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The CCD detector

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The CCD detector. Sami Dib, Max-Planck-Institute ... It seems that this near-infrared (8900 ) picture of Uranus was the first ... 3 How does a CCD work? ( 1) ... – PowerPoint PPT presentation

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Title: The CCD detector

1
The CCD detector

Sami Dib, Max-Planck-Institute for Astronomy,
Heidelberg
Jean Surdej, Institut dAstrophysique et de
Géophysique, Liège
modified by
Martin Hennemann, Stefan Hippler and Jutta
Stegmaier (2006)
1 Introduction
2 History of the CCD
3 How does a CCD work ?
4 Advantages of CCDs
5 Observations with a CCD

2
1 Introduction

It seems that this near-infrared (8900 Å)
picture of Uranus was the first celestial object
to be photographed by a CCD in 1975 by
astronomers at the JPL and University of Arizona.
This image has been obtained by the 61 inch
telescopes located at Santa Catalina mountains
near Tucson (Arizona). The dark region in the
image correspond to an absorption region with
some Methane bands close to the southern pole of
Uranus.
3
2 History

In 1969 Willard S. Boyle and George E. Smith,
while working at Bell Laboratories, designed the
first Charge Coupled Device (CCD), a working
version was produced just a year later. The CCD
has become the bedrock of the digital imaging
revolution including digital photography and
video. In January 2006 they have been honored
with the Charles Stark Draper Prize which is
presented by the National Academy of Engineering.
4
3 How does a CCD work? (1)

Determining the distribution of an astronomical
object (star, planet, galaxy, a martian
spacecraft (?)) with the help of a CCD is
similar to measuring the quantity of infalling
rain on a field. As soon as the rain stops,
collecting buckets are displaced horizontally on
conveyor belts. Then the water content of the
buckets is collected in other buckets on a
vertical conveyor belt. The overall content is
sent onto a weighting system.
5
3 How does a CCD work? (2)

output register
pixel
(a)
(b)
to output amplifier
electrodes
electrons
The way a CCD works is illustrated by means of a
simplified CCD made out of 9 pixels, an output
register and an amplifier. Each pixel is divided
into 3 regions (electrodes who create a potential
well). (a) For the charge collection process
during an exposure the central electrode of each
pixel is maintained at a higher potential
(yellow) than the others (green). (b) At the end
of the exposure, the electrodes potentials are
changed and the charges transferred from one
electrode to the other.
6
3 How does a CCD work? (3)
(b)
(a)
impurity (doping)

By changing the potential of the electrodes in a
synchronized way, electrons are transferred from
pixel to pixel. Charges on the right are guided
to the output register
(b) The horizontal transfer of charges is then
stopped and each charge package at the output
register is transferred vertically to an output
amplifier and then read one by one. The cycle
starts again until all the charges have been
read. The reading time amounts to about one
minute for a large CCD.

7
4 Advantages of CCDs (1)

1) Good spatial resolution
2) Very high quantum efficiency
3) Large spectral window
4) Very low noise
5) Large variations in the signal strength
allowed (high dynamic range)
6) High photometric precision
7) Very good linearity
8) A reliable rigidity

8
4 Advantages of CCDs (2)

Spatial Resolution

Mosaic of 4 CCDs containing four times 2040 x
2048 pixels. This composite detector is about 6
cm large and contains a total of 16 millions
pixels (Kitt Peak National Observatory, Arizona).
9
4 Advantages of CCDs (3)

Quantum Efficiency

Above you see several quantum efficiency curves
of different types of CCDs as a function of the
wavelength. The large domain of wavelengths for
the spectral response of CCDs becomes obvious.
10
4 Advantages of CCDs (4)

Spectral
Range
FI front
illuminated
BN back
illuminated, no
coating
DD deep
depletion

11
4 Advantages of CCDs (5)

Linearity and Dynamic Range

Dynamic range ratio between brightest and
faintest detectable signal
CCDs are extremely linear detectors, i.e., the
received signal increases linearly with the
exposure time (see figure on the left). Therefore
CCDs enable the simultaneous detection of both
very faint and very bright objects. In contrast
photographic plates have a very limited linear
regime there is a minimum exposure time for an
image of an object to form. Further on during the
exposure, the image gets saturated quickly
(S-shape gamma curve). The dynamic range of CCDs
is about 100 times larger compared to films.
12
4 Advantages of CCDs (6)

Flat field technique

(b)
(c)
(a)
13
5 Observations with a CCD (1)
4 exposures of the galaxy M100 with exposure
times of 1, 10, 100 and 1000 seconds (obtained
with a 11 inch Celestron telescope).
14
5 Observations with a CCD (2)

5.1 Subtraction of the bias

Processed image
Raw image ...
15
5 Observations with a CCD (3)

5.2 The darks (1)
Sn(t) Rn0 2(T - T0) / ?T t (5.2.1)

16
5 Observations with a CCD (4)

5.2 The darks (2)
ST n S and NT2 (n N2)
(5.2.2)
ST / NT (S / N) ?n
(5.2.3)
S Sa - ST and N ?(Na2 NT2)
(5.2.4)
S / N (Sa - ST) / ?(Na2 NT2) (5.2.5)

17
5 Observations with a CCD (5)

5.3 The flat field technique (1)
S So / Sf
(5.3.1)
(S/N) 1 / ?(No/So)2 (Nf/Sf)2
(5.3.2)

18
5 Observations with a CCD (6)

5.3 The flat field technique (2)

Raw image (left) from which we subtract the Bias
image (middle) and the dark image (right).
We then divide the obtained result by the flat
field image (left) and obtain the final image
(right).
19
5 Observations with a CCD (7)