 2011. "Kids Binoculars". Archived from the original on 2022-01-20. Retrieved 2022-04-19. "Optolyth Royal 9×63 Abbe-König, Binoculars". Archived from the original on 2022-05-31. Retrieved 2022-04-21. Stephen Mensing, Star gazing through binoculars: a complete guide to binocular astronomy, page 32 "What Is The Binoculars Housing Made Of". 11 April 2020. Archived from the original on 2022-05-31. Retrieved 2022-04-16. "About housings and focusing". 8 March 2021. Archived from the original on 2021-09-20. Retrieved 2022-07-31. Thompson, Robert Bruce; Thompson, Barbara Fritchman (2005). Astronomy Hacks: O'Reilly Series. O'Reilly Media, Inc. p. 35. ISBN 9780596100605. Archived from the original on 2016-12-27. Retrieved 2016-10-10. An Introduction to Optical Coatings Binocular Lens and Prism Coatings "History of Camera Lenses from Carl Zeiss — 1935 — Alexander Smakula develops anti-reflection coating". Archived from the original on 2016-10-08. Retrieved 2022-04-03. Anti-Reflection (AR) Coatings "ZEISS T* Coating". 13 July 2020. Archived from the original on 2022-05-20. Retrieved 2022-04-04. "Camera Lens Anti-Reflection Coatings: Magic Explained". 4 March 2022. Archived from the original on 2022-09-09. Retrieved 2022-05-07. "Carl Zeiss – A History of a Most Respected Name in Optics". Southwest Museum of Engineering, Communications and Computation. 2007. Archived from the original on 2017-06-27. Retrieved 2022-05-07. Vapor Deposition Method Suits Coating Curved Optics by Evan Craves Paul Maurer: Phase Compensation of Total Internal Reflection. In: Journal of the Optical Society of America. Band 56, Nr. 9, 1. September 1966, S. 1219–1221, doi:10.1364/JOSA.56.001219 A. Weyrauch, B. Dörband: P-Coating: Improved imaging in binoculars through phase-corrected roof prisms. In: Deutsche Optikerzeitung. No. 4, 1988. "Why do the best roof-prism binoculars need a phase-correction coating?". 24 July 2006. Archived from the original on 2022-05-23. Retrieved 2022-05-20. Konrad Seil: Progress in binocular design. In: SPIE Proceedings. Band 1533, 1991, S. 48–60, doi:10.1117/12.48843 Metallic Mirror Coatings Highly Reflective Coatings Coating on roof (Dach) prism "www.zbirding.info". www.zbirding.info. Archived from the original on 2009-05-27. Retrieved 2009-11-03. Optik für Jagd und Naturbeobachtung, Carl Zeiss Sports Optics / Walter J. Schwab, 2. Ausgabe- Wetzlar - 2017, page 45 Slaiby, ZenaE.; Turki, Saeed N. (November–December 2014). "Study the reflectance of dielectric coating for the visiblespectrum" (PDF). International Journal of Emerging Trends & Technology in Computer Science. 3 (6): 1–4. 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"VECTOR series range finder binoculars product flyer" (PDF). Archived (PDF) from the original on 2022-06-01. Retrieved 2022-04-10. "Make the right choice of marine binoculars". Archived from the original on 2021-07-28. Retrieved 2022-04-10. "What to look for in a good pair of marine binoculars". 27 October 2021. Archived from the original on 2022-05-31. Retrieved 2022-04-10. Sky & Telescope, October 2012, Gary Seronik, "The Messier Catalog: A Binocular Odyssey" (pg 68) Ed Zarenski (2004). "Limiting Magnitude in Binoculars" (PDF). Cloudy Nights. Archived (PDF) from the original on 2011-07-21. Retrieved 2011-05-06. "Blaser Primus bonoculars presentation". 12 June 2017. Archived from the original on 2019-05-30. Retrieved 2019-06-06. "Optolyth catalog". Archived from the original on 2022-09-09. Retrieved 2022-04-28. "www.steiner-binoculars.com". Archived from the original on 2009-01-07. Retrieved 2009-12-21. "www.regionhall.at —The Swarovski story". Regionhall.at. Archived from the original on 2010-09-07. Retrieved 2009-11-03. Further reading Wikisource has the text of the 1911 Encyclopædia Britannica article "Binocular Instrument". Walter J. Schwab, Wolf Wehran: "Optics for Hunting and Nature Observation". ISBN 978-3-00-034895-2. 1st Edition, Wetzlar (Germany), 2011 External links Wikimedia Commons has media related to Binoculars. The history of the telescope & the binocular by Peter Abrahams, May 2002 Glossary of Optical Terms Binocular Optics and Mechanics Chapter from Binocular Astronomy by Stephen Tonkin Binocular Astronomy by Stephen Tonkin vte Astronomy Outline History Timeline Astronomer Astronomical symbols Astronomical object Glossary Astronomy by Manner Amateur Observational Sidewalk Space telescope Celestial subject Galactic / Extragalactic Local system Solar EM methods Radio Submillimetre Infrared (Far-infrared) Visible-light (optical) Ultraviolet X-ray Gamma-ray Other methods Neutrino Cosmic rays Gravitational radiation High-energy Radar Spherical Multi-messenger Culture Australian Aboriginal Babylonian Chechen (Nakh) Chinese Egyptian Greek Hebrew Indian Inuit Maya Medieval Islamic Persian Serbian folk Tibetan Optical telescopes List Category Extremely large telescope Gran Telescopio Canarias Hubble Space Telescope Keck Observatory Large Binocular Telescope Southern African Large Telescope Very Large Telescope Related Archaeoastronomy Astrobiology Astrochemistry Astrophysics Astrology and astronomy Astrometry Astroparticle physics Binoculars Photometry Planetarium Planetary geology Physical cosmology Quantum cosmology List of astronomers French Medieval Islamic Russian Women Telescope history lists Zodiac

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Type: Binoculars

Clothing Type: Binoculars

Era: 1816-1913

Conflict: World War I (1914-1918)

Country/ Organization: Great Britain

Service: Navy

Theme: Militaria

Country/Region of Manufacture: United Kingdom

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