Glossary
Terms that are on use on this site.
You can always search for entries (regexp permitted).

Begins with Contains Exactly matches

All | A | B | C | D | E | F | G | H | I | L | M | N | O | P | R | S | T | U | V | W | Z


All
Pages: 1
Term Definition
Aberrationhe image formed by an ideal photographic lens would have the following characteristics: 1. A point would be formed as a point. 2. A plane (such as a wall) perpendicular to the optical axis would be formed as a plane. 3. The image formed by the lens would have the same shape as the subject. Also, from the standpoint of image expression, a lens should exhibit true color reproduction. If only light rays entering the lens close to the optical axis are used and the light is monochromatic (one specific wavelength), it is possible to realize virtually ideal lens performance. With real photographic lenses, however, where a large aperture is used to obtain sufficient brightness and the lens must converge light not only from near the optical axis but from all areas of the image, it is extremely difficult to satisfy the above-mentioned ideal conditions due to the existence of the following obstructive factors: * Since most lenses are constructed solely of lens elements with spherical surfaces, light rays from a single subject point are not formed in the image as a perfect point. (A problem unavoidable with spherical surfaces.) * The focal point position differs for different types (i.e., different wavelengths) of light. * There are many requirements related to changes in angle of view (especially with wide-angle, zoom and telephoto lenses). The general term used to describe the difference between an ideal image and the actual image affected by the above factors is \"aberration.\" Thus, to design a high-performance lens, aberration must be extremely small, with the ultimate objective being to obtain an image as close as possible to the ideal image. Aberration can be broadly divided into two classifications: chromatic aberrations, which occur due to differences in wavelength, and monochromatic aberrations, which occur even for a single wavelength.
 
AC adapterAnalogue-Digital Converter. Hardware that converts analogue information into digital data. (AD-Conversion)
 
Achromat, achromatic lensA lens which corrects chromatic aberration for two wavelengths of light. When referring to a photographic lens, the two corrected wavelengths are in the blue-violet range and yellow range.
 
AF DC-NIKKOR lensesAF DC-NIKKOR lenses feature exclusive Nikon Defocus-image Control technology. This allows photographers to control the degree of spherical aberration in the foreground or background by rotating the lens’ DC ring. This will create a rounded out-of-focus blur that is ideal for portrait photography. No other lenses in the world offer this special technique.
 
AF Stop featureAnother feature unique to Canon\'s four Image Stabilized super-telephoto lenses. Four buttons appear on the outer barrel near the front of these lenses; pushing any one will temporarily lock AF if the camera is in the AI Servo AF mode. Custom Functions on many newer EOS bodies allow these buttons to assume a variety of additional functions.
 
Air lensThe air spaces between the glass lens elements making up a photographic lens can be thought of as lenses made of glass having the same index of refraction as air (1.0). An air space designed from the beginning with this concept in mind is called an air lens. Since the refraction of an air lens is opposite that of a glass lens, a convex shape acts as a concave lens and a concave shape acts as a convex lens. This principle was first propounded in 1898 by a man named Emil von Hoegh working for the German company Goerz.
 
AnalogueOpposite of digital. Analogue data merges continuously into each other without clearly defined steps. (E.g. the colours of a rainbow are not obviously separable from one another.)
 
Angle of viewThe area of a scene, expressed as an angle, which can be reproduced by the lens as a sharp image. The nominal diagonal angle of view is defined as the angle formed by imaginary lines connecting the lens\' second principal point with both ends of the image diagonal (43.2mm). Lens data for EF lenses generally includes the horizontal (36mm) angle of view and vertical (24mm) angle of view in addition to the diagonal angle of view.
 
Angular apertureThe angle between the subject point on the optical axis and the diameter of the entrance pupil, or the angle between the image point on the optical axis and the diameter of the exit pupil.
 
Aperture / effective apertureThe aperture of a lens is related to the diameter of the group of light rays passing through lens and determines the brightness of the subject image formed on the focal plane. The optical aperture (also called the effective aperture) differs from the real aperture of the lens in that it depends on the diameter of the group of light rays passing through the lens rather than the actual lens diameter.
 
Aperture Priority AEWhen using this mode, the user selects the aperture giving control over the Depth of Field. A large aperture letting more light in gives a small depth of field, meaning not much will be in focus. Whereas a small aperture, not letting much light in, will give a greater depth of field or more will be in focus from the front to back of the image
 
Aperture ratioA value used to express image brightness, calculated by dividing the lens\' effective aperture (D) by its focal length (f). Since the value calculated from D/f is almost always a small decimal value less than 1 and therefore difficult to use practically, it is common to express the aperture ratio on the lens barrel as the ratio of the effective aperture to the focal length, with the effective aperture set equal to 1. (For example, the EF 85mm f/1.2L lens barrel is imprinted with 1:1.2, indicating that the focal length is 1.2 times the effective aperture when the effective aperture is equal to 1.) The brightness of an image produced by a lens is proportional to the square of the aperture ratio. In general, lens brightness is expressed as an F number, which is the inverse of the aperture ratio (f/D).
 
APODefinition for apochromatic corrected lenses (mostly made of fuorit-glas). Apochromatic corrected lenses have the property of breaking the beams of light so that the red, green and blue beams/waves exactly will meet on the same point and therefore will not be any chromatic abberation.
 
Apochromat, apochromatic lensA lens which corrects chromatic aberration for three wavelengths of light, with aberration reduced to a large degree particularly in the secondary spectrum. EF super-telephoto lenses are examples of apochromatic lenses.
 
APSAdvanced Photo System. Developed together by five companies, this film system is distinguished by simple operation, a new picture format (16 x 30 mm) as well as a choice of three picture formats. Additional information (such as exposure, aperture and date) can be recorded on the magnetic strip of the APS film. However, APS is not digital photography.
 
ArchiveA collection of data in long term storage, usually the hard drive on your PC or an external hard drive.
 
ASIC chipA chip designed for a specific application. They are used by cameras to quickly process the captured image data.
 
Aspect RatioThe ration of horizontal to vertical dimensions of an image. For example, 35mm slide film = 3:2, TV = 4:3, HDTV = 16:9, 4x5 Film = 5:4.
 
Aspherical lensPhotographic lenses are generally constructed of several single lens elements, all of which, unless otherwise specified, have spherical surfaces. Because all surfaces are spherical, it becomes especially difficult to correct spherical aberration in large-aperture lenses and distortion in super-wide-angle lenses. A special lens element with a surface curved with the ideal shape to correct these aberrations, i.e., a lens having a free-curved surface which is not spherical, is called an aspherical lens. The theory and usefulness of aspherical lenses have been known since the early days of lens making, but due to the extreme difficulty of actually processing and accurately measuring aspherical surfaces, practical aspherical lens manufacturing methods were not realized until fairly recently. The first SLR photographic lens to incorporate an aspherical lens was Canon\'s FD 55mm f/1.2AL released in March 1971. (Leica offered the 50mm f/1.2 Noctilux lens with aspherical surfaces for its rangefinder cameras many years before 1971.) Due to revolutionary advances in production technology since that time, Canon\'s current EF lens group makes abundant use of various aspherical lens types such as ground and polished glass aspherical lens elements, ultra-precision glass molded (GMo) aspherical lens elements, composite aspherical lens elements and replica aspherical lens elements.
 
Aspherical lens elementsNikon introduced the first photographic lens with aspherical lens elements in 1968. What sets them apart? Aspherical lenses virtually eliminate the problem of coma and other types of lens aberration — even when used at the widest aperture. They are particularly useful in correcting the distortion in wideangle lenses. In addition, use of aspherical lenses contributes to a lighter and smaller lens design. Nikon employs three types of aspherical lens elements. Precision-ground aspherical lens elements are the finest expression of lens-crafting art, demanding extremely rigorous production standards. Hybrid lenses are made of a special plastic molded onto optical glass. Molded glass aspherical lenses are manufactured by molding a unique type of optical glass using a special metal die technique.
 
Auto bracketingUsing this mode, a series of shots – each adjusted to a different exposure value – is taken in succession. This is very useful in tricky lighting conditions where it is difficult to assess the settings. After all shots have been taken, the best may be selected and the others deleted.
 
Auto flashOne of the flash modes. When the flash mode is set to [AUTO], the camera sets off the flash according to the ambient light conditions. When the flash goes off, the shutter speed will be fixed at a value that is less prone to camera movement blur.
 
Autofocus illuminatorSome cameras are equipped with an AF illuminator which assists the normal autofocus in poor lighting conditions by illuminating the subject. In this way, the regular passive AF system (e.g. contrast detecting / phase differential method) can determine the correct focus settings – even in dark surroundings.
 
Automatic ExposureThe camera sets the shutter speed and aperture for the correct exposure according to the light.
 
Automatic FocusThe lens on the camera focuses automatically when the shutter is half pressed. The viewfinder normally has focussing points shown to assist the user in knowing what will be in focus.
 
Automatic ProgramWithin a programm automat the diaphragm and the shutterspeed according to the lightconditions are automatically set. On most cameras indicated with the symbol \"P\".
 
AVIAudio Video Interleave. Standard file format from Microsoft (and therefore for Windows computers). It is used for saving video sequences with or without sound.
 
AWB Automatic White Balance. Most digital cameras have this feature where the camera sets the white balance. Override is available in most DSLR's.
 
B & WAbbreviation for Black and White
 
Back LitMeaning the subject is lit from behind which can cause underexposing. Is also used for portrait photography for special effects and bringing catchlights to the hair
 
BacklightLight coming from behind the subject. When light from behind is the main source of light, the subject is backlit.
 
BandingDepiction error often occurring in dark sections of an image when shooting with a high sensitivity setting. Smooth lines of brightness or colour look like bands of brightness or colour.
 
Barrel DistortionA common geometric lens distortion causing an aquired image to pucker towards the centre and be rounded along the outer edges
 
BatchIn computer technology this notion is used together with batch editing files. These are small programms which carries out series of orders automatically.With that it is possible to rename at the same time a large file with pictures, copy, delete and so on without doing every step to every single picture.
 
Battery packAlso called power pack. Rechargeable battery protected by casing. It provides camera, external flash, etc, with additional power.
 
BinaryThis is the name given to the representation system of numbers consisting solely of the figures 0 and 1. Just like the ten figure decimal system (0-9), in the binary system, larger numbers are made up by combining the numbers 0 and 1.
 
BitBinary digit. The smallest digital unit that can show only two states, 0 or 1. 8 bits produce one byte.
 
Bit DepthRefers to the colour or grey scale of each individual pixel. For example a pixel with 8 bits per colour (red, green and blue), gives a 24 bit image. 24 bit resolution is 16.7 million colours.
 
BitmapA representational form for a digital image in which each bit in the computers memory corresponds to one dot on the screen or printer.
 
Blackboard/ WhiteboardThese two picture effects record images using only pure black and white to heighten the image’s contrast value. This makes them ideal for capturing text.
 
BloomingThe opposite of noise; an image error that has been more or less eradicated in the newer digital cameras. It describes the “overflow” of electrical charges between the individual sensors on a CCD element.
 
BlueboxA process from television and movie production. Actors stand in front of a coloured wall, usually painted blue. Later, a different background is put in for the blue areas on the recorded image, giving the impression that the actors are e.g. on top of a mountain, although they never left the studio.
 
BluetoothStandard introduced by Ericsson, Intel, IBM, Nokia and Toshiba for wireless, radio-wave communication between different devices. Unlike the infrared data transfer method, which is also wireless, Bluetooth does not even require visual contact between the communications devices. It operates on a frequency of 2.4 GHz and offers a regular transfer rate of 1 Mbit/s. Its normal range is 10 metres.
 
BlurThere are many reasons why a subject may appear blurred in a picture. Blur may occur if the subject is moving too fast (subject blur), or if the camera is not stable or moves while the shutter button is pressed (camera blur). Camera blur and camera movement may occur more frequently even at the same shutter speed when using the zoom or a lens with a long focal length.
 
BMPBitmapped graphics file format which is popular with Windows PC's. It is an uncompressed file format like a TIFF
 
BorderlessQuite simply, this means a printed photograph with no border around it.
 
Bridge-KameraA bridge camera makes a bridge between a compact camera and a single reflex camera (SLR). It has a single reflex viewer but no exchangeble objectives.
 
BrightnessValue of a pixel in a digital image giving its value of lightness from black to white, with o being black and 255 being white
 
Buffer (Buffer memory)A form of temporary memory (RAM) where images are saved briefly before being written to the storage media. This type of memory is necessary because memory cards are comparably slower due to their architecture and cannot save the files at the speed the camera produces them. Buffer memory is particularly helpful when shooting sequence photos.
 
Bulb modeLong exposure mode. In bulb mode, the shutter stays open as long as the release is held down. This allows exposure times of several minutes or even hours. However, in some models the bulb mode is limited to a number of minutes regardless of how long the release is held.
 
Burst modeAnother term for sequence mode or continuous shooting.
 
BusInternal interface for data transfer between individual system components such as microprocessor, memory, etc.
 
ByteBinary data packet made up of 8 bits. A byte can represent values between 0 and 255. It can depict 256 symbols, numbers or colours. In the computer field, larger byte size is described using the prefix letter for the abbreviation of the exponent of 2. Therefore: 1 Kilobyte = 1 KB = 1,024 bytes 1 Megabyte = 1 MB = 1,048,576 bytes 1 Gigabyte = 1 GB = 1,073,741,824 bytes 1 Tera-byte = 1 TB = 1,099,511,627,776 bytes.
 
CalibrationThe act of adjusting the colour of one device to match that of another. For example when you match the calibration of your screen to that of your printer to ensure what you see is what you print. It is also used in the film SLR's Canon EOS-3 and EOS 5 which have eye-controlled focussing. You calibrate the cameras focussing to where your eye is looking in the viewfinder. (Some fighter planes also have this. The missile follows the trajectory of the pilot's eye).
 
Camera shakeA major cause of unclear pictures, this unwanted movement is caused by involuntary hand and body tremors jarring the camera.
 
Card ReaderUsed for transferring data from your flash memory card to your PC. A better way of transferring your image files than connecting the camera to your PC. Sometimes the cameras circuitry can become corrupt. Better to fry a memory card than your camera
 
CCD(Charged Coupled Device). This is a light sensitive chip used in your digital camera for image gathering. The CCD Pixels gather the colour from the light and pass it to the shift register for storage. CCD's are analogue sensors, the digitising occurs when the electrons are passed through the A to D converter. This "Analogue to Digital" converter converts the analogue signal to a digital file or signal
 
Chromatic aberrationWhen white light (light containing many colors uniformly mixed so that the eye does not sense any particular color and thus perceives the light as white) such as sunlight is passed through a prism, a rainbow spectrum can be observed. This phenomenon occurs because the prism\'s index of refraction (and rate of dispersion) varies depending on the wavelength (short wavelengths are more strongly refracted than long wavelengths). While most visible in a prism, this phenomenon also occurs in photographic lenses, and since it occurs at different wavelengths is called chromatic aberration. There are two types of chromatic aberration: \"axial chromatic aberration,\" where the focal point position on the optical axis varies according to the wavelength, and \"chromatic difference of magnification,\" where the image magnification in peripheral areas varies according to the wavelength. In actual photographs, axial chromatic aberration appears as color blur or flare, and chromatic difference of magnification appears as color fringing (where edges show color along their borders). Chromatic aberration in a photographic lens is corrected by combining different types of optical glass having different refraction and dispersion characteristics. Since the effect of chromatic aberration increases at longer focal lengths, precise chromatic aberration correction is particularly important in super-telephoto lenses for good image sharpness. Although there is a limit to the degree of correction possible with optical glass, significant performance improvements can be achieved using man-made crystal such as fluorite or UD glass. Axial chromatic aberration is also sometimes referred to as \"longitudinal chromatic aberration\" (since it occurs longitudinally with respect to the optical axis), and chromatic difference of magnification can be referred to as \"lateral chromatic aberration\" (since it occurs laterally with respect to the optical axis). Note: While chromatic aberration is most noticeable when using color film, it affects black-and-white images as well, appearing as a reduction in sharpness.
 
Circle of confusionSince all lenses contain a certain amount of spherical aberration and astigmatism, they cannot perfectly converge rays from a subject point to form a true image point (i.e., an infinitely small dot with zero area). In other words, images are formed from a composite of dots (not points) having a certain area, or size. Since the image becomes less sharp as the size of these dots increases, the dots are called \"circles of confusion.\" Thus, one way of indicating the quality of a lens is by the smallest dot it can form, or its \"minimum circle of confusion.\" The maximum allowable dot size in an image is called the \"permissible circle of confusion.\"
 
Circular apertureCertain Canon lenses feature a new Circular Aperture diaphragm unit, which uses curved aperture blades to provide for a more rounded opening as the lens is stopped down. It\'s especially effective at rendering out of focus background highlights as natural rounded shapes. In lenses such as the EF 70-200mm f/2.8L IS lens, the lens opening is virtually circular from f/2.8 to f/5.6. These lenses retain all the benefits previously available with Canon\'s Electromagnetic Diaphragm  smooth and consistent stop-down operation (even at up to 10fps with the EOS-1v), near-silent aperture control, and total absence of mechanical levers or switches in the lens mount.
 
Circular polarizing filterA circular polarizing filter is functionally the same as a linear polarizing filter as it only passes light vibrating in a certain direction. However, the light passing through a circular polarizing filter differs from light passing through a linear polarizing filter in that the vibrational locus rotates in a spiral pattern as it propagates. Thus, the effect of the filter does not interfere with the effect of half-mirrors: allowing normal operation of TTL-AE and AF functions. When using a polarizing filter with an EOS camera, be sure to always use a circular polarizing filter. The effectiveness of a circular polarizing filter in eliminating reflected light is the same as that of a linear polarizing filter.
 
Close-Range Correction systemThe Close-Range Correction (CRC) system is one of Nikon’s most important focusing innovations, for it provides superior picture quality at close focusing distances and increases the focusing range. With CRC, the lens elements are configured in a “floating element” design wherein each lens group moves independently to achieve focusing. This ensures superior lens performance even when shooting at close distances. The CRC system is used in fisheye, wideangle, Micro, and selected medium telephoto NIKKOR lenses.
 
CoatingWhen light enters and exits a lens, approximately 5% of the light is reflected back at each lens-air boundary due to the difference in index of refraction. This not only reduces the amount of light passing through the lens but can also lead to repeating reflections which can cause unwanted flare or ghost images. To prevent this reflection, lenses are processed with a special coating. Basically this is carried out using vacuum vapor deposition to coat the lens with a thin film having a thickness l/4 the wavelength of the light to be affected, with the film made of a substance (such as magnesium fluoride) which has an index of refraction of n, where n is the index of refraction of the lens glass. Instead of a single coating affecting only a single wavelength, however, EF lenses feature a superior multi layer coating (multiple layers of vapor deposited film reducing the reflection rate to 0.2-0.3%) which effectively prevents reflections of all wavelengths in the visible light range. Lens coating is carried out not only to prevent reflections, however. By coating the various lens elements with appropriate substances having different properties, coating plays an important role in providing the overall lens system with optimum color balance characteristics.
 
Color balanceThe color reproduction fidelity of a photo taken through a lens compared to the original subject. Color balance in all EF lenses is based on ISO recommended reference values and maintained within a strict tolerance range that is tighter than ISO\'s CCI allowable value range.
 
Coma, comatic aberrationComa, or comatic aberration, is a phenomenon visible in the periphery of an image produced by a lens which has been corrected for spherical aberration, and causes light rays entering the edge of the lens at an angle to converge in the form of a comet instead of the desired point, hence the name. The comet shape is oriented radially with the tail pointing either toward or away from the center of the image. The resulting blur near the edges of the image is called comatic flare. Coma, which can occur even in lenses which correctly reproduce a point as a point on the optical axis, is caused by a difference in refraction between light rays from an off-axis point passing through the edge of the lens and the principal light ray from the same point passing through the lens center. Coma increases as the angle of the principal ray increases, and causes a decrease in contrast near the edges of the image. A certain degree of improvement is possible by stopping down the lens. Coma can also cause blurred areas of an image to flare, resulting in an unpleasing effect. The elimination of both spherical aberration and coma for a subject at a certain shooting distance is called aplanatism, and a lens corrected as such is called an aplanat.
 
ContrastThe degree of distinction between areas of different brightness levels in a photograph, i.e., the difference in brightness between light and dark areas. For example, when the reproduction ratio between white and black is clear, contrast is said to be high, and when unclear, contrast is said to be low. In general, quality lenses producing high quality images have both high resolution and high contrast.
 
Cos4 lawStates that light fall-off in peripheral areas of the image increases as the angle of view increases, even if the lens is completely free of vignetting. The peripheral image is formed by groups of light rays entering the lens at a certain angle with respect to the optical axis, and the amount of light fall-off is proportional to the cosine of that angle raised to the fourth power. As this is a law of physics, it cannot be avoided. However, with wide-angle lenses having a large angle of view, decreases in peripheral illumination can be prevented by increasing the lens\' aperture efficiency (ratio of the area of the on-axis entrance pupil to the area of the off-axis entrance pupil).
 
Curvature of fieldCurvature of field is a phenomenon which causes the image formation plane to become curved like the inside of a shallow bowl, preventing the lens from producing a flat image of a flat subject. When the center of the image is in focus, the periphery is out of focus, and when the periphery is in focus, the center is out of focus. The degree of curvature of field is largely affected by the method used for correcting astigmatism. Since the image plane falls between the sagittal and meridional image surfaces, good correction of astigmatism results in small curvature of field. Since curvature of field cannot be improved very much by stopping down the lens, lens designers reduce it as much as possible using various methods such as changing the shapes of the various single lens elements making up the lens and changing the position of the aperture. In doing this, one necessary condition that must be satisfied to simultaneously correct astigmatism and curvature of field is Petzval\'s Condition (1843). Petzval\'s Condition states that a lens element is good if a result of zero is obtained when the inverse of the product of the index of refraction and focal length of that lens element is added to the total number of lens elements making up the lens. This sum is called Petzval\'s Sum.
 
Depth of fieldThe area in front of and behind a focused subject in which the photographed image appears sharp. In other words, the depth of sharpness to the front of sharpness to the front and rear of the subject where image blur in the film plane falls within the limits of the permissible circle of confusion. Depth of field varies according to the lens\' focal length, aperture value and shooting distance, so if these values are known, a rough estimate of the depth of field can be calculated using the following formulas: Front depth of field = d x F x a2 / (f2 + d x F x a) Rear depth of field = d x F x a2 / (f2 - d x F x a) f: focal length F: F number d: minimum circle of confusion diameter a: subject distance (distance from 1st principal point to subject) If the hyperfocal distance is known, the following formulas can also be used: Near Point limiting = Hyperfocal distance X shooting distance Hyperfocal distance + shooting distance Far Point limiting = Hyperfocal distance X shooting distance Hyperfocal distance – shooting distance (Shooting distance: Distance from film plane to subject) In general photography, depth of field is characterized by the following attributes: 1. Depth of field is deep at short focal lengths, shallow at long focal lengths. 2. Depth of field is deep at small apertures, shallow at large apertures. 3. Depth of field is deep at far shooting distances, shallow at close shooting distances. 4. Front depth of field is shallower than rear depth of field.
 
Depth of focusThe area in front of and behind the focal plane in which the image can be photographed as a sharp image. Depth of focus is the same on both sides of the image plane (film plane) and can be determined by multiplying the minimum circle of confusion by the F number, regardless of the lens focal length. With modern autofocus SLR cameras, focusing is performed by detecting the state of focus in the image plane (film plane) using a sensor which is both optically equivalent (1:1 magnification) and positioned out of the film plane, and automatically controlling the lens to bring the subject image within the depth of focus area
 
DiffractionA phenomenon in which light waves enter the shadow area of an object. With a photographic lens, exposure is often adjusted by varying the size of the lens\' diaphragm (aperture) to adjust the amount of light passing through the lens. Diffraction in a photographic lens occurs at small apertures where the diaphragm edges obstruct the straight-line path of advancing light waves, causing light rays passing near the edge of the diaphragm to bend around the edges as they pass through the diaphragm.
 
Diffractive OpticsDiffractive Optics, a revolutionary new lens optical technology that permits super-telephoto lenses that are significantly shorter and lighter than previously possible, while simultaneously improving optical performance by reducing chromatic aberrations and even spherical aberrations.
 
DiopterThe degree to which the light ray bundles leaving the viewfinder converge or disperse. The standard diopter of all EOS cameras is set at - 1 dpt. This setting is designed to allow the finder image to appear to be seen from a distance of 1m. Thus, if a person cannot see the viewfinder image clearly, the person should attach to the camera\'s eyepiece a dioptric adjustment lens having a power which, when added to the viewfinder\'s standard diopter, makes it possible to easily see an object at one meter. The numerical values printed on EOS dioptric adjustment lenses indicate the total diopter obtained when the dioptric adjustment lens is attached to the camera.
 
DispersionA phenomenon whereby the optical properties of a medium vary according to the wavelength of light passing through the medium. When light enters a lens or prism, the dispersion characteristics of the lens or prism cause the index of refraction to vary depending on the wavelength thus dispersing the light. This is also sometimes referred to as color dispersion.
 
Distance informationD-type and G-type NIKKOR lenses relay subject-to-camera distance information to AF Nikon camera bodies. This then makes possible advances like 3D Matrix Metering and 3D Multi-Sensor Balanced Fill-Flash. Note: D-type and G-type NIKKOR lenses provide distance information to the following cameras: Auto exposure; F6, F5, F100, F90X, F80, F75, F70, F65, F60, F55, F50, PRONEA S, PRONEA 600i, D2 series, D1 series, D100 and D70s/D70. Flash control; F6, F5, F100, F90X, F80, F75, F70, D2 series, D1 series, D100 and D70s/D70.
 
Distance of incidenceDistance from the optical axis of a parallel ray entering a lens.
 
DXCompact and lightweight DX NIKKOR lenses featuring a smaller image circle are specially designed and optimized for Nikon D2-series, D1-series, D100 and D70s/D70 digital SLR cameras. These are ideal options for landscape photographers and others who need to shoot expansive scenes with Nikon DX-Format digital SLRs. Note: We do not recommend use of DX NIKKOR with 35mm (135) or IX240 format cameras.
 
ED glassNikon developed ED (Extra-low Dispersion) glass to enable the production of lenses that offer superior sharpness and color correction by minimizing chromatic aberration. Put simply, chromatic aberration is a type of image and color dispersion that occurs when light rays of varying wavelengths pass through optical glass. In the past, correcting this problem for telephoto lenses required special optical elements that offer anomalous dispersion characteristics — specifically calcium fluoride crystals. However, fluorite easily cracks and is sensitive to temperature changes that can adversely affect focusing by altering the lens’ refractive index. So Nikon designers and engineers put their heads together and came up with ED glass, which offers all the benefits, yet none of the drawbacks of calcium fluorite-based glass. With this innovation, Nikon developed several types of ED glass suitable for various lenses. They deliver stunning sharpness and contrast even at their largest apertures. In this way, NIKKOR’s ED-series lenses exemplify Nikon’s preeminence in lens innovation and performance.
 
EMD (Electromagnetic Diaphragm)Designed for use with the digital data transfer of the EOS system made possible by the fully electronic mount, every EF lens incorporates an EMD that electronically controls aperture diameter. The EMD is a diaphragm drive control actuator comprised of a deformation stepping motor and diaphragm blade unit. Features include the following. Because the system is digitally controlled, its level of precision is far higher than that of mechanical linkage systems. The small rotor blades help deliver excellent start/stop response and control. Elimination of linkage shock from mechanical levers makes the system extremely quiet. The fully electronic mount system makes it possible to close down the aperture and confirm the setting and depth of field at the touch of a button. The EMD mechanism delivers superior durability and reliability. Its diaphragm control components are integrated into a single compact unit. And, the electronic control system allows a high degree of freedom in designing unit layout.
 
Extension amountWith a lens that moves the entire optical system backward and forward when focusing, the amount of lens movement necessary to focus a subject at a limited distance from the infinity focus position.
 
Extraordinary partial dispersionThe human eye can sense monochromatic light wavelengths within the range of 400nm (purple) to 700nm (red). Within this range, the difference in index of refraction between two different wavelengths is called partial dispersion. Most ordinary optical materials have similar partial dispersion characteristics. However, partial dispersion characteristics differ for some glass materials, such as glass that exhibits larger partial dispersion at short wavelengths, FK glass which features a small index of refraction and low dispersion characteristics, fluorite, and glass that exhibits larger partial dispersion at long wavelengths. These types of glass are classified as having extraordinary partial dispersion characteristics. Glass with this property is used in apochromatic lenses to compensate chromatic aberration.
 
Eyesight, visual acuityThe ability of the eye to distinguish details of an object\'s shape. Expressed as a numerical value which indicates the inverse of the minimum visual angle at which the eye can clearly distinguish two points or lines, i.e. the resolution of the eye in reference to a resolution of 1\'. (Ratio with a resolution of 1\' assumed as 1.)
 
Far-sightednessThe eye condition in which the image of an infinitely distant point is formed to the retina when the eye is in the accommodation rest state.
 
Five aberrations of SeidelIn 1856, a German named Seidel determined through analysis the existence of five lens aberations which occur with monochromatic (single wavelength) light. These are called the five aberrations of Seidel.
 
Flange backDistance from the camera\'s lens mount reference surface to the focal plane (film plane). In the EOS system, flange back is set at 44.00 mm on all cameras. Flange back is also referred to as flange-focal distance.
 
Floating systemGeneral photographic lenses are designed to achieve an optimum balance of aberration compensation at only one commonly-used shooting distance. Thus, although aberrations are well compensated at the reference shooting distance, aberrations increase at other shooting distances (especially at close shooting distances) and cause image degradation. To prevent this from happening, a floating system is used which varies the interval between certain lens elements in accordance with the extension amount. This method is also referred to as a close-distance aberration compensation mechanism.
 
FluoriteFluorite has extremely low indexes of refraction and dispersion compared to optical glass and features special partial dispersion characteristics (extraordinary partial dispersion), enabling virtually ideal correction of chromatic aberrations when combined with optical glass. This fact has long been known, and in 1880 natural fluorite was already in practical use in the apochromatic objective lenses of microscopes. However, since natural fluorite exists only in small pieces, it cannot be used practically in photographic lenses. In answer to this problem, Canon in 1968 succeeded in establishing production technology for manufacturing large artificial crystals. Thus opening the door for fluorite use in photographic lenses.
 
Focal lengthWhen parallel light rays enter the lens parallel to the optical axis, the distance along the optical axis from the lens\' second principal point (rear principal point) to the focal point is called the focal length. In simpler terms, the focal length of a lens is the distance along the optical axis from the lens\' second principal point to the film plane when the lens is focused at infinity.
 
Focal point, focusWhen light rays enter a convex lens parallel to the optical axis, an ideal lens will converge all the light rays to a single point from which the rays again fan out in a cone shape. This point at which all rays converge is called the focal point. A familiar example of this is when a magnifying glass is used to focus the rays of the sun to a small circle on a piece of paper or other surface; the point at which the circle is smallest is the focal point. In optical terminology, a focal point is further classified as being the rear or image-side focal point if it is the point at which light rays from the subject converge on the film plane side of the lens. It is the front or object-side focal point if it is the point at which light rays entering the lens parallel to the optical axis from the film plane side converge on the object side of the lens.
 
Focus PresetA feature on the Image Stabilized super-telephoto EF lenses. The photographer can focus upon a subject and memorize that focus setting, and later return instantly to it with a brief turn of the metal \"playback\" ring on the lens\' barrel.
 
Fraunhofer\'s linesAbsorption lines discovered in 1814 by a German physicist named Fraunhofer (1787-1826), comprising the absorption spectrum present in the continuous spectrum of light emitted from the sun created by the effect of gases in the sun\'s and earth\'s atmospheres. Since each line is located at a fixed wavelength, the lines are used for reference in regard to the color (wavelength) characteristics of optical glass. The index of refraction of optical glass is measured based on nine wavelengths selected from among Fraunhofer\'s lines. In lens design, calculations for correcting chromatic aberrations are also based on these wavelengths.
 
Fresnel lensA type of converging lens, formed by finely dividing the convex surface of a flat convex lens into many concentric circle-shaped ring lenses and combining them to extremely reduce the thickness of the lens while retaining its function as convex lens. In an SLR, to efficiently direct peripheral diffused light to the eyepiece, the side opposite the matte surface of the focusing screen is formed as a fresnel lens with a 0.05mm pitch. Fresnel lenses are also commonly used in flash units, indicated by the concentric circular lines visible on the white diffusion screen covering the flash tube. The projection lens used to project light from a lighthouse is an example of a giant fresnel lens.
 
Front group linear extensionThe rear group remains fixed and only the front group moves straight backward and forward during focusing. Examples of front group linear extension lenses include the EF 50mm f/2.5 Compact Macro and the EF 85mm f/1.2L USM.
 
Front group rotational extensionThe lens barrel section holding the front lens group rotates to move the front group backward and forward during focusing. This type of focusing is used only in zoom lenses and is not found in single focal length lenses. Representative examples of lenses using this method are the EF 35-80mm f/4-5.6 USM and EF 100-300mm f/5.6L. Since the filter attachment ring and hood rotate with the lens during focusing, care must be taken when shooting through a glass window to make sure the end of the lens does not contact the glass.
 
Full-time manual focusingA system that allows the photographer to turn the lens\' manual focusing ring and instantly override autofocus – while the lens\' AF/MF switch is still in the autofocus mode. More than half of Canon\'s EF lenses with Ultrasonic Motors have this feature.
 
Fully electronic mount systemDevelopment of the EOS system began with Canon\'s own \"body range-finding and in-lens motor drive system\" and \"fully electronic mount system\", technologies that were developed in 1985 to quickly respond to the trend towards full-fledged autofocusing SLR cameras. The EOS system centers on the camera body and consists of various components including Canon\'s full line of EF lenses, Speedlite flash units, and interchangeable backs. The three main features of the EOS system are as follows. 1. Multi-processor system control A high-speed processor in the camera body interfaces with processors in the lens and the flash units, (for high-speed data processing, calculation and communications), to carry out high level systems control. 2. Multi-actuator system The ideal actuator for each drive unit is located near the drive unit to form a multi-actuator system that realizes high-level automation, high efficiency, and high performance. 3. Fully electronic interface All data transfer between the camera body, lens, flash and interchangeable back is handled electronically. This not only increases the functionality of the current system, but also creates a network ready to accept future system developments.
 
G-type NIKKORThe G-type NIKKOR has no aperture ring; aperture should be selected from camera body.
 
Ghost imageA type of flare occurring when the sun or other strong light source is included in the scene and a complex series of reflections among the lens surfaces causes a clearly defined reflection to appear in the image in a position symmetrically opposite the light source. This phenomenon is differentiated from flare by the term \"ghosting\" due to its ghost-like appearance. Ghost images caused by surface reflections in front of the aperture have the same shape as the aperture a ghost image caused by reflections behind the aperture appears as an out-of-focus area of light fogging. Since ghost images can also be caused by strong light sources outside the picture area, use of a hood or other shading device is recommended for blocking undesired light. Whether or not ghosting will actually occur when the picture is taken can be verified beforehand by looking through the viewfinder and using the camera\'s depth-of-field check function to close down the lens to the actual aperture to be used during exposure.
 
Hyperfocal distanceUsing the depth of field principle, as a lens is gradually focused to farther subject distances, a point will eventually be reached where the far limit of the rear depth of field will be equivalent to \"infinity.\" The shooting distance at this point, i.e., the closest shooting distance at which \"infinity\" falls within the depth of field, is called the hyperfocal distance. The hyperfocal distance can be determined as follows: Hyperfocal distance = f2 / (d • F) f: focal length F: F number d: minimum circle of confusion diameter Thus, by presetting the lens to the hyperfocal distance, the depth of field will extend from a distance equal to half the hyperfocal distance to infinity. This method is useful for presetting a large depth of field and taking snapshots without having to worry about adjusting the lens focus, especially when using a wide-angle lens. (For example, when the EF 24mm is set to f/11and the shooting distance is set to the hyperfocal distance of approximately 1.5m/4.9ft, all subjects within a range of approximately 70cm/2.3ft from the camera to infinity will be in focus.)
 
Image circleThe diameter of the sharp image circle formed by a lens. Interchangeable lenses for 35mm format cameras must have an image circle at least as large as the diagonal of the 24 x 36mm image area, and EF lenses generally have an image circle of about 43.2mm. TS-E lenses, however, are designed with a larger image circle of 58.6mm to cover the lens\' tilt and shift movements.
 
Image distanceThe distance from the lens\' rear principal point to the film plane when the lens is focused on a subject at a certain distance.
 
Image magnificationThe ratio (length ratio) between the actual subject size and the size of the image reproduced on film. A macro lens with a magnification indication of 1:1 can reproduce an image on film the same size as the original subject (actual size). Magnification is generally expressed as a proportional value indicating the size of the image compared to the actual subject. (For example, a magnification of 1:4 is expressed as 0.25x.)
 
Image StabilizerA superb new technology that allows the lens to sense movement from \"shake\" or vibrations, and instantly apply an optical correction by moving a group of lens elements. The improvement in steadiness can be seen even in the viewfinder, and most users find they can shoot hand-held or on a monopod at shutter speeds about two stops slower than previously possible and consistently get sharp images.
 
Index of refractionA numerical value indicating the degree of refraction of a medium, expressed by the formula n=sin i/sin r is a constant which is unrelated to the light ray\'s angle of incidence and indicates the refractive index of the refracting medium with respect to the medium from which the light impinges. For general optical glass, \"n\" usually indicates the index of refraction of the glass with respect to air.
 
Inner focusingFocusing is performed by moving one or more lens groups positioned between the front lens group and the diaphragm.
 
Internal FocusingImagine being able to focus a lens without it changing in size. Nikon’s IF technology enables just that. All internal optical movement is limited to the interior of the nonextending lens barrel. This allows for a more compact, lightweight construction as well as a closer focusing distance. In addition, a smaller and lighter focusing lens group is employed to ensure faster focusing. The IF system is featured in most NIKKOR telephoto and selected NIKKOR zoom lenses.
 
Linear polarizing filterA filter which only passes light vibrating in a certain direction. Since the vibrational locus of the light allowed to pass through the filter is linear in nature, the filter is called a linear polarizing filter. This type of filter eliminates reflections from glass and water the same way as a circular polarizing filter, but it cannot be used effectively with most auto exposure and autofocus cameras as it will cause exposure errors in AE cameras equipped with TTL metering systems using half-mirrors, and will cause focusing errors in AF cameras incorporating AF rangefinding systems using half-mirrors.
 
M/A modeAF-S NIKKOR lenses feature Nikon’s exclusive M/A mode, that allows switching from autofocus to manual operation with virtually no time lag — even during AF servo operation and regardless of AF mode in use.
 
Macro lensesMacro lenses are essential for shooting close-ups of flowers, insects and other small items at life-size magnification or larger. Quality optical characteristics, sharp definition and true color fidelity combine to capture the appeal of your subject with bold realism.
 
Mechanical distanceThe distance from the front edge of the lens barrel to the film plane.
 
Micro USMThe micro USM is an advanced motor developed as a \"multi-purpose miniature ultrasonic motor\", and its features are as follows. Advantages over ring-type USMs The micro USM carries no lens diameter restrictions, so it can be incorporated into a wide variety of lens designs. The stator, rotor and output gear are integrated into a single compact unit that is roughly half the size and weight of a ring-type USM. And the cost is only about 1/3 that of the already reasonably priced ring-type USM. Advantages over DC micro motors Low-speed, high-torque characteristics make it possible to set the AF drive gear ratio low enough to realize quiet drive operation, (roughly 1/4 the level of a DC micro motor). The micro USM also features excellent start/stop response and control, and the large holding torque provides superior focus positioning precision.
 
MTF chart: How to readMTF charts (short for Modulation Transfer Function) provide a graph analyzing a lens\' ability to resolve sharp details in very fine sets of parallel lines, and a lens\' contrast or ability to provide a sharp transfer between light and dark areas in sets of thicker parallel lines. Fine repeating line sets are created parallel to a diagonal line running from corner to corner of the 35mm frame, directly through the exact center of the image area. These are called sagittal lines, sometimes designated \"S\" on Canon\'s MTF charts. At a 90° angle to these, additional sets of repeating lines are drawn, called Meridional (or \"M\") line sets. Repeating extremely fine short parallel lines spaced at 30 lines per millimeter measure the lens\' ability to record fine details, or its resolution. Even more important in the eyes of many optical designers is the lens\' contrast capability, which is measured with thicker sets of parallel repeating lines drawn at 10 lines per millimeter. At first glance, it would appear that any good lens would record lines running parallel to a diagonal drawn across the film with the same accuracy as lines drawn perpendicular to them. However, in real-world testing, this is often not the case. Especially in the Meridional direction, faithful reproduction of fine line sets becomes increasingly difficult as you move away from the center of the image toward one of the corners. And it\'s a fact that almost all lenses produce sharper results in general near the center of the frame than at the outer edges. MTF charts display the lens\' performance from center to corner. Running along the chart\'s horizontal axis, labeled 0 to over 20, is the distance from the dead center (\"0\") of a 35mm image along a diagonal line to the corner of the frame, which is about 21.5mm away. On the chart\'s vertical axis is a scale representing the degree of accuracy with which the fine and coarse line sets are reproduced, in both the sagittal (parallel to the diagonal of the film format) and meridonal directions. Solid lines on the MTF charts indicate the performance of sagittal lines (parallel to the diagonal of the film), dashed lines are for the perpendicular meridional test target lines. In theory, a perfect lens would produce nothing but straight horizontal lines across the very top of an MTF chart, indicating 100% accurate reproduction from the center of the picture (toward the left of the chart) to its outermost corners (at the right side of the chart). Of course, no such thing as a perfect lens exists from any SLR manufacturer, so MTF charts typically show lines that tend to curve downward as they move left to right (tracking the lens\' performance from center to corner of the frame). Canon\'s MTF charts give results at two apertures: wide-open, and stopped down to f/8, with the lens set to infinity focus. While MTF charts don\'t include many factors that can be important when selecting a lens (size, cost, handling, closest focusing distances, AF speed, linear distortion, evenness of illumination, and of course features like Image Stabilization which may produce superior real-world results), they can indicate to the knowledgeable reviewer some of the optical characteristics they can expect from a particular lens.
 
Nano Crystal CoatNano Crystal Coat is an antireflective coating that originated in the development of NSR-series (Nikon Step and Repeat) semiconductor manufacturing devices. It virtually eliminates internal lens element reflections across a wide range of wavelengths, and is particularly effective in reducing ghost and flare peculiar to ultra-wideangle lenses. Nano Crystal Coat employs multiple layers of Nikon’s outstanding extra-low refractive index coating, which features ultra-fine crystallized particles of nano size (one nanometer equals one millionth of a mm). Nikon now proudly marks a world first by applying this coating technology to a wide range of lenses for use in consumer optical products.
 
Near-sightednessThe eye condition in which the image of an infinitely distant point is formed in front of the retina when the eye is in the accommodation rest state.
 
Normal vision, emmetropiaThe eye condition in which the image of an infinitely distant point is formed on the retina when the eye is in the accommodation rest state.
 
Numerical aperture (NA)A value used to express the brightness or resolution of a lens\' optical system. The numerical aperture, usually indicated as NA, is a numerical value calculated from the formula nsin¸, where 2¸ is the angle (angular aperture) at which an object point on the optical axis enters the entrance pupil and n is the index of reflection of the medium in which the object exists. Although not often used with photographic lenses, the NA value is commonly imprinted on the objective lenses of microscopes, where it is used more as an indication of resolution than of brightness. A useful relationship to know is that the NA value is equal to half the inverse of the F number. For example, F 1.0 = NA 0.5, F 1.4 = NA 0.357, F2 = NA 0.25, and so on.
 
Optical axisA straight line connecting the center points of the spherical surfaces on each side of a lens. In other words, the optical axis is a hypothetical center line connecting the center of curvature of each lens surface. In photographic lenses comprised of several lens elements, it is of utmost importance for the optical axis of each lens element to be perfectly aligned with the optical axes of all other lens elements. Particularly in zoom lenses, which are constructed of several lens groups that move in a complex manner, extremely precise construction is necessary to maintain proper optical axis alignment.
 
Overall linear extensionThe entire lens optical system moves straight backward and forward when focusing is carried out. Representative examples of lenses using this type of focusing include the EF 50mm f/1.8 II and TS-E 90mm f/2.8.
 
Parallel pencil of raysA group of light rays traveling parallel to the optical axis from an infinitely far point. When these rays pass through a lens, they converge in the shape of a cone to form a point image within the film plane.
 
Paraxial rayA light ray which passes close to the optical axis and is inclined at a very small angle with respect to the optical axis. The point at which paraxial rays converge is called the paraxial focal point. Since the image formed by a monochromatic paraxial ray is in principle free of aberrations, the paraxial ray is an important factor in understanding the basic operation of lens systems.
 
Peripheral illuminationThe brightness of a lens is determined by the F number, but this value only indicates the brightness at the optical axis position, i.e., at the center of the image. The brightness (image surface illuminance) at the edge of the image is called peripheral illumination and is expressed as a percent (%) of the amount of illumination at the image center. Peripheral illumination is affected by lens vignetting and the cos4 (cosine 4) law and is inevitably lower than the center of the image.
 
Polarized lightSince light is a type of electromagnetic wave, it can be thought of as uniformly vibrating in all directions in a plane perpendicular to the direction of propagation. This type of light is called natural light (or natural polarized light). If the direction of vibration of natural light becomes polarized for some reason, that light is called polarized light. When natural light is reflected from the surface of glass or water, for example, the reflected light vibrates in one direction only and is completely polarized. Also, on a sunny day the light from the area of the sky at a 90° angle from the sun becomes polarized due to the effect of air molecules and particles in the atmosphere. The half-mirrors used in autofocus SLR cameras also cause light polarization.
 
Principal point (Nodal point)The focal length of a thin, double-convex, single-element lens is the distance along the optical axis from the center of the lens to its focal point. This center point of the lens is called the principal point. However, since actual photographic lenses consist of combinations of several convex and concave lens elements, it is not visually apparent where the center of the lens might be. The principal point of a multi-element lens is therefore defined as the point on the optical axis at a distance equal to the focal length measured back toward the lens from the focal point. The principal point measured from the front focal point is called the front principal point, and the principal point measured from the rear focal point is called the rear principal point. The distance between these two principal points is called the principal point interval.
 
Principal rayA light ray which enters the lens at an angle at a point other than the optical axis point and passes through the center of the diaphragm opening. Principal light rays are the fundamental light rays used for image exposure at all diaphragm openings from maximum aperture to minimum aperture.
 
Rear focusingFocusing is accomplished by moving one or more lens elements positioned internally, behind the lens’ diaphragm assembly. By moving internal elements, less weight is required to be moved, so focusing can be faster and more responsive. Furthermore, the front of the lens does not move during focusing - ideal for photographers who use filters.
 
Rear Focusing (RF)With Nikon’s Rear Focusing (RF) system, all the lens elements are divided into specific lens groups, with only the rear lens group moving for focusing. This makes autofocusing operation smoother and faster.
 
Reduction in overall lens lengthTo reduce the length of a telephoto lens, it is necessary to increase the mutual power of the convex-concave groupings. Fluorite’s low index of refraction makes it possible to achieve significant reduction in lens length while maintaining high image quality. Although the extraordinary optical properties of fluorite were discovered in the 19th century and lens designers have long desired to use it, naturally formed pieces of fluorite large enough for use in lens production are extremely difficult to find. Deciding to solve this problem, Canon took up the challenge of developing synthetic crystals, bringing practical fluorite production technology on-line by the late 1960’s.
 
ReflectionReflection differs from reflection in that it is a phenomenon which causes a portion of the light striking the surface of glass or other medium to break off and propagate in an entirely new direction. The direction of propagation is the same regardless of wavelength. When light enters and leaves a lens which does not have an anti-reflection coating, approximately 5% of the light is reflected at the glass-air boundary. The amount of light direction of propagation. The two elements of a light wave which can actually be detected by the human eye are the wavelength and amplitude. Differences in wavelength are sensed as differences in color (within the visible light range) and differences in amplitude are sensed as differences in brightness (light intensity). The third element which cannot be detected by the human eye is the direction of vibration within the plane perpendicular to the light wave’s direction of propagation.
 
ResolutionThe resolution of a lens indicates the capacity of reproduction of a subject point of the lens. The resolution of the final photograph depends on three factors: the resolution of the lens, the resolution of the film, and the resolution of the printing paper. Resolution is evaluated by photographing, at a specified magnification, a chart containing groups of black and white stripes that gradually decrease in narrowness, then using a microscope to observe the negative image at a magnification of 50x. It is common to hear resolution expressed as a numerical value such as 50 lines or 100 lines. This value indicates the number of lines per millimeter of the smallest black and white line pattern which can be clearly recorded on the film. To test the resolution of a lens alone, a method is used in which a fine resolution chart is positioned in the location corresponding to the film plane and projected through the test lens onto a screen. The numerical value used for expressing resolving power is only an indication of the degree of resolution possible, and does not indicate resolution clarity or contrast.
 
Shooting distance (camera distance)The distance from the film plane (focal plane) to the subject. The position of the film plane is indicated on the top of most cameras by a \"line though a circle\" symbol.
 
Silent Wave MotorNikon's unique Silent Wave Motor (SWM) technology converts "traveling waves" into rotational energy tp focus the optics, allowing accurate, uncommonly quite high-speed autofocusing. Standard on all AF-S Nikkors, SWM technology has enjoyed univeral praise from porfessional photographers.
 
Spherical aberrationThis aberration exists to some degree in all lenses constructed entirely of spherical elements. Spherical aberration causes parallel light rays passing through the edge of a lens to converge at a focal point closer to the lens than light rays passing through the center of the lens. (The amount of focal point shift along the optical axis is called longitudinal spherical aberration.) The degree of spherical aberration tends to be larger in large-aperture lenses. A point image affected by spherical aberration is sharply formed by light rays near the optical axis but is affected by flare from the peripheral light rays (this flare is also called halo, and its radius is called lateral spherical aberration). As a result, spherical aberration affects the entire image area from the center to the edges, and produces a soft, low-contrast image which looks as if covered with a thin veil. Correction of spherical aberration in spherical lenses is very difficult. Although commonly carried out by coming two lenses-one convex and one concave-based on light rays with a certain height of incidence (distance from the optical axis), there is a limit to the degree of correction possible using spherical lenses, so some aberration always remains. This remaining aberration can be largely eliminated by stopping down the diaphragm to cut the amount of peripheral light. With large aperture lenses at full aperture, the only effective way to thoroughly compensate spherical aberration is to use an aspherical lens element.
 
Stop/diaphragm/apertureThe opening which adjusts the diameter of the group of light rays passing through the lens. In interchangeable lenses used with single lens reflex cameras, this mechanism is usually constructed as an iris diaphragm consisting of several blades which can be moved to continuously vary the opening diameter. With conventional SLR camera lenses, the aperture is adjusted by turning an aperture ring on the lens barrel. With modern camera lenses, however, aperture adjustment is commonly controlled by operating an electronic dial on the camera body.
 
Subject distanceThe distance from the lens’ front principal point to the subject.
 
Super Integrated CoatingTo enhance the performance of its optical lens elements, Nikon employs an exclusive multilayer lens coating that helps reduce ghost and flare to a negligible level. Nikon Super Integrated Coating achieves a number of objectives, including minimized reflection in the wider wavelength range and superior color balance and reproduction. Nikon Super Integrated Coating is especially effective for lenses with a large number of elements, like our Zoom-NIKKOR lenses. Also, Nikon\'s multilayer coating process is tailored to the design of each particular lens. The number of coatings applied to each lens element is carefully calculated to match the lens type and glass used, and also to assure the uniform color balance that characterizes NIKKOR lenses. This results in lenses that meet much higher standards than the rest of the industry.
 
Super Spectra coatingAll EF lenses are coated in accordance with Canon’s own standards, which are even more strict than t