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In photography and optics, the f-number or focal ratio of an optical system expresses the diameter of the entrance pupil in terms of the effective focal length of the lens.

Notation

The f-number f/#, often notated as $N$ , is given by

f/\#=N={\frac {f}{D}}\ ,

where $f$ is the focal length, and $D$ is the diameter of the entrance pupil. By convention, "f/#" is treated as a single symbol, and specific values of f/# are written by replacing the number sign with the value. For example, if the focal length is 16 times the pupil diameter, the f-number is f/16, or $N=16$ . The greater the f-number, the less light per unit area reaches the image plane of the system.

The literal interpretation of the f/ $N$ notation for f-number $N$ is as an arithmetic expression for the effective aperture diameter (input pupil diameter), the focal length divided by the f-number: $D=f/N$ .

The pupil diameter is proportional to the diameter of the aperture stop of the system. In a camera, this is typically the diaphragm aperture, which can be adjusted to vary the size of the pupil, and hence the amount of light that reaches the film or image sensor. Other types of optical system, such as telescopes and binoculars may have a fixed aperture, but the same principle holds: the greater the focal ratio, the fainter the images created (measuring brightness per unit area of the image). Note that the common assumption in photography that the pupil diameter is equal to the aperture diameter is not correct for all types of camera lens. A focal ratio of f/16 does not always mean that the physical aperture inside the camera lens has diameter equal to one sixteenth the focal length.

Stops, f-stop conventions, and exposure

The term stop is sometimes confusing due to its multiple meanings. A stop can be a physical object: an opaque part of an optical system that blocks certain rays. The aperture stop is the aperture that limits the brightness of the image by restricting the input pupil size, while a field stop is a stop intended to cut out light that would be outside the desired field of view and might cause flare or other problems if not stopped.

In photography, stops are also a unit used to quantify ratios of light or exposure, with one stop meaning a factor of two, or one-half. The one-stop unit is also known as the EV (exposure value) unit. On a camera, the f-number is usually adjusted in discrete steps, known as f-stops. Each "stop" is marked with its corresponding f-number, and represents a halving of the light intensity from the previous stop. This corresponds to a decrease of the pupil and aperture diameters by a factor of ${\sqrt {2}}$ , and hence a halving of the area of the pupil.

Modern lenses use a standard f-stop scale that corresponds to the sequence of the powers of ${\sqrt {2}}$ : f/0.7, f/1, f/1.4, f/2, f/2.8, f/4, f/5.6, f/8, f/11, f/16, f/22, f/32, f/45, f/64, f/90, f/128, etc. The values of the ratios are rounded off to these particular conventional numbers, to make them easy to remember and write down.

The slash indicates division. For example, f/16 means that the pupil diameter is equal to the focal length divided by sixteen; that is, if the camera has an 80 mm lens, all the light that reaches the film passes through a circle that is 5 mm (80 mm/16) in diameter. The location of this circle inside the lens depends on the optical design. It may simply be the opening of the aperture stop, or may be a magnified image of the aperture stop, formed by elements within the lens.

Shutter speeds are arranged in a similar scale, so that one stop in the shutter speed scale corresponds to one stop in the aperture scale. Opening up a lens by one stop allows twice as much light to fall on the film in a given period of time, therefore to have the same exposure, you must have a shutter speed twice as fast (shutter open half as long). Alternatively, you could use a film which is half as sensitive to light. This fundamental principle of photographic technique is known as reciprocity.

Photographers sometimes express other exposure ratios in terms of 'stops'. If we ignore the f-number markings, the f-stops make a logarithmic scale of exposure intensity. Given this interpretation, you can then think of taking a half-step along this scale, to make an exposure difference of "half a stop".

Fractional stops

On modern cameras, especially when aperture is set on the camera body, f-number is often divided more finely than steps of one stop. Steps of one-third stop (1/3 EV) are the most common, since this matches the ISO system of film speeds. Half-stop steps are also seen on some cameras. As an example, the aperture that is one-third stop smaller than f/2.8 is f/3.2, two-thirds smaller is f/3.5, and one whole stop smaller is f/4. The next few f-stops in this sequence are

f/4.5, f/5, f/5.6, f/6.3, f/7.1, f/8, etc.

ISO speed is defined only in one-third stop increments, and shutter speeds of digital cameras are commonly on the same scale in reciprocal seconds. A portion of the ISO range is the sequence

4, 5, 6, 8, 10, 12, 16, 20, 25, 32, 40, 64, 80, 100, 125, 160, 200, 250, 320, 400, 500, 640, 800, 1000, 1250, 1600

while shutter speeds in reciprocal seconds have a few conventional differences in their numbers (1/15, 1/30, and 1/60 second instead of 1/16, 1/32, and 1/64).

In practice the maximum aperture of a lens may not be an integral power of ${\sqrt {2}}$ , in which case it is usually a half or third stop above or below an integral power of ${\sqrt {2}}$ .

Modern electronically-controlled interchangeable lenses, such as those from Canon and Sigma for SLR cameras, have f-stops specified internally in 1/8-stop increments, so the cameras' 1/3-stop settings are approximated by the nearest 1/8-stop setting in the lens.

t-stops

Since all lenses absorb some portion of the light passing through them (particularly zoom lenses containing many elements), for exposure purposes t-stops are sometimes used instead of f-stops. The t-numbers are adjusted so that the amount of light transmitted through the lens at a given t-stop is equal to that going through an ideal non-absorbing lens set at that f-stop. (The t in t-stop stands for transmission.)

Sunny 16 rule

As an example of the use of f-numbers in photography, an approximately correct exposure will be obtained on a sunny day by using an aperture of f/16 and a shutter speed close to the reciprocal of the ISO speed of the film; thus, using ISO 100 film, an aperture of f/16 and a shutter speed of 1/100 second. This is called the sunny 16 rule.

Effects on image quality

Depth of field increases with f-number, as illustrated in the photos to the right. Picture quality also varies with f-number. The optimal f-stop varies with the lens characteristics. For modern standard lenses having 6 or 7 elements, the sharpest image is obtained around f/5.6–f/8, while for older standard lenses having only 4 elements (Tessar formula) stopping to f/11 will give the sharpest image. The reason the sharpness is best at medium f-numbers is that the sharpness at high f-number is constrained by diffraction, whereas at low f-numbers limitations of the lens design known as aberrations will dominate. The larger number of elements in modern lenses allow the designer to compensate for aberrations, allowing the lens to give good pictures at a lower f-stop. Light falloff is also sensitive to f-stop. Many wide-angle lenses will show a significant light falloff (vignetting) at the edges for large apertures.

Photojournalists have a saying, "f/8 and be there." People have interpreted the expression differently, but one meaning is that f/8 will give a good enough picture, and being on the scene is more important than worrying excessively about technical details.

Other examples

The f-number of the human eye varies from about f/8.3 in a very brightly lit place to about f/2.1 in the dark^[1].

History

The system of f-numbers for specifying relative apertures evolved in the late nineteenth century, in competition with several other systems of aperture notation.

Sutton and Dawson 1867 defined "apertal ratio" as essentially the reciprocal of the modern f-number:

"In every lens there is, corresponding to a given apertal ratio (that is, the ratio of the diameter of the stop to the focal length), a certain distance of a near object from it, between which and infinity all objects are in equally good focus. For instance, in a single view lens of 6 inch focus, with a 1/4 in. stop (apertal ratio one-twenty-fourth), all objects situated at distances lying between 20 feet from the lens and an infinite distance from it (a fixed star, for instance) are in equally good focus. Twenty feet is therefore called the 'focal range' of the lens when this stop is used. The focal range is consequently the distance of the nearest object, which will be in good focus when the ground glass is adjusted for an extremely distant object. In the same lens, the focal range will depend upon the size of the diaphragm used, while in different lenses having the same apertal ratio the focal ranges will be greater as the focal length of the lens is increased. The terms 'apertal ratio' and 'focal range' have not come into general use, but it is very desirable that they should, in order to prevent ambiguity and circumlocution when treating of the properties of photographic lenses."

In 1874, James Henry Dallmeyer called this ratio $1/N$ the "intensity ratio" of a lens. His son Thomas R. Dallmeyer, inventor of the telephoto lens, followed this terminology in 1899.

At the same time, there were a number of aperture numbering systems designed with the goal of making exposure times vary in direct or inverse proportion with the aperture, rather than with the square of the f-number or inverse square of the apertal ratio or intensity ratio. But these systems all involved some arbitrary constant, as opposed to the simple ratio of focal length and diameter.

For example, the Uniform System (U.S.) of apertures was adopted as a standard by the Photographic Society of Great Britain in the 1880s. Bothamley in 1891 said "The stops of all the best makers are now arranged according to this system." U.S. 16 is the same aperture as f/16, but apertures that are larger or smaller by a full stop use doubling or halving of the US number, for example f/11 is U.S. 8 and f/8 is U.S. 4. The exposure time required is directly proportional to the U.S. number. Eastman Kodak used U.S. stops on many of their cameras at least in the 1920s.

By 1895, Hodges contradicts Bothamley, saying that the f-number system has taken over: "This is called the f/x system, and the diaphragms of all modern lenses of good construction are so marked."

Beck and Andrews 1902 talk about the Royal Photographic Society standard of f/4, f/5.6, f/8, f/11.3, etc. The R.P.S. had changed their name and moved off of the US system some time between 1895 and 1902. Their standard sequence doesn't quite match the modern conventions, e.g. at 11.3.

Piper 1901 discusses five different systems of aperture marking: the old and new Zeiss systems based on actual intensity (proportional to reciprocal square of the f-number); and the U.S., C.I., and Dallmeyer systems based on exposure (proportional to square of the f-number). He calls the f-number the "ratio number," "aperture ratio number," and "ratio aperture." He calls expressions like f/8 the "fractional diameter" of the aperture, even though it is literally equal to the "absolute diameter" which he distinguishes as a different term. He also sometimes uses expressions like "an aperture of f 8" without the division indicated by the slash.

Thomas Sutton and George Dawson, A Dictionary of Photography, London: Sampson Low, Son & Marston, 1867, (p. 122).

John Henry Dallmeyer, Photographic Lenses: On Their Choice and Use - Special Edition Edited for American Photographers, pamphlet, 1874.

C. H. Bothamley, Ilford Manual of Photography, London: Brittania Works Co. Ltd., 1891.

John A. Hodges, Photographic Lenses: How to Choose, and How to Use, Bradford: Percy Lund & Co., 1895.

Thomas R. Dallmeyer, Telephotography: An elementary treatise on the construction and application of the telephotographic lens, London: Heinemann, 1899.

C. Welborne Piper, A First Book of the Lens: An Elementary Treatise on the Action and Use of the Photographic Lens, London: Hazell, Watson, and Viney, Ltd., 1901.

Conrad Beck and Herbert Andrews, Photographic Lenses: A Simple Treatise, second edition, London: R. & J. Beck Ltd., c. 1902.

References

^ *Hecht, Eugene (1987). Optics (2nd ed. ed.). Addison Wesley. ISBN 0-201-11609-X. {{cite book}}: |edition= has extra text (help) Sect. 5.7.1

External links

f Number Arithmetic
Film Speed
Large format photography—how to select the f-stop
A Tedious Explanation of the f/stop f/stops cause a lot of people confusion. This explanation shows why the numbers go like they do and why they make sense.
What the f-stop really means, and where these numbers come from.
Changing the f-stop will change your Depth of Field.
The F Number - Demystified.

[1] *Hecht, Eugene (1987). Optics (2nd ed. ed.). Addison Wesley. ISBN 0-201-11609-X. {{cite book}}: |edition= has extra text (help) Sect. 5.7.1

[1]

@@ Line 17: / Line 17: @@
 The term ''stop'' is sometimes confusing due to its multiple meanings.  A stop can be a physical object: an opaque part of an optical system that blocks certain rays.  The ''[[aperture stop]]'' is the aperture that limits the brightness of the image by restricting the input pupil size, while a ''field stop'' is a stop intended to cut out light that would be outside the desired field of view and might cause flare or other problems if not stopped.
 In photography, stops are also a ''unit'' used to quantify ratios of light or exposure, with one stop meaning a factor of two, or one-half. On a camera, the f-number is usually adjusted in discrete steps, known as '''f-stops'''. Each "stop" is marked with its corresponding f-number, and represents a halving of the light intensity from the previous stop. This corresponds to a decrease of the pupil and aperture diameters by a factor of <math>\sqrt{2}</math>, and hence a halving of the area of the pupil.
 [[Image:lens aperture side.jpg|240px|thumb|right|A 35mm lens set to {{f/}}11, as indicated by the white dot above the f-stop scale on the aperture ring. This lens has an aperture range of {{f/}}2.0 to {{f/}}22]]
@@ Line 28: / Line 28: @@
 Photographers sometimes express other [[Exposure (photography)|exposure]] ratios in terms of 'stops'. If we ignore the f-number markings, the f-stops make a logarithmic scale of exposure intensity. Given this interpretation, you can then think of taking a half-step along this scale, to make an exposure difference of "half a stop".
+===Fractional stops===
-On modern cameras, especially when aperture is set on the camera body, f-number is often divided more finely than steps of one stop. Steps of one third stop are the most common, since this matches the ISO system of [[film speed]]s. Half-stop steps are also seen on some cameras. As an example, the aperture that is one third stop smaller than {{f/}}2.8 is {{f/}}3.2, two thirds smaller is {{f/}}3.5, and one whole stop smaller is {{f/}}4.  The next few f-stops in this sequence are {{f/}}4.5, {{f/}}5, {{f/}}5.6, {{f/}}6.3, {{f/}}7.1, {{f/}}8, etc. In practice the maximum aperture of a lens may not be an [[integer|integral]] power of <math>\sqrt{2}</math>, in which case it is usually a half or third stop above or below an integral power of <math>\sqrt{2}</math>.
+On modern cameras, especially when aperture is set on the camera body, f-number is often divided more finely than steps of one stop. Steps of onethird stop are the most common, since this matches the ISO system of [[film speed]]s. Half-stop steps are also seen on some cameras. As an example, the aperture that is onethird stop smaller than {{f/}}2.8 is {{f/}}3.2, twothirds smaller is {{f/}}3.5, and one whole stop smaller is {{f/}}4.  The next few f-stops in this sequence are
+:{{f/}}4.5, {{f/}}5, {{f/}}5.6, {{f/}}6.3, {{f/}}7.1, {{f/}}8, etc.
+ISO speed is defined only in one-third stop increments, and shutter speeds of digital cameras are commonly on the same scale in reciprocal seconds.  A portion of the ISO range is the sequence
+: 4, 5, 6, 8, 10, 12, 16, 20, 25, 32, 40, 64, 80, 100, 125, 160, 200, 250, 320, 400, 500, 640, 800, 1000, 1250, 1600
+while shutter speeds in reciprocal seconds have a few conventional differences in their numbers (1/15, 1/30, and 1/60 second instead of 1/16, 1/32, and 1/64).
+In practice the maximum aperture of a lens may not be an [[integer|integral]] power of <math>\sqrt{2}</math>, in which case it is usually a half or third stop above or below an integral power of <math>\sqrt{2}</math>.
+Modern electronically-controlled interchangeable lenses, such as those from Canon and Sigma for SLR cameras, have f-stops specified internally in 1/8-stop increments, so the cameras' 1/3-stop settings are approximated by the nearest 1/8-stop setting in the lens.
+===t-stops===
 Since all lenses absorb some portion of the light passing through them (particularly [[zoom lens]]es containing many elements), for exposure purposes '''t-stops''' are sometimes used instead of f-stops. The t-numbers are adjusted so that the amount of light transmitted through the lens at a given t-stop is equal to that going through an ideal non-absorbing lens set at that f-stop.  (The '''t''' in t-stop stands for ''transmission''.)