Lens speed refers to the maximum aperture diameter, or minimum f-number, of a photographic lens. A lens with a larger maximum aperture (that is, a smaller minimum f-number) is called a "fast lens" because it can achieve the same exposure with a faster shutter speed. Conversely, a smaller maximum aperture (larger minimum f-number) is "slow" because it delivers less light intensity and requires a slower (longer) shutter speed.
A fast lens speed is desirable in taking pictures in dim light, or with long telephoto lenses and for controlling depth of field and bokeh, especially in portrait photography, and for sports photography and photojournalism.
Lenses may also be referred to as being "faster" or "slower" than one another; so an f/3.5 lens can be described as faster than an f/5.6.
Video Lens speed
Tradeoffs
Attaining maximum lens speed requires engineering tradeoffs, and as such, "prime" (fixed focal length) lenses are generally faster than zoom lenses, and modern manual-focus lenses are generally faster than their autofocus counterparts.
With 35mm cameras, the fastest lenses are typically in the "normal lens" range near 50mm and there are several high-quality fast lenses available that are relatively inexpensive. For example, the Canon EF 50mm f/1.8 II or Nikon AF Nikkor 50mm f/1.8D are very inexpensive, but quite fast and optically well-regarded. Old fast manual focus lenses, just as the Nikkor-S(C) or Nikkor AI-S 50mm f/1.4, were historically produced abundantly, and are thus sold relatively inexpensively on the used lens market.
Especially outside of the "normal lenses", lens speed also tends to correlate with the price and/or quality of the lens. This is because lenses with larger maximum apertures require greater care with regard to design, precision of manufacture, special coatings and quality of glass. At wide apertures, spherical aberration becomes more significant and must be corrected. Faster telephoto and wide-angle retrofocus designs tend to be much more expensive.
Maps Lens speed
Fast lenses
The fastest lenses in general production now are f/1.2 or f/1.4, with more at f/1.8 and f/2.0, and many at f/2.8 or slower. What is considered "fast" has evolved to lower f-numbers over the years, due to advances in lens design, optical manufacturing, quality of glass, optical coatings, and the move toward smaller imaging formats. For example, the 1911 Encyclopædia Britannica states that "...[Lenses] are also sometimes classified according to their rapidity, as expressed by their effective apertures, into extra rapid, with apertures larger than f/6; rapid, with apertures from f/6 to f/8; slow, with apertures less than f/11."
For scale, note that f/0.5, f/0.7, f/1.0, f/1.4, and f/2.0 are each 1 f-stop apart (2× as fast), as an f-stop corresponds to a factor of square root of 2, about 1.4. Thus around f/1.0, a change of 0.1 corresponds to about 1/4 of an f-stop (by linear approximation): f/1.0 is about 50% faster than f/1.2, which is about 50% faster than f/1.4.
As of 2017, Canon, Nikon, Pentax and Sony all make an autofocus 50mm f/1.4 lens. These are not unusual lenses and are relatively inexpensive. Canon also makes autofocus 50mm and 85mm f/1.2 lenses, while Nikon makes a manual focus 50mm f/1.2 lens and an autofocus 85mm f/1.4; see Canon EF 50mm lenses and Canon EF 85mm lenses for details. Pentax makes a 50mm f/1.4 lens and 55mm f/1.4 lens for APS-C cameras; see Pentax lenses. Sony makes a 50mm f/1.4 lens which is a continuation of the Minolta AF 50mm f/1.4 lens, and two lenses with Carl Zeiss: a 50mm f/1.4 and 85mm f/1.4.
The maximum exposure time in free-hand photography can be enhanced even more also for fast lenses, if the camera is equipped with an image stabilisation system. In 2014 Panasonic introduced the fastest lens with in-built stabilisation, the Leica Nocticron 42.5 mm f/1.2, which in the meantime even can be operated with dual image stabilisation (Dual I.S.), provided that the camera body has an additional stabilising system at the image sensor, too.
In the mid 60s there was something of a fad for fast lenses among the major manufacturers. In 1966 in response to the trend Carl Zeiss displayed a prop lens christened the Super-Q-Gigantar 40mm f/0.33 at photokina. Made from various parts found around the factory (the lenses came from a darkroom condenser enlarger), the claimed speed and focal lengths were purely nominal and it wasn't usable for photography.
Maximum possible speed
Ultimately, the speed of a lens is limited by mechanical constraints of the camera system (shutter or mirror clearance, mount diameter). The smallest possible working f-number is
where
- NAmax is the largest possible numerical aperture,
- n is the index of refraction of the medium behind the lens, most often air where n = 1,
- ? is the half-angle of the maximum cone of light that can reach the film or sensor.
This sets a limit close to f/1.0 to f/1.2 for most SLR mounts, whereas lenses for rangefinder and mirrorless cameras can be faster, as they can be brought closer to the image plane. Reproduction lenses incapable of infinity focus can have nominal f-numbers smaller than this limit, as the limit applies to the working f-number (the f-number corrected by the bellows factor), not to the nominal f-number. It should be noted that only the working f-number correctly assesses the light gathering power of the lens.
Since sin ? < 1, it follows that no lens can be faster than f/0.5 if it operates in air. Lenses can be made faster than this by requiring the film emulsion to be in physical contact with the rear element, thus eliminating the air gap between the lens and the emulsion. Another option is to use oil immersion techniques.
List of ultrafast lenses
Some of the fastest camera lenses in production as of 2017 were as follows:
- Handevision Ibelux 40mm f/0.85, Made for multiple camera mounts including Micro 4/3, Sony E-Mount and Fujifilm X-Mount
- Fujinon 43mm f/0.85
- Cosina Voigtländer Nokton 17.5mm f/0.95 Aspherical Micro Four Thirds mount
- Cosina Voigtländer Nokton 25mm f/0.95 Micro Four Thirds mount
- Cosina Voigtländer Nokton 42.5mm f/0.95 Micro Four Thirds mount
- Leica Noctilux-M 50mm f/0.95 ASPH announced on September 15, 2008, it is one of the fastest aspherical lens to have ever reached mass production, with a MSRP of £6290 (approximately US$10,000).
- SLR Magic HyperPrime LM 50mm T0.95 (f/0.92)
- Noktor 50mm f/0.95 'HyperPrime' a fast CCTV lens design adapted for the Micro Four Thirds system
- SLR Magic 25mm T/0.95
- SLR Magic 35mm T/0.95
- Mitakon 50mm and 35mm f/0.95
- Vantage One T/1.0 Cine lenses - 17.5mm to 120mm Super35mm Spherical Primes.
- Metabones 0.58x BMPCC Speed Booster (for Blackmagic Pocket Cinema Camera) combined with an f/1.2 SLR lens to yield f/0.74 or combined with an f/1.4 SLR lens to yield f/0.80
- Metabones 0.64x Speed Booster XL (for Micro Four Thirds format) combined with an f/1.2 SLR lens to yield f/0.80 or combined with an f/1.4 SLR lens to yield f/0.90
- Metabones 0.71x Speed Booster ULTRA (for either Micro Four Thirds or APS-C formats) combined with an f/1.2 SLR lens to yield f/0.90 or combined with an f/1.4 SLR lens to yield f/1.0
The following camera lenses are no longer in production as of 2010:
- American Optical 81mm f/0.38 Solid Schmidt Mirror lens. Designed for aerial reconnaissance
- GOI CV 20mm f/0.5 Mirror lens
- Signal Corps Engineering 33mm f/0.6
- GOI Iskra-3 72mm f/0.65 Mirror lens
- Fujinon-IDEAX 125mm f/0.67
- Zeiss Planar 50mm f/0.7 Limited production lens built for the NASA space program, used on 35mm movie cameras by Stanley Kubrick for some candlelit scenes in Barry Lyndon
- Tokyo Kogaku Similar 50mm f/0.7, 8 elements in 4 groups, limited produced in 1944 for Japanese Army. (In 1951 another three were produced, two of which were used on a South Pole expedition)
- Kinoptik Lynxar 60mm f/0.7 Reproduction lens, not for photography.
- Wray 64mm f/0.71 Reproduction lens, not for photography.
- LOMO 60mm f/0.75 Reproduction lens, not for photography.
- Aerojet Delft Rayxar 105mm f/0.75 Full Frame aerial photography lens
- Aerojet Delft Rayxar 150mm f/0.75 Medium Format aerial photography lens
- Aerojet Delft Rayxar 250mm f/0.75 Large Format aerial photography lens
- American Optical 43mm f/0.8
- JML Optical 64mm f/0.85
- Leica Summar 75mm f/0.85
- Leica Leitz-IR 150mm f/0.85
- Farrand Super Farron 76mm f/0.87
- Farrand Super Farron 150mm f/0.87 Medium Format aerial photography lens
- ??????-4 52mm f/0.9
- Nikon TV-Nikkor 35mm f/0.9 Fastest Nikon lens ever made. (TV lens in M39 lens mount, 12.6 mm diameter image circle)
- Noktor HyperPrime CINE 50mm f/0.92 T0.95, Fastest cinema lens made for 35mm interchangeable lens camera
- Canon 50mm f/0.95 Available in TV (c-mount) and Canon 7 Rangefinder Version
- Astro Berlin 52mm f/0.95
- Perkin Elmer 114mm f/0.95 Medium Format aerial photography lens
- Pacific Optical 25mm f/1.0 Medium Format Fish-eye lens. Only 3 were ever made for the Canadian Government for aurora borealis research in the late 60s/early 70s. One of these lenses was used in the production of the IMAX movie Solarmax
- Leica Noctilux 50mm f/1.0 Leica M mount, discontinued and replaced 2008 with a new Noctilux, see above
- Canon EF 50mm f/1.0 for Canon autofocus SLR, now out of production
- Panavision 50mm f/1.0
- Nikkor-O 50mm f/1.0 Prototype lens for Nikkor-S Rangefinder camera
- Leica ELCAN 90mm f/1.0
- Wild Heerbrugg Reconar 98mm f/1.0 Medium Format aerial photography lens
- Kollmorgen 153mm f/1.0
- Zeiss UR 250mm f/1.0
- Canon 8.5-25.5mm f/1.0 zoom lens, made 1975-1983 for the 310XL Super 8mm silent and sound camera series, fastest lens ever made in Super8, was originally advertised as facilitating "shooting at candlelight" in combination with 160-ASA films.
Many very fast lenses exist in C-mount (such as used by 16mm film cameras, CCTV, medical & scientific imaging systems), including:
- Fujinon 50mm f/0.7
- Canon 'TV-16' 25mm f/0.78
- Apollo 25mm f/0.85
- Ernitec 25mm f/0.85
- Fujinon 25mm f/0.85
- Tarcus 25mm f/0.85
- Kern Switar 18mm f/0.9 built for NASA for Apollo Moon landing
- Ampex 'LE610 Television Lens' 25mm f/0.95
- Angenieux 'M1' and 'M2' 25mm f/0.95 (M1 was a consumer product, while M2 was aimed at the professional cine market)
- Angenieux 'M2' 28mm f/1.1
- Angenieux 35mm f/0.95
- Angenieux 50mm f/0.95 Type M1 (original more common), and Type M2 (better corrected for aberrations and distortions, designed for NASA, very rare and hard to find)
- AstroScope 25mm f/0.95
- Avenir 25mm f/0.95
- Century 'Nighthawk' 25mm f/0.95
- Carl Meyer 25mm f/0.95
- Cinetar 25mm f/0.95
- Goyo Optical 17mm, 25mm, and 50mm f/0.95
- JML 25mm and 50mm f/0.95
- Navitar 25mm and 50mm f/0.95
- Navitron 25mm and 50mm f/0.95
- Schneider Kreuznach 'Xenon' 17mm, 25mm, and 50mm f/0.95
- Senko 25mm and 50mm f/0.95
- Soligor 'Super Elitar' 25mm f/0.95
- Som Berthiot 'Cinor' 25mm and 50mm f/0.95
- Tarcus 'I.T.V. Lens' 50mm f/0.95
- Precise Optics 50mm f/0.95
- Kowa 50mm f/0.95
- Yakumo 25mm and 50mm f/0.95
- Zeika 'Nominar' 25mm f/0.95
- Kaligar 'Nominar' 25mm f/0.95
- Dallmeyer 25mm f/0.99 (1930)
- Astro Berlin 25mm f/1.0
- Bausch & Lomb 29mm f/1.0
- Astro Berlin 'Tachonar' 35mm and 75mm f/1.0
- Carl Meyer 38mm f/1.0
- RTH (Rank/Taylor Hobson) Monital 130mm f/1.0 made by SOPELEM in France
Very fast lenses in D-mount for 8mm movie use on H8 cameras:
- Kern Switar 13mm f/0.9
- Cinetor 'TELE-PHOTO' 37.5mm f/1.0
- Walz 'TELEPHOTO' 37.5mm f/1.0
- Amitar 'Telephoto' 38.1mm f/1.0
- Rexer 'TELE' 38mm f/1.0
- Manon 'Telephoto' 37.5mm f/1.0
Very fast lenses used in x-ray machines:
- Zeiss R-Biotar 100mm f/0.73
- LOMO 100mm f/0.73
- Canon 50mm/65mm f/0.75
- Leitz 50mm/65mm f/0.75
- Rayxar 50mm/65mm/150mm f/0.75
- Rayxar 90mm f/1.0
- Tachon Astro-Berlin 65mm f/0.75
- Rodenstock XR-Heligon 42mm/50mm f/0.75
- Rodenstock XR-Heligon 68mm f/0.95 etc.
- Kowa 42mm/65mm f/0.75
- Carl Zeiss Jena 50mm f/0.77
- Kowa 55mm f/0.8
- Zeiss R-Biotar 55mm f/0.85
- Lenzar Optics 184.6mm f/0.9 (Photographic lens made by Lenzar Optics Corp., Riviera Beach FL, f0.9-f8)
- Kowa 33.5mm f/0.95
- Kowa 55mm f/1.0
- Rodenstock Heligon 68mm f/1.0
- Canon 65mm/90mm f/1.0
- Fuji 90mm f/1.0
- Kowa 90mm f/1.0
- Leitz 90mm f/1.0
- Mt Prospect 90mm f/1.0
- Zeiss R-Biotar 120mm f/1.0
References
External links
- Just how fast is that lens? f-number doesn't directly determine focal-plane illuminance, due to light transmission losses.
Source of article : Wikipedia