An Occassional Glossary: C, D, E

Here's a bit more on the ongoing glossary project, C through E

Center-weighted Metering Pattern: In a metering scheme, an exposure system that takes most of its information from the center portion of the frame. Most center-weighted systems also take additional readings from the surrounding areas, but weight the reading towards the center.

Color Balance (digital camera): The setting in a digital camera that matches the available or artificial light to faithfully renders color.

Color Temperature: Described by the Kelvin scale, which is defined in degrees. It is used as a standard for judging the effect or color cast a certain light source will have on color rendition.


Continuous: The shooting mode that allows for continuous firing without lifting the finger from the shutter release button In tonality, a smooth range of tones from black to white. In autofocus, allowing shutter release regardless of whether subject focus has been attained.

Contrast: The relationship between the lightest and darkest areas in a scene and/or photograph. A small difference means low contrast; a great difference, high contrast. High contrast scenes may cause exposure metering problems; however, their “difficulty” can mean they hold the potential for more expression. In addition, combining bracketed exposures, HDR and tone curve compensation techniques can overcome high contrast challenges, Though contrast is often linked with scene brightness, there can be low contrast in a bright scene and high contrast in dim light. Contrast can also describe attributes of color, composition, and inherent qualities of film and sensors.

Correct Exposure: The combination of aperture and shutter speed that yields a full-toned image and the best possible representation of the scene. The constants in an exposure calculation are the ISO or sensitivity of the sensor and the brightness of the scene; the variables are the aperture and shutter speed.


Dedicated Flash: A flash that coordinates with the camera's exposure, and sometimes focusing, systems. Dedicated flashes may, among other things, automatically pick up the camera’s ISO setting, set the camera sync speed, and "tell" the camera when it’s ready to fire. Flashes dedicated to autofocusing cameras may also vary their angle of flash throw (coverage) according to the lens in use (even with zoom lenses), and emit autofocus beams that aid focusing in very dim light or even total darkness. For outdoor work, dedicated flashes may provide totally automatic fill flash exposure. In short, a dedicated flash can make flash photography as simple as automated natural light photography.

Depth of Field: The zone, or range of distances, within a scene that will record as sharp. Depth of field is influenced by the focal length of the lens in use, the f-stop setting on the lens, and the distance from the camera to the subject. It can be shallow or deep, and can be totally controlled by the photographer. It is one of the most creative and profound image effects available to photographers.

Depth-of-field Preview Button: A switch, button, or electronic push button on SLRs that allows the photographer to preview the depth of field of a selected aperture in the viewfinder. During composition the lens is wide open, thus the depth of field in the viewfinder is always that of the maximum aperture of the lens. DOF Preview is very useful for critical selective focus shots.

Dynamic Range: The ability of a sensor to record a certain range of light.

Electronic Flash: Known as a flashgun, strobe, or speedlight, a device consisting of a gas-filled tube that is fired by an electrical charge. It can be mounted directly on the camera hot shoe (which links the shutter release to the flash firing), or on a bracket or stand, and be connected to the camera via a sync cord or wirelessly through IR beams or radio signals.

Equivalent Exposure: Recording the same amount of light, even though aperture and shutter speeds have shifted. For example, an exposure of f/11 at 1/125 second is equivalent to an exposure of f/8 at 1/250 second.

Exposure: The amount of light that enters the lens and strikes the sensor. Exposures are broken down into aperture, which is the diameter of the opening of the lens, and shutter speed, which is the amount of time the light strikes the film. Thus, exposure is a combination of the intensity and duration of light.

Exposure Compensation Control: A camera function that allows for overriding the automatic exposure reading. The bias, or shift, can be set in full or partial stops. Used in difficult lighting conditions, when the reflective meter might fail (that is, dark or bright value dominance), or for deliberate under- or overexposure of a scene. Can also be used to bracket exposures.

Exposure Meter: Light-reading instrument that yields signals that are translated to f-stops and shutter speeds.

EV Numbers: A system of expressing exposure that combines apertures and shutter speed. Scene brightness translated to aperture and shutter speed values. For example, EV 15 at ISO 100 might mean 1/1000 second at f/5.6, or 1/500 second at f/8. EV numbers are often used as shorthand for the combined aperture and shutter speed value combinations and are used for making exposure compensation, when doing autoexposure bracketing or for readouts of exposure.

Very Selective Focus

There are a number of lenses that allow you to break the rules of depth of field. Because you can shift and tilt these lenses on an unusual axis not parallel to the image sensor, you can correspondingly tilt (up and down) and shift (side to side) the planes of focus in the photo. This technique is often used by large format, view camera photographers to attain unusually deep depth of field, where the shifts and tilts can be coordinated between both the front (lens stage) and back of the camera itself. Because the back of a DSLR is rigid there is less freedom of movement, and while specialty lenses can be used to create very deep depth of field, I use them for creating an almost angular plane of focus, thus a very shallow depth of field and “odd” focusing effects. What is most unusual is that these lenses allow you to turn the rules of depth of field on their head, if you will, by allowing you to have sharpness in, for example, one subject six feet away on the right side of the frame while another subject six feet away on the left side is quite unsharp.

While you can attain this effect via software, shooting with lenses that mount on your camera in the field is a much more visceral and engaging activity. I have used two types of lenses for this work-- “Lensbabys”, with various options for effects and operation, and a PC (perspective control) lens. Both are available for most every make of DSLR. They require manual focusing but usually can be used with automatic exposure, albeit with some occasional exposure compensation required.

PC lenses have a tilt and shift mechanism with various knobs and locks on the barrel. This allows you to tilt the lens to and fro and shift plus and minus. If you look at the back of the lens you will notice the rear element is recessed into the barrel. This so-called retrofocus-type construction allows the lens to be swung to and fro because the coverage of the lens circle exceeds the diameter of the sensor or film. Most of these pricey lenses are constructed so the tilts and shifts do not cause excessive vignetting, although you should watch for that with some more extreme movements.

You can play with the planes of focus in odd ways with one of the Lensbabys (www.lensbaby.com). This replaces the normal lens directly on your camera and allows you to shift the focusing planes so they are not parallel to the camera, something that is at odds with how we think about photographic sharpness. You do this by literally twisting or pressing down on one side of the lens; the bellows in the mount give way to make the lens surfaces sit at odd angles to the sensor. The lens can be shot wide open (usually about f/2.8) as supplied, or you can insert small diaphragms that create various aperture settings. I usually don’t use those stops as I want as shallow a plane of focus as possible.

Tools: PC (perspective control) lens or one of the Lensbaby models. Live View if available. Aperture priority or manual exposure mode. Manual focusing.

Depth of Field

The aperture setting determines the “thickness of the pipe” through which light flows, thus the volume of light and exposure. But as, if not more importantly it influences depth of field, thus plays a major part in creative focusing decisions.

You can think of depth of field as a grid of distance markers from the front to the back of your photo, sort of like a football field. When you make different aperture settings you are influencing how sharp objects at the ten, twenty, thirty yard lines, etc, will be. You are also influencing how sharp they will be in relation to the point or distance you actually have focus set.

Some settings will make the difference of sharpness between, say, the ten and thirty yard lines quite dramatic, and others will make it less so, and others will eliminate any sharpness difference between those distant points.

How can we control the fact that this image shows sharp foreground trees as well as the massive falls miles away? That’s the kind of control depth of field gives you. With a 24mm lens, exposure at ISO 250 was f/9 at 1/125 second.

Obsolete So Soon? A Look Back at Early Digicams

The rush of events in the past few years has left us all fairly breathless, what with the pace of change wrought by digital. As product trumps product, and new operating systems and formats rush to grab our attention, older systems and gear quickly fall by the wayside. Some have come to rest in my Museum of Photographic Obsolescence (MOPO). The halls of that hallowed institution have become quite crowded of late; a new wing is being built as you read this.

You needn’t go too far back to find tech and gear that vie for space in that exhibition hall. Look through the back booths of a book store and you might find a few ragged copies of 1940-1950 era Pop Photo or even good old Modern Photography and been amused by the proliferation of ads for movie projectors, tape recorders and even some old Federal enlargers, once staples on a dealers’ shelves. But I didn’t have to reach that far back to find some goodies and more recent exhibits for the MOPO; indeed, many came to the fore when I did some spring cleaning recently and discovered some clippings from writings past. I thought you might get a kick out of some of the hyperbole and prognostications.

Here’s one, from July of 1984. The lead reads: “Eastman Kodak Company announced its entry into the consumer electronics field at CES last January when it introduced the Kodavision Series 2000 video system.” According to then VP Roger Sharp, ‘Most reactions from dealers indicate they are particularly happy to see ½ inch video cassettes on their shelves... It will provide another incentive by making it easier for people to take electronic home movies and play them back through their VCRs.” Along with a classic hardware entry into the Halls of the MOPO, I counted one major technology and one format that went down the tubes from that release. (Anyone recall Polavision? Yes, that’s in the days when marketers didn’t capitalize mid-word.)

In the same year, there was some prognostication that was not too far off the mark. Buried about five paragraphs down from a frothy lead about the future of video still cameras, Mikio Ashikawa of Toshiba was quoted as reporting that to overcome the resolution hurdle, video still cameras might catch up to film by “not increasing the pixels but in electronic rearrangement of the available information, that is, image enhancement through computers.” The movement of that enhancement from desktop to inside the camera is what marks digital imaging today.

The article goes on to say, “Many scientists (at the SPSE conference in 1984) feel that electronics and film will make a happy marriage, with film serving as the input and electronics taking care of the processing side of the business. One scenario is that film, once developed, would be scanned by a device that converts the information into digital form and then that data would be put through various image producing and enhancing channels.” Well, that wasn’t too bad, even in 1984.

It’s always fun to read ad and promotional copy from years past, only because some of it seems almost naïve in light of what we’re experiencing today. I quote from Nikon copy from 1999 not to pick on Nikon, but to illustrate how quickly things have changed. Indeed, everyone was caught up in the same game.

After a flurry of promotional matters the copy goes on to say: “Now, Nikon asserts that (digital photography) leadership again with the announcement of two new digital cameras—the Coolpix 950 and 700—both of which break the 2 megapixel barrier in the affordable, under $1000 digital camera category. This means that photographers can now record uncompressed TIFF images as large as 6MB, resulting in never-before seen quality in affordable cameras.” The changes this press material mark from just eleven years back are glaring. The 2MP cameras are now gone, or relegated to toys; that model category, though non-existent today, would be probably $1300 in 2009 dollars; the camera, if sold now, would probably be 10% of the then asked for price of “under $1000”; and of course TIFF as an in-camera format has for the most part gone away. The memory cards of the time were also quite expensive, and those prices have dropped 80-90% from 1999 as well.

And while we’re on cameras, just for fun I pulled a 1987 PMA report that breathlessly reported “tremendous gains in the electronic still photography field in the past year.” Known then as ESP (electronic still photography) there was the Panasonic Photovision 3100, which recorded 300K images on a 47mm video floppy disk; the Konica SV-C40 (another 300K unit which could fire off four frames per second in the “higher resolution” frame mode); and the Fujix ES-2P, which delivers “380K images, resulting in higher picture quality than most similar cameras.” These video still cameras have a special hall in the evolutionary exhibits in our MOPO.

One of the most interesting pieces from the yellowing archives was an interview done with Robert C. Davis, then president of Bremson Data Systems, in 1985. In response to what we might see in 1995 (ten years from the date of that interview), Davis said: “The big question on everyone’s mind is whether silver halide based imaging is going away. Everyone’s concerned with that…You may get a system where you dump in a roll of film at one end and out the other will come pictures and negatives all wrapped together, and in between you may get a videotape and a video disk along with it. At that point a (pro) photographer may be showing his proofs on a video screen...The professional may begin to use electronic cameras in the studio. We may get a cartridge, or a floppy disk, and put it in a processor and out will come 11x14s to wallet packages. Package work may bypass film. It all depends on how fast the U.S. and Japan will develop the chips necessary to do that—there’s still the resolution problem to deal with.” Most prescient for 1985 eh?

The mid-eighties saw digital photography as just a glimmer in some engineers’ eyes. In each sector—camera makers and photo processors—the groundwork was being laid for the coming sea changes in photography. The point of me bringing all this up is that we might just be in a similar period today. The changes wrought over event he past three years are incredible. We even have people today who are quite avid photographers who never exposed a picture on a roll of film in their life. Where this might lead, and what formats, gear and technology that are now the hot items will be new entrants in our MOPO, is anyone’s guess. But we can all rest assured that what we see as breakthroughs today will be quickly overtaken by what’s just around the corner. And we might look back in 2030 with similar amusement about how naïve it all seems in 2010. Or will we gain that perspective by 2011?

Creative Focus: Part 1

At first glance it would seem that focusing is a simple matter. You look through the lens, press the shutter release button to activate the autofocus mechanism and make the photograph. Or, when using a manual focus lens, merely turn the focusing collar on the lens until the image seems sharp in the viewfinder, and then press the shutter release. This would work fine if we lived in a two-dimensional world. Yet subjects in most scenes sit different distances from one another. Some may be close together while others could be miles apart. Working with focusing techniques you can either make subjects at great distances appear sharp within the picture or have a background that is as close as a foot to your subject appear unsharp.

Focusing is one of the most important creative options. The technique for creative focusing play is called selective focus or depth of field, and it is based on the idea of “circles of confusion”, or what our eyes perceive as sharp and unsharp in an image.

Think of a magnifying lens slanted toward the sun and a piece of paper receiving the rays of light through the lens. As you move the lens back and forth the rays from the sun form a circle or a point on the paper. When a lens is mounted on a camera it directs light toward the film or sensor. Those rays that converge on the film or sensor at a point, or at a near point, are what we perceive as sharp in the image. Those that form a circle beyond a certain diameter are perceived as unsharp in the image.

Our eyes tolerate a certain diameter of circle, or “blob” as being sharp. We do this at a certain distance and with a certain degree of magnification of the image. Change the viewing distance and/or the magnification and what appeared as sharp might later seem unsharp. That’s why when we enlarge prints that looked good in a snapshot size print (4 x 6 inches) to 11 x 14 inches the print may look slightly unsharp. Close inspection of image before enlargement can help prevent this problem.

Next: Viewfinders and Live View

Photo and Text copyright George Schaub 2010. Depth of field controls set up what is sharp and unsharp in the photograph. A deep depth of field, as shown here, means the eye perceives everything from front to back as in focus, or sharp.

An Occassional Glossary: A, B

AMBIENT LIGHT: The light in the scene, as opposed to the light provided by the photographer with flash, photofloods, etc.

ANGLE OF VIEW: The maximum angle a lens covers in the field. Measured in degrees, and qualified by terms such as wide-angle, normal, and telephoto. A wide angle lens has a wider angle of view than a telephoto lens.

APERTURE: The opening of a lens, the size of which is controlled by a diaphragm. The term aperture is also used to designate f-stops, such as f/4, f/5.6 etc. Actual aperture size may be different on different lenses but always allow in the same amount of light. Thus, f/11 on a 110mm focal length lens allows in the same amount of light as f/11 on a 28mm lens. The wider the opening, the lower the f-number, the more light is let through the lens.

APERTURE PRIORITY: An autoexposure mode in which you select the aperture and the exposure system selects the appropriate shutter speed for a correct exposure. Sometimes referred to as Av or simply A on exposure mode control panels.

ARTIFICIAL LIGHT: Any light not directly produced by the sun. Can be tungsten, flash, household bulbs, sodium vapor street lamps, etc.

AUTOEXPOSURE: A method of exposure where aperture and shutter speed settings are first read, then set, by the camera itself. Various autoexposure modes allow you to customize, or bias the automation.

AUTOEXPOSURE LOCK: A pushbutton, switch, or lever that locks in exposure after you have made a reading, regardless of a change in camera position or light conditions. Useful for making highlight or shadow readings of select portions of the frame, and an essential feature for critical exposure control with automated cameras.

AUTOFOCUS: A method of focusing where focusing distances are set automatically. In SLRs, a passive phase detection system that compares contrast and edge of subjects within the confines of the autofocus brackets in the viewfinder and automatically sets focusing distance on the lens. Autofocusing motors may be in the camera body or the lens itself. Active IR (infrared) autofocusing systems may also be in some cameras in the form of beams that are emitted from the camera or flash, bounce off the subject, then return and set focusing range, and are used when light or contrast is too low for the passive system to work.

AUXILIARY LENS: An add-on optical device that alters the focal length of the prime lens for closeup, telephoto, or other special effects photography. Closeup lenses, for example, usually comes in +1, +2, and +3 powers; the higher the number the greater the magnification. As differentiated from Lensbaby optics, auxiliary lenses are usually added onto the camera lens via the threads on the lens collar.

AUXILIARY LIGHT: A flash, strobe, or tungsten lamp or bulbs used to change the character of light in a scene. Any light under the control of the photographer.

AVAILABLE LIGHT: The light that's normal in a scene, although the term is generally used when the light level is low. Available light shooting usually involves high ISO settings, low shutter speeds and apertures, and/or the use of a tripod.

AVERAGING: In light metering, a metering setup where the light is read from most of the viewfinder frame (70%) then averaged to yield an overall, standard exposure for the scene that averages all the values read to middle gray.

B or BULB: A shutter setting that indicates that the shutter will remain open for as long as the shutter release is pressed. The term originated with the rubber air shutter bulbs used to operate shutters in the old days. B settings are generally used in nighttime and time/motion study photography.

BACKGROUND: The portion of a scene that sits behind the main, foreground subject. We can make the background sharp or de-focused through the use of selective focus techniques.

BACKLIGHTING: From camera position, light that comes from behind the subject. Usually, a backlit main subject will be underexposed unless the metering system is set to read selectively off the subject. Extreme backlighting can be exploited to create silhouettes.

BATTERY: The power supply of the camera and flash. In many of today's cameras (and certainly in flashes), no power means no pictures.

BLACK-AND-WHITE: Monochrome images. Though we think of black and white mainly in terms of a grayscale, monochrome images can have a wide variety of subtle tones, from blue- to brown-black.

BLUR: Unsharpness because of the movement of the camera or subject during exposure. Though we usually want images sharp, blur can be used for many creative effects.

BOUNCE LIGHT: In flash photography, directing the burst of light from the flash so it literally bounces off a ceiling, wall, or other surface to illuminate the subject. This method of flash is often preferred because it softens the overall light and eliminates the harsh, frontal look of an on-camera, straightforward flash.

BRACKET: Making exposures above and below the normal exposure, or that which is suggested by the camera's autoexposure system. Useful as a failsafe method for getting "correct" exposure in difficult lighting conditions. Bracketing can also be used to make subtle changes in the nuance of tone and light in any scene and is an essential ingredient in HDR processing.

BRIGHTNESS: The luminance of objects. The brightness of any area of the subject is dependent on how much light falls on it and how reflective it is. Brightness range is the relationship we perceive between the light and dark subjects in a scene. Brightness contrast is a judgement of the relative measure of that range, such as high, low, or normal.

BURNING-IN: In processing, giving additional density (dark tones) to a portion of a print or image.

BURNT-OUT: Jargon that refers to loss of details in the highlight portion of a scene due to overexposure. It might mean that no image detail has been recorded, or that highlights show no texture or tonal information.

Photo and text: copyright George Schaub 2010. Backlighting is when the main light in the scene sits behind the subject facing camera position. It can be used for creating silhouettes or here as a combination of silhouette and translucent light quality.

Spot Metering

One of the three options you have for a metering pattern, or the area in the viewfinder where the metering system takes its information to calculate an exposure, is known as “spot.” The spot options generally takes its information right from the center of the viewfinder and is often defined by a small, etched circular pattern. Some Custom Functions allow you to define the exact circumference of the spot area or move the spot to match a focusing point.

Because spot metering is quite exclusive it does require that you occasionally use it in conjunction with exposure compensation. Like all metering it converts what it reads to a middle gray, so if you meter a white area and want it to record as white you have to add exposure to the reading; conversely if you meter a very dark area and want it to stay dark as seen then you have to take away exposure.

The best way to add or subtract exposure when using a spot meter is to use the exposure compensation feature. You can preset this at +1.5 when, for example, shooting on a bright snowy day and reading from the brightest areas. This should insure that you get texture in the bright white (although it still might shadows areas to become underexposed.)

Spot metering also aids in making readings from smaller areas within the scene, such as a backlit face. In that case no compensation is required.

The easy rules for spot are:

When you spot bright white add exposure (usually +1 or +1.5EV) if you want to render it bright white in the recording.

When you spot a color you will saturate that color.

Text and photo Copyright George Schaub 2010

To saturate the bright yellow and red here all it takes is placing the spot pattern on the color and locking exposure.

Center-Weighted Metering Pattern

Center-weighted averaging is a bit more “old fashioned” in that it is how light was read, for the most part, before advanced microprocessors got into the mix. The light is read from all parts of the viewfinder, with 70% of the light reading coming from the center of the frame and the remaining 30% of the calculation from the edges of the frame. It is called “averaging” because it takes in all the various brightness levels and then averages them to what is called a “middle gray” exposure reading. This is the basis for much of how metering and translating light value works, so is worth some consideration.

When the metering system receives light from the scene it attempts to average the exposure values so that the bright areas record as bright and the shadows as dark, in essence arranging the light values along a scale of light and dark. Let's say you are working with a scene where there is a range of values, from the bright white in clouds to the deep shadow of a valley. If you read the clouds alone with a spot meter they might read f/11. The edge of the valley might read f/8; the shadow area reads f/5.6. An averaged exposure would be f/8. This “places” the brightest clouds as a highlight, the edge of the formation as the middle value and the deep shadow as quite dark. Thus, exposing at around f/8 places the brightness values as they appear in the scene.

Because the pupil of the camera (the lens opening) is fixed at the moment of exposure, there is no leeway for adjusting to various levels of brightness within the frame. This means that one exposure time has to handle all the lights and darks in a scene, and try to get detail from them all. This is, as you can imagine, a delicate situation. How it is handled is to arrive at an exposure that allows in just enough light to bring detail into the dark areas (the shadows) and not get overwhelmed by the bright areas (the highlights.) This is usually an average of the two intensities of light. The average reading sorts out the lights and darks accordingly so some records as brighter than the average and some darker than the average, as it should be.

Although the exposure system is quite sophisticated you too have to do your part. In essence, the information you “feed” the brain of the meter is the information it acts upon. In exposure that means making a reading by pointing the camera and sometimes locking exposure values to get it right.

For example, let’s say light values EV 11, EV 7 and EV 9 exist in the scene. A change in 1 EV (exposure value) is one stop difference. The average of these three readings is EV 9, which we’ll call f/11 at 1/125 second. That’s the reading the meter will recommend and set for you. EV 9 then becomes the middle gray of the light to dark brightness value, or tonal scale of that image. In essence, the meter has read and set up a range of tones that will be recorded. With EV 9 as the middle gray, EV 11 records as a brighter value and EV 7 as a darker value.

If, however, the reading was made incorrectly and the middle gray was set at EV 7 (which you would get if you just read the shadow areas) then the EV 11 (quite bright) value would record as very bright, and result in overexposure. Conversely, if the middle gray were EV 11 (created if you just read the highlight area) then the EV 7 reading would become much darker than it appears to your eye. All the values work in lock step, so making a bright value a middle gray makes all the dark values darker (and perhaps underexposed, where no detail is seen) and making a dark value middle gray can cause all the bright values to become quite overexposed.

A sunset scene is a classic shot for center-weighted metering. The intent is not to get detail in the ground but to use it as a form that offsets the sky and defines the horizon line. The simplest approach to sunset shots where you want to have a rich sky is to use center-weighted metering, aim the camera at the sky (not the sun!), lock exposure and shoot. Use this method and you’ll never miss a dazzling sunset again.

This might seem quite confusing in the abstract, but working with the camera and making readings exclusively from certain brightness values in the scene, and observing results, will quickly show you how this system works. In fact, you can even make use of this knowledge to create very expressive exposures.

The key to center-weighted reading is to "bias the exposure" towards the highlight. In other words, point the camera towards the highlight area (including other areas as well) and make the reading from that area. This is especially true if the highlight area sits at the corner or out of the center of your framing.

Photo and text copyright George Schaub 2010. In this scene the camera was set on center-weighted metering pattern, pointed towards the brighter area in the upper right, and then exposure was locked and the image reframed to the compositon you see here. Matrix or evaluative would have undoubtedly overexposed the highlights in this scene.

Basics: Lens Aperture

Exposure is controlled by the aperture and the shutter speed settings. The aperture setting also influences depth of field, thus plays a major part in creative focusing decisions. Aperture settings are called f-numbers, and are expressed by "f/" followed by the number of the aperture set.

Aperture settings are indicated on a lens by a series of numbers; with some cameras and lenses there is no aperture scale on the lens barrel and the settings appear in the camera's viewfinder and/or LCD panel. A typical aperture scale might read: 1.4, 2, 2.8, 4, 5.6, 8, 11, 16. Each number indicates the ratio of the actual diaphragm opening to the focal length of the lens in use, thus any same aperture on any lens always allows in the same amount of light. As these are actually fractional numbers the smaller numbers signify larger openings. Thus, f/2 (or 1/2) represents a wider opening (or greater value) than f/16 (or 1/16).

As mentioned, f-numbers represent the same light value regardless of the lens or format in use. Thus, f/2 on a 50mm lens for a 35mm camera delivers the same amount of light through the lens as f/2 on a 200mm lens for a medium-format camera, even though the diameter of the openings themselves are different. If this wasn't the case the entire light control system in photography simply wouldn't work.

Each subsequent number in an aperture scale represents a halving or doubling of the amount of light that the aperture allows through the lens. (You can calculate the next higher number in any one-stop-step scale by multiplying the previous number by 1.4). Each step in the scale (say, from f/2 to f/2.8) is called a stop. Thus, every time you open up or close down the lens by one stop (opening means going to the next lower number, or wider opening; closing down means going to the next higher number, or narrower opening) you are changing the amount of light entering by the power of 2. A one stop change (say, f/8 to f/5.6) is a 2X difference; a two-stop change (sat f/8 to f/4) is a 4X difference; and so forth.

The best way to see how aperture settings effect light transmission is to take the lens off the camera, hold it up to the light and click through the aperture settings. (Note: Some lenses do not allow for aperture changes on the lens itself, but rely on the camera to change apertures,) You'll see that the maximum aperture, say f/2, is the widest opening. As you click through the scale, you'll see the diaphragm in the lens getting smaller. Think of water as it flows through a pipe. Given that the water will always fill the pipe, a larger diameter pipe will allow more water through. This can be applied to light flow and the aperture diameter.

Most lenses and cameras today allow for partial stops, like older lenses with click stops, or detents, between the aperture settings. On older lenses these are half-stops, and though not marked indicate a halfway point between the two aperture numbers on the ring. On newer lenses you can have 1/3, 1/4 or other fractional spreads. These step-less aperture settings means any value can be set, such as f/9.7 or f/11.3. These values are indicated in the camera viewfinder and/or the LCD panel on the camera.

Aperture rings are usually inscribed with all the available full stop settings on the lens, from the maximum, or widest, to minimum, or narrowest lens opening. The range of the aperture scale may differ depending upon the construction of the lens and its focal length. One scale may read f/2, 2.8, 4, 5.6, 8, 11, 16, while another may read f/4, 5.6,8, 11, 16, 22, 32 (the latter is more typical of zoom or telephoto lenses.) The lowest number in the scale (thus the widest opening) is called the maximum aperture; the highest number on the scale (thus the narrowest opening) is called the minimum aperture.

Photo and text copyright George Schaub 2010. Aperture settings allow you to control the depth of field, what appears sharp and unsharp in your photo. To get focus from foreground to background here an f/16 setting was used.

Color and Light

The overall quality of the light source can have a profound effect on color perception. Light and dark tints of color that in flat light would show as one hue become more differentiated in bright light--the effect of color contrast. Yet, if that light is too bright and the surface is glossy we will get greater interference, thus some of the color that we might see in flat light becomes "washed out" or replaced by white. If the surface is matte the reflection becomes more diffuse we see more color. Thus, the greater the surface reflection the less the color richness or saturation we perceive. Rough surfaces throw off all sorts of reflections that can vary the color in many ways.

Atmospheric effects also alter color. If you look at a range of mountains from a distance, for example, you see them as blue. When you walk or drive closer to them, however, you see them as green, or red or whatever color they might be.

The same goes for the color changes subjects seem to undergo throughout the day. The inherent color, if you will, of sandstone formations do not change but we all know that photographing those formations late in the day, on a clear day, will yield the most spectacular results. Those afternoon colors are influenced by the prevailing light. Their amber tint results from the color bias of the light as it travels longer distances later in the day.

The color of any one thing does not exist in a vacuum. It is influenced by the color of subjects around it and how those subjects absorb and reflect light. It's as if we exist in a world of color mirrors and reflectors that bounce light from one subject to another. This sets up the world of color relationships and creates many of the color enhancing vibrations and associations we see around us.

In short, the way we see color is almost subjective--it is certainly conditional. Just as brightness is influenced by a host of factors, color itself is always changing and being affected by the energy around it.

The color mood of this image is affected greatly by atmospheric conditions. Photo and text copyright George Schaub 2010

Looking at Scene Contrast

The main issue in making good exposures in high contrast scenes is learning the difference between how your eye “sees” and handles contrast and how the sensor “sees” and records brightness values. Contrast is defined as the difference between the brightest and darkest areas in a scene. In photography the areas that define a usable contrast range are those in which you can see and record detail and tonal values; the compositional decisions often involve how you treat those brightness areas that fall outside this range.

For example, if you photograph a white car in bright light you would want texture and tonal value in the car body and details and perhaps even in the tire tread. But you might not care about the details in the asphalt that sits in the shadow of the car. Or, if you’re taking a portrait in bright light you’ll want good skin tones values in your subject but may not care about information (details) in the shadow he or she casts. When we talk about a usable contrast range we are talking about those areas that you want to record and not those that may also be in the scene but that can fall into tone without detail, like a deep shadow. We can call this usable range of values the "significant" tones, with the brightest in which you want texture the significant highlight and the darkest in which you want detail the significant shadow.

If you take an exposure reading of just the significant highlight you are placing that highlight on the middle of the recording scale—-in essence, you are telling the exposure system that you want the highlight to record darker than it appears in the scene.

And, if you take a reading of just the significant shadow area (like in the image shown here) you will be recording it as brighter than it appears in the scene. This throws off the balance of brightness values in recordings where there are both bright and dark values. If you make a reading of and record the darker areas alone it will cause the brighter areas to “burn up” and become overexposed, just like the side of the building here.

If you want to make a quick test of how making readings from the lighter or darker parts of the scene affects your results, set up a bracketing sequence at +/-2 EV and take three pictures of a brightly lit scene with shadows and highlights. One exposure may average the two values, one will expose for the highlights and one for the shadows. You’ll see how making exposures for just a certain part of the brightness scale affects the other areas.

Photo and text copyright George Schaub 2010. Exposure here was read from the shadow areas. The result in a high contrast scene such as this is fairly substantial overexposure of the highlights, never a good thing in digital (or film) photography.