A hot mirror is the opposite, the coating preferentially reflects infrared. Mirror surfaces are sometimes given thin film overcoatings both to retard degradation of the surface and to increase their reflectivity in parts of the spectrum where they will be used. For instance, aluminium mirrors are commonly coated with silicon dioxide or magnesium fluoride. The reflectivity as a function of wavelength depends on both the thickness of the coating and on how it is applied.

Obwohl die individuelle Pixelgröße beim Form 4 größer ist als bei einigen Konkurrenten, zeigen die Testergebnisse, dass der Drucker im Vergleich zu MSLA-3D-Druckern mit kleineren Pixelgrößen eine vergleichbare, wenn nicht sogar bessere Oberflächengüte, Maßgenauigkeit und minimale Strukturgröße erreicht. Indem unser Team das ideale Gleichgewicht erarbeitete, war es außerdem in der Lage, den Form 4 im Hinblick auf andere Kriterien zu optimieren, die für Kunden entscheidend sind – schnellere Druckzeiten, höhere Zuverlässigkeit und eine wesentlich längere Lebensdauer der Komponenten.

Absolute Abweichung der gemessenen Abmessungen vom Idealwert (mm): Länge (0,72), Breite (0,22), Breite erhabener Merkmale (0,12), minimale Länge erhabener Merkmale (0,06)

The first mirrors used by humans were most likely pools of still water, or shiny stones.[5] The requirements for making a good mirror are a surface with a very high degree of flatness (preferably but not necessarily with high reflectivity), and a surface roughness smaller than the wavelength of the light.

Mirrors are integral parts of a solar power plant. The one shown in the adjacent picture uses concentrated solar power from an array of parabolic troughs.[64]

Die Auflösung hängt nicht nur von der Größe und Form des Lichts ab, das einen LCD-Bildschirm passiert oder von einem Laser oder Lichtprojektor ausgestrahlt wird. Sie ist auch von der PSF dieses Lichts, den Druckprozessen, der mechanischen Konsistenz und den optischen Eigenschaften des Kunstharzes abhängig. Die Auflösung sollte als nur ein Faktor betrachtet werden, wenn es um die erreichbare Oberflächengüte, Merkmalsgröße und Maßgenauigkeit geht. Diese Informationen und Perspektiven können bei der Entscheidung helfen, welcher Drucker am besten für Ihre spezifischen Bedürfnisse geeignet ist.

In short, an aspheric lens is a lens that provides higher-quality imaging. They adjust curvature and shape to correct problems such as spherical aberration, ...

A convex parabolic mirror, on the other hand, will reflect rays that are parallel to its axis into rays that seem to emanate from the focus of the surface, behind the mirror. Conversely, it will reflect incoming rays that converge toward that point into rays that are parallel to the axis. A convex mirror that is part of a prolate ellipsoid will reflect rays that converge towards one focus into divergent rays that seem to emanate from the other focus.[41]

The surface of curved mirrors is often a part of a sphere. Mirrors that are meant to precisely concentrate parallel rays of light into a point are usually made in the shape of a paraboloid of revolution instead; they are used in telescopes (from radio waves to X-rays), in antennas to communicate with broadcast satellites, and in solar furnaces. A segmented mirror, consisting of multiple flat or curved mirrors, properly placed and oriented, may be used instead.

Wedge errors are caused by the deviation of the surfaces from perfect parallelism. An optical wedge is the angle formed between two plane-surfaces (or between the principle planes of curved surfaces) due to manufacturing errors or limitations, causing one edge of the mirror to be slightly thicker than the other. Nearly all mirrors and optics with parallel faces have some slight degree of wedge, which is usually measured in seconds or minutes of arc. For first-surface mirrors, wedges can introduce alignment deviations in mounting hardware. For second-surface or transmissive mirrors, wedges can have a prismatic effect on the light, deviating its trajectory or, to a very slight degree, its color, causing chromatic and other forms of aberration. In some instances, a slight wedge is desirable, such as in certain laser systems where stray reflections from the uncoated surface are better dispersed than reflected back through the medium.[44][50]

Thin flexible plastic mirrors are sometimes used for safety, since they cannot shatter or produce sharp flakes. Their flatness is achieved by stretching them on a rigid frame. These usually consist of a layer of evaporated aluminium between two thin layers of transparent plastic.[citation needed]

Die Genauigkeit wird mit Messschiebern, einer Koordinatenmessmaschine (CMM), einem 3D-Scanner, Prüfstiften oder anderen Passungstests gemessen. Neben der Pixel- oder Laserspotgröße haben die Drucktemperatur, die mechanische Wiederholbarkeit und die optische Konsistenz maßgeblichen Einfluss auf die Genauigkeit.

Die Pixel- oder Laserspotgröße stellt beispielsweise eine Untergrenze für die Größe positiver Merkmale in der horizontalen Ebene dar (d. h. es kann kein positives Merkmal geben, das kleiner als die Pixel- oder Spotgröße ist). In der Regel liegt die minimale Strukturgröße jedoch weit über diesem Grenzwert (oft weit über 100 µm), was auf mehrere Faktoren zurückzuführen ist, wie z. B. die Abzugskräfte.

Die Oberflächenbeschaffenheit ist mit bloßem Auge praktisch nicht zu unterscheiden. Gekrümmte Oberflächen erscheinen glatt, Kanten sind scharf, und sowohl positive als auch negative oder eingravierte Merkmale sind klar umrissen. Der geprägte Text ist detailliert, gut lesbar und gleichmäßig auf der Oberfläche erhaben.

Applications requiring higher reflectivity or greater durability, where wide bandwidth is not essential, use dielectric coatings, which can achieve reflectivities as high as 99.997% over a limited range of wavelengths. Because they are often chemically stable and do not conduct electricity, dielectric coatings are almost always applied by methods of vacuum deposition, and most commonly by evaporation deposition. Because the coatings are usually transparent, absorption losses are negligible. Unlike with metals, the reflectivity of the individual dielectric-coatings is a function of Snell's law known as the Fresnel equations, determined by the difference in refractive index between layers. Therefore, the thickness and index of the coatings can be adjusted to be centered on any wavelength. Vacuum deposition can be achieved in a number of ways, including sputtering, evaporation deposition, arc deposition, reactive-gas deposition, and ion plating, among many others.[17]: p.103, 107

Tradition states that Archimedes used a large array of mirrors to burn Roman ships during an attack on Syracuse. This has never been proven or disproved. On the TV show MythBusters, a team from MIT tried to recreate the famous "Archimedes Death Ray". They were unsuccessful at starting a fire on a ship.[69] Previous attempts to set a boat on fire using only the bronze mirrors available in Archimedes' time were unsuccessful, and the time taken to ignite the craft would have made its use impractical, resulting in the MythBusters team deeming the myth "busted". It was however found that the mirrors made it very difficult for the passengers of the targeted boat to see; such a scenario could have impeded attackers and have provided the origin of the legend. (See solar power tower for a practical use of this technique.)

More specifically, a concave parabolic mirror (whose surface is a part of a paraboloid of revolution) will reflect rays that are parallel to its axis into rays that pass through its focus. Conversely, a parabolic concave mirror will reflect any ray that comes from its focus towards a direction parallel to its axis. If a concave mirror surface is a part of a prolate ellipsoid, it will reflect any ray coming from one focus toward the other focus.[41]

The earliest manufactured mirrors were pieces of polished stone such as obsidian, a naturally occurring volcanic glass.[6] Examples of obsidian mirrors found at Çatalhöyük in Anatolia (modern-day Turkey) have been dated to around 6000 BCE.[7] Mirrors of polished copper were crafted in Mesopotamia from 4000 BCE,[7] and in ancient Egypt from around 3000 BCE.[8] Polished stone mirrors from Central and South America date from around 2000 BCE onwards.[7]

The most common mirrors consist of a plate of transparent glass, with a thin reflective layer on the back (the side opposite to the incident and reflected light) backed by a coating that protects that layer against abrasion, tarnishing, and corrosion. The glass is usually soda-lime glass, but lead glass may be used for decorative effects, and other transparent materials may be used for specific applications.[citation needed]

When a sufficiently narrow beam of light is reflected at a point of a surface, the surface's normal direction n → {\displaystyle {\vec {n}}} will be the bisector of the angle formed by the two beams at that point. That is, the direction vector u → {\displaystyle {\vec {u}}} towards the incident beams's source, the normal vector n → {\displaystyle {\vec {n}}} , and direction vector v → {\displaystyle {\vec {v}}} of the reflected beam will be coplanar, and the angle between n → {\displaystyle {\vec {n}}} and v → {\displaystyle {\vec {v}}} will be equal to the angle of incidence between n → {\displaystyle {\vec {n}}} and u → {\displaystyle {\vec {u}}} , but of opposite sign.[41]

Die Oberflächenqualität ist entscheidend – sie beeinflusst nicht nur das Aussehen und die Haptik eines Teils, sondern auch, wie dieses Teil in eine bestehende Baugruppe passt oder als Formwerkzeug funktioniert. Die Oberflächengüte lässt sich visuell beurteilen – wie glatt ein Teil also zu sein scheint – oder mit einem Messgerät für die Oberflächenrauheit (Ra) bestimmen. Neben der Pixel- oder Laserspotgröße wird die Oberflächenqualität in erster Linie durch die Schichthöhe in der Z-Achse, die optischen Eigenschaften des Kunstharzes und die Konsistenz der Abläufe zwischen den Schichten (Ablösen und Eintauchen) beeinflusst.

Maßgenauigkeit (wie gut das Teil also mit den Abmessungen der Originaldatei übereinstimmt) ist wichtig für die Wiederholbarkeit und die Nutzbarkeit des Teils. Wenn ein Drucker die Geometrie nicht umsetzen kann, funktionieren die Teile in der vorgesehenen Umgebung nicht. Bei bestimmten Anwendungen, wie z. B. bei zahnmedizinischen oder kieferorthopädischen Modellen, ist Maßgenauigkeit besonders wichtig, denn hier ist die perfekte Reproduktion der Scandatei und damit der Patientenanatomie für den Erfolg der Anwendung entscheidend.

For scientific optical work, dielectric mirrors are often used. These are glass (or sometimes other material) substrates on which one or more layers of dielectric material are deposited, to form an optical coating. By careful choice of the type and thickness of the dielectric layers, the range of wavelengths and amount of light reflected from the mirror can be specified. The best mirrors of this type can reflect >99.999% of the light (in a narrow range of wavelengths) which is incident on the mirror. Such mirrors are often used in lasers.

Mirrors are commonly used as aids to personal grooming.[53] They may range from small sizes (portable), to full body sized; they may be handheld, mobile, fixed or adjustable. A classic example of an adjustable mirror is the cheval glass, which the user can tilt.

Freitragende Wände waren für alle Drucker eine Herausforderung, mit unterschiedlichem Grad der Aufrichtung. Die freitragende Wand mit der größten Wandstärke wurde von jedem Drucker erfolgreich gedruckt, während der Form 4 auch die folgenden vier Wände relativ aufrecht erstellte. Sowohl bei Drucker C als auch bei Drucker D stürzten die ungestützten Wände bei Verringerung der Wandstärke vollkommen ein. Obwohl diese Drucker mit verschiedenen Bereichen des Testmodells Probleme hatten, korrelierten die Fehldrucke nicht mit der Größe der Pixel- oder Laserpunkte. Daraus lässt sich ableiten, dass die minimale Strukturgröße von mehreren Faktoren abhängt, darunter die Mechanismen des Druckprozesses und die Eigenschaften des Kunstharzes.

Mirrors are often produced by the wet deposition of silver, or sometimes nickel or chromium (the latter used most often in automotive mirrors) via electroplating directly onto the glass substrate.[27]

Monochromatisches Licht. Monochromatisches Licht ist Licht einer bestimmten Farbe. Bei Gasolec verwenden wir Lampen mit grünem, blauem, rotem und extra-warmem ...

Vergleicht man die PSF des Form 4 (bei dem das Licht durch einen aus 50 µm großen Pixeln bestehenden LCD-Bildschirm projiziert wird) mit dem Form 3+ (bei dem das Licht von einem Laser mit einer Spotgröße von 80 µm stammt), so zeigt sich, dass der Form 4 konzentriertes, direktes Licht einsetzt, wobei die höchste Energiedichte in der Mitte des Pixels gebündelt ist.

A mirror, also known as a looking glass, is an object that reflects an image. Light that bounces off a mirror will show an image of whatever is in front of it, when focused through the lens of the eye or a camera. Mirrors reverse the direction of the image in an equal yet opposite angle from which the light shines upon it. This allows the viewer to see themselves or objects behind them, or even objects that are at an angle from them but out of their field of view, such as around a corner. Natural mirrors have existed since prehistoric times, such as the surface of water, but people have been manufacturing mirrors out of a variety of materials for thousands of years, like stone, metals, and glass. In modern mirrors, metals like silver or aluminium are often used due to their high reflectivity, applied as a thin coating on glass because of its naturally smooth and very hard surface.

Surface quality, or surface accuracy, measures the deviations from a perfect, ideal surface shape. Increasing the surface quality reduces distortion, artifacts, and aberration in images, and helps increase coherence, collimation, and reduce unwanted divergence in beams. For plane mirrors, this is often described in terms of flatness, while other surface shapes are compared to an ideal shape. The surface quality is typically measured with items like interferometers or optical flats, and are usually measured in wavelengths of light (λ). These deviations can be much larger or much smaller than the surface roughness. A normal household-mirror made with float glass may have flatness tolerances as low as 9–14λ per inch (25.4 mm), equating to a deviation of 5600 through 8800 nanometers from perfect flatness. Precision ground and polished mirrors intended for lasers or telescopes may have tolerances as high as λ/50 (1/50 of the wavelength of the light, or around 12 nm) across the entire surface.[45][44] The surface quality can be affected by factors such as temperature changes, internal stress in the substrate, or even bending effects that occur when combining materials with different coefficients of thermal expansion, similar to a bimetallic strip.[46]

These early glass mirrors were made by blowing a glass bubble, and then cutting off a small circular section from 10 to 20 cm in diameter. Their surface was either concave or convex, and imperfections tended to distort the image. Lead-coated mirrors were very thin to prevent cracking by the heat of the molten metal.[16]: p.10  Due to the poor quality, high cost, and small size of glass mirrors, solid-metal mirrors (primarily of steel) remained in common use until the late nineteenth century.[16]: p.13

Das Design des Druckers, einschließlich der Pixelgröße als eines von vielen Charakteristika, hat Auswirkungen auf drei wichtige Eigenschaften der Druckteile. Diese Eigenschaften – Oberflächenqualität, minimale Strukturgröße und Maßgenauigkeit – sind messbar und standardisiert, aber da sie durch eine komplexe Kombination von Prozessen und Komponenten beeinflusst werden, sind sie schwieriger zu erfassen. Eine etwas größere Pixelgröße wirkt sich weniger stark aus als die Qualität, die Konsistenz und die Uniformität des Lichts, welches das Pixel abdeckt oder durchlässt.

Mirrors reflect an image to the observer. However, unlike a projected image on a screen, an image does not actually exist on the surface of the mirror. For example, when two people look at each other in a mirror, both see different images on the same surface. When the light waves converge through the lens of the eye they interfere with each other to form the image on the surface of the retina, and since both viewers see waves coming from different directions, each sees a different image in the same mirror. Thus, the images observed in a mirror depend upon the angle of the mirror with respect to the eye. The angle between the object and the observer is always twice the angle between the eye and the normal, or the direction perpendicular to the surface. This allows animals with binocular vision to see the reflected image with depth perception and in three dimensions.

A mirror is a wave reflector. Light consists of waves, and when light waves reflect from the flat surface of a mirror, those waves retain the same degree of curvature and vergence, in an equal yet opposite direction, as the original waves. This allows the waves to form an image when they are focused through a lens, just as if the waves had originated from the direction of the mirror. The light can also be pictured as rays (imaginary lines radiating from the light source, that are always perpendicular to the waves). These rays are reflected at an equal yet opposite angle from which they strike the mirror (incident light). This property, called specular reflection, distinguishes a mirror from objects that diffuse light, breaking up the wave and scattering it in many directions (such as flat-white paint). Thus, a mirror can be any surface in which the texture or roughness of the surface is smaller (smoother) than the wavelength of the waves.

Looking at an image of oneself with the front-back axis flipped results in the perception of an image with its left-right axis flipped. When reflected in the mirror, a person's right hand remains directly opposite their real right hand, but it is perceived by the mind as the left hand in the image. When a person looks into a mirror, the image is actually front-back reversed (inside-out), which is an effect similar to the hollow-mask illusion. Notice that a mirror image is fundamentally different from the object (inside-out) and cannot be reproduced by simply rotating the object. An object and its mirror image are said to be chiral.

Convex mirrors provide a wider field of view than flat mirrors,[54] and are often used on vehicles,[55] especially large trucks, to minimize blind spots. They are sometimes placed at road junctions, and at corners of sites such as parking lots to allow people to see around corners to avoid crashing into other vehicles or shopping carts. They are also sometimes used as part of security systems, so that a single video camera can show more than one angle at a time.[56] Convex mirrors as decoration are used in interior design to provide a predominantly experiential effect.[57]

Laserbasierte SLA-3D-Drucker haben in der Regel eine sehr hohe Auflösung, da der Laser in der XY-Ebene präzise gesteuert werden kann und eine kleine Spotgröße hat. Diese Eigenschaften sind jedoch nur ein Faktor – die tatsächliche minimale Merkmalsgröße wird von mehreren weiteren Faktoren beeinflusst, sodass die Druckergebnisse mit professionellen MSLA-Druckern ohne Laser vergleichbar sind. Außerdem haben SLA-Drucker mit einem Laser als Lichtquelle oft längere Druckzeiten, weil der Querschnitt des Teils über die gesamte Schicht nachgezeichnet werden muss.

During the early European Renaissance, a fire-gilding technique developed to produce an even and highly reflective tin coating for glass mirrors. The back of the glass was coated with a tin-mercury amalgam, and the mercury was then evaporated by heating the piece. This process caused less thermal shock to the glass than the older molten-lead method.[16]: p.16  The date and location of the discovery is unknown, but by the 16th century Venice was a center of mirror production using this technique. These Venetian mirrors were up to 40 inches (100 cm) square.

Anhand des Drucks und der Analyse mehrerer Teile aus dem Form 4 (Desktop-MSLA, 50 µm Pixelgröße, 10" 4K-Bildschirm), Form 3+ (laserbasierte SLA mit 85 µm Laserspotgröße), Drucker C (Desktop-MSLA, 28 µm Pixelgröße, 9" 8K-Bildschirm) und Drucker D (Desktop-MSLA, 19 x 24 µm Pixelgröße, 9" 12K-Bildschirm) werden wir demonstrieren, dass die gängige Kennzahl der Auflösung keinen direkte Effekt auf das Druckergebnis hat.

Beim DLP-3D-Druck wird die XY-Auflösung von der Pixelgröße bestimmt, dem kleinsten Merkmal, das der Projektor in einer einzelnen Schicht reproduzieren kann. Dies hängt von der Auflösung des Projektors – Full-HD (1080p) ist die häufigste – sowie vom Abstand zum optischen Fenster ab. Darum haben die meisten DLP-3D-Drucker im Desktop-Format eine feste XY-Auflösung, die im Allgemeinen zwischen 35 und 100 Mikrometern liegt.

Vergleicht man die Punktspreizfunktion (PSF) des Form 4 mit der des Form 3, so lässt sich feststellen, dass beide Drucker ein hochkonzentriertes Licht erzeugen, das sich in der Mitte des Pixels oder des Laserspots bündelt – was sich direkt auf die Auflösung auswirkt.

Telescopes and other precision instruments use front silvered or first surface mirrors, where the reflecting surface is placed on the front (or first) surface of the glass (this eliminates reflection from glass surface ordinary back mirrors have). Some of them use silver, but most are aluminium, which is more reflective at short wavelengths than silver. All of these coatings are easily damaged and require special handling. They reflect 90% to 95% of the incident light when new. The coatings are typically applied by vacuum deposition. A protective overcoat is usually applied before the mirror is removed from the vacuum, because the coating otherwise begins to corrode as soon as it is exposed to oxygen and humidity in air. Front silvered mirrors have to be resurfaced occasionally to maintain their quality. There are optical mirrors such as mangin mirrors that are second surface mirrors (reflective coating on the rear surface) as part of their optical designs, usually to correct optical aberrations.[65]

For perfectly specular reflection, the surface roughness must be kept smaller than the wavelength of the light. Microwaves, which sometimes have a wavelength greater than an inch (~25 mm) can reflect specularly off a metal screen-door, continental ice-sheets, or desert sand, while visible light, having wavelengths of only a few hundred nanometers (a few hundred-thousandths of an inch), must meet a very smooth surface to produce specular reflection. For wavelengths that are approaching or are even shorter than the diameter of the atoms, such as X-rays, specular reflection can only be produced by surfaces that are at a grazing incidence from the rays.

Surface defects are small-scale, discontinuous imperfections in the surface smoothness. Surface defects are larger (in some cases much larger) than the surface roughness, but only affect small, localized portions of the entire surface. These are typically found as scratches, digs, pits (often from bubbles in the glass), sleeks (scratches from prior, larger grit polishing operations that were not fully removed by subsequent polishing grits), edge chips, or blemishes in the coating. These defects are often an unavoidable side-effect of manufacturing limitations, both in cost and machine precision. If kept low enough, in most applications these defects will rarely have any adverse effect, unless the surface is located at an image plane where they will show up directly. For applications that require extremely low scattering of light, extremely high reflectance, or low absorption due to high energy levels that could destroy the mirror, such as lasers or Fabry-Perot interferometers, the surface defects must be kept to a minimum.[51]

Absolute Abweichung der gemessenen Abmessungen vom Idealwert (mm): Länge (+0,77), Breite (-0,37), Breite erhabener Merkmale (-0,371), minimale Länge erhabener Merkmale (-0,052)

Periscopes were used to great effect in war, especially during the World Wars where they were used to peer over the parapet of trenches to ensure that the soldier using the periscope could see safely without the risk of incoming direct fire from other small arms.

Kunstharz-3D-Drucker verfügen entweder über einen Laser (laserbasierte SLA), einen digitalen Lichtprojektor (DLP) oder eine Lichtverarbeitungseinheit (meist ein LCD-Bildschirm), die eine Lichtquelle wie etwa eine Reihe LEDs selektiv maskiert (MSLA).

Mirrors are a popular design-theme in architecture, particularly with late modern and post-modernist high-rise buildings in major cities. Early examples include the Campbell Center in Dallas, which opened in 1972,[73] and the John Hancock Tower (completed in 1976) in Boston.

More recently, two skyscrapers designed by architect Rafael Viñoly, the Vdara in Las Vegas and 20 Fenchurch Street in London, have experienced unusual problems due to their concave curved-glass exteriors acting as respectively cylindrical and spherical reflectors for sunlight. In 2010, the Las Vegas Review Journal reported that sunlight reflected off the Vdara's south-facing tower could singe swimmers in the hotel pool, as well as melting plastic cups and shopping bags; employees of the hotel referred to the phenomenon as the "Vdara death ray",[74] aka the "fryscraper." In 2013, sunlight reflecting off 20 Fenchurch Street melted parts of a Jaguar car parked nearby and scorching or igniting the carpet of a nearby barber-shop.[75] This building had been nicknamed the "walkie-talkie" because its shape was supposedly similar to a certain model of two-way radio; but after its tendency to overheat surrounding objects became known, the nickname changed to the "walkie-scorchie".

In the Middle Ages, mirrors existed in various shapes for multiple uses. Mostly they were used as an accessory for personal hygiene but also as tokens of courtly love, made from ivory in the ivory-carving centers in Paris, Cologne and the Southern Netherlands.[81] They also had their uses in religious contexts as they were integrated in a special form of pilgrim badges or pewter/lead mirror boxes[82] From the late 14th century. Burgundian ducal inventories show us that the dukes owned a mass of mirrors or objects with mirrors, not only with religious iconography or inscriptions, but combined with reliquaries, religious paintings or other objects that were distinctively used for personal piety.[83] Considering mirrors in paintings and book illumination as depicted artifacts and trying to draw conclusions about their functions from their setting, one of these functions is to be an aid in personal prayer to achieve self-knowledge and knowledge of God, in accord with contemporary theological sources. For example, the famous Arnolfini Wedding by Jan van Eyck shows a constellation of objects that can be recognized as one which would allow a praying man to use them for his personal piety: the mirror surrounded by scenes of the Passion to reflect on it and on oneself, a rosary as a device in this process, the veiled and cushioned bench to use as a prie-dieu, and the abandoned shoes that point in the direction in which the praying man kneeled.[83] The metaphorical meaning of depicted mirrors is complex and many-layered, e.g. as an attribute of Mary, the "speculum sine macula" (mirror without blemish), or as attributes of scholarly and theological wisdom and knowledge as they appear in book illuminations of different evangelists and authors of theological treatises. Depicted mirrors – orientated on the physical properties of a real mirror – can be seen as metaphors of knowledge and reflection and are thus able to remind beholders to reflect and get to know themselves. The mirror may function simultaneously as a symbol and as a device of a moral appeal. That is also the case if it is shown in combination with virtues and vices, a combination which also occurs more frequently in the 15th century: the moralizing layers of mirror metaphors remind the beholder to examine themself thoroughly according to their own virtuous or vicious life. This is all the more true if the mirror is combined with iconography of death. Not only is Death as a corpse or skeleton holding the mirror for the still-living personnel of paintings, illuminations and prints, but the skull appears on the convex surfaces of depicted mirrors, showing the painted and real beholders their future face.[83]

The Greek in Classical Antiquity were familiar with the use of mirrors to concentrate light. Parabolic mirrors were described and studied by the mathematician Diocles in his work On Burning Mirrors.[29] Ptolemy conducted a number of experiments with curved polished iron mirrors,[2]: p.64  and discussed plane, convex spherical, and concave spherical mirrors in his Optics.[30]

Painters depicting someone gazing into a mirror often also show the person's reflection. This is a kind of abstraction—in most cases the angle of view is such that the person's reflection should not be visible. Similarly, in movies and still photography an actor or actress is often shown ostensibly looking at him- or herself in a mirror, and yet the reflection faces the camera. In reality, the actor or actress sees only the camera and its operator in this case, not their own reflection. In the psychology of perception, this is known as the Venus effect.

Dielectric mirrors can reflect greater than 99.99% of light, but only for a narrow range of wavelengths, ranging from a bandwidth of only 10 nm to as wide as 100 nm for tunable lasers. However, dielectric coatings can also enhance the reflectivity of metallic coatings and protect them from scratching or tarnishing. Dielectric materials are typically very hard and relatively cheap, however the number of coats needed generally makes it an expensive process. In mirrors with low tolerances, the coating thickness may be reduced to save cost, and simply covered with paint to absorb transmission.[44]

Large mirrors are used in rear-projection televisions. Light (for example from a DLP as discussed above) is "folded" by one or more mirrors so that the television set is compact.

These lenses are computer designed to effectively minimize spherical aberration and coma when operating at an infinite conjugate ratio. Unlike singlet lenses, ...

Speculum metal is a highly reflective alloy of copper and tin that was used for mirrors until a couple of centuries ago.[when?][vague] Such mirrors may have originated in China and India.[14] Mirrors of speculum metal or any precious metal were hard to produce and were only owned by the wealthy.[15]

The reflectivity of a mirror is determined by the percentage of reflected light per the total of the incident light. The reflectivity may vary with wavelength. All or a portion of the light not reflected is absorbed by the mirror, while in some cases a portion may also transmit through. Although some small portion of the light will be absorbed by the coating, the reflectivity is usually higher for first-surface mirrors, eliminating both reflection and absorption losses from the substrate.

Mirrors are usually manufactured by either polishing a naturally reflective material, such as speculum metal, or by applying a reflective coating to a suitable polished substrate.[52]

UV Bandpass Filter. PIXELTEQ's ultraviolet (UV) optical bandpass filters deliver precise transmission of specific UV spectral bands while blocking out-of-band ...

For a century, Venice retained the monopoly of the tin amalgam technique. Venetian mirrors in richly decorated frames served as luxury decorations for palaces throughout Europe, and were very expensive. For example, in the late seventeenth century, the Countess de Fiesque was reported to have traded an entire wheat farm for a mirror, considering it a bargain.[24] However, by the end of that century the secret was leaked through industrial espionage. French workshops succeeded in large-scale industrialization of the process, eventually making mirrors affordable to the masses, in spite of the toxicity of mercury's vapor.[25]

Two or more mirrors aligned exactly parallel and facing each other can give an infinite regress of reflections, called an infinity mirror effect. Some devices use this to generate multiple reflections:

Jede dieser Eigenschaften kann durch nahezu jeden Schlüsselaspekt des Systems, der Optik, der Materialien und des Druckprozesses und seiner Parameter erheblich beeinflusst werden. Es ist nicht möglich, einzelne Eingangsparameter direkt mit bestimmten Resultaten gleichzusetzen – außer als Grenzwert.

Microscopic mirrors are a core element of many of the largest high-definition televisions and video projectors. A common technology of this type is Texas Instruments' DLP. A DLP chip is a postage stamp-sized microchip whose surface is an array of millions of microscopic mirrors. The picture is created as the individual mirrors move to either reflect light toward the projection surface (pixel on), or toward a light-absorbing surface (pixel off).

Due to its location in a steep-sided valley, the Italian town of Viganella gets no direct sunlight for seven weeks each winter. In 2006 a €100,000 computer-controlled mirror, 8×5 m, was installed to reflect sunlight into the town's piazza. In early 2007 the similarly situated village of Bondo, Switzerland, was considering applying this solution as well.[70][71] In 2013, mirrors were installed to reflect sunlight into the town square in the Norwegian town of Rjukan.[72] Mirrors can be used to produce enhanced lighting effects in greenhouses or conservatories.

Die Auflösung von DLP-3D-Druckern verringert sich mit steigendem Fertigungsvolumen, da keine Projektoren mit signifikant höherer Pixelzahl verfügbar sind. Somit müssen Hersteller bei gleichbleibender Pixelzahl den Abstand von der Lichtquelle vergrößern, was zu einer verringerten Auflösung und Druckqualität führt.

The most common structural material for mirrors is glass, due to its transparency, ease of fabrication, rigidity, hardness, and ability to take a smooth finish.

the lens or system of lenses in a telescope or microscope that is nearest the object being viewed.

The reflectivity of the mirror coating can be measured using a reflectometer and for a particular metal it will be different for different wavelengths of light. This is exploited in some optical work to make cold mirrors and hot mirrors. A cold mirror is made by using a transparent substrate and choosing a coating material that is more reflective to visible light and more transmissive to infrared light.

Only a few animal species have been shown to have the ability to recognize themselves in a mirror, most of them mammals. Experiments have found that the following animals can pass the mirror test:

The mirror forms a virtual image of whatever is in the opposite angle from the viewer, meaning that objects in the image appear to exist in a direct line of sight—behind the surface of the mirror—at an equal distance from their position in front of the mirror. Objects behind the observer, or between the observer and the mirror, are reflected back to the observer without any actual change in orientation; the light waves are simply reversed in a direction perpendicular to the mirror. However, when viewer is facing the object and the mirror is at an angle between them, the image appears inverted 180° along the direction of the angle.[42]

Optical discs are modified mirrors which encode binary data as a series of physical pits and lands on an inner layer between the metal backing and outer plastic surface. The data is read and decoded by observing distortions in a reflected laser beam caused by the physical variations in the inner layer. Optical discs typically use aluminum backing like conventional mirrors, though ones with silver and gold backings also exist.

Absolute Abweichung der gemessenen Abmessungen vom Idealwert (mm): Länge (0,38), Breite (0,30), Breite erhabener Merkmale (0,07), minimale Länge erhabener Merkmale (-0,05)

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A phase-conjugating mirror uses nonlinear optics to reverse the phase difference between incident beams. Such mirrors may be used, for example, for coherent beam combination. The useful applications are self-guiding of laser beams and correction of atmospheric distortions in imaging systems.[38][39][40]

Obwohl Druckerhersteller die Pixelgröße umstandslos als das A und O der 3D-Druckauflösung anpreisen, ist die Wahrheit (und der tatsächliche Effekt) etwas komplizierter.

Glass began to be used for mirrors in the 1st century CE, with the development of soda-lime glass and glass blowing.[17] The Roman scholar Pliny the Elder claims that artisans in Sidon (modern-day Lebanon) were producing glass mirrors coated with lead or gold leaf in the back. The metal provided good reflectivity, and the glass provided a smooth surface and protected the metal from scratches and tarnishing.[18][19][20][16]: p.12 [21] However, there is no archeological evidence of glass mirrors before the third century.[22]

In astronomy, adaptive optics is a technique to measure variable image distortions and adapt a deformable mirror accordingly on a timescale of milliseconds, to compensate for the distortions.

With the sun as the light source, a mirror can be used to signal by variations in the orientation of the mirror. The signal can be used over long distances, possibly up to 60 kilometres (37 mi) on a clear day. Native American tribes and numerous militaries used this technique to transmit information between distant outposts.

Mirrors which are reflective on the front surface (the same side of the incident and reflected light) may be made of any rigid material.[33] The supporting material does not necessarily need to be transparent, but telescope mirrors often use glass anyway. Often a protective transparent coating is added on top of the reflecting layer, to protect it against abrasion, tarnishing, and corrosion, or to absorb certain wavelengths.[34]

Common metal mirrors tarnished and required frequent polishing. Bronze mirrors had low reflectivity and poor color rendering, and stone mirrors were much worse in this regard.[16]: p.11  These defects explain the New Testament reference in 1 Corinthians 13 to seeing "as in a mirror, darkly."

Mirrors can be manufactured to a wide range of engineering tolerances, including reflectivity, surface quality, surface roughness, or transmissivity, depending on the desired application. These tolerances can range from wide, such as found in a normal household-mirror, to extremely narrow, like those used in lasers or telescopes. Tightening the tolerances allows better and more precise imaging or beam transmission over longer distances. In imaging systems this can help reduce anomalies (artifacts), distortion or blur, but at a much higher cost. Where viewing distances are relatively close or high precision is not a concern, wider tolerances can be used to make effective mirrors at affordable costs.

Trotz des Fokus auf die Anzahl der Pixel oder die Größe der einzelnen Pixel zählen für die meisten Menschen beim 3D-Druck vor allem die greifbaren Ergebnisse: Oberflächengüte, Maßgenauigkeit und die minimale Strukturgröße. Die Pixelgröße ist jedoch nur einer von vielen Faktoren, die darauf Einfluss haben: Das Druckergebnis hängt von einer ganzen Reihe von Gesichtspunkten ab, etwa Materialeigenschaften, optischen Einstellungen, mechanischer Konsistenz und mehr.

By the Bronze Age most cultures were using mirrors made from polished discs of bronze, copper, silver, or other metals.[6][9] The people of Kerma in Nubia were skilled in the manufacturing of mirrors. Remains of their bronze kilns have been found within the temple of Kerma.[10] In China, bronze mirrors were manufactured from around 2000 BC,[11] some of the earliest bronze and copper examples being produced by the Qijia culture. Such metal mirrors remained the norm through to Greco-Roman Antiquity and throughout the Middle Ages in Europe.[12] During the Roman Empire silver mirrors were in wide use by servants.[13]

The evolution of glass mirrors in the Middle Ages followed improvements in glassmaking technology. Glassmakers in France made flat glass plates by blowing glass bubbles, spinning them rapidly to flatten them, and cutting rectangles out of them. A better method, developed in Germany and perfected in Venice by the 16th century, was to blow a cylinder of glass, cut off the ends, slice it along its length, and unroll it onto a flat hot plate.[16]: p.11  Venetian glassmakers also adopted lead glass for mirrors, because of its crystal-clarity and its easier workability.

Absolute Abweichung der gemessenen Abmessungen vom Idealwert (mm): Länge (0,44), Breite (0,42), Breite erhabener Merkmale (0,16), minimale Länge erhabener Merkmale (0,09)

Die Auflösung von LCD-Bildschirmen wird in der Regel anhand der Anzahl der Pixel auf ihrer Längsachse gemessen – eine Kennzahl, die den meisten von digitalen Bildschirmen in Telefonen, Fernsehern und Tablets vertraut ist. Dabei wird nicht nur die Pixelanzahl hervorgehoben, sondern auch die Größe der einzelnen Pixel – mit der Begründung: je kleiner die Pixel, desto höher die Auflösung.

The reflectivity is often determined by the type and thickness of the coating. When the thickness of the coating is sufficient to prevent transmission, all of the losses occur due to absorption. Aluminium is harder and more resistant to tarnishing than silver, and will reflect 85 to 90% of the light in the visible to near-ultraviolet range, but experiences a drop in its reflectance between 800 and 900 nm. Gold is very soft and easily scratched, but does not tarnish. Gold is greater than 96% reflective to near and far-infrared light between 800 and 12000 nm, but poorly reflects visible light with wavelengths shorter than 600 nm (yellow). Silver is expensive, soft, and quickly tarnishes, but has the highest reflectivity in the visual to near-infrared of any metal. Silver can reflect up to 98 or 99% of light to wavelengths as long as 2000 nm, but loses nearly all reflectivity at wavelengths shorter than 350 nm.

The invention of the ribbon machine in the late Industrial Revolution allowed modern glass panes to be produced in bulk.[16] The Saint-Gobain factory, founded by royal initiative in France, was an important manufacturer, and Bohemian and German glass, often rather cheaper, was also important.

Bei MSLA-3D-Druckern, die das Licht mithilfe von LCD-Bildschirmen maskieren, ist das tatsächliche, auf das Kunstharz projizierte Bild in der Regel deutlich größer und diffuser als das ursprüngliche Pixel. Dieser Effekt wird als Punktspreizfunktion (PSF) bezeichnet: die Art und Weise, wie ein ursprüngliches oder idealisiertes Bild durch den Projektionsprozess unscharf wird. Bei MSLA-Druckern ist also die Pixelgröße weniger entscheidend als die Leistungsverteilung und die Form des auf das Kunstharz treffenden Lichts.

The Greek philosopher Socrates urged young people to look at themselves in mirrors so that, if they were beautiful, they would become worthy of their beauty, and if they were ugly, they would know how to hide their disgrace through learning.[16]: p.106

A similar aberration occurs with parabolic mirrors when the incident rays are parallel among themselves but not parallel to the mirror's axis, or are divergent from a point that is not the focus – as when trying to form an image of an object that is near the mirror or spans a wide angle as seen from it. However, this aberration can be sufficiently small if the object image is sufficiently far from the mirror and spans a sufficiently small angle around its axis.[41]

Bei der Entwicklung der Light Processing Unit des Form 4 hat Formlabs die Wechselwirkung zwischen Pixelgröße, Geschwindigkeit, Zuverlässigkeit und Lebensdauer der Komponenten sorgfältig abgewogen. Da die Pixelgröße des LCD-Bildschirms keinen spürbaren Einfluss auf die drei wichtigsten Charakteristika der Auflösung hat, bedeutet eine höhere Pixelgröße keinen Kompromiss – sondern eine Investition in Leistung und Geschwindigkeit.

A plate of transparent plastic may be used instead of glass, for lighter weight or impact resistance. Alternatively, a flexible transparent plastic film may be bonded to the front and/or back surface of the mirror, to prevent injuries in case the mirror is broken. Lettering or decorative designs may be printed on the front face of the glass, or formed on the reflective layer. The front surface may have an anti-reflection coating.[citation needed]

When looking at a mirror, one will see a mirror image or reflected image of objects in the environment, formed by light emitted or scattered by them and reflected by the mirror towards one's eyes. This effect gives the illusion that those objects are behind the mirror, or (sometimes) in front of it. When the surface is not flat, a mirror may behave like a reflecting lens. A plane mirror yields a real-looking undistorted image, while a curved mirror may distort, magnify, or reduce the image in various ways, while keeping the lines, contrast, sharpness, colors, and other image properties intact.

Surface roughness is typically measured in microns, wavelength, or grit size, with ~80,000–100,000 grit or ~½λ–¼λ being "optical quality".[47][44][48]

A mirror is commonly used for inspecting oneself, such as during personal grooming; hence the old-fashioned name "looking glass".[1] This use, which dates from prehistory,[2] overlaps with uses in decoration and architecture. Mirrors are also used to view other items that are not directly visible because of obstructions; examples include rear-view mirrors in vehicles, security mirrors in or around buildings, and dentist's mirrors. Mirrors are also used in optical and scientific apparatus such as telescopes, lasers, cameras, periscopes, and industrial machinery.

The Rayleigh length is the distance (from the waist) where the beam area is twice the beam area at the waist (the radius is times bigger). This parameter is ...

Wie bereits erwähnt, scheint die Pixelgröße oder die Laserspotgröße intuitiv ein einfacher Maßstab für die Größe positiver Merkmale zu sein. In der Praxis gibt es allerdings keine Drucker, die einzelne positive Merkmale in der Größe einzelner Pixel – 20 µm, 30 µm, 50 µm oder 80 µm – produzieren können. Stattdessen sind die Faktoren, die die minimale Strukturgröße wirklich beeinflussen, die Temperatur, die mechanische Wiederholbarkeit und die optische Konsistenz. Wie die Fotos zeigen, bietet der Form 4 einige der besten Minimalwerte. Alle Drucker hatten Schwierigkeiten, sämtliche Negativkanäle fertigzustellen, aber Form 4 und Drucker D gaben vier von fünf Kanälen klar wieder, während Form 3+ und Drucker C nur drei von fünf Kanälen erstellen konnten.

The structural material may be a metal, in which case the reflecting layer may be just the surface of the same. Metal concave dishes are often used to reflect infrared light (such as in space heaters) or microwaves (as in satellite TV antennas). Liquid metal telescopes use a surface of liquid metal such as mercury.

Silver-coated metal mirrors were developed in China as early as 500 CE. The bare metal was coated with an amalgam, then heated until the mercury boiled away.[23]

I did a common website for FOV calculation and got 148 degrees. That sounds wrong to me. AMS2 only goes up to 120 - but is that degrees?

Wie die Scans zeigen, führt eine geringere Pixel- oder Laserpunktgröße nicht zwangsläufig zu einer höheren Maßgenauigkeit. Die Dentalmodelle aus Druckern mit „größeren“ einzelnen Lichtpunkten sind nahezu vollkommen maßstabsgetreu: Das Zahnmodell aus dem Form 4 ist genauer als das auf Drucker C hergestellte, obwohl Drucker C eine kleinere Pixelgröße hat.

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A similar phenomenon had been observed with incandescent light bulbs: the metal in the hot filament would slowly sublimate and condense on the bulb's walls. This phenomenon was developed into the method of evaporation coating by Pohl and Pringsheim in 1912. John D. Strong used evaporation coating to make the first aluminium-coated telescope mirrors in the 1930s.[28] The first dielectric mirror was created in 1937 by Auwarter using evaporated rhodium.[17]

Mirrors that are intended to concentrate sunlight onto a long pipe may be a circular cylinder or of a parabolic cylinder.[32]

This property can be explained by the physics of an electromagnetic plane wave that is incident to a flat surface that is electrically conductive or where the speed of light changes abruptly, as between two materials with different indices of refraction.

Glass mirrors for optical instruments are usually produced by vacuum deposition methods. These techniques can be traced to observations in the 1920s and 1930s that metal was being ejected from electrodes in gas discharge lamps and condensed on the glass walls forming a mirror-like coating. The phenomenon, called sputtering, was developed into an industrial metal-coating method with the development of semiconductor technology in the 1970s.

The invention of the silvered-glass mirror is credited to German chemist Justus von Liebig in 1835.[26] His wet deposition process involved the deposition of a thin layer of metallic silver onto glass through the chemical reduction of silver nitrate. This silvering process was adapted for mass manufacturing and led to the greater availability of affordable mirrors.

Die Strukturgröße oder Merkmalsgröße als Leistungsmaßstab bezieht sich auf die minimale Merkmalsgröße oder die kleinste Struktur, die ein 3D-Drucker herstellen kann. Diese Strukturgröße ändert sich je nachdem, ob es sich etwa um eingravierte Merkmale, geprägte Merkmale, einen hervorstehenden Draht, ein vertieftes Loch oder einen Kanal handelt. Die Merkmale können durch eine einfache Pass/Fail-Prüfung oder mithilfe von Messschiebern, einem CMM oder einem 3D-Scanner gemessen werden.

Mirrors can also be used to attract the attention of search-and-rescue parties. Specialized types of mirrors are available and are often included in military survival kits.[63]

Although most mirrors are designed to reflect visible light, surfaces reflecting other forms of electromagnetic radiation are also called "mirrors". The mirrors for other ranges of electromagnetic waves are used in optics and astronomy. Mirrors for radio waves (sometimes known as reflectors) are important elements of radio telescopes.

The terms "mirror" and "reflector" can be used for objects that reflect any other types of waves. An acoustic mirror reflects sound waves. Objects such as walls, ceilings, or natural rock-formations may produce echos, and this tendency often becomes a problem in acoustical engineering when designing houses, auditoriums, or recording studios. Acoustic mirrors may be used for applications such as parabolic microphones, atmospheric studies, sonar, and seafloor mapping.[4] An atomic mirror reflects matter waves and can be used for atomic interferometry and atomic holography.

Die Auflösung ist beim 3D-Druck ein Thema, das viel diskutiert, aber häufig missverstanden wird. Die Vielfalt der 3D-Drucktechnologien und die wachsende Zahl der Hersteller haben die Angelegenheit noch komplizierter gemacht. Durch die Einführung der maskierten Stereolithographie (MSLA), bei der das Licht mit einem LCD-Bildschirm selektiv maskiert wird, um nur die vorgesehenen Bereiche des flüssigen Kunstharzes zu belichten, erhält die Debatte rund um die Auflösung eine neue Ebene. MSLA-3D-Drucker erfreuen sich großer Beliebtheit, denn sie sind in der Lage, hochwertige Teile in kürzester Zeit zu drucken.

Um mehr über die nächste Generation des SLA-3D-Drucks zu erfahren, lernen Sie den Form 4 kennen. Sind Sie neugierig auf die Oberflächenqualität, die minimale Strukturgröße und die Maßgenauigkeit, die mit der LFD-Technologie des Form 4 möglich sind? Dann fordern Sie einen kostenlosen Probedruck an, der an Ihren Arbeitsplatz gesendet wird.

In some applications, generally those that are cost-sensitive or that require great durability, such as for mounting in a prison cell, mirrors may be made from a single, bulk material such as polished metal. However, metals consist of small crystals (grains) separated by grain boundaries that may prevent the surface from attaining optical smoothness and uniform reflectivity.[17]: p.2, 8

Mirrors can be classified in many ways; including by shape, support, reflective materials, manufacturing methods, and intended application.

Surface roughness describes the texture of the surface, often in terms of the depth of the microscopic scratches left by the polishing operations. Surface roughness determines how much of the reflection is specular and how much diffuses, controlling how clear or cloudy the image will be.

In X-ray telescopes, the X-rays reflect off a highly precise metal surface at almost grazing angles, and only a small fraction of the rays are reflected.[36] In flying relativistic mirrors conceived for X-ray lasers, the reflecting surface is a spherical shockwave (wake wave) created in a low-density plasma by a very intense laser-pulse, and moving at an extremely high velocity.[37]

Mirrors that reflect only part of the light, while transmitting some of the rest, can be made with very thin metal layers or suitable combinations of dielectric layers. They are typically used as beamsplitters. A dichroic mirror, in particular, has surface that reflects certain wavelengths of light, while letting other wavelengths pass through. A cold mirror is a dichroic mirror that efficiently reflects the entire visible light spectrum while transmitting infrared wavelengths. A hot mirror is the opposite: it reflects infrared light while transmitting visible light. Dichroic mirrors are often used as filters to remove undesired components of the light in cameras and measuring instruments.

Spherical mirrors do not reflect parallel rays to rays that converge to or diverge from a single point, or vice versa, due to spherical aberration. However, a spherical mirror whose diameter is sufficiently small compared to the sphere's radius will behave very similarly to a parabolic mirror whose axis goes through the mirror's center and the center of that sphere; so that spherical mirrors can substitute for parabolic ones in many applications.[41]

Oberflächenqualität, Merkmalsgröße und Genauigkeit werden von allen Komponenten des 3D-Druckers und des Druckprozesses beeinflusst. Einzelne Faktoren wie die Pixelgröße können theoretische Untergrenzen festlegen, die in realistischen Situationen aber nicht vorkommen. Zum Beispiel könnte eine Pixel- oder Laserspotgröße von 80 Mikrometern theoretisch die Mindestgröße zur Aushärtung einzelner positiver Merkmale (wie des Durchmessers eines zylindrischen Stifts) festlegen, doch die auf das Teil wirkenden Abzugskräfte wären zu stark und würden zu einem Fehldruck führen. Deshalb liegt der tatsächliche Mindestdurchmesser für solche Stifte bei etwa 500 Mikrometern.

For things that may be considered as two-dimensional objects (like text), front-back reversal cannot usually explain the observed reversal. An image is a two-dimensional representation of a three-dimensional space, and because it exists in a two-dimensional plane, an image can be viewed from front or back. In the same way that text on a piece of paper appears reversed if held up to a light and viewed from behind, text held facing a mirror will appear reversed, because the image of the text is still facing away from the observer. Another way to understand the reversals observed in images of objects that are effectively two-dimensional is that the inversion of left and right in a mirror is due to the way human beings perceive their surroundings. A person's reflection in a mirror appears to be a real person facing them, but for that person to really face themselves (i.e.: twins) one would have to physically turn and face the other, causing an actual swapping of right and left. A mirror causes an illusion of left-right reversal because left and right were not swapped when the image appears to have turned around to face the viewer. The viewer's egocentric navigation (left and right with respect to the observer's point of view; i.e.: "my left...") is unconsciously replaced with their allocentric navigation (left and right as it relates another's point of view; "...your right") when processing the virtual image of the apparent person behind the mirror. Likewise, text viewed in a mirror would have to be physically turned around, facing the observer and away from the surface, actually swapping left and right, to be read in the mirror.[42]

Transmissivity is determined by the percentage of light transmitted per the incident light. Transmissivity is usually the same from both first and second surfaces. The combined transmitted and reflected light, subtracted from the incident light, measures the amount absorbed by both the coating and substrate. For transmissive mirrors, such as one-way mirrors, beam splitters, or laser output couplers, the transmissivity of the mirror is an important consideration. The transmissivity of metallic coatings are often determined by their thickness. For precision beam-splitters or output couplers, the thickness of the coating must be kept at very high tolerances to transmit the proper amount of light. For dielectric mirrors, the thickness of the coat must always be kept to high tolerances, but it is often more the number of individual coats that determine the transmissivity. For the substrate, the material used must also have good transmissivity to the chosen wavelengths. Glass is a suitable substrate for most visible-light applications, but other substrates such as zinc selenide or synthetic sapphire may be used for infrared or ultraviolet wavelengths.[49]: p.104–108

The metal coating of glass mirrors is usually protected from abrasion and corrosion by a layer of paint applied over it. Mirrors for optical instruments often have the metal layer on the front face, so that the light does not have to cross the glass twice. In these mirrors, the metal may be protected by a thin transparent coating of a non-metallic (dielectric) material. The first metallic mirror to be enhanced with a dielectric coating of silicon dioxide was created by Hass in 1937. In 1939 at the Schott Glass company, Walter Geffcken invented the first dielectric mirrors to use multilayer coatings.[17]

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In common mirrors, the reflective layer is usually some metal like silver, tin, nickel, or chromium, deposited by a wet process; or aluminium,[27][35] deposited by sputtering or evaporation in vacuum. The reflective layer may also be made of one or more layers of transparent materials with suitable indices of refraction.

The coating of glass with a reflective layer of a metal is generally called "silvering", even though the metal may not be silver. Currently the main processes are electroplating, "wet" chemical deposition, and vacuum deposition.[17] Front-coated metal mirrors achieve reflectivities of 90–95% when new.

Other projection technologies involving mirrors include LCoS. Like a DLP chip, LCoS is a microchip of similar size, but rather than millions of individual mirrors, there is a single mirror that is actively shielded by a liquid crystal matrix with up to millions of pixels. The picture, formed as light, is either reflected toward the projection surface (pixel on), or absorbed by the activated LCD pixels (pixel off). LCoS-based televisions and projectors often use 3 chips, one for each primary color.

Objects viewed in a (plane) mirror will appear laterally inverted (e.g., if one raises one's right hand, the image's left hand will appear to go up in the mirror), but not vertically inverted (in the image a person's head still appears above their body).[43] However, a mirror does not actually "swap" left and right any more than it swaps top and bottom. A mirror swaps front and back. To be precise, it reverses the object in the direction perpendicular to the mirror surface (the normal), turning the three dimensional image inside out (the way a glove stripped off the hand can be turned inside out, turning a left-hand glove into a right-hand glove or vice versa). When a person raises their left hand, the actual left hand raises in the mirror, but gives the illusion of a right hand raising because the imaginary person in the mirror is literally inside-out, hand and all. If the person stands side-on to a mirror, the mirror really does reverse left and right hands, that is, objects that are physically closer to the mirror always appear closer in the virtual image, and objects farther from the surface always appear symmetrically farther away regardless of angle.