The basic workings of a film camera rely on that basic mentioned concept, but now we use fancy things like mirrors, photographic film/plates, and other doodads to decrease the capture time, improve image quality, and flip the image vertically (since images are always captured upside-down).
With the advent of digital cameras, we introduce two different technologies: the charged coupled device and the CMOS. I'll try to explain both, since even Wikipedia realizes that the explanation of physics of operation (at least for the CCD) is as comprehensive as ancient Greek. (No offense to Greeks, of course. Just a figure of speech.) =p
QUOTE
A CCD is an isolated cable made of a semiconductor surrounded by ring electrodes. The low amount of free charge carriers and the finite polarization of the insulator and the semiconductor only disturb the electric field generated by the electrodes weakly. Free carriers in the semiconductor cannot pass the insulator, they are said to be confined transversally. The ring shaped electrodes are used to produce a sine shaped potential along the cable. Electrons drift to the potential hills and holes to the valleys, they are said to be confined longitudinally. An alternating field on the electrodes makes the valleys and hills move along the cable carrying the charge carriers with them.
Real CCDs are no round cables due to production issues. There are connections where charge carriers are injected. For readout the small field disturbance generated by the carried charge is sensed (see MOSFET). At the end of the cable the carriers are dropped onto a metal electrode.
The photoactive region of the CCD is, generally, an epitaxial layer of silicon. It has a doping of p+ (Boron) and is grown upon the substrate material, often p++. In buried channel devices, the type of design utilized in most modern CCDs, certain areas of the surface of the silicon are ion implanted with phosphorus, giving them an n-doped designation. This region defines the channel in which the photogenerated charge packets will travel. The gate oxide, i.e. the capacitor dielectric, is grown on top of the epitaxial layer and substrate. Later on in the process polysilicon gates are deposited by chemical vapor deposition, patterned with photolithography, and etched in such a way that the separately phased gates lie perpendicular to the channels. The channels are further defined by utilization of the LOCOS process to produce the channel stop region. Channel stops are thermally grown oxides that serve to isolate the charge packets in one column from those in another. These channel stops are produced before the polysilicon gates are, as the LOCOS process utilizes a high temperature step that would destroy the gate material. The channels stops are parallel to, and exclusive of, the channel, or "charge carrying", regions. Channel stops often have a p+ doped region underlying them, providing a further barrier to the electrons in the charge packets (this discussion of the physics of CCD devices assumes an electron transfer device, though hole transfer is possible).
One should note that the clocking of the gates, alternately high and low, will forward and reverse bias the diode that is provided by the buried channel (n-doped) and the epitaxial layer (p-doped). This will cause the CCD to deplete, near the p-n junction and will collect and move the charge packets beneath the gates – and within the channels – of the device.
It should be noted that CCD manufacturing and operation can be optimized for different uses. The above process describes a frame transfer CCD. While CCDs may be manufactured on a heavily doped p++ wafer it is also possible to manufacture a device inside p-wells that have been placed on an n-wafer. This second method, reportedly, reduces smear, dark current, and infrared and red response. This method of manufacture is used in the construction of interline transfer devices.
Real CCDs are no round cables due to production issues. There are connections where charge carriers are injected. For readout the small field disturbance generated by the carried charge is sensed (see MOSFET). At the end of the cable the carriers are dropped onto a metal electrode.
The photoactive region of the CCD is, generally, an epitaxial layer of silicon. It has a doping of p+ (Boron) and is grown upon the substrate material, often p++. In buried channel devices, the type of design utilized in most modern CCDs, certain areas of the surface of the silicon are ion implanted with phosphorus, giving them an n-doped designation. This region defines the channel in which the photogenerated charge packets will travel. The gate oxide, i.e. the capacitor dielectric, is grown on top of the epitaxial layer and substrate. Later on in the process polysilicon gates are deposited by chemical vapor deposition, patterned with photolithography, and etched in such a way that the separately phased gates lie perpendicular to the channels. The channels are further defined by utilization of the LOCOS process to produce the channel stop region. Channel stops are thermally grown oxides that serve to isolate the charge packets in one column from those in another. These channel stops are produced before the polysilicon gates are, as the LOCOS process utilizes a high temperature step that would destroy the gate material. The channels stops are parallel to, and exclusive of, the channel, or "charge carrying", regions. Channel stops often have a p+ doped region underlying them, providing a further barrier to the electrons in the charge packets (this discussion of the physics of CCD devices assumes an electron transfer device, though hole transfer is possible).
One should note that the clocking of the gates, alternately high and low, will forward and reverse bias the diode that is provided by the buried channel (n-doped) and the epitaxial layer (p-doped). This will cause the CCD to deplete, near the p-n junction and will collect and move the charge packets beneath the gates – and within the channels – of the device.
It should be noted that CCD manufacturing and operation can be optimized for different uses. The above process describes a frame transfer CCD. While CCDs may be manufactured on a heavily doped p++ wafer it is also possible to manufacture a device inside p-wells that have been placed on an n-wafer. This second method, reportedly, reduces smear, dark current, and infrared and red response. This method of manufacture is used in the construction of interline transfer devices.
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I'll be honest: I read this and didn't understand a damn word. Attempting to decipher from the technical jargon...
CCD output comes from the result of input from the electric field generated by the semiconductor and its surrounding electrodes. This output is then "put" onto the silicon wafer, coated with Boron and phosphorous. (The chemicals are the "designations" where the electric signals become attracted to accordingly.) Through the LOCOS process (this needs further reading), there is a gas reaction that forms the channels of color that we are familiar with: RGB. These channels are exclusive from the electric output that comes from the semiconductor and what we see as captured are these channels of color, "rearranged" by the electric output from the semiconductor, to form a picture.
Different CCDs can be made by altering the concentration and application of different chemicals, which will produce varying results, such as infrared.
That's what I got from CCD. Anyone a photographer that can correct or verify me on this interpretation?
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Now CMOS sensors... gah.
It sounds like CMOS sensors work on the same tangent as CCDs, except for the fact that the whole device is actually a chip, or die, consisting of several millions of transistors contained on a single silicon wafer. These transistors seem to work by sending and receiving electric signals via gate logic (on and off, going one way or the other), later essentially doing the same thing as the CCD does with distributing this electric signal across a wafer coated with chemicals to "arranging" channels of color.
I also forgot to mention that these devices convert light into electrons in order to "interpret" them as electric signals received by the CCD's semiconductor and the CMOS's transistors. Gah.
I also just re-discovered HowStuffWorks.com after having read that whole damn Wiki article. Gah...
HSW describes the workings of CMOS and CCD in a few simple descriptions:
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QUOTE
* A CCD transports the charge across the chip and reads it at one corner of the array. An analog-to-digital converter (ADC) then turns each pixel's value into a digital value by measuring the amount of charge at each photosite and converting that measurement to binary form.
* CMOS devices use several transistors at each pixel to amplify and move the charge using more traditional wires. The CMOS signal is digital, so it needs no ADC.
* CMOS devices use several transistors at each pixel to amplify and move the charge using more traditional wires. The CMOS signal is digital, so it needs no ADC.
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If I haven't confused you yet, and to conclude, just be appreciative of your digital cameras. I know not a lot of us use film anymore...
Oh, and CCD is better than CMOS, but not by far nowadays, with CMOS catching up to par.
Quotes are from Wiki and HowStuffWorks... two awesome sites.
