Roper Photometric Security Camera User Manual


 
Chapter 3. Advanced CCD Theory 37
CCD Camera
Implementations
To take advantage of the high performance a CCD has to offer, special slow-scan
or still-imaging cameras have been designed to operate at a significantly lower
speed than conventional video cameras. These cameras bring together several
diverse technologies: high-performance signal processors, solid-state coolers,
precision digitizers, and high-speed digital controllers. The benefits of slow-
scan readout are ultra-low noise, maximum CCD performance, and photometric
precision in the image data.
A precision analog processing circuit and analog-to-digital converter are
employed to amplify and digitize the CCD output signal. CCD readout may
take from one tenth of a second up to several seconds, as each pixel is digitized
with up to 16-bit precision. The digitized electronic image read out from the
CCD can be stored in a computer’s memory. Slow-scan camera systems produce
large quantities of data. A 2000 x 2000 pixel CCD with a dynamic range of
20,000:1 requires eight megabytes of storage for each image.
Cooling the CCD reduces dark current to negligible levels, allowing exposure
times of up to hours in duration. To achieve the highest possible sensitivity,
astronomers cool the CCD with liquid nitrogen, eliminating the dark current
produced by thermal generation at warmer temperatures. High energy
physicists, on the other hand, use CCDs in ultra-high-speed cameras to observe
transient phenomena where dark current is not relevant.
A conventional shutter can be used to acquire exposures as brief as a few
milliseconds or as long as an hour; a microchannel plate image intensifier can be
used to gate exposures of a few nanoseconds.
Resolution
The resolution of a CCD camera is determined by the geometry of the specific
CCD in use. The CCD pixels set the limit of resolution. In scientific-grade CCDs,
a pixel varies in size from a few micrometers up to 48 µm; the total imaging area
is 1 to 24 cm
2
. In order to avoid aliasing, moiré, or beat frequencies, the
magnification must be chosen so that at least two CCD pixels cover a desired
resolution element in the image plane.
There is no dead space between pixels. Charge generated by photons striking
the CCD between pixels diffuses to the nearest potential well. This is referred to
as “fill factor.”
Sensitivity
The sensitivity of a CCD imager to light is determined by system noise level
(discussed later in this chapter) and quantum efficiency.
Quantum efficiency measures the sensor’s efficiency in generating electronic
charge from incident photons. Electron-hole pairs are produced by photons in
the region from 400 to 1100 nm. Within the visible spectrum, the photon to
electron conversion factor is less than unity and it varies as a function of
wavelength. At a given wavelength, the creation of charge from incident light is
intrinsically linear.