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-DEPTH OF FIELD -
Depth of field is the range of distance around the focal plane which is acceptably sharp. The depth of field varies depending on camera type, aperture and focusing distance, although print size and viewing distance can influence our perception of it. This section is designed to give a better intuitive and technical understanding for photography, and provides a depth of field calculator to show how it varies with your camera settings.
CIRCLE OF CONFUSION
Since there is no critical point of transition, a more rigorous term called the "circle of confusion" is used to define how much a point needs to be blurred in order to be perceived as unsharp. When the circle of confusion becomes perceptible to our eyes, this region is said to be outside the depth of field and thus no longer "acceptably sharp." The circle of confusion above has been exaggerated for clarity; in reality this would be only a tiny fraction of the camera sensor's area. When does the circle of confusion become perceptible to our eyes? An acceptably sharp circle of confusion is loosely defined as one which would go unnoticed when enlarged to a standard 8x10 inch print, and observed from a standard viewing distance of about 1 foot.| At this viewing distance and print size, camera manufactures assume a circle of confusion is negligible if no larger than 0.01 inches (when enlarged). As a result, camera manufacturers use the 0.01 inch standard when providing lens depth of field markers (shown below for f/22 on a 50mm lens). In reality, a person with 20-20 vision or better can distinguish features 1/3 this size or smaller, and so the circle of confusion has to be even smaller than this to achieve acceptable sharpness throughout. |
CONTROLLING DEPTH OF FIELD
Although print size and viewing distance are important factors which influence how large the circle of confusion appears to our eyes, aperture and focal distance are the two main factors that determine how big the circle of confusion will be on your camera's sensor. Larger apertures (smaller F-stop number) and closer focal distances produce a shallower depth of field. The following depth of field test was taken with the same focus distance and a 200 mm lens (320 mm field of view on a 35 mm camera), but with various apertures:| f/8.0 | f/5.6 | f/2.8 |
CLARIFICATION: FOCAL LENGTH AND DEPTH OF FIELD
Note how I did not mention focal length as influencing depth of field. Even though telephoto lenses appear to create a much shallower depth of field, this is mainly because they are often used to make the subject appear bigger when one is unable to get closer. If the subject occupies the same fraction of the viewfinder (constant magnification) for both a wide angle and a telephoto lens, the total depth of field is virtually* constant with focal length! This would of course require you to either get much closer with a wide angle lens or much further with a telephoto lens, as demonstrated in the following depth of field chart:| Focal Length (mm) | Focus Distance (m) | Depth of Field (m) |
| 10 | 0.5 | 0.482 |
| 20 | 1.0 | 0.421 |
| 50 | 2.5 | 0.406 |
| 100 | 5.0 | 0.404 |
| 200 | 10 | 0.404 |
| 400 | 20 | 0.404 |
| Distribution of the Depth of Field | ||
| Focal Length (mm) | Rear | Front |
| 10 | 70.2 % | 29.8 % |
| 20 | 60.1 % | 39.9 % |
| 50 | 54.0 % | 46.0 % |
| 100 | 52.0 % | 48.0 % |
| 200 | 51.0 % | 49.0 % |
| 400 | 50.5 % | 49.5 % |
*Note: We describe depth of field as being virtually constant because there are limiting cases where this does not hold true. For focal distances resulting in high magnification, or very near the hyperfocal distance, wide angle lenses may provide a greater DoF than telephoto lenses. On the other hand, for situations of high magnification the traditional DoF calculation becomes inaccurate due to another factor: pupil magnification. This actually acts to offset the DoF advantage for most wide angle lenses, and increase it for telephoto and macro lenses. At the other limiting case, near the hyperfocal distance, the increase in DoF arises because the wide angle lens has a greater rear DoF, and can thus more easily attain critical sharpness at infinity for any given focal distance.
CALCULATING DEPTH OF FIELD
In order to calculate the depth of field, one needs to first decide on an appropriate value for the maximum allowable circle of confusion. This is based on both the camera type (sensor or film size), and on the viewing distance / print size combination. Depth of field calculations ordinarily assume that a feature size of 0.01 inches is required for acceptable sharpness (as discussed earlier), however people with 20-20 vision can see features 1/3 this size. If you use the 0.01 inch standard of eyesight, understand that the edge of the depth of field may not appear acceptably sharp. The depth of field calculator below assumes this standard of eyesight, however I also provide a more flexible depth of field calculator.| Depth of Field Calculator | ||
| Camera Type | digital compact with 1/2.5" Sensordigital compact with 1/1.8" Sensordigital compact with 1/1.7" Sensordigital compact with 2/3" Sensordigital compact with 4/3" Sensordigital SLR with CF of 1.6Xdigital SLR with CF of 1.5Xdigital SLR with CF of 1.3X35 mmAPS6x45 cm6x6 cm6x7 cm5x4 inch10x8 inch | |
| Selected aperture | F 1.4F 1.8F 2F 2.8F 4F 5.6F 8F 11F 16F 22F 32F 64 | |
| Actual lens focal length | mm | |
| Focus distance (to subject) | meters | |
| Closest distance of acceptable sharpness Furthest distance of acceptable sharpness Total Depth of Field | ||
DEPTH OF FOCUS
Another implication of the circle of confusion is the concept of depth of focus (also called the "focus spread"). It differs from depth of field in that it describes the distance over which light is focused at the camera's sensor, as opposed to how much of the subject is in focus. This is important because it sets tolerances on how flat/level the camera's film or digital sensor have to be in order to capture proper focus in all regions of the image.OTHER NOTES
Why not just use the smallest aperture (largest number) to achieve the best possible depth of field? Other than the fact that this may require prohibitively long shutter speeds without a tripod, too small of an aperture softens the image by creating a larger circle of confusion (or "Airy disk") due to an effect called diffraction-- even within the plane of focus. Diffraction quickly becomes more of a limiting factor than depth of field as the aperture gets smaller. Despite their extreme depth of field, this is also why "pinhole cameras" have limited resolution. For macro photography (high magnification), the depth of field is actually influenced by another factor: pupil magnification. This is equal to one for lenses which are internally symmetric, although for wide angle and telephoto lenses this is greater or less than one, respectively. A greater depth of field is achieved (than would be ordinarily calculated) for a pupil magnification less than one, whereas the pupil magnification does not change the calculation when it is equal to one. The problem is that the pupil magnification is usually not provided by lens manufacturers, and one can only roughly estimate it visually.
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