LCD
TFT
LED-OLED
CCD
CMOS
DISPLAY SYSTEMS AND PHOTOSENSORS (PART 4)
Charged Coupled Device(CCD)
Many image sensors: Infrared, gamma ray, x-rays etc. Focus on sensors for visible light (slightly into infrared and uv light)
Michael Thomas, TU Berlin, 2010 Processing Digital Camera Images, WS 2010/2011, Alexa/Eitz 2
CCD and CMOS sensors are normally used for visible lightHave good natural sensitivity in near infrared, usually removes that by filtersCan be specially adapted for other parts of the spectrum e.g. X- rays
The beginnings• Video camera tube sensors in the 1930s•.1969, George Smith ،•First , CCD , Willard Boyl • Fairchild's effort, led by ex-Bell researcher Gil Amelio, was the first with commercial devices, and by 1974 had a linear 500-element device and a 2-D 100 x 100 pixel device. • The first KH-11 KENNAN reconnaissance satellite equipped with charge- coupled device array technology for imaging was launched in December 1976.[6] • Under the leadership of Kazuo Iwama, Sony also started a big development effort on CCDs involving a significant investment. Eventually, Sony managed to mass produce CCDs for their camcorders. Before this happened, Iwama died in August 1982; subsequently, a CCD chip was placed on his tombstone to acknowledge his contribution.[7]
Michael Thomas, TU Berlin, 2010 Processing Digital Camera Images, WS 2010/2011, Alexa/Eitz 3
How to convert light to electric charge? Inner photoelectric-effect at a photodiode: Photon excites electron creating a free electron and a hole The hole moves towards the anode, the electron towards the cathodeNow we have our charge!
Michael Thomas, TU Berlin, 2010 Processing Digital Camera Images, WS 2010/2011, Alexa/Eitz 4
Charge-Coupled Device (CCD)• Integrated circuit• Array of connected capacitors (Shift register)• Charge of capacitor is transfered to neighbour capacitor• At the end of chain, charge is converted into voltage by charge amplifier Transfer stepped by Clock-Signal
CCD has photosites, arranged in a matrix.Each comprises a photodiode which converts light into charge and a charge holding regionThe charges are shifted out of the sensor as a bucket brigade
The A/D conversion is done at the edge of the circuit• Serial charge processing
Michael Thomas, TU Berlin, 2010 Processing Digital Camera Images, WS 2010/2011, Alexa/Eitz 5
• Each capacitor is coupled with a photodiode• All capacitors are charged parallelly• Charges are transferred serially
CCD-Sensor• But how to prevent light to charge up the capacitors while transferring?• Mechanical shutter• Buffer of capacitors that store the charge until it is transferred• Loss of resolution or larger sensor → more expensive
One-or three-chip camera three-chip is usually at least 3 times as expensive
The color filter matrix for one-chip, usually ”Bayer mosaic” Reduces color resolution to about halfAlso reduces light collection efficiencyAnisotropic in x and yA new method invented by Foveon uses “vertical filters” with less resolution loss
• What happens, if too much light hits the sensor?• Capacitors overload• Charge “spills“ over to neighbor capacitors• Blooming effect occurs
CCD:Pro:• No rolling shutter• Lower noise• Good image qualityCon:• Analog device!• Blooming effect
Michael Thomas, TU Berlin, 2010 Processing Digital Camera Images, WS 2010/2011, Alexa/Eitz 12
CCD vs. CMOSCMOS:Pro:• No blooming• Cheaper• Lower power consumption• Faster readoutCon:• Rolling shutter• Variations in brightness (per Pixel)
CMOS IMAGE SENSORS
Presenter: Alireza eyvazzadeh
Complementary metal–oxide–semiconductor
a technology for constructing integrated circuits
CMOS technology is used in MicroprocessorsMicrocontrollersstatic RAMother digital logic circuits
CMOS technology is also used for several analog circuits such as
image sensorsdata converters
Two most common types of sensors used in digital cameras:
CCD - Charge Coupled Device
CMOS - Complementary Metal Oxide Semiconductor
With the CMOS imager both the 'Photon-to-Electron' conversion and the 'Electron-to-Voltage' conversion is done within the pixel
CMOS image sensors
All CCD and CMOS image sensors operate by exploiting the photoelectric effect to convert light into electricity
Some drawbacks of CCDscomplex clocking requirementshigh power consumptiondifficulty of on-chip integration of circuitrylimited frame rate
CMOS image sensors address these drawbacks by using the same technology as microprocessors and memory chips
Advantages and drawbacks of the CMOS image sensorsLow Power Consumption
Also they are still too noisy and less sensitive than CCDs
one-third to more than 100 times less than that of CCDs
Lower cost compared to CCD’s technology
On chip functionalityA sensor can integrate various signal and image processing blocks such as amplifiers, ADCs, circuits for color processing and data compression, etc. on the same chip
Miniaturization
Random access of image data
Selective read-out mechanism
High-speed imaging
internet cameradigital still cameramachine visionAutomotivechildren’s toymedicine and dentistryfingerprint ID surveillanceaerospacemotion analysisindustrial inspectionquality controlprocess controltarget trackingspectroscopy
present applications of CMOS image sensors
Overall architectureCMOS imagers architecture can be divided into four main blocks:
1. Pixel Array2. Analog Signal Processors3. Row and Column Selector4. Timing and Control
Each pixel contains a photodetector and some transistors. This area is the heart of an image sensor and the imaging quality is largely determined by the performance of this area.
active pixels (APS)passive pixels (PPS)
APS are sensors that implement a buffer per pixel. Currently, APS are the predominant devices, although in some cases PPS are also used.
Basic pixel structures
An APS has three transistors in a pixel, while a PPS has only one transistor. To achieve further improvement, an advanced APS that has four transistors in a pixel, the so-called 4T-APS, has been developed.
Pixel circuits
The in-pixel amplifier in APS enables non-destructive read of the photodiode charge at a faster speed and a generally higher signal-to-noise ratio (SNR) than PPS
Operation of a photodetector comprises:
(a) generation of free electron-hole pairs due to impinging light
(b) separation and collection of electrons and holes
(c) production of an output signal through interaction with other components
Several popular silicon-based photosensing devices are
Photoconductors
PN and PIN photodiodes
Phototransistors
photo gates
PN junction photodiode
an important sensor for digital imaging
The potential voltage decreases when electrons accumulate. By measuring the voltage drop, the total amount of light power can be obtained.
ACTIVE PIXEL SENSOR, 3T-APSFirst, the reset transistor MRS is turned on
PD is reset to the value Vdd −Vth
Vth is the threshold voltage of transistor MRS
MRS is turned off and the PD is electrically floated
The accumulated charge changes the potential in the PD; the voltage of the PD,VPD ,decreases according to the input light intensity
After an accumulation time, the select transistor MSEL is turned on and the output signal in the pixel is read out in the vertical output line. When the read-out process is finished MSEL is turned off and MRS is again turned on to repeat the above process.
Sensor peripherals
Addressing
In CMOS image sensors, to address each pixel, a scanner or a decoder is used
Readout circuits
The voltage of a PD is read with a source follower (SF)
a follower transistor MSF is placed in a pixel and a current load Mb is placed in each column
The End
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