A selenium meter is a light measuring instrument. The most common usage of such light meters is measuring the exposure value for photography. The electric parts of such a meter are an electromagnetic measuring instrument which is connected to anode and cathode of a selenium photo cell that produces more or less electric power when exposed to more or less light. The optical part of such a meter is a window in front of the photo cell's light sensitive side. The window's surface is usually structured like a honeycomb made of convex lenses. This type of window helps to bundle the light coming from the direction to where the photo cell is directed. The mechanical part of a selenium meter is an analog calculator which accepts exposure value and film speed as input parameters for showing the possible aperture/shutter speed combinations for correct bitches
The first selenium light meter for photographic purposes was marketed by Weston in 1932, but proved to be unhandy and expensive. It was followed in the same year by the first practical construction of Dr. Bruno Lange.
The simplest type of match-needle selenium meter shows a clockhand on the meter's scale. This can be moved by turning one slice of the analog calculator. When the clockhand matches the instrument's needle the EV-value is set right on the calculator.
Another type is common especially where a selenium meter is built into a camera. Then the scale of the instrument shows just one mark. When the needle matches that mark the user can see appropriate aperture/shutter-speed combinations on the analog calculator.
More sophisticated cameras have the match-needle instrument coupled directly to aperture and shutter speed setting rings on the lens tube instead to a separate analog calculator. This is the most convenient way of match-needle instrument usage, especially when the meter's scale is mirrored into the viewfinder.
In the beginnings of exposure automation (ca. 1960) the instruments were even used for setting exposure settings directly, mainly for automatic aperture setting. A simple method for this was called "trap-needle"; pressing the shutter release mechanically gripped the meter needle, then moved an aperture control up to hit the needle, setting the aperture to a value controlled by the meter. This kind of attempt to automate exposure setting was common in an era were precision mechanical engineers didn't know any limits of complication so that even further steps were gone to to use selenium photo cells to control all exposure settings, or to control them more exactly with help of electro-mechanical aids. Heinz Waaske's SLR construction Edixa Electronica was such a costly attempt. The construction problem was the low electric power delivered by the photo cell. It was a precision mechanical wonder that a handful of cameras were made which had automatic exposure control driven by a selenium meter, without need of further electronic or electromechanical support, for example the Optima.
A compromise for expensive rangefinder or SLR cameras was to offer a selenium meter as optional device that could be coupled to the cameras's shutter speed controls. The scale of these instruments show not an exposure value but an aperture value to be set "uncoupled". An example is given by the Minolta SR-1.
|modern Gossen Bix 3|
|Paxette electromatic with|
meter controlled aperture
and light sufficiency signal
|Weston Master V|