Bokeh

From Wikipedia, the free encyclopedia
Coarse bokeh on a photo shot with an 85 mm lens and 70 mm entrance pupil diameter, which corresponds to f/1.2

In photography, bokeh (Originally /ˈbkɛ/,[1] /ˈbk/ BOH-kay — also sometimes heard as /ˈbkə/ BOH-kə,[2] Japanese: [boke]) is the blur,[3][4] or the aesthetic quality of the blur,[5][6][7] in out-of-focus areas of an image. Bokeh has been defined as "the way the lens renders out-of-focus points of light".[8] However, differences in lens aberrations and aperture shape cause some lens designs to blur the image in a way that is pleasing to the eye, while others produce blurring that is unpleasant or distracting—"good" and "bad" bokeh, respectively.[3] Bokeh occurs for parts of the scene that lie outside the depth of field. Photographers sometimes deliberately use a shallow focus technique to create images with prominent out-of-focus regions.

Bokeh is often most visible around small background highlights, such as specular reflections and light sources, which is why it is often associated with such areas.[3] However, bokeh is not limited to highlights; blur occurs in all out-of-focus regions of the image.

Origin

The term comes from the Japanese word boke (暈け or ボケ), which means "blur" or "haze", or boke-aji (ボケ味), the "blur quality". The Japanese term boke is also used in the sense of a mental haze or senility.[9] The term bokashi (暈かし) is related, meaning intentional blurring or gradation.

The English spelling bokeh was popularized in 1997 in Photo Techniques magazine, when Mike Johnston, the editor at the time, commissioned three papers on the topic for the March/April 1997 issue; he altered the spelling to suggest the correct pronunciation to English speakers, saying "it is properly pronounced with bo as in bone and ke as in Kenneth, with equal stress on either syllable".[4] The spellings bokeh and boke have both been in use at least since 1996, when Merklinger had suggested "or Bokeh if you prefer."[10] The term bokeh has appeared in photography books at least since 1998.[5] It is sometimes pronounced /ˈbkə/ (boke-uh).[2]

Bokeh and lens design

The depth of field is the region where the size of the circle of confusion is less than the resolution of the human eye.
An extremely shallow depth of field, a common effect in macrophotography, emphasizes bokeh.
200 mm lens at f/2.
An example of the bokeh produced by the Canon 85 mm prime f/1.8 lens. The polygonal shapes are due to the 8-bladed aperture diaphragm being slightly closed. At its full aperture (f/1.8) these shapes would be smooth and not polygonal.
The bokeh produced by a catadioptric lens (also called a mirror lens).
Catadioptric lens bokeh seen in more detail.

Though difficult to quantify, some lenses have subjectively more pleasing out-of-focus areas. "Good" bokeh is especially important for macro lenses and long telephoto lenses, because they're typically used in situations that produce shallow depth of field. Good bokeh is also important for medium telephoto lenses (typically 85–150 mm on 35 mm format). When used in portrait photography (for their "natural" perspective), the photographer usually wants a shallow depth of field, so that the subject stands out sharply against a blurred background.

Bokeh characteristics may be quantified by examining the image's circle of confusion. In out-of-focus areas, each point of light becomes an image of the aperture, generally a more or less round disc. Depending how a lens is corrected for spherical aberration, the disc may be uniformly illuminated, brighter near the edge, or brighter near the center. Lenses that are poorly corrected for spherical aberration will show one kind of disc for out-of-focus points in front of the plane of focus, and a different kind for points behind. This may actually be desirable, as blur circles that are dimmer near the edges produce less-defined shapes which blend smoothly with the surrounding image. Lens manufacturers including Nikon, Minolta, and Sony make lenses designed with specific controls to change the rendering of the out-of-focus areas.

An example of the creative application of bokeh.

The shape of the aperture has an influence on the subjective quality of bokeh as well. For conventional lens designs (with bladed apertures), when a lens is stopped down smaller than its maximum aperture size (minimum f-number), out-of-focus points are blurred into the polygonal shape formed by the aperture blades. This is most apparent when a lens produces hard-edged bokeh. For this reason, some lenses have many aperture blades and/or blades with curved edges to make the aperture more closely approximate a circle rather than a polygon. Minolta has been on the forefront of promoting and introducing lenses with near-ideal circular apertures since 1987, but most other manufacturers now offer lenses with shape-optimized diaphragms, at least for the domain of portraiture photography. In contrast, a catadioptric telephoto lens renders bokehs resembling doughnuts, because its secondary mirror blocks the central part of the aperture opening. Recently, photographers have exploited the shape of the bokeh by creating a simple mask out of card with shapes such as hearts or stars, that the photographer wishes the bokeh to be, and placing it over the lens.[11]

Leica lenses, especially vintage ones, are often claimed to excel in bokeh quality because they used to have 11, 12, or 15 blades. Because of this, the lenses don't need to reach high apertures to get better circles (instead of polygons). In the past, high aperture lenses (f/2, f/2.8) were very expensive due to their complex mathematical design and manufacturing know-how, at a time when all computations and glass making were done by hand. And Leica could reach a good bokeh at f/4.5. Today it is much easier to make f/1.8 lens, and a 9-bladed lens at f/1.8 is enough for an 85mm lens to achieve a great bokeh.

The Minolta/Sony STF 135mm f/2.8 [T4.5] (with STF standing for smooth trans focus) is a lens specifically designed to produce pleasing bokeh. Is possible to choose between two diaphragms: one with 9 and another with 10 blades. An apodization filter is used to soften the aperture edges which results in a smooth defocused area with gradually fading circles. Those qualities make it the only lens of this kind currently on the market.

The Nikon 105 mm DC-Nikkor and 135 mm DC-Nikkor lenses (DC stands for "Defocus Control") have a control ring that permits the over-correction or under-correction of spherical aberration to change the bokeh in front of and behind the focal plane.

The 'Sigma YS System Focusing' 135mm f/2.8 also has an extra manually-moved component, intended to compensate for aberration at close-focus distances. It can be re-purposed for defocus control. [12]

Emulation

No bokeh or blurSynthetic bokehGaussian blur

Bokeh can be simulated by convolving the image with a kernel that corresponds to the image of an out-of-focus point source taken with a real camera. Unlike conventional convolution, this convolution has a kernel that depends on the distance of each image point and – at least in principle – has to include image points that are occluded by objects in the foreground.[13] Also, bokeh is not just any blur. To a first approximation, defocus blur is convolution by a uniform disk, a more computationally intensive operation than the "standard" Gaussian blur; the former produces sharp circles around highlights whereas the latter is a much softer effect. Diffraction may alter the effective shape of the blur. Some graphics editors have a filter to do this, usually called "Lens Blur."[14]

An alternative mechanical mechanism has been proposed for generating bokeh in small aperture cameras such as compacts or cellphone cameras, called image destabilisation,[15][16] in which both the lens and sensor are moved in order to maintain focus at one focal plane, while defocusing nearby ones. This effect currently generates blur in only one axis.

Other applications

In 2009,[17] a research group at MIT Media Lab showed that the bokeh effect can be used to make imperceptibly small barcodes, or bokodes. By using barcodes as small as 3 mm with a small lens over them, if the barcode is viewed out of focus through an ordinary camera focused at infinity, the resulting image is large enough to scan the information in the barcode.[18]

See also

References

  1. "Bokeh in Pictures". Luminous-landscape.com. 2004-04-04. Retrieved 2011-11-15. 
  2. 2.0 2.1 Wes McDermott (2009). Real World Modo: The Authorized Guide: In the Trenches with Modo. Focal Press. p. 198. ISBN 978-0-240-81199-4. 
  3. 3.0 3.1 3.2 Harold Davis (2008). Practical Artistry: Light & Exposure for Digital Photographers. O'Reilly Media. p. 62. ISBN 978-0-596-52988-8. 
  4. 4.0 4.1 Johnston, Mike (April 4, 2004). "The Sunday Morning Photographer, 2004: Bokeh in Pictures". The Luminous Landscape. Retrieved July 3, 2009. 
  5. 5.0 5.1 Gerry Kopelow (1998). How to photograph buildings and interiors (2nd ed.). Princeton Architectural Press. pp. 118–119. ISBN 978-1-56898-097-3. 
  6. Roger Hicks and Christopher Nisperos (2000). Hollywood Portraits: Classic Shots and How to Take Them. Amphoto Books. p. 132. ISBN 978-0-8174-4020-6. 
  7. Tom Ang (2002). Dictionary of Photography and Digital Imaging: The Essential Reference for the Modern Photographer. Watson–Guptill. ISBN 0-8174-3789-4. 
  8. "PhotoWords/Lens". PhotoGuide Japan. 
  9. John W. Traphagan (2000). Taming oblivion: aging bodies and the fear of senility in Japan. SUNY Press. p. 134. ISBN 978-0-7914-4499-3. 
  10. Merklinger, Harold. "Understanding Boke". The Luminous Landscape. Retrieved July 3, 2009. 
  11. Karsten Stroemvig. "DIY — Create your own Bokeh". 
  12. Markus Keinath. "Cheap DC Nikkor Substitute". 
  13. Potmesil, M.; Chakravarty, I. (1982), Synthetic Image Generation with a Lens and Aperture Camera Model, ACM Transactions on Graphics 1 (2 (1982)), ACM, pp. 85–108, doi:10.1145/357299.357300, ISSN 0730-0301 
  14. Adobe Photoshop CS3 Livedocs. "Add lens blur". 
  15. Giles, Jim. "Next-generation cameras bring photography tricks to the masses". New Scientist (Subscription required). Retrieved 2011-04-04. 
  16. Ankit Mohan and Douglas Lanman and Shinsaku Hiura and Ramesh Raskar. "Image Destabilization: Programmable Defocus using Lens and Sensor Motion". 
  17. Fildes, Jonathan (2009-07-27). "Technology | Barcode replacement shown off". BBC News. Retrieved 2012-02-19. 
  18. Mohan, A., Woo, G, Hiura, S, Smithwick, Q, Raskar, R. Bokode: Imperceptible Visual Tags for Camera Based Interaction from a Distance. ACM SIGGRAPH 2009.

External links

This article is issued from Wikipedia. The text is available under the Creative Commons Attribution/Share Alike; additional terms may apply for the media files.