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Wikipedia

Fresnel lens

January 01, 1970

A Fresnel lens (/ˈfrnɛl, -nəl/ FRAY-nel, -⁠nəl; /ˈfrɛnɛl, -əl/ FREN-el, -⁠əl; or /frˈnɛl/ fray-NEL[1]) is a type of composite compact lens which reduces the amount of material required compared to a conventional lens by dividing the lens into a set of concentric annular sections.

First-order rotating catadioptric Fresnel lens, dated 1870, displayed at the Musée national de la Marine, Paris. In this case the dioptric prisms (inside the bronze rings) and catadioptric prisms (outside) are arranged to concentrate the light from the central lamp into four revolving beams, seen by sailors as four flashes per revolution. The assembly stands 2.54 metres (8.3 ft) tall and weighs about 1.5 tonnes (3,300 lb).

The simpler dioptric (purely refractive) form of the lens was first proposed by Georges-Louis Leclerc, Comte de Buffon[2], and independently reinvented by the French physicist Augustin-Jean Fresnel (1788–1827) for use in lighthouses.[3][4] The catadioptric (combining refraction and reflection) form of the lens, entirely invented by Fresnel, has outer prismatic elements that use total internal reflection as well as refraction to capture more oblique light from the light source and add it to the beam, making it more visible at greater distances.

The design allows the construction of lenses of large aperture and short focal length without the mass and volume of material that would be required by a lens of conventional design. A Fresnel lens can be made much thinner than a comparable conventional lens, in some cases taking the form of a flat sheet.

Because of its use in lighthouses, it has been called "the invention that saved a million ships".[5]

History edit

Forerunners edit

The first person to focus a lighthouse beam using a lens was apparently the London glass-cutter Thomas Rogers, who proposed the idea to Trinity House in 1788.[6] The first Rogers lenses, 53 cm in diameter and 14 cm thick at the center, were installed at the Old Lower Lighthouse at Portland Bill in 1789. Behind each lamp was a back-coated spherical glass mirror, which reflected rear radiation back through the lamp and into the lens. Further samples were installed at Howth Baily, North Foreland, and at least four other locations by 1804. But much of the light was wasted by absorption in the glass.[6][7]

In 1748, Georges-Louis Leclerc, Comte de Buffon was the first to replace a convex lens with a series of concentric annular prisms, ground as steps in a single piece of glass,[2]to reduce weight and absorption. In 1790[8] (although secondary sources give the date as 1773[9]: 609  or 1788[10]), the Marquis de Condorcet suggested that it would be easier to make the annular sections separately and assemble them on a frame; but even that was impractical at the time.[11][12] These designs were intended not for lighthouses,[2] but for burning glasses.[9]: 609  David Brewster, however, proposed a system similar to Condorcet's in 1811,[2][10][13] and by 1820 was advocating its use in British lighthouses.[14]

Publication and refinement edit

 
Cross-section of a first-generation Fresnel lighthouse lens, with sloping mirrors m, n above and below the refractive panel RC (with central segment A). The design was later improved by replacing the mirrors with reflective prisms to reduce losses. If the cross-section in every vertical plane through the lamp L is the same (cylindrical symmetry), the light is spread evenly around the horizon.

The French Commission des Phares [FR] (Commission of Lighthouses) was established by Napoleon in 1811, and placed under the authority of French physicist Augustin-Jean Fresnel's employer, the Corps of Bridges and Roads. As the members of the commission were otherwise occupied, it achieved little in its early years.[15] However, on 21 June 1819—three months after winning the physics Grand Prix of the Academy of Sciences for his celebrated memoir on diffraction—Fresnel was "temporarily" seconded to the commission on the recommendation of François Arago (a member since 1813), to review possible improvements in lighthouse illumination.[11][16]

By the end of August 1819, unaware of the Buffon-Condorcet-Brewster proposal,[11][13] Fresnel made his first presentation to the commission,[17] recommending what he called lentilles à échelons ('lenses by steps') to replace the reflectors then in use, which reflected only about half of the incident light.[18] Another report by Fresnel, dated 29 August 1819 (Fresnel, 1866–70, vol. 3, pp. 15–21), concerns tests on reflectors, and does not mention stepped lenses except in an unrelated sketch on the last page of the manuscript. The minutes of the meetings of the Commission go back only to 1824, when Fresnel himself took over as Secretary.[19] Thus the exact date on which Fresnel formally recommended lentilles à échelons is unknown.[citation needed] Much to Fresnel's embarrassment, one of the assembled commissioners, Jacques Charles, recalled Buffon's suggestion.[20] However, whereas Buffon's version was biconvex and in one piece,[21] Fresnel's was plano-convex and made of multiple prisms for easier construction.

With an official budget of 500 francs, Fresnel approached three manufacturers. The third, François Soleil, found a way to remove defects by reheating and remolding the glass. Arago assisted Fresnel with the design of a modified Argand lamp with concentric wicks (a concept that Fresnel attributed to Count Rumford[22]), and accidentally discovered that fish glue was heat-resistant, making it suitable for use in the lens. The prototype, finished in March 1820, had a square lens panel 55 cm on a side, containing 97 polygonal (not annular) prisms—and so impressed the Commission that Fresnel was asked for a full eight-panel version. This model, completed a year later in spite of insufficient funding, had panels 76 cm square. In a public spectacle on the evening of 13 April 1821, it was demonstrated by comparison with the most recent reflectors, which it suddenly rendered obsolete.[23]

Soon after this demonstration, Fresnel published the idea that light, including apparently unpolarized light, consists exclusively of transverse waves, and went on to consider the implications for double refraction and partial reflection.[24]

Fresnel acknowledged the British lenses and Buffon's invention in a memoir read on 29 July 1822 and printed in the same year.[25] The date of that memoir may be the source of the claim that Fresnel's lighthouse advocacy began two years later than Brewster's;[14] but the text makes it clear that Fresnel's involvement began no later than 1819.[26]

Fresnel's next lens was a rotating apparatus with eight "bull's-eye" panels, made in annular arcs by Saint-Gobain,[12] giving eight rotating beams—to be seen by mariners as a periodic flash. Above and behind each main panel was a smaller, sloping bull's-eye panel of trapezoidal outline with trapezoidal elements.[27] This refracted the light to a sloping plane mirror, which then reflected it horizontally, 7 degrees ahead of the main beam, increasing the duration of the flash.[28] Below the main panels were 128 small mirrors arranged in four rings, stacked like the slats of a louver or Venetian blind. Each ring, shaped like a frustum of a cone, reflected the light to the horizon, giving a fainter steady light between the flashes. The official test, conducted on the unfinished Arc de Triomphe on 20 August 1822, was witnessed by the Commission—and by Louis XVIII and his entourage—from 32 kilometres (20 mi) away. The apparatus was stored at Bordeaux for the winter, and then reassembled at Cordouan Lighthouse under Fresnel's supervision—in part by Fresnel's own hands. On 25 July 1823, the world's first lighthouse Fresnel lens was lit.[29] As expected, the light was visible to the horizon, more than 32 kilometres (20 mi) out.[30]

The day before the test of the Cordouan lens in Paris, a committee of the Academy of Sciences reported on Fresnel's memoir and supplements on double refraction—which, although less well known to modern readers than his earlier work on diffraction, struck a more decisive blow for the wave theory of light.[31] Between the test and the reassembly at Cordouan, Fresnel submitted his papers on photoelasticity (16 September 1822), elliptical and circular polarization and optical rotation (9 December), and partial reflection and total internal reflection (7 January 1823),[32] essentially completing his reconstruction of physical optics on the transverse wave hypothesis. Shortly after the Cordouan lens was lit, Fresnel started coughing up blood.[33]

In May 1824,[13] Fresnel was promoted to Secretary of the Commission des Phares, becoming the first member of that body to draw a salary,[34] albeit in the concurrent role of Engineer-in-Chief.[35] Late that year, being increasingly ill, he curtailed his fundamental research and resigned his seasonal job as an examiner at the École Polytechnique, in order to save his remaining time and energy for his lighthouse work.[36][37]

In the same year he designed the first fixed lens—for spreading light evenly around the horizon while minimizing waste above or below.[11] Ideally the curved refracting surfaces would be segments of toroids about a common vertical axis, so that the dioptric panel would look like a cylindrical drum. If this was supplemented by reflecting (catoptric) rings above and below the refracting (dioptric) parts, the entire apparatus would look like a beehive.[38] The second Fresnel lens to enter service was indeed a fixed lens, of third order, installed at Dunkirk by 1 February 1825.[39] However, due to the difficulty of fabricating large toroidal prisms, this apparatus had a 16-sided polygonal plan.[40]

In 1825 Fresnel extended his fixed-lens design by adding a rotating array outside the fixed array. Each panel of the rotating array was to refract part of the fixed light from a horizontal fan into a narrow beam.[11][41]

Also in 1825, Fresnel unveiled the Carte des Phares ('lighthouse map'), calling for a system of 51 lighthouses plus smaller harbor lights, in a hierarchy of lens sizes called "orders" (the first being the largest), with different characteristics to facilitate recognition: a constant light (from a fixed lens), one flash per minute (from a rotating lens with eight panels), and two per minute (16 panels).[42]

In late 1825,[43] to reduce the loss of light in the reflecting elements, Fresnel proposed to replace each mirror with a catadioptric prism, through which the light would travel by refraction through the first surface, then total internal reflection off the second surface, then refraction through the third surface.[44] The result was the lighthouse lens as we now know it. In 1826 he assembled a small model for use on the Canal Saint-Martin,[45] but he did not live to see a full-sized version: he died on 14 July 1827, at the age of 39.

After Fresnel edit

The first stage of the development of lighthouse lenses after the death of Augustin Fresnel consisted in the implementation of his designs. This was driven in part by his younger brother Léonor—who, like Augustin, was trained as a civil engineer but, unlike Augustin, had a strong aptitude for management. Léonor entered the service of the Lighthouse Commission in 1825, and went on to succeed Augustin as Secretary.[46]

The first fixed lens to be constructed with toroidal prisms was a first-order apparatus designed by the Scottish engineer Alan Stevenson under the guidance of Léonor Fresnel, and fabricated by Isaac Cookson & Co. using French glass; it entered service at the Isle of May, Scotland, on 22 September 1836.[47] The first large catadioptric lenses were made in 1842 for the lighthouses at Gravelines and Île Vierge, France; these were fixed third-order lenses whose catadioptric rings (made in segments) were one metre in diameter. Stevenson's first-order Skerryvore lens, lit in 1844, was only partly catadioptric; it was similar to the Cordouan lens except that the lower slats were replaced by French-made catadioptric prisms, while mirrors were retained at the top. The first fully catadioptric first-order lens, installed at Pointe d'Ailly in 1852, also gave eight rotating beams plus a fixed light at the bottom; but its top section had eight catadioptric panels focusing the light about 4 degrees ahead of the main beams, in order to lengthen the flashes. The first fully catadioptric lens with purely revolving beams—also of first order—was installed at Saint-Clément-des-Baleines in 1854, and marked the completion of Augustin Fresnel's original Carte des Phares.[48]

Thomas Stevenson (younger brother of Alan) went a step beyond Fresnel with his "holophotal" lens, which focused the light radiated by the lamp in nearly all directions, forward or backward, into a single beam.[49] The first version, described in 1849, consisted of a standard Fresnel bull's-eye lens, a paraboloidal reflector, and a rear hemispherical reflector (functionally equivalent to the Rogers mirror of 60 years earlier, except that it subtended a whole hemisphere). Light radiated into the forward hemisphere but missing the bull's-eye lens was deflected by the paraboloid into a parallel beam surrounding the bull's-eye lens, while light radiated into the backward hemisphere was reflected back through the lamp by the spherical reflector (as in Rogers' arrangement), to be collected by the forward components. The first unit was installed at North Harbour, Peterhead, in August 1849. Stevenson called this version a "catadioptric holophote", although each of its elements was either purely reflective or purely refractive. In the second version of the holophote concept, the bull's-eye lens and paraboloidal reflector were replaced by a catadioptric Fresnel lens—as conceived by Fresnel, but expanded to cover the whole forward hemisphere. The third version, which Stevenson confusingly called a "dioptric holophote", was more innovative: it retained the catadioptric Fresnel lens for the front hemisphere, but replaced the rear hemispherical reflector with a hemispherical array of annular prisms, each of which used two total internal reflections to turn light diverging from the center of the hemisphere back toward the center. The result was an all-glass holophote, with no losses from metallic reflections.[50]

James Timmins Chance modified Thomas Stevenson's all-glass holophotal design by arranging the double-reflecting prisms about a vertical axis. The prototype was shown at the 1862 International Exhibition in London. Later, to ease manufacturing, Chance divided the prisms into segments, and arranged them in a cylindrical form while retaining the property of reflecting light from a single point back to that point. Reflectors of this form, paradoxically called "dioptric mirrors", proved particularly useful for returning light from the landward side of the lamp to the seaward side.[51]

 
First-order group-flashing Fresnel lens, on display at the Point Arena Lighthouse Museum, Point Arena Lighthouse, Mendocino County, California. The three dioptric panels (inside the brass rings) and three catadioptric panels (outside) are partly split in two, giving three double-flashes per rotation.

As lighthouses proliferated, they became harder to distinguish from each other, leading to the use of colored filters, which wasted light. In 1884, John Hopkinson eliminated the need for filters by inventing the "group-flashing" lens, in which the dioptric and/or the catadioptric panels were split so as to give multiple flashes—allowing lighthouses to be identified not only by frequency of flashes, but also by multiplicity of flashes. Double-flashing lenses were installed at Tampico (Mexico) and Little Basses (Sri Lanka) in 1875, and a triple-flashing lens at Casquets Lighthouse (Channel Islands) in 1876.[52] The example shown (right) is the double-flashing lens of the Point Arena Light, which was in service from 1908 to 1977.[53]

The development of hyper-radial lenses was driven in part by the need for larger light sources, such as gas lights with multiple jets, which required a longer focal length for a given beam-width, hence a larger lens to collect a given fraction of the generated light. The first hyper-radial lens was built for the Stevensons in 1885 by F. Barbier & Cie of France, and tested at South Foreland Lighthouse with various light sources. Chance Brothers (Hopkinson's employers) then began constructing hyper-radials, installing their first at Bishop Rock Lighthouse in 1887.[54] In the same year, Barbier installed a hyper-radial at Tory Island. But only about 30 hyper-radials went into service[55] before the development of more compact bright lamps rendered such large optics unnecessary (see Hyperradiant Fresnel lens).

Production of one-piece stepped dioptric lenses—roughly as envisaged by Buffon—became feasible in 1852, when John L. Gilliland of the Brooklyn Flint-Glass Company patented a method of making lenses from pressed and molded glass. The company made small bull's-eye lenses for use on railroads, steamboats, and docks;[56] such lenses were common in the United States by the 1870s.[13]: 488  In 1858 the company produced "a very small number of pressed flint-glass sixth-order lenses" for use in lighthouses—the first Fresnel lighthouse lenses made in America.[56] By the 1950s, the substitution of plastic for glass made it economic to use Fresnel lenses as condensers in overhead projectors.[57]

Design edit

 
1: Cross-section of Buffon/Fresnel lens. 2: Cross-section of conventional plano-convex lens of equivalent power. (Buffon's version was biconvex.[20])
 
Close-up view of a flat Fresnel lens shows concentric circles on the surface

The Fresnel lens reduces the amount of material required compared to a conventional lens by dividing the lens into a set of concentric annular sections. An ideal Fresnel lens would have an infinite number of sections. In each section, the overall thickness is decreased compared to an equivalent simple lens. This effectively divides the continuous surface of a standard lens into a set of surfaces of the same curvature, with stepwise discontinuities between them.

In some lenses, the curved surfaces are replaced with flat surfaces, with a different angle in each section. Such a lens can be regarded as an array of prisms arranged in a circular fashion with steeper prisms on the edges and a flat or slightly convex center. In the first (and largest) Fresnel lenses, each section was actually a separate prism. 'Single-piece' Fresnel lenses were later produced, being used for automobile headlamps, brake, parking, and turn signal lenses, and so on. In modern times, computer-controlled milling equipment (CNC) or 3-D printers might be used to manufacture more complex lenses.[citation needed]

Fresnel lens design allows a substantial reduction in thickness (and thus mass and volume of material) at the expense of reducing the imaging quality of the lens, which is why precise imaging applications such as photography usually still use larger conventional lenses.

Fresnel lenses are usually made of glass or plastic; their size varies from large (old historical lighthouses, meter size) to medium (book-reading aids, OHP viewgraph projectors) to small (TLR/SLR camera screens, micro-optics). In many cases they are very thin and flat, almost flexible, with thicknesses in the 1 to 5 mm (132 to 316 in) range.[citation needed]

Most modern Fresnel lenses consist only of refractive elements. Lighthouse lenses, however, tend to include both refracting and reflecting elements, the latter being outside the metal rings seen in the photographs. While the inner elements are sections of refractive lenses, the outer elements are reflecting prisms, each of which performs two refractions and one total internal reflection, avoiding the light loss that occurs in reflection from a silvered mirror.

Lighthouse lens sizes edit

 
Description of lens orders, from Block Island Southeast Light, Rhode Island.
 
Makapuu Point Light
Walking around a fresnel lens on display in Chiba, Japan.

Fresnel designed six sizes of lighthouse lenses, divided into four orders based on their size and focal length.[58] The 3rd and 4th orders were sub-divided into "large" and "small". In modern use, the orders are classified as first through sixth order. An intermediate size between third and fourth order was added later, as well as sizes above first order and below sixth.

A first-order lens has a focal length of 920 mm (36+14 in) and stands about 2.59 m (8 ft 6 in) high, and 1.8 m (6 ft) wide. The smallest (sixth) order has a focal length of 150 mm (6 in) and a height of 433 mm (17+116 in).[58][59][60]

The largest Fresnel lenses are called hyperradiant (or hyper-radial). One such lens was on hand when it was decided to build and outfit the Makapuu Point Light in Hawaii. Rather than order a new lens, the huge optic construction, 3.7 metres (12 ft) tall and with over a thousand prisms, was used there.[61]

Lighthouse lens orders[62]
Modern order Fresnel order Focal length (mm) Height (m) First installed Application
Hyper-radial 1330 3.76 1887 Major "landfall" lighthouses
Mesoradial 1125 3.20 1909 Two Brazilian lighthouses
1st 1st 920 2.59 1823 Large seacoast lights
2nd 2nd 700–750 2.07 Great Lakes lighthouses, seacoasts, islands, sounds
3rd 3rd (large) 500 1.58 1825 Seacoast sounds, river entry, bays, channels, range lights
3+12 375 1.09
4th 3rd (small) 250 0.722 Shoals, reefs, harbor lights, islands in rivers and harbors
5th 4th (large) 187.5 0.541 Breakwaters, river and channel lights, Small islands in sounds
6th 4th (small) 150 0.433 Pier and breakwater lights in harbors
7th 100–140 0.165 Used in Scotland and Canada
8th 70–75 0.0826 Used in Scotland and Canada
  •  
    First-order lens.
  •  
    First-order lens (Cape Meares Lighthouse)
  •  
    First-order lens from Destruction Island WA, built in France 1888. Currently at Westport Maritime Museum.
  •  
    Close-up of a second-order lens.
  •  
    Third-order lens (St. Simons Island Light).
  •  
    Fourth-order lens (Sekizaki Lighthouse, Oita, Japan).
  •  
    Fourth order lens from Cape Arago Lighthouse. Currently at Coos History Museum.
  •  
    Fifth-order lens, at Key West Lighthouse
  •  
    Sixth-order lens (Ponce de Leon Inlet Light)
  •  
    Comparison of first- and fourth-order lenses (Key West Lighthouse)

Types edit

There are two main types of Fresnel lens: imaging and non-imaging. Imaging Fresnel lenses use segments with curved cross-sections and produce sharp images, while non-imaging lenses have segments with flat cross-sections, and do not produce sharp images.[63] As the number of segments increases, the two types of lens become more similar to each other. In the abstract case of an infinite number of segments, the difference between curved and flat segments disappears.

Imaging lenses can be classified as:

Spherical
A spherical Fresnel lens is equivalent to a simple spherical lens, using ring-shaped segments that are each a portion of a sphere, that all focus light on a single point. This type of lens produces a sharp image, although not quite as clear as the equivalent simple spherical lens due to diffraction at the edges of the ridges.
Cylindrical
A cylindrical Fresnel lens is equivalent to a simple cylindrical lens, using straight segments with circular cross-section, focusing light on a single line. This type produces a sharp image, although not quite as clear as the equivalent simple cylindrical lens due to diffraction at the edges of the ridges.

Non-imaging lenses can be classified as:

Spot
A non-imaging spot Fresnel lens uses ring-shaped segments with cross sections that are straight lines rather than circular arcs. Such a lens can focus light on a small spot, but does not produce a sharp image. These lenses have application in solar power, such as focusing sunlight on a solar panel. Fresnel lenses may be used as components of Köhler illumination optics resulting in very effective nonimaging optics Fresnel-Köhler (FK) solar concentrators.[64]
Linear
A non-imaging linear Fresnel lens uses straight segments whose cross sections are straight lines rather than arcs. These lenses focus light into a narrow band. They do not produce a sharp image, but can be used in solar power, such as for focusing sunlight on a pipe, to heat the water within.[65]

Uses edit

Illumination edit

 
Inchkeith lighthouse lens and drive mechanism at the National Museum of Scotland

High-quality glass Fresnel lenses were used in lighthouses, where they were considered state of the art in the late 19th and through the middle of the 20th centuries; most lighthouses have now retired glass Fresnel lenses from service and replaced them with much less expensive and more durable aerobeacons, which themselves often contain plastic Fresnel lenses.[citation needed] Lighthouse Fresnel lens systems typically include extra annular prismatic elements, arrayed in faceted domes above and below the central planar Fresnel, in order to catch all light emitted from the light source. The light path through these elements can include an internal reflection, rather than the simple refraction in the planar Fresnel element. These lenses conferred many practical benefits upon the designers, builders, and users of lighthouses and their illumination. Among other things, smaller lenses could fit into more compact spaces. Greater light transmission over longer distances, and varied patterns, made it possible to triangulate a position.[citation needed]

Perhaps the most widespread use of Fresnel lenses, for a time, occurred in automobile headlamps, where they can shape the roughly parallel beam from the parabolic reflector to meet requirements for dipped and main-beam patterns, often both in the same headlamp unit (such as the European H4 design). For reasons of economy, weight, and impact resistance, newer cars have dispensed with glass Fresnel lenses, using multifaceted reflectors with plain polycarbonate lenses. However, Fresnel lenses continue in wide use in automobile tail, marker, and reversing lights.

 
A Fresnel lantern with the lens open to show the ridges

Glass Fresnel lenses also are used in lighting instruments for theatre and motion pictures (see Fresnel lantern); such instruments are often called simply Fresnels. The entire instrument consists of a metal housing, a reflector, a lamp assembly, and a Fresnel lens. Many Fresnel instruments allow the lamp to be moved relative to the lens' focal point, to increase or decrease the size of the light beam. As a result, they are very flexible, and can often produce a beam as narrow as 7° or as wide as 70°.[66] The Fresnel lens produces a very soft-edged beam, so is often used as a wash light. A holder in front of the lens can hold a colored plastic film (gel) to tint the light or wire screens or frosted plastic to diffuse it. The Fresnel lens is useful in the making of motion pictures not only because of its ability to focus the beam brighter than a typical lens, but also because the light is a relatively consistent intensity across the entire width of the beam of light.

 
Optical landing system on US Navy aircraft carrier USS Dwight D. Eisenhower

Aircraft carriers and naval air stations typically use Fresnel lenses in their optical landing systems. The "meatball" light aids the pilot in maintaining proper glide slope for the landing. In the center are amber and red lights composed of Fresnel lenses. Although the lights are always on, the angle of the lens from the pilot's point of view determines the color and position of the visible light. If the lights appear above the green horizontal bar, the pilot is too high. If it is below, the pilot is too low, and if the lights are red, the pilot is very low.[67]

Fresnel lenses are also commonly used in searchlights, spotlights, and flashlights.

Imaging edit

 
A plastic Fresnel lens sold as a TV-screen enlarging device
 
The Fresnel lens used in the Sinclair FTV1 portable CRT TV, which enlarges the vertical aspect of the display only

Fresnel lenses are used as simple hand-held magnifiers. They are also used to correct several visual disorders, including ocular-motility disorders such as strabismus.[68] Fresnel lenses have been used to increase the visual size of CRT displays in pocket televisions, notably the Sinclair TV80. They are also used in traffic lights.

Fresnel lenses are used in left-hand-drive European lorries entering the UK and Republic of Ireland (and vice versa, right-hand-drive Irish and British trucks entering mainland Europe) to overcome the blind spots caused by the driver operating the lorry while sitting on the wrong side of the cab relative to the side of the road the car is on. They attach to the passenger-side window.[69]

Another automobile application of a Fresnel lens is a rear view enhancer, as the wide view angle of a lens attached to the rear window permits examining the scene behind a vehicle, particularly a tall or bluff-tailed one, more effectively than a rear-view mirror alone.

Fresnel lenses have also been used in the field of popular entertainment. The British rock artist Peter Gabriel made use of them in his early solo live performances to magnify the size of his head, in contrast to the rest of his body, for dramatic and comic effect. In the Terry Gilliam film Brazil, plastic Fresnel screens appear ostensibly as magnifiers for the small CRT monitors used throughout the offices of the Ministry of Information. However, they occasionally appear between the actors and the camera, distorting the scale and composition of the scene to humorous effect. The Pixar movie Wall-E features a Fresnel lens in the scenes where the protagonist watches the musical Hello, Dolly! magnified on an iPod.

Virtual reality headsets, such as the Meta Quest 2 and the HTC Vive Pro use Fresnel lenses,[70] as they allow a thinner and lighter form factor than regular lenses.[71] Newer devices, such as the Meta Quest Pro, have switched to a pancake lens design[72] due to its smaller form factor and less chromatic aberration than Fresnel lenses.[73]

Multi-focal Fresnel lenses are also used as a part of retina identification cameras, where they provide multiple in- and out-of-focus images of a fixation target inside the camera. For virtually all users, at least one of the images will be in focus, thus allowing correct eye alignment.

Canon and Nikon have used Fresnel lenses to reduce the size of telephoto lenses. Photographic lenses that include Fresnel elements can be much shorter than corresponding conventional lens design. Nikon calls the technology Phase Fresnel.[74][75] The Polaroid SX-70 camera used a Fresnel reflector as part of its viewing system. View and large format cameras can utilize a Fresnel lens in conjunction with the ground glass, to increase the perceived brightness of the image projected by a lens onto the ground glass, thus aiding in adjusting focus and composition.

Projection edit

The use of Fresnel lenses for image projection reduces image quality, so they tend to occur only where quality is not critical or where the bulk of a solid lens would be prohibitive. Cheap Fresnel lenses can be stamped or molded of transparent plastic and are used in overhead projectors and projection televisions.

Fresnel lenses of different focal lengths (one collimator, and one collector) are used in commercial and DIY projection. The collimator lens has the lower focal length and is placed closer to the light source, and the collector lens, which focuses the light into the triplet lens, is placed after the projection image (an active matrix LCD panel in LCD projectors). Fresnel lenses are also used as collimators in overhead projectors.

Solar power edit

Since plastic Fresnel lenses can be made larger than glass lenses, as well as being much cheaper and lighter, they are used to concentrate sunlight for heating in solar cookers, in solar forges, and in solar collectors used to heat water for domestic use. They can also be used to generate steam or to power a Stirling engine.

Fresnel lenses can concentrate sunlight onto solar cells with a ratio of almost 500:1.[76] This allows the active solar-cell surface to be reduced, lowering cost and allowing the use of more efficient cells that would otherwise be too expensive.[77] In the early 21st century, Fresnel reflectors began to be used in concentrating solar power (CSP) plants to concentrate solar energy. One application was to preheat water at the coal-fired Liddell Power Station, in Hunter Valley Australia.

Fresnel lenses can be used to sinter sand, allowing 3D printing in glass.[78]

See also edit

References edit

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  2. ^ a b c d Chisholm, Hugh, ed. (1911), "Lighthouse" , Encyclopædia Britannica, vol. 16 (11th ed.), Cambridge University Press, pp. 627–651.
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  5. ^ Bernhard, Adrienne (21 June 2019), "The invention that saved a million ships", BBC, retrieved 4 August 2019.
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  7. ^ Levitt, 2013, p. 57.
  8. ^ N. de Condorcet, Éloge de M. le Comte de Buffon, Paris: Chez Buisson, 1790, pp. 11–12. (This obituary also appeared in Histoire de l'Académie Royale des Sciences for 1788, printed in 1791.)
  9. ^ a b D. Appleton & Co., "Sea-lights", Dictionary of Machines, Mechanics, Engine-work, and Engineering, 1861, vol. 2, pp. 606–618.
  10. ^ a b T. Tag, "Chronology of Lighthouse Events", U.S. Lighthouse Society, accessed 22 August 2017; 8 April 2017.
  11. ^ a b c d e T. Tag, "The Fresnel lens", U.S. Lighthouse Society, accessed 12 August 2017; 22 July 2017.
  12. ^ a b Levitt, 2013, p. 71.
  13. ^ a b c d G. Ripley and C.A. Dana (eds.), "Fresnel, Augustin Jean", American Cyclopædia, 1879, vol. 7, pp. 486–489.
  14. ^ a b Chisholm, Hugh, ed. (1911), "Brewster, Sir David" , Encyclopædia Britannica, vol. 4 (11th ed.), Cambridge University Press, pp. 513–514.
  15. ^ Levitt, 2013, pp. 49–50.
  16. ^ Levitt, 2013, pp. 51, 53; Elton, 2009, p. 190; Fresnel, 1866–70, vol. 1, p. xcvii, and vol. 3, p. xxiv. ("July 21" in Levitt, 2013, p. 240, is a transcription error, inconsistent with the primary source cited.)
  17. ^ Fresnel, 1866–70, vol. 3, pp. 5–14; on the date, see p. 6n. Levitt (2013, p. 58) gives the date only as August 1819.
  18. ^ Levitt, 2013, pp. 56, 58.
  19. ^ Fresnel, 1866–70, vol. 3, p. 6n.
  20. ^ a b Levitt, 2013, p. 59.
  21. ^ Levitt, 2013, p. 59. The biconvex shape may be inferred from Buffon's description, quoted in Fresnel, 1822, tr. Tag, at p. 4.
  22. ^ Fresnel, 1822, tr. Tag, p. 11.
  23. ^ Levitt, 2013, pp. 59–66. Levitt gives the size of the eight-panel version as 720 mm (28+13 in). Elton (2009, p. 193) gives it as 76 cm and indicates that the first panel was tested on 31 October 1820; cf. Fresnel, 1866–70, vol. 3, pp. xxxii & xxxiv, and Fresnel, 1822, tr. Tag, p. 7.
  24. ^ A. Fresnel, "Note sur le calcul des teintes que la polarisation développe dans les lames cristallisées" et seq., Annales de Chimie et de Physique, Ser. 2, vol. 17, pp. 102–111 (May 1821), 167–196 (June 1821), 312–315 ("Postscript", July 1821); reprinted in Fresnel, 1866–1870, vol. 1, pp. 609–648; translated as "On the calculation of the tints that polarization develops in crystalline plates, & postscript", Zenodo4058004 / doi:10.5281/zenodo.4058004, 2021.
  25. ^ Fresnel, 1822, tr. Tag, pp. 2–4.
  26. ^ Fresnel, 1822, tr. Tag, p. 1.
  27. ^ D. Gombert, photograph of the Optique de Cordouan in the collection of the Musée des Phares et Balises, Ouessant, France, 23 March 2017.
  28. ^ Fresnel, 1822, tr. Tag, pp. 13, 25.
  29. ^ Elton, 2009, p. 195; Levitt, 2013, pp. 72–76.
  30. ^ B. Watson, "Science Makes a Better Lighthouse Lens", Smithsonian, vol. 30 no. 5 (August 1999), pp 30–31.
  31. ^ Buchwald, 1989, pp. 260, 288–290, 297; cf. Born & Wolf, 1999, p. xxviii.
  32. ^ Fresnel, 1866–1870, vol. 1, pp. 713–718, 731–751, 767–799.
  33. ^ Levitt, 2013, p. 97.
  34. ^ Levitt, 2013, p. 82.
  35. ^ Elton, 2009, p. 190.
  36. ^ H.M. Brock, "Fresnel, Augustin-Jean", Catholic Encyclopedia, 1907–12, vol. 6 (1909).
  37. ^ Young, 1855, p. 399; Boutry, 1948, pp. 601–602.
  38. ^ Cf. Elton, 2009, p. 198, Figure 12.
  39. ^ Levitt, 2013, p. 84.
  40. ^ Elton, 2009, pp. 197–198.
  41. ^ Elton, 2009, pp. 198–199.
  42. ^ Levitt, 2013, pp. 82–84.
  43. ^ Elton, 2009, p. 200.
  44. ^ Levitt, 2013, pp. 79–80.
  45. ^ Musée national de la Marine, "Appareil catadioptrique, Appareil du canal Saint-Martin", accessed 26 August 2017; 26 August 2017.
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  48. ^ Levitt, 2013, pp. 108–110, 113–116, 122–123. Elton (2009, p. 208) notes that although the Skerryvore lens was lit on 1 February 1844, the catadioptric portion was yet to be added.
  49. ^ Elton, 2009, pp. 209–210, 238.
  50. ^ Elton, 2009, pp. 210–213.
  51. ^ Elton, 2009, pp. 221–223.
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Bibliography edit

  • M. Born and E. Wolf, Principles of Optics, 7th Ed., Cambridge, 1999.
  • G.-A. Boutry, 1948, "Augustin Fresnel: His time, life and work, 1788–1827", Science Progress, vol. 36, no. 144 (October 1948), pp. 587–604; jstor.org/stable/43413515.
  • J. Z. Buchwald, 1989, The Rise of the Wave Theory of Light: Optical Theory and Experiment in the Early Nineteenth Century, University of Chicago Press, ISBN 978-0-226-07886-1.
  • J. Elton, 2009, "A Light to Lighten our Darkness: Lighthouse Optics and the Later Development of Fresnel's Revolutionary Refracting Lens 1780–1900", International Journal for the History of Engineering & Technology, vol. 79, no. 2 (July 2009), pp. 183–244; doi:10.1179/175812109X449612.
  • A. Fresnel, 1822, "Mémoire sur un nouveau système d'éclairage des phares", read 29 July 1822; reprinted in Fresnel, 1866–1870, vol. 3, pp. 97–126; translated by T. Tag as "Memoir upon a new system of lighthouse illumination", U.S. Lighthouse Society, accessed 26 August 2017; 19 August 2016. (Cited page numbers refer to the translation.)
  • A. Fresnel (ed. H. de Sénarmont, E. Verdet, and L. Fresnel), 1866–1870, Oeuvres complètes d'Augustin Fresnel (3 vols.), Paris: Imprimerie Impériale; vol. 1 (1866), vol. 2 (1868), vol. 3 (1870).
  • T. H. Levitt, 2013, A Short Bright Flash: Augustin Fresnel and the Birth of the Modern Lighthouse, New York: W.W. Norton, ISBN 978-0-393-35089-0.
  • T. Young (ed. G. Peacock), 1855, Miscellaneous Works of the late Thomas Young, London: J. Murray, vol. 1.

Further reading edit

  • "The Fresnel Lens", The Keeper's Log, Winter 1985, pp. 12–14.
  • U.S. Coast Guard, Aids to Navigation, Washington, DC: U.S. Government Printing Office, 1945.
  • U.S. Coast Guard, Lighthouses, Lenses, Illuminants, Engineering, & Augustin Fresnel: A Historical Bibliography on Works Published Through 2007.

External links edit

 
Wikimedia Commons has media related to Fresnel lenses.
  • United States Lighthouse Society, especially "Fresnel Lenses 2 March 2021 at the Wayback Machine".
  • W. A. Britten, "The Fresnel lens" (with photographs).
  • J. Francis, , 13 April 2009.
  • J. Hare, "How the Fresnel lens works" (5-minute video), Vega Science Trust, 2008.
  • T. Pepper, , archived from the original on 30 January 2008.
  • The Fresnel Lens: the Invention That Saved 1000 Ships

January 01, 1970
fresnel, lens, fray, nəl, fren, fray, type, composite, compact, lens, which, reduces, amount, material, required, compared, conventional, lens, dividing, lens, into, concentric, annular, sections, first, order, rotating, catadioptric, dated, 1870, displayed, m. A Fresnel lens ˈ f r eɪ n ɛ l n el FRAY nel nel ˈ f r ɛ n ɛ l el FREN el el or f r eɪ ˈ n ɛ l fray NEL 1 is a type of composite compact lens which reduces the amount of material required compared to a conventional lens by dividing the lens into a set of concentric annular sections First order rotating catadioptric Fresnel lens dated 1870 displayed at the Musee national de la Marine Paris In this case the dioptric prisms inside the bronze rings and catadioptric prisms outside are arranged to concentrate the light from the central lamp into four revolving beams seen by sailors as four flashes per revolution The assembly stands 2 54 metres 8 3 ft tall and weighs about 1 5 tonnes 3 300 lb The simpler dioptric purely refractive form of the lens was first proposed by Georges Louis Leclerc Comte de Buffon 2 and independently reinvented by the French physicist Augustin Jean Fresnel 1788 1827 for use in lighthouses 3 4 The catadioptric combining refraction and reflection form of the lens entirely invented by Fresnel has outer prismatic elements that use total internal reflection as well as refraction to capture more oblique light from the light source and add it to the beam making it more visible at greater distances The design allows the construction of lenses of large aperture and short focal length without the mass and volume of material that would be required by a lens of conventional design A Fresnel lens can be made much thinner than a comparable conventional lens in some cases taking the form of a flat sheet Because of its use in lighthouses it has been called the invention that saved a million ships 5 Contents 1 History 1 1 Forerunners 1 2 Publication and refinement 1 3 After Fresnel 2 Design 3 Lighthouse lens sizes 4 Types 5 Uses 5 1 Illumination 5 2 Imaging 5 3 Projection 5 4 Solar power 6 See also 7 References 8 Bibliography 9 Further reading 10 External linksHistory editForerunners edit The first person to focus a lighthouse beam using a lens was apparently the London glass cutter Thomas Rogers who proposed the idea to Trinity House in 1788 6 The first Rogers lenses 53 cm in diameter and 14 cm thick at the center were installed at the Old Lower Lighthouse at Portland Bill in 1789 Behind each lamp was a back coated spherical glass mirror which reflected rear radiation back through the lamp and into the lens Further samples were installed at Howth Baily North Foreland and at least four other locations by 1804 But much of the light was wasted by absorption in the glass 6 7 In 1748 Georges Louis Leclerc Comte de Buffon was the first to replace a convex lens with a series of concentric annular prisms ground as steps in a single piece of glass 2 to reduce weight and absorption In 1790 8 although secondary sources give the date as 1773 9 609 or 1788 10 the Marquis de Condorcet suggested that it would be easier to make the annular sections separately and assemble them on a frame but even that was impractical at the time 11 12 These designs were intended not for lighthouses 2 but for burning glasses 9 609 David Brewster however proposed a system similar to Condorcet s in 1811 2 10 13 and by 1820 was advocating its use in British lighthouses 14 Publication and refinement edit nbsp Cross section of a first generation Fresnel lighthouse lens with sloping mirrors m n above and below the refractive panel RC with central segment A The design was later improved by replacing the mirrors with reflective prisms to reduce losses If the cross section in every vertical plane through the lamp L is the same cylindrical symmetry the light is spread evenly around the horizon The French Commission des Phares FR Commission of Lighthouses was established by Napoleon in 1811 and placed under the authority of French physicist Augustin Jean Fresnel s employer the Corps of Bridges and Roads As the members of the commission were otherwise occupied it achieved little in its early years 15 However on 21 June 1819 three months after winning the physics Grand Prix of the Academy of Sciences for his celebrated memoir on diffraction Fresnel was temporarily seconded to the commission on the recommendation of Francois Arago a member since 1813 to review possible improvements in lighthouse illumination 11 16 By the end of August 1819 unaware of the Buffon Condorcet Brewster proposal 11 13 Fresnel made his first presentation to the commission 17 recommending what he called lentilles a echelons lenses by steps to replace the reflectors then in use which reflected only about half of the incident light 18 Another report by Fresnel dated 29 August 1819 Fresnel 1866 70 vol 3 pp 15 21 concerns tests on reflectors and does not mention stepped lenses except in an unrelated sketch on the last page of the manuscript The minutes of the meetings of the Commission go back only to 1824 when Fresnel himself took over as Secretary 19 Thus the exact date on which Fresnel formally recommended lentilles a echelons is unknown citation needed Much to Fresnel s embarrassment one of the assembled commissioners Jacques Charles recalled Buffon s suggestion 20 However whereas Buffon s version was biconvex and in one piece 21 Fresnel s was plano convex and made of multiple prisms for easier construction With an official budget of 500 francs Fresnel approached three manufacturers The third Francois Soleil found a way to remove defects by reheating and remolding the glass Arago assisted Fresnel with the design of a modified Argand lamp with concentric wicks a concept that Fresnel attributed to Count Rumford 22 and accidentally discovered that fish glue was heat resistant making it suitable for use in the lens The prototype finished in March 1820 had a square lens panel 55 cm on a side containing 97 polygonal not annular prisms and so impressed the Commission that Fresnel was asked for a full eight panel version This model completed a year later in spite of insufficient funding had panels 76 cm square In a public spectacle on the evening of 13 April 1821 it was demonstrated by comparison with the most recent reflectors which it suddenly rendered obsolete 23 Soon after this demonstration Fresnel published the idea that light including apparently unpolarized light consists exclusively of transverse waves and went on to consider the implications for double refraction and partial reflection 24 Fresnel acknowledged the British lenses and Buffon s invention in a memoir read on 29 July 1822 and printed in the same year 25 The date of that memoir may be the source of the claim that Fresnel s lighthouse advocacy began two years later than Brewster s 14 but the text makes it clear that Fresnel s involvement began no later than 1819 26 Fresnel s next lens was a rotating apparatus with eight bull s eye panels made in annular arcs by Saint Gobain 12 giving eight rotating beams to be seen by mariners as a periodic flash Above and behind each main panel was a smaller sloping bull s eye panel of trapezoidal outline with trapezoidal elements 27 This refracted the light to a sloping plane mirror which then reflected it horizontally 7 degrees ahead of the main beam increasing the duration of the flash 28 Below the main panels were 128 small mirrors arranged in four rings stacked like the slats of a louver or Venetian blind Each ring shaped like a frustum of a cone reflected the light to the horizon giving a fainter steady light between the flashes The official test conducted on the unfinished Arc de Triomphe on 20 August 1822 was witnessed by the Commission and by Louis XVIII and his entourage from 32 kilometres 20 mi away The apparatus was stored at Bordeaux for the winter and then reassembled at Cordouan Lighthouse under Fresnel s supervision in part by Fresnel s own hands On 25 July 1823 the world s first lighthouse Fresnel lens was lit 29 As expected the light was visible to the horizon more than 32 kilometres 20 mi out 30 The day before the test of the Cordouan lens in Paris a committee of the Academy of Sciences reported on Fresnel s memoir and supplements on double refraction which although less well known to modern readers than his earlier work on diffraction struck a more decisive blow for the wave theory of light 31 Between the test and the reassembly at Cordouan Fresnel submitted his papers on photoelasticity 16 September 1822 elliptical and circular polarization and optical rotation 9 December and partial reflection and total internal reflection 7 January 1823 32 essentially completing his reconstruction of physical optics on the transverse wave hypothesis Shortly after the Cordouan lens was lit Fresnel started coughing up blood 33 In May 1824 13 Fresnel was promoted to Secretary of the Commission des Phares becoming the first member of that body to draw a salary 34 albeit in the concurrent role of Engineer in Chief 35 Late that year being increasingly ill he curtailed his fundamental research and resigned his seasonal job as an examiner at the Ecole Polytechnique in order to save his remaining time and energy for his lighthouse work 36 37 In the same year he designed the first fixed lens for spreading light evenly around the horizon while minimizing waste above or below 11 Ideally the curved refracting surfaces would be segments of toroids about a common vertical axis so that the dioptric panel would look like a cylindrical drum If this was supplemented by reflecting catoptric rings above and below the refracting dioptric parts the entire apparatus would look like a beehive 38 The second Fresnel lens to enter service was indeed a fixed lens of third order installed at Dunkirk by 1 February 1825 39 However due to the difficulty of fabricating large toroidal prisms this apparatus had a 16 sided polygonal plan 40 In 1825 Fresnel extended his fixed lens design by adding a rotating array outside the fixed array Each panel of the rotating array was to refract part of the fixed light from a horizontal fan into a narrow beam 11 41 Also in 1825 Fresnel unveiled the Carte des Phares lighthouse map calling for a system of 51 lighthouses plus smaller harbor lights in a hierarchy of lens sizes called orders the first being the largest with different characteristics to facilitate recognition a constant light from a fixed lens one flash per minute from a rotating lens with eight panels and two per minute 16 panels 42 In late 1825 43 to reduce the loss of light in the reflecting elements Fresnel proposed to replace each mirror with a catadioptric prism through which the light would travel by refraction through the first surface then total internal reflection off the second surface then refraction through the third surface 44 The result was the lighthouse lens as we now know it In 1826 he assembled a small model for use on the Canal Saint Martin 45 but he did not live to see a full sized version he died on 14 July 1827 at the age of 39 After Fresnel edit The first stage of the development of lighthouse lenses after the death of Augustin Fresnel consisted in the implementation of his designs This was driven in part by his younger brother Leonor who like Augustin was trained as a civil engineer but unlike Augustin had a strong aptitude for management Leonor entered the service of the Lighthouse Commission in 1825 and went on to succeed Augustin as Secretary 46 The first fixed lens to be constructed with toroidal prisms was a first order apparatus designed by the Scottish engineer Alan Stevenson under the guidance of Leonor Fresnel and fabricated by Isaac Cookson amp Co using French glass it entered service at the Isle of May Scotland on 22 September 1836 47 The first large catadioptric lenses were made in 1842 for the lighthouses at Gravelines and Ile Vierge France these were fixed third order lenses whose catadioptric rings made in segments were one metre in diameter Stevenson s first order Skerryvore lens lit in 1844 was only partly catadioptric it was similar to the Cordouan lens except that the lower slats were replaced by French made catadioptric prisms while mirrors were retained at the top The first fully catadioptric first order lens installed at Pointe d Ailly in 1852 also gave eight rotating beams plus a fixed light at the bottom but its top section had eight catadioptric panels focusing the light about 4 degrees ahead of the main beams in order to lengthen the flashes The first fully catadioptric lens with purely revolving beams also of first order was installed at Saint Clement des Baleines in 1854 and marked the completion of Augustin Fresnel s original Carte des Phares 48 Thomas Stevenson younger brother of Alan went a step beyond Fresnel with his holophotal lens which focused the light radiated by the lamp in nearly all directions forward or backward into a single beam 49 The first version described in 1849 consisted of a standard Fresnel bull s eye lens a paraboloidal reflector and a rear hemispherical reflector functionally equivalent to the Rogers mirror of 60 years earlier except that it subtended a whole hemisphere Light radiated into the forward hemisphere but missing the bull s eye lens was deflected by the paraboloid into a parallel beam surrounding the bull s eye lens while light radiated into the backward hemisphere was reflected back through the lamp by the spherical reflector as in Rogers arrangement to be collected by the forward components The first unit was installed at North Harbour Peterhead in August 1849 Stevenson called this version a catadioptric holophote although each of its elements was either purely reflective or purely refractive In the second version of the holophote concept the bull s eye lens and paraboloidal reflector were replaced by a catadioptric Fresnel lens as conceived by Fresnel but expanded to cover the whole forward hemisphere The third version which Stevenson confusingly called a dioptric holophote was more innovative it retained the catadioptric Fresnel lens for the front hemisphere but replaced the rear hemispherical reflector with a hemispherical array of annular prisms each of which used two total internal reflections to turn light diverging from the center of the hemisphere back toward the center The result was an all glass holophote with no losses from metallic reflections 50 James Timmins Chance modified Thomas Stevenson s all glass holophotal design by arranging the double reflecting prisms about a vertical axis The prototype was shown at the 1862 International Exhibition in London Later to ease manufacturing Chance divided the prisms into segments and arranged them in a cylindrical form while retaining the property of reflecting light from a single point back to that point Reflectors of this form paradoxically called dioptric mirrors proved particularly useful for returning light from the landward side of the lamp to the seaward side 51 nbsp First order group flashing Fresnel lens on display at the Point Arena Lighthouse Museum Point Arena Lighthouse Mendocino County California The three dioptric panels inside the brass rings and three catadioptric panels outside are partly split in two giving three double flashes per rotation As lighthouses proliferated they became harder to distinguish from each other leading to the use of colored filters which wasted light In 1884 John Hopkinson eliminated the need for filters by inventing the group flashing lens in which the dioptric and or the catadioptric panels were split so as to give multiple flashes allowing lighthouses to be identified not only by frequency of flashes but also by multiplicity of flashes Double flashing lenses were installed at Tampico Mexico and Little Basses Sri Lanka in 1875 and a triple flashing lens at Casquets Lighthouse Channel Islands in 1876 52 The example shown right is the double flashing lens of the Point Arena Light which was in service from 1908 to 1977 53 The development of hyper radial lenses was driven in part by the need for larger light sources such as gas lights with multiple jets which required a longer focal length for a given beam width hence a larger lens to collect a given fraction of the generated light The first hyper radial lens was built for the Stevensons in 1885 by F Barbier amp Cie of France and tested at South Foreland Lighthouse with various light sources Chance Brothers Hopkinson s employers then began constructing hyper radials installing their first at Bishop Rock Lighthouse in 1887 54 In the same year Barbier installed a hyper radial at Tory Island But only about 30 hyper radials went into service 55 before the development of more compact bright lamps rendered such large optics unnecessary see Hyperradiant Fresnel lens Production of one piece stepped dioptric lenses roughly as envisaged by Buffon became feasible in 1852 when John L Gilliland of the Brooklyn Flint Glass Company patented a method of making lenses from pressed and molded glass The company made small bull s eye lenses for use on railroads steamboats and docks 56 such lenses were common in the United States by the 1870s 13 488 In 1858 the company produced a very small number of pressed flint glass sixth order lenses for use in lighthouses the first Fresnel lighthouse lenses made in America 56 By the 1950s the substitution of plastic for glass made it economic to use Fresnel lenses as condensers in overhead projectors 57 Design edit nbsp 1 Cross section of Buffon Fresnel lens 2 Cross section of conventional plano convex lens of equivalent power Buffon s version was biconvex 20 nbsp Close up view of a flat Fresnel lens shows concentric circles on the surface The Fresnel lens reduces the amount of material required compared to a conventional lens by dividing the lens into a set of concentric annular sections An ideal Fresnel lens would have an infinite number of sections In each section the overall thickness is decreased compared to an equivalent simple lens This effectively divides the continuous surface of a standard lens into a set of surfaces of the same curvature with stepwise discontinuities between them In some lenses the curved surfaces are replaced with flat surfaces with a different angle in each section Such a lens can be regarded as an array of prisms arranged in a circular fashion with steeper prisms on the edges and a flat or slightly convex center In the first and largest Fresnel lenses each section was actually a separate prism Single piece Fresnel lenses were later produced being used for automobile headlamps brake parking and turn signal lenses and so on In modern times computer controlled milling equipment CNC or 3 D printers might be used to manufacture more complex lenses citation needed Fresnel lens design allows a substantial reduction in thickness and thus mass and volume of material at the expense of reducing the imaging quality of the lens which is why precise imaging applications such as photography usually still use larger conventional lenses Fresnel lenses are usually made of glass or plastic their size varies from large old historical lighthouses meter size to medium book reading aids OHP viewgraph projectors to small TLR SLR camera screens micro optics In many cases they are very thin and flat almost flexible with thicknesses in the 1 to 5 mm 1 32 to 3 16 in range citation needed Most modern Fresnel lenses consist only of refractive elements Lighthouse lenses however tend to include both refracting and reflecting elements the latter being outside the metal rings seen in the photographs While the inner elements are sections of refractive lenses the outer elements are reflecting prisms each of which performs two refractions and one total internal reflection avoiding the light loss that occurs in reflection from a silvered mirror Lighthouse lens sizes edit nbsp Description of lens orders from Block Island Southeast Light Rhode Island nbsp Makapuu Point Light source source source source source source source source source source Walking around a fresnel lens on display in Chiba Japan Fresnel designed six sizes of lighthouse lenses divided into four orders based on their size and focal length 58 The 3rd and 4th orders were sub divided into large and small In modern use the orders are classified as first through sixth order An intermediate size between third and fourth order was added later as well as sizes above first order and below sixth A first order lens has a focal length of 920 mm 36 1 4 in and stands about 2 59 m 8 ft 6 in high and 1 8 m 6 ft wide The smallest sixth order has a focal length of 150 mm 6 in and a height of 433 mm 17 1 16 in 58 59 60 The largest Fresnel lenses are called hyperradiant or hyper radial One such lens was on hand when it was decided to build and outfit the Makapuu Point Light in Hawaii Rather than order a new lens the huge optic construction 3 7 metres 12 ft tall and with over a thousand prisms was used there 61 Lighthouse lens orders 62 Modern order Fresnel order Focal length mm Height m First installed Application Hyper radial 1330 3 76 1887 Major landfall lighthouses Mesoradial 1125 3 20 1909 Two Brazilian lighthouses 1st 1st 920 2 59 1823 Large seacoast lights 2nd 2nd 700 750 2 07 Great Lakes lighthouses seacoasts islands sounds 3rd 3rd large 500 1 58 1825 Seacoast sounds river entry bays channels range lights 3 1 2 375 1 09 4th 3rd small 250 0 722 Shoals reefs harbor lights islands in rivers and harbors 5th 4th large 187 5 0 541 Breakwaters river and channel lights Small islands in sounds 6th 4th small 150 0 433 Pier and breakwater lights in harbors 7th 100 140 0 165 Used in Scotland and Canada 8th 70 75 0 0826 Used in Scotland and Canada nbsp First order lens nbsp First order lens Cape Meares Lighthouse nbsp First order lens from Destruction Island WA built in France 1888 Currently at Westport Maritime Museum nbsp Close up of a second order lens nbsp Third order lens St Simons Island Light nbsp Fourth order lens Sekizaki Lighthouse Oita Japan nbsp Fourth order lens from Cape Arago Lighthouse Currently at Coos History Museum nbsp Fifth order lens at Key West Lighthouse nbsp Sixth order lens Ponce de Leon Inlet Light nbsp Comparison of first and fourth order lenses Key West Lighthouse Types editThere are two main types of Fresnel lens imaging and non imaging Imaging Fresnel lenses use segments with curved cross sections and produce sharp images while non imaging lenses have segments with flat cross sections and do not produce sharp images 63 As the number of segments increases the two types of lens become more similar to each other In the abstract case of an infinite number of segments the difference between curved and flat segments disappears Imaging lenses can be classified as Spherical A spherical Fresnel lens is equivalent to a simple spherical lens using ring shaped segments that are each a portion of a sphere that all focus light on a single point This type of lens produces a sharp image although not quite as clear as the equivalent simple spherical lens due to diffraction at the edges of the ridges Cylindrical A cylindrical Fresnel lens is equivalent to a simple cylindrical lens using straight segments with circular cross section focusing light on a single line This type produces a sharp image although not quite as clear as the equivalent simple cylindrical lens due to diffraction at the edges of the ridges Non imaging lenses can be classified as Spot A non imaging spot Fresnel lens uses ring shaped segments with cross sections that are straight lines rather than circular arcs Such a lens can focus light on a small spot but does not produce a sharp image These lenses have application in solar power such as focusing sunlight on a solar panel Fresnel lenses may be used as components of Kohler illumination optics resulting in very effective nonimaging optics Fresnel Kohler FK solar concentrators 64 Linear A non imaging linear Fresnel lens uses straight segments whose cross sections are straight lines rather than arcs These lenses focus light into a narrow band They do not produce a sharp image but can be used in solar power such as for focusing sunlight on a pipe to heat the water within 65 Uses editIllumination edit nbsp Inchkeith lighthouse lens and drive mechanism at the National Museum of Scotland High quality glass Fresnel lenses were used in lighthouses where they were considered state of the art in the late 19th and through the middle of the 20th centuries most lighthouses have now retired glass Fresnel lenses from service and replaced them with much less expensive and more durable aerobeacons which themselves often contain plastic Fresnel lenses citation needed Lighthouse Fresnel lens systems typically include extra annular prismatic elements arrayed in faceted domes above and below the central planar Fresnel in order to catch all light emitted from the light source The light path through these elements can include an internal reflection rather than the simple refraction in the planar Fresnel element These lenses conferred many practical benefits upon the designers builders and users of lighthouses and their illumination Among other things smaller lenses could fit into more compact spaces Greater light transmission over longer distances and varied patterns made it possible to triangulate a position citation needed Perhaps the most widespread use of Fresnel lenses for a time occurred in automobile headlamps where they can shape the roughly parallel beam from the parabolic reflector to meet requirements for dipped and main beam patterns often both in the same headlamp unit such as the European H4 design For reasons of economy weight and impact resistance newer cars have dispensed with glass Fresnel lenses using multifaceted reflectors with plain polycarbonate lenses However Fresnel lenses continue in wide use in automobile tail marker and reversing lights nbsp A Fresnel lantern with the lens open to show the ridges Glass Fresnel lenses also are used in lighting instruments for theatre and motion pictures see Fresnel lantern such instruments are often called simply Fresnels The entire instrument consists of a metal housing a reflector a lamp assembly and a Fresnel lens Many Fresnel instruments allow the lamp to be moved relative to the lens focal point to increase or decrease the size of the light beam As a result they are very flexible and can often produce a beam as narrow as 7 or as wide as 70 66 The Fresnel lens produces a very soft edged beam so is often used as a wash light A holder in front of the lens can hold a colored plastic film gel to tint the light or wire screens or frosted plastic to diffuse it The Fresnel lens is useful in the making of motion pictures not only because of its ability to focus the beam brighter than a typical lens but also because the light is a relatively consistent intensity across the entire width of the beam of light nbsp Optical landing system on US Navy aircraft carrier USS Dwight D Eisenhower Aircraft carriers and naval air stations typically use Fresnel lenses in their optical landing systems The meatball light aids the pilot in maintaining proper glide slope for the landing In the center are amber and red lights composed of Fresnel lenses Although the lights are always on the angle of the lens from the pilot s point of view determines the color and position of the visible light If the lights appear above the green horizontal bar the pilot is too high If it is below the pilot is too low and if the lights are red the pilot is very low 67 Fresnel lenses are also commonly used in searchlights spotlights and flashlights Imaging edit nbsp A plastic Fresnel lens sold as a TV screen enlarging device nbsp The Fresnel lens used in the Sinclair FTV1 portable CRT TV which enlarges the vertical aspect of the display only Fresnel lenses are used as simple hand held magnifiers They are also used to correct several visual disorders including ocular motility disorders such as strabismus 68 Fresnel lenses have been used to increase the visual size of CRT displays in pocket televisions notably the Sinclair TV80 They are also used in traffic lights Fresnel lenses are used in left hand drive European lorries entering the UK and Republic of Ireland and vice versa right hand drive Irish and British trucks entering mainland Europe to overcome the blind spots caused by the driver operating the lorry while sitting on the wrong side of the cab relative to the side of the road the car is on They attach to the passenger side window 69 Another automobile application of a Fresnel lens is a rear view enhancer as the wide view angle of a lens attached to the rear window permits examining the scene behind a vehicle particularly a tall or bluff tailed one more effectively than a rear view mirror alone Fresnel lenses have also been used in the field of popular entertainment The British rock artist Peter Gabriel made use of them in his early solo live performances to magnify the size of his head in contrast to the rest of his body for dramatic and comic effect In the Terry Gilliam film Brazil plastic Fresnel screens appear ostensibly as magnifiers for the small CRT monitors used throughout the offices of the Ministry of Information However they occasionally appear between the actors and the camera distorting the scale and composition of the scene to humorous effect The Pixar movie Wall E features a Fresnel lens in the scenes where the protagonist watches the musical Hello Dolly magnified on an iPod Virtual reality headsets such as the Meta Quest 2 and the HTC Vive Pro use Fresnel lenses 70 as they allow a thinner and lighter form factor than regular lenses 71 Newer devices such as the Meta Quest Pro have switched to a pancake lens design 72 due to its smaller form factor and less chromatic aberration than Fresnel lenses 73 Multi focal Fresnel lenses are also used as a part of retina identification cameras where they provide multiple in and out of focus images of a fixation target inside the camera For virtually all users at least one of the images will be in focus thus allowing correct eye alignment Canon and Nikon have used Fresnel lenses to reduce the size of telephoto lenses Photographic lenses that include Fresnel elements can be much shorter than corresponding conventional lens design Nikon calls the technology Phase Fresnel 74 75 The Polaroid SX 70 camera used a Fresnel reflector as part of its viewing system View and large format cameras can utilize a Fresnel lens in conjunction with the ground glass to increase the perceived brightness of the image projected by a lens onto the ground glass thus aiding in adjusting focus and composition Projection edit The use of Fresnel lenses for image projection reduces image quality so they tend to occur only where quality is not critical or where the bulk of a solid lens would be prohibitive Cheap Fresnel lenses can be stamped or molded of transparent plastic and are used in overhead projectors and projection televisions Fresnel lenses of different focal lengths one collimator and one collector are used in commercial and DIY projection The collimator lens has the lower focal length and is placed closer to the light source and the collector lens which focuses the light into the triplet lens is placed after the projection image an active matrix LCD panel in LCD projectors Fresnel lenses are also used as collimators in overhead projectors Solar power edit Since plastic Fresnel lenses can be made larger than glass lenses as well as being much cheaper and lighter they are used to concentrate sunlight for heating in solar cookers in solar forges and in solar collectors used to heat water for domestic use They can also be used to generate steam or to power a Stirling engine Fresnel lenses can concentrate sunlight onto solar cells with a ratio of almost 500 1 76 This allows the active solar cell surface to be reduced lowering cost and allowing the use of more efficient cells that would otherwise be too expensive 77 In the early 21st century Fresnel reflectors began to be used in concentrating solar power CSP plants to concentrate solar energy One application was to preheat water at the coal fired Liddell Power Station in Hunter Valley Australia Fresnel lenses can be used to sinter sand allowing 3D printing in glass 78 See also editFresnel imager Fresnel zone plate Lenticular lens Linear Fresnel reflector Prism lightingReferences edit J Wells 3 April 2008 Longman Pronunciation Dictionary 3rd ed Pearson Longman ISBN 978 1 4058 8118 0 a b c d Chisholm Hugh ed 1911 Lighthouse Encyclopaedia Britannica vol 16 11th ed Cambridge University Press pp 627 651 Fresnel lens Merriam Webster archived from the original on 17 December 2013 retrieved 19 March 2013 Wells John 3 April 2008 Longman Pronunciation Dictionary 3rd ed Pearson Longman ISBN 978 1 4058 8118 0 Bernhard Adrienne 21 June 2019 The invention that saved a million ships BBC retrieved 4 August 2019 a b T Tag Lens use prior to Fresnel U S Lighthouse Society accessed 12 August 2017 archived 20 May 2017 Levitt 2013 p 57 N de Condorcet Eloge de M le Comte de Buffon Paris Chez Buisson 1790 pp 11 12 This obituary also appeared in Histoire de l Academie Royale des Sciences for 1788 printed in 1791 a b D Appleton amp Co Sea lights Dictionary of Machines Mechanics Engine work and Engineering 1861 vol 2 pp 606 618 a b T Tag Chronology of Lighthouse Events U S Lighthouse Society accessed 22 August 2017 archived 8 April 2017 a b c d e T Tag The Fresnel lens U S Lighthouse Society accessed 12 August 2017 archived 22 July 2017 a b Levitt 2013 p 71 a b c d G Ripley and C A Dana eds Fresnel Augustin Jean American Cyclopaedia 1879 vol 7 pp 486 489 a b Chisholm Hugh ed 1911 Brewster Sir David Encyclopaedia Britannica vol 4 11th ed Cambridge University Press pp 513 514 Levitt 2013 pp 49 50 Levitt 2013 pp 51 53 Elton 2009 p 190 Fresnel 1866 70 vol 1 p xcvii and vol 3 p xxiv July 21 in Levitt 2013 p 240 is a transcription error inconsistent with the primary source cited Fresnel 1866 70 vol 3 pp 5 14 on the date see p 6n Levitt 2013 p 58 gives the date only as August 1819 Levitt 2013 pp 56 58 Fresnel 1866 70 vol 3 p 6n a b Levitt 2013 p 59 Levitt 2013 p 59 The biconvex shape may be inferred from Buffon s description quoted in Fresnel 1822 tr Tag at p 4 Fresnel 1822 tr Tag p 11 Levitt 2013 pp 59 66 Levitt gives the size of the eight panel version as 720 mm 28 1 3 in Elton 2009 p 193 gives it as 76 cm and indicates that the first panel was tested on 31 October 1820 cf Fresnel 1866 70 vol 3 pp xxxii amp xxxiv and Fresnel 1822 tr Tag p 7 A Fresnel Note sur le calcul des teintes que la polarisation developpe dans les lames cristallisees et seq Annales de Chimie et de Physique Ser 2 vol 17 pp 102 111 May 1821 167 196 June 1821 312 315 Postscript July 1821 reprinted in Fresnel 1866 1870 vol 1 pp 609 648 translated as On the calculation of the tints that polarization develops in crystalline plates amp postscript Zenodo 4058004 doi 10 5281 zenodo 4058004 2021 Fresnel 1822 tr Tag pp 2 4 Fresnel 1822 tr Tag p 1 D Gombert photograph of the Optique de Cordouan in the collection of the Musee des Phares et Balises Ouessant France 23 March 2017 Fresnel 1822 tr Tag pp 13 25 Elton 2009 p 195 Levitt 2013 pp 72 76 B Watson Science Makes a Better Lighthouse Lens Smithsonian vol 30 no 5 August 1999 pp 30 31 Buchwald 1989 pp 260 288 290 297 cf Born amp Wolf 1999 p xxviii Fresnel 1866 1870 vol 1 pp 713 718 731 751 767 799 Levitt 2013 p 97 Levitt 2013 p 82 Elton 2009 p 190 H M Brock Fresnel Augustin Jean Catholic Encyclopedia 1907 12 vol 6 1909 Young 1855 p 399 Boutry 1948 pp 601 602 Cf Elton 2009 p 198 Figure 12 Levitt 2013 p 84 Elton 2009 pp 197 198 Elton 2009 pp 198 199 Levitt 2013 pp 82 84 Elton 2009 p 200 Levitt 2013 pp 79 80 Musee national de la Marine Appareil catadioptrique Appareil du canal Saint Martin accessed 26 August 2017 archived 26 August 2017 Levitt 2013 pp 28 72 99 Elton 2009 pp 199 200 202 Levitt 2013 pp 104 105 Levitt 2013 pp 108 110 113 116 122 123 Elton 2009 p 208 notes that although the Skerryvore lens was lit on 1 February 1844 the catadioptric portion was yet to be added Elton 2009 pp 209 210 238 Elton 2009 pp 210 213 Elton 2009 pp 221 223 Elton 2009 pp 227 230 Levitt 2013 p 219 Point Arena Lighthouse Keepers Inc Lighthouse History Archived 19 January 2021 at the Wayback Machine accessed 1 March 2021 Elton 2009 p 233 Levitt 2013 pp 222 224 T Tag Hyper Radial Lenses U S Lighthouse Society accessed 28 February 2021 archived 11 February 2021 a b T Tag American Made Fresnel Lenses U S Lighthouse Society accessed 1 March 2021 archived 21 February 2021 A Finstad New developments in audio visual materials Higher Education vol 8 no 15 1 April 1952 pp 176 178 at p 176 a b Baiges Mabel A 1988 Fresnel Orders TIFF archived from the original on 21 September 2015 retrieved 9 September 2012 Fresnel lenses archived from the original on 27 September 2007 Fresnel lenses Michigan Lighthouse Conservancy 31 January 2008 archived from the original on 21 September 2012 retrieved 27 February 2021 Anderson Kraig Makapu u HI Lighthouse Friends archived from the original on 5 October 2008 retrieved 26 February 2009 United States Lighthouse Society Fresnel Lens Orders Sizes Weights Quantities and Costs Archived 27 June 2023 at the Wayback Machine R Winston J C Minano and P G Benitez Nonimaging Optics Academic Press 2005 Chaves Julio 2015 Introduction to Nonimaging Optics Second Edition CRC Press ISBN 978 1 4822 0673 9 Linear Concentrator System Concentrating Solar Thermal Power Basics Energy gov Retrieved 31 May 2021 Mumm Robert C Photometrics Handbook 2nd Ed Broadway Press 1997 p 36 Fresnel Lens Optical Landing System public2 nhhcaws local Retrieved 16 April 2022 permanent dead link Shishavanf Amir Asgharzadeh Nordin Leland Tjossem Paul Abramoff Michael D Toor Fatima 2016 Engheta Nader Noginov Mikhail A Zheludev Nikolay I eds PMMA based ophthalmic contact lens for vision correction of strabismus Metamaterials Metamaterials Metadevices and Metasystems 2016 9918 Society of Photo Optical Instrumentation Engineers 99180C Bibcode 2016SPIE 9918E 0CA doi 10 1117 12 2237994 S2CID 125689110 retrieved 21 June 2020 Lowe David 3 December 2011 Lowe s Transport Manager s and Operator s Handbook 2012 Kogan Page Publishers ISBN 978 0 7494 6410 3 Poore Shaun 21 April 2022 What Tech is Inside of a VR Headset Quest 2 Teardown ShaunPoore com Retrieved 27 October 2022 How Lenses for Virtual Reality Headsets Work VR Lens Lab 8 March 2016 Archived from the original on 27 October 2022 Retrieved 27 October 2022 Introducing Meta Quest Pro an Advanced VR Device for Collaboration and Creation www oculus com Retrieved 27 October 2022 C Mark 26 April 2022 The difference between pancakes lenses and current fresnel lenses found on VR headsets VR Expert Enterprise VR AR Hardware Supplier Retrieved 27 October 2022 Nikon Corp AF S NIKKOR 300mm f 4E PF ED VR 6 January 2015 Archived 15 February 2015 at the Wayback Machine Phase Fresnel The PF in Nikon s New 300mm f 4E PF ED VR The Digital Picture Archived 14 January 2015 at the Wayback Machine Soitec s Concentrix technology archived from the original on 17 April 2011 retrieved 3 September 2013 Soitec s high performance Concentrix technology archived from the original on 23 September 2013 retrieved 27 February 2021 M Margolin 24 August 2016 This 3D printer runs on sand and sun Vice archived from the original on 1 December 2017 retrieved 27 February 2021 Bibliography editM Born and E Wolf Principles of Optics 7th Ed Cambridge 1999 G A Boutry 1948 Augustin Fresnel His time life and work 1788 1827 Science Progress vol 36 no 144 October 1948 pp 587 604 jstor org stable 43413515 J Z Buchwald 1989 The Rise of the Wave Theory of Light Optical Theory and Experiment in the Early Nineteenth Century University of Chicago Press ISBN 978 0 226 07886 1 J Elton 2009 A Light to Lighten our Darkness Lighthouse Optics and the Later Development of Fresnel s Revolutionary Refracting Lens 1780 1900 International Journal for the History of Engineering amp Technology vol 79 no 2 July 2009 pp 183 244 doi 10 1179 175812109X449612 A Fresnel 1822 Memoire sur un nouveau systeme d eclairage des phares read 29 July 1822 reprinted in Fresnel 1866 1870 vol 3 pp 97 126 translated by T Tag as Memoir upon a new system of lighthouse illumination U S Lighthouse Society accessed 26 August 2017 archived 19 August 2016 Cited page numbers refer to the translation A Fresnel ed H de Senarmont E Verdet and L Fresnel 1866 1870 Oeuvres completes d Augustin Fresnel 3 vols Paris Imprimerie Imperiale vol 1 1866 vol 2 1868 vol 3 1870 T H Levitt 2013 A Short Bright Flash Augustin Fresnel and the Birth of the Modern Lighthouse New York W W Norton ISBN 978 0 393 35089 0 T Young ed G Peacock 1855 Miscellaneous Works of the late Thomas Young London J Murray vol 1 Further reading edit The Fresnel Lens The Keeper s Log Winter 1985 pp 12 14 U S Coast Guard Aids to Navigation Washington DC U S Government Printing Office 1945 U S Coast Guard Lighthouses Lenses Illuminants Engineering amp Augustin Fresnel A Historical Bibliography on Works Published Through 2007 External links edit nbsp Wikimedia Commons has media related to Fresnel lenses United States Lighthouse Society especially Fresnel Lenses Archived 2 March 2021 at the Wayback Machine W A Britten The Fresnel lens with photographs J Francis Fresnel Lens Maxwell Simulation 13 April 2009 J Hare How the Fresnel lens works 5 minute video Vega Science Trust 2008 T Pepper Seeing the Light Lighthouses on the western Great Lakes archived from the original on 30 January 2008 The Fresnel Lens the Invention That Saved 1000 Ships Retrieved from https en wikipedia org w index php title Fresnel lens amp oldid 1220072704 Lighthouse lens sizes, wikipedia, wiki, book, books, library,

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