1. Contents of the Lecture
1. Introduction
2. Methods for I/O Operations
3. Buses
4. Liquid Crystal Displays
5. Other Types of Displays
6. Graphics Adapters
7. Optical Discs
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2. 5. Other Types of Displays
Plasma Displays
Field Emission Displays
OLED Displays
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3. Input/Output Systems and Peripheral Devices (05)
Plasma Displays
Plasma Displays
Principle of Plasma Displays
Structure and Operation
Advantages
Disadvantages
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4. Principle of Plasma Displays (1)
Use a screen coated with phosphor dots  active displays
Use a grill of electrodes to address individual pixels
Principle: applying a voltage to an inert gas releases photons  ultraviolet domain
The photons strike the phosphor particles  generate visible light
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5. Principle of Plasma Displays (2)
Normally, the atoms of an inert gas contain an equal number of protons and electrons
If a voltage is applied, free electrons are generated  collide with the atoms
The atoms loose electrons  positive ions
Plasma: gas consisting of free electrons, positive ions, and neutral particles
The collisions between particles cause the gas atoms to release photons
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6. Principle of Plasma Displays (3)
Original image © HowStuffWorks, Inc.
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7. Input/Output Systems and Peripheral Devices (05)
Plasma Displays
Plasma Displays
Principle of Plasma Displays
Structure and Operation
Advantages
Disadvantages
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8. Structure and Operation (1)
Two glass plates
Electrodes for row and column selection
Address electrodes (vertical)
Display electrodes (horizontal): in a dielectric layer, covered with a protective layer (MgO)
Phosphor particles: cover the rear plate
Gas: neon mixed with argon or xenon
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9. Structure and Operation (2)
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10. Structure and Operation (3)
Original image © HowStuffWorks, Inc.
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11. Structure and Operation (4)
The gas inside the display is partitioned into cells  separators
Sub-cells for the primary colors
To ionize the gas cells, a priming voltage is applied between pairs of electrodes
The cells are ionized in turn
If an additional voltage is applied to a cell, the gas releases ultraviolet photons
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12. Structure and Operation (5)
The released photons interact with the phosphor coated on the cell’s inside wall
The phosphor’s electrons release energy in the form of visible light photons
To create colors, the intensity of each sub-pixel color is varied
Pulse width modulation (PWM) of the addressing pulses: adjusting their widths in 256 steps  16.7 million colors
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13. Input/Output Systems and Peripheral Devices (05)
Plasma Displays
Plasma Displays
Principle of Plasma Displays
Structure and Operation
Advantages
Disadvantages
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14. Input/Output Systems and Peripheral Devices (05)
Advantages
The possibility to produce large-sized flat screens
For multimedia presentations (60”..150”)
For TV sets (32”..60”)
High contrast ratio (10,000:1 static)
Accurate color reproduction
Wide viewing angles
Faster response time (1 ms) compared to LCDs  superior performance for video images
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15. Input/Output Systems and Peripheral Devices (05)
Plasma Displays
Plasma Displays
Principle of Plasma Displays
Structure and Operation
Advantages
Disadvantages
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16. Input/Output Systems and Peripheral Devices (05)
Disadvantages
Relatively large pixel size
Reducing the pixel size below 0.3 mm is difficult
Luminosity decreases over time
Lifespan: 60, ,000 hours
Image retention problems may occur (screen burn-in)
Average power consumption is higher than that of LCDs
Higher weight compared to LCDs
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17. 5. Other Types of Displays
Plasma Displays
Field Emission Displays
OLED Displays
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18. Field Emission Displays
Principle of Field Emission Displays
Structure and Operation
Advantages and Disadvantages
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19. Principle of Field Emission Displays
FED – Field Emission Display
The screen is covered with phosphor dots, which are hit by electron beams
Millions of miniature emitters and electron beams are used
The emitters are at a small distance (fraction of mm) from the screen
The electrons are emitted by a cold cathode
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20. Field Emission Displays
Principle of Field Emission Displays
Structure and Operation
Advantages and Disadvantages
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21. Structure and Operation (1)
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22. Structure and Operation (2)
Each R, G, and B sub-pixel is an emitter made as a miniature vacuum tube
A large number of electron emitters are used for each pixel
The emitters are made from a material based on molybdenum  emits electrons when a low voltage difference is applied
Colors are generated sequentially: green, red, blue
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23. Field Emission Displays
Principle of Field Emission Displays
Structure and Operation
Advantages and Disadvantages
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24. Advantages and Disadvantages (1)
Power consumption is lower than that of liquid crystal displays
Consumption: dependent on the image
With liquid crystal displays, the backlight is permanently on
The viewing angle is wide: 160
There is a redundancy by construction
The brightness is not affected even if 20% of the emitters fail
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25. Advantages and Disadvantages (2)
Response time is lower than that of liquid crystal displays
Color reproduction is of high quality, similar to that of cathode ray tubes
Mass production is more difficult
To withstand the difference of pressure, the display must be mechanically robust and sealed
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26. 5. Other Types of Displays
Plasma Displays
Field Emission Displays
OLED Displays
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27. Input/Output Systems and Peripheral Devices (05)
OLED Displays
OLED Displays
Organic Materials
Principle of Operation
Manufacturing Technologies
Passive-Matrix Displays
Active-Matrix Displays
Advantages and Disadvantages
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28. Input/Output Systems and Peripheral Devices (05)
Organic Materials (1)
OLED – Organic Light Emitting Diode
Electroluminescent organic materials have been discovered in the 1950’s
Materials based on conductive polymers have been developed in the 1970’s
Examples: polyacetylene; polyaniline
The first organic LED has been developed at Eastman Kodak company (1987)
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29. Input/Output Systems and Peripheral Devices (05)
Organic Materials (2)
Two types of materials, depending on the size of molecules:
With small molecules: SM-OLED (Small Molecule OLED)
With large molecules (polymers): LEP (Light Emitting Polymer)
Both types generate light by forming electrons and holes, and then by their recombination
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30. Input/Output Systems and Peripheral Devices (05)
OLED Displays
OLED Displays
Organic Materials
Principle of Operation
Manufacturing Technologies
Passive-Matrix Displays
Active-Matrix Displays
Advantages and Disadvantages
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31. Principle of Operation (1)
Organic LED:
One or more layers of organic materials ( nm)
Two electrodes (anode, cathode)
Substrate (plastic, glass)
Early OLEDs: a single organic layer
Multilayer OLEDs: have improved efficiency
Many OLEDs have two layers: conductive layer, emissive layer
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32. Principle of Operation (2)
Concepts related to particle physics
Spin
Angular momentum carried by elementary and composite particles
Vector quantity: it has magnitude and direction
Spin magnitude: indicated by the spin quantum number (s)
For fermions – particles that make all known matter: s = ½
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33. Principle of Operation (3)
Spin direction: direction in which the spin vector is pointing
For spin-½ particles: two quantum states, with the spin pointing in the +z or –z direction
Singlet state
Obtained when two spin-½ particles are combined  they form an exciton
If the particles have opposite spins, the total spin is s = 0  only one quantum state
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34. Principle of Operation (4)
Triplet state
Set of three quantum states of a particle or combination of particles
Each state has a total spin of s = 1
Combination of two spin-½ particles: the spin directions are the same
Formation of a triplet state is more probable
Triplet  singlet transition: phosphorescence
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35. Principle of Operation (5)
Structure of a typical OLED cell
Two organic layers
Two electrodes
Cathode: metallic mirror
Anode: transparent (ITO)
Substrate: glass or plastic
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36. Principle of Operation (6)
When a voltage is applied:
A current of electrons flows through the organic layers (cathode  anode)
Electrons and holes are attracted towards each other by electrostatic forces
An electron and a hole recombine  exciton in a singlet state or triplet state
Decay of the singlet state  release of energy as a photon
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37. Principle of Operation (7)
Efficiency of an OLED cell: limited by the ratio of singlet states to triplet states
SM-OLED materials:
The formation of the singlet state is three times less probable  efficiency limited to 25%
Phosphorescent OLEDs: doping with compounds
LEP materials:
The singlet/triplet ratio can be > 1
Very high efficiency
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38. Principle of Operation (8)
Structure of an OLED display (bottom emission)
Other variant: with top emission
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39. Input/Output Systems and Peripheral Devices (05)
OLED Displays
OLED Displays
Organic Materials
Principle of Operation
Manufacturing Technologies
Passive-Matrix Displays
Active-Matrix Displays
Advantages and Disadvantages
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40. Manufacturing Technologies (1)
Small-molecule LEDs
Conductive (hole transport) layer: metal-phthalocyanine, triphenylamine
Emissive layer: fluorescent dyes
Process: thermal evaporation in vacuum
Advantages:
Homogeneous film layers can be formed
Complex multi-layer structures can be achieved
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41. Manufacturing Technologies (2)
Disadvantages:
Expensive process
Not scalable to very large substrates
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42. Manufacturing Technologies (3)
Creating the pattern for the RGB subpixels: thermal evaporation using shadow masks
A precise alignment of the masks is required for each of the R, G, and B emissive materials
Disadvantages: the process is not scalable; not suitable for high-volume production
Another method for creating the subpixel pattern: laser transfer
The materials are transferred spot-by-spot
Disadvantage: slow process
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43. Manufacturing Technologies (4)
RGB subpixel definition by shadow masking
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44. Manufacturing Technologies (5)
WOLED (White-emitting OLED) technology
Uniform deposition of a white-emitting OLED material
Color filters applied according to the subpixel pattern
Color filter deposition: photolithographic methods  technology also used for LCDs
Advantages: high speed; process scalable to large displays; no color balance problems
Disadvantage: higher power consumption
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45. Manufacturing Technologies (6)
Polymer LEDs
Conducting layer: polyaniline
Emissive layer: polyphenylene vinylene (PPV), polyfluorene (PF)
Spin coating: solution placed on the substrate, which is rotated at high speed
Advantages:
Scalable process for high-volume manufacturing
Fewer vacuum deposition steps
Inkjet printing can be used for the emissive layer
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46. Manufacturing Technologies (7)
Disadvantage:
Multi-layer structures are difficult to form
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47. Input/Output Systems and Peripheral Devices (05)
OLED Displays
OLED Displays
Organic Materials
Principle of Operation
Manufacturing Technologies
Passive-Matrix Displays
Active-Matrix Displays
Advantages and Disadvantages
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48. Passive-Matrix Displays (1)
PMOLED
Drivers attached to each electrode
The pixel rows are selected successively
A certain voltage is applied to the columns of selected row  an electric current
Advantage: manufacturing costs are low
Disadvantages: relatively intensive currents are required  high power consumption; only suitable for small screens
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49. Passive-Matrix Displays (2)
Original image © HowStuffWorks, Inc.
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50. Input/Output Systems and Peripheral Devices (05)
OLED Displays
OLED Displays
Organic Materials
Principle of Operation
Manufacturing Technologies
Passive-Matrix Displays
Active-Matrix Displays
Advantages and Disadvantages
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51. Active-Matrix Displays (1)
AMOLED
An array of thin film transistors (TFTs)
At least two transistors and a storage capacitor are needed for each subpixel
First TFT: charges the storage capacitor
Second TFT: provides a correct voltage
Advantages: higher refresh rates; higher brightness; reduced power consumption
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52. Active-Matrix Displays (2)
Original image © HowStuffWorks, Inc.
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53. Active-Matrix Displays (3)
PenTile Matrices
Set of subpixel layout methods  Samsung Display
Inspired by peculiarity of the human retina  fewer sensors for perceiving blue colors
Use proprietary algorithms for subpixel rendering
Any input pixel is mapped to a logical pixel
Compatibility with conventional RGB layout
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54. Active-Matrix Displays (4)
PenTile RG-BG Matrix
G subpixels, alternating R and B subpixels
The input image is mapped to subpixels  1:1 mapping only for G subpixels
Only two subpixels are used for a pixel  the subpixel density can be reduced
Resolution of the luminance information is not affected significantly
Disadvantage: the pixel structure may be more visible
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55. Active-Matrix Displays (5)
PenTile RG-BG pixel layout – Google/HTC Nexus One (800480)
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56. Active-Matrix Displays (6)
Integrated touch panels
The capacitive sensor array is integrated during the AMOLED manufacturing process
Manufacturers:
Samsung Display
AU Optronics
Super AMOLED (Samsung Display)
Integrated touch panel
PenTile matrix
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57. Active-Matrix Displays (7)
Super AMOLED Plus
Conventional RGB layout
Higher brightness and energy efficiency
Example: Samsung Galaxy S II (800480)
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58. Active-Matrix Displays (8)
HD Super AMOLED
Higher resolution (1280720)
With PenTile RG-BG matrix (e.g., Samsung Galaxy S III)
With RGB matrix (e.g., Samsung Galaxy Note II, image on the right)
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59. Active-Matrix Displays (9)
Full HD Super AMOLED
Full HD resolution (19201080)
PenTile matrix, with a different pixel arrangement
Example: Samsung Galaxy S4
441 pixels/inch
Color gamut: 97% of Adobe RGB color space
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60. Active-Matrix Displays (10)
Example: Samsung Galaxy S5
Full HD resolution
432 pixels/inch (ppi)
Samsung Galaxy Prime (LTE-A): QHD resolution (25601440, 560 ppi)
New organic materials
Modified subpixel structure
Higher brightness (up to 698 cd/m2)
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61. Input/Output Systems and Peripheral Devices (05)
OLED Displays
OLED Displays
Organic Materials
Principle of Operation
Manufacturing Technologies
Passive-Matrix Displays
Active-Matrix Displays
Advantages and Disadvantages
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62. Advantages and Disadvantages (1)
High contrast ratio (>1,000,000:1), both static and dynamic
Wide viewing angles  no color shifting
Wide color gamut
Fast response time (0.01 ms .. 1 ms)
On average, power consumption is lower compared to LCDs (40% .. 80%)
The plastic substrate is lightweight
Flexible and transparent displays can be built
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63. Advantages and Disadvantages (2)
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64. Advantages and Disadvantages (3)
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65. Advantages and Disadvantages (4)
Currently, the cost of the manufacturing process is high
The lifetime of some organic materials (blue OLEDs) is limited (e.g., 14,000 hours)
Color balance may change in time
Biasing the color balance towards blue
Optimizing the size of R, G, and B subpixels  larger blue subpixels
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66. Advantages and Disadvantages (5)
Image persistence may occur
The display may be damaged by prolonged exposure to ultraviolet rays
The organic materials can be damaged by water
Readability in outdoor conditions may be limited
Circular polarizer; anti-reflective coating
Power consumption is increased when displaying images on white background
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67. Input/Output Systems and Peripheral Devices (05)
Summary (1)
Plasma displays are based on applying a voltage to an inert gas
The gas releases ultraviolet photons
The photons are transformed into visible light by phosphor particles coated on the screen
Advantages: accurate color reproduction; wide viewing angles; fast response time
Field emission displays use a large number of miniature emitters and electron beams
Advantage: redundancy by construction
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68. Input/Output Systems and Peripheral Devices (05)
Summary (2)
There are two types of electroluminescent organic materials: SM-OLED and LEP
The operation of OLED displays is based on forming electrons and holes, and then recombining them to form excitons
Decay of the singlet state: releases photons
Manufacturing technology for SM-OLED materials: thermal evaporation in vacuum
Creating the subpixel pattern: shadow masks; laser transfer; white-emitting OLED technology
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69. Input/Output Systems and Peripheral Devices (05)
Summary (3)
Manufacturing technologies for LEP materials: spin coating; inkjet printing
Active-matrix OLED displays require two transistors and a capacitor for each pixel
Advantages: higher brightness; reduced power consumption
Advantages of OLED displays: high contrast; wide viewing angles; fast response time
Disadvantages: limited lifetime of blue OLEDs; color balance may change in time
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70. Input/Output Systems and Peripheral Devices (05)
Concepts, Knowledge (1)
Principle of plasma displays
Structure and operation of plasma displays
Advantages of plasma displays
Disadvantages of plasma displays
Principle of field emission displays
Advantages of field emission displays
Types of electroluminescent organic materials
Structure and operation of an OLED cell
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71. Input/Output Systems and Peripheral Devices (05)
Concepts, Knowledge (2)
Manufacturing technologies for small-molecule LEDs
White-emitting OLED technology
Manufacturing technologies for polymer LEDs
Active-matrix OLED displays
PenTile matrices
Advantages of OLED displays
Disadvantages of OLED displays
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72. Input/Output Systems and Peripheral Devices (05)
Questions
What are the advantages and disadvantages of plasma displays?
What is the operating principle of field emission displays?
What is the difference between SM-OLED and LEP organic materials considering the efficiency of light emission?
What are the advantages of OLED displays?
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