broadcast-edge 1 1.ppt

TV BROADCASTINGTV BROADCASTING

TELEVISIONTELEVISION

“to see at a distance”

TELEVISION BROADCASTINGTELEVISION BROADCASTING

The science of transmitting rapidly changing pictures from one point to another by means

of electrical signals.

DEFINITIONS

1. STUDIO OR OUTSIDE THE

STATION

2. PICTURE AND SOUND TRANSMITTER

COMPONENTS OF A COMPLETE TV BROADCASTING SYSTEM

COMPONENTS OF A COMPLETE TV BROADCASTING SYSTEM

3. MEDIUM (COAXIAL CABLE / FIBER OPTIC CABLE

4. A NUMBER OF RECEIVERS

STL – STUDIO TO TRANSMITTER LINK

ENG – ELECTRONIC NEWS GATHERING

ACRONYMS

SNG – SATELLITE NEWS GATHERING

SEG – SPECIAL EFFECTS

GENERATOR

EFP – ELECTRONIC FIELD PRODUCTION

ACRONYMS

TV TRANSMITTER

TV RECEIVER

DIPLEXERDIPLEXERA special coupling device that permits the transmission of both audio and video signals using one antenna system.

VSB – VESTIGIAL VSB – VESTIGIAL SIDEBANDSIDEBANDTo conserve

electromagnetic spectrum, it produces

only the full USB and only a portion of the LSB

DEFINITIONS

MONOCHROMEMONOCHROMEShades of black, gray and

whiteCOLORCOLOR

Red, green and blue

TV BROADCAST TV BROADCAST CHANNELCHANNEL

The band of frequencies assigned for the transmission of the picture and sound signals.

TV BROADCASTING FREQUENCY ALLOCATION

CHANNEL CHANNEL NUMBERNUMBER

FREQUENCY FREQUENCY RANGE RANGE (MHz)(MHz)

1 44 - 5054 - 6060 - 6666 - 7276 - 82

6 82 - 88

43

5

2

174 - 180180 - 186186 - 192192 - 198198 - 204204 - 210210 - 216

7

12

109

11

8

13

ANALOG COLOR TV SYSTEMS IN THE WORLD (ASPECT RATIO, 4:3)

UPPER VHF – CHANNELS 7 - 13

UHF – CHANNELS 14 - 83

FLOWER = 6N + 132

FLOWER = 6N + 386

470 – 890 MHz

TV BROADCASTING STANDARDS

PARAMETERSPARAMETERS RP STANDARDRP STANDARD

Broadcasting Band

54 – 890 MHzCh 2 to 4 (54 – 72 MHz) VHF Low

Ch 5 to 6 (76 – 88 MHz)Ch 7 to 13 (174 – 216 MHz) VHF

HighCh 14 to 83 (470 – 890 MHz) UHFChannel width 6 MHzBaseband Freq Video: 0 – 4 MHz Audio: 50 Hz – 15

kHz

PARAMETERSPARAMETERS

Max no. of stations

25 stationsPicture IF: 45.75 MHzSound IF: 41.25 MHz

Picture Carrier: +/- 1000 HzColor Carrier: +/- 10 Hz

Sound Carrier: +/- 1000 Hz

Fc Tolerance

IF - Rx

CircularPolarization

TV BROADCASTING STANDARDS

RP STANDARDRP STANDARD

PARAMETERSPARAMETERS

Type of Emission Video: C3EAudio: F3E (mono)

Multi-channel TV Sound (stereo)Audio : FM

Video: AM / Vestigial SidebandReceiver SuperheterodyneType of

PropagationSpace wave

Modulation

TV BROADCASTING STANDARDS

RP STANDARDRP STANDARD

STANDARDS FOR ANALOG TV SYSTEM

PARAMETERSPARAMETERS American , NTSCAmerican , NTSC

No. of lines/frame 525No. of lines/field 262 ½ (odd/even)

No. of frames/sec 30Field frequency 60 (59.94) HzLine frequency 15,750 (15,735.36)

HzChannel width 6 MHzVideo bandwidth 4 MHz

European, PALEuropean, PAL

625312 ½ (odd/even)

2550 Hz

15,625 Hz7 MHz5 MHz

PARAMETERSPARAMETERS American, NTSCAmerican, NTSC

Color Subcarrier 3.58 MHzSound System FM

Max Sound Deviation

+ / - 25 kHzIntercarrier Frequency

4.5 MHz

European, PALEuropean, PAL

4.43 MHzFM

+ /- 50 kHz5.5 MHz

STANDARDS FOR ANALOG TV SYSTEM

THE 6 MHZ BANDWIDTH – COLOR TV SPECTRUM

SCANNINGSCANNING

The process of analyzing successively

according to a pre-determined method, the

light values of picture elements constituting the total picture area

INTERLACED INTERLACED SCANNING PATTERNSCANNING PATTERN

Odd fields first then even fields; from left to right; then from top to

bottom

SCANNING

HORIZONTAL SCANNING FREQUENCY : 15,750 HzVERTICAL SCANNING FREQUENCY : 60 Hz

SCANNING

Progressive scan differs from interlaced scan in that the image is displayed on a screen by scanning each line (or

row of pixels) in a sequential order rather than an alternate order, as is done with interlaced scan.

PROGRESSIVE SCANNING PATTERNPROGRESSIVE SCANNING PATTERN

SCANNING

SYNCHRONIZATIONSYNCHRONIZATION

Keeps the transmitter and receiver scanning in step with each other

Rectangular pulses

SYNCHRONIZATION

HORIZONTAL SYNC FREQUENCY : 15,750 HzVERTICAL SYNC FREQUENCY : 60 Hz

Occur during blanking time when no picture information is sent (blacker than

black region)

EQUALIZATIONEQUALIZATION

Serves to maintain continuous flow of sync information to the horizontal

scanning system.

EQUALIZATION

EQUALIZING PULSE FREQUENCY : 31,500 Hz

Occur before and after each V sync pulse

BLANKINGBLANKING

Prevents the electron beam from reaching the screen, thus

retraces (flyback) are made invisible.

BLANKING

HORIZONTAL BLANKING FREQUENCY : 15,750 Hz

VERTICAL BLANKING FREQUENCY : 60 Hz

NEGATIVE TRANSMISSIONNEGATIVE TRANSMISSION

As the signal increases, the picture

becomes darkerCOMPONENTS OF A COMPONENTS OF A COMPOSITE VIDEO COMPOSITE VIDEO

SIGNALSIGNAL

Picture (video)

DEFINITIONS

Lowest amplitudes are the whitest color

Blanking pulses

Sync (H and V)

COMPOSITE VIDEO SIGNAL

a. a. BRIGHTNESSBRIGHTNESSOverall or average intensity of illumination

which determines the background level in the reproduced picture

b. CONTRASTb. CONTRASTDifference in intensity between black and

white parts of the reproduced picture

PICTURE QUALITIES

c. DETAILc. DETAILDepends on the number of

picture elements that can be produced within the frame.

d. COLOR d. COLOR LEVELLEVELThe color should vary the picture

from no color to pale and medium colors up to vivid

intense color.

Also known as Resolution or Definition

PICTURE QUALITIES

e. HUEe. HUEThe color of the

object

f. ASPECT f. ASPECT RATIORATIOThe ratio of the width to

the height of the picture frame.

g. VIEWING g. VIEWING DISTANCEDISTANCE

Standard: 4:3

4 to 8 times the picture height

SPECIAL FACILITIES IN CAMERA ASSEMBLY

5. IRIS 5. IRIS CONTROLCONTROLLevel of illumination

6. MECHANICAL 6. MECHANICAL FOCUSFOCUSCw / ccw or lock to a

scene7. 7.

VIEWFINDERVIEWFINDERTo find a sample of the material

SPECIAL FACILITIES IN CAMERA ASSEMBLY

1. 1. INTERCOMMUNICATIONINTERCOMMUNICATION

2. MULTIPLE LENS 2. MULTIPLE LENS TURRETTURRETCollection of different

lenses3. TALLY 3. TALLY LIGHTSLIGHTSMounted on camera

housing ; “on air”

4. PAN / TILT 4. PAN / TILT CONTROLSCONTROLSUp/down; left/right; zoon

in/out

1. 1. PHOTOEMISSIONPHOTOEMISSIONLiberation of electrons

from a material under the influence of

illumination

2. 2. PHOTOCONDUCTIONPHOTOCONDUCTION

Changes of conductivity of a surface due to

illumination

METHODS OF PRODUCING AN IMAGE WITHIN THE TUBE

3. PHOTOVOLTAIC 3. PHOTOVOLTAIC ACTIONACTIONGeneration of voltage due

to chemical or physical changes induced by

illumination

1. LIGHT 1. LIGHT TRANSFER TRANSFER CAPABILITYCAPABILITY

Ratio of brightness variations in the

reproduced image to the brightness variations in

the original scene

2. SPECTRAL 2. SPECTRAL RESPONSERESPONSESame as the eye; colors

are rendered in their proper tones

CHARACTERISTICS OF CAMERA TUBES

3. SENSITIVITY3. SENSITIVITYUnit: Lumen; output

photosignal per incident illumination

4. DARK 4. DARK CURRENTCURRENT

Small amount of signal current flowing in the output circuit even in

the absence of illumination on the

faceplate of the tube.

5. LAG 5. LAG CHARACTERISTICCHARACTERISTIC

Inability of the photosensitive layer in the

pick up tube to follow faster changes in illumination.6. RESOLVING 6. RESOLVING

POWERPOWERResolution

power

CHARACTERISTICS OF CAMERA TUBES

The light image is transformed into an electronic image, which can then be read from the back of

the target by a beam of electrons.

HOW CAMERA TUBES WORK

In a camera tube pickup device, the front of the tube contains a layer of photosensitive material

called a target. The lens of a camera focuses light from a scene onto the front of the camera tube, and this light causes

changes in the target material.

This varying voltage is the electronic television signal.

HOW CAMERA TUBES WORK

The beam of electrons is produced by an electron gun at the back of the camera tube.

The beam is controlled by a system of electromagnets that make the beam

systematically scan the target material.

Whenever the electron beam hits the bright parts of the electronic image on the target

material, the tube emits a high voltage, and when the beam hits a dark part of the image,

the tube emits a low voltage.

TYPES OF CAMERA TUBES

1. NIPKOW DISK1. NIPKOW DISK

A photoelectric tube is used with a rotating wheel punched with

small holes spiraling in toward the center to

scan the picture elements.

2. IMAGE 2. IMAGE DISSECTOR / DISSECTOR / ICONOSCOPEICONOSCOPEThe first all electric pick

up device.

3. IMAGE 3. IMAGE ORTHICONORTHICONIndicates the linear

relation between light input and signal output;

highly sensitive but relatively large and

expensive.

TYPES OF CAMERA TUBES

4. FLYING SPOT 4. FLYING SPOT SCANNERSCANNERThe spot of light from the screen

of the CRT is used as the light source to scan a film slide

5. VIDICON5. VIDICONMost widely used; a very small

camera tube of relatively simple construction, a photoconductive target plate and an electron gun.

Image plate is made up of Antimony Trisulfide

TYPES OF CAMERA TUBES

6. PLUMBICON (PHILIPS)6. PLUMBICON (PHILIPS)Similar to the Vidicon except that the image plate is made of Lead

Oxide (PbO)7. SATICON (HITACHI, 7. SATICON (HITACHI,

LTD)LTD) The image plate is made of Selenium, Arsenic and Tellurium.

8. SILICON VIDICON8. SILICON VIDICONA Silicon semiconductor junction is used for the target

material; extremely high sensitivity for low light applications.

TYPES OF CAMERA TUBES

9. CHALNICON 9. CHALNICON (TOSHIBA)(TOSHIBA)

The target is a multilayer arrangement consisting of Tin Oxide, Cadnium Selenide and Arsenic Trisulfide; very high

sensitivity.

10. NEWVICON (MATSUSHITA 10. NEWVICON (MATSUSHITA ELECTRIC)ELECTRIC)

The target is made of Amorphous Zinc Selendie layer backed by Antimony Trisulfide.

TYPES OF CAMERA TUBES

CHARGE COUPLED DEVICE

A charge-coupled device (CCD) is a light-sensitive integrated circuit that stores and displays the data for an image in such a way that each pixel (picture

element) in the image is converted into an electrical charge the intensity of which is related to a color in

the color spectrum

CHARGE COUPLED DEVICE

In a CCD, the light from a scene strikes an array of photodiodes

arranged on a silicon chip.

Photodiodes are devices that conduct electricity when they are struck by light; they send

this electricity to tiny capacitors.

The capacitors store the electrical charge, with the amount of charge stored

depending on the strength of the light that struck the photodiode.

The CCD converts the incoming light from the scene into an

electrical signal by releasing the charges from the photodiodes in

an order that follows the scanning pattern that the

receiver will follow in re-creating the image.

CHARGE COUPLED DEVICE

CRITERIA FOR COMPATIBILITYCRITERIA FOR COMPATIBILITY

1. The color TV system must transmit and be capable of receiving a luminance signal

which is either identical to a monochrome transmission or easily converted to it.

2. Must use the same 6 MHz bandwidth

3. Must transmit the Chrominance information in such a way that it is sufficient for adequate color reproduction but easy to

ignore by a monochrome receiver.

COLOR TV SYSTEM

COLOR TV SYSTEM

1. LUMINANCE1. LUMINANCEIndicates the amount of light intensity, which is perceived

by the eye as brightness.Contains all information

required to construct a black and white picture from the

signal

Where: R – Red video signal

G – Green video signalB – Blue video signal

PRIMARY COLOR SIGNALS

Y = 0.30R + 0.59G + Y = 0.30R + 0.59G + 0.11B0.11B

2. 2. CHROMINANCECHROMINANCE

Term used to combine both hue (amplitude of C

signal) and saturation (phase angle)

Is the 3.58 MHz color subcarrier with

quadrature modulation by I and Q color signals

a. IN-PHASE CHROMINANCEa. IN-PHASE CHROMINANCEColor video signal transmitted as amplitude

modulation of the 3.58 MHz C signalThe only color video signal with bandwidth

of 0 to 1.3 MHz

I = 0.60R – 0.28G – I = 0.60R – 0.28G – 0.32B0.32B

The positive polarity of the I signal is orange while the negative polarity is cyan

CHROMINANCE SIGNALS

b. QUADRATURE PHASE CHROMINANCEb. QUADRATURE PHASE CHROMINANCE

Color video signal that modulates the 3.58 MHz C signal in quadrature with the I signal

with bandwidth of 0 to 0.5 MHz

Q = 0.21R – 0.52G + Q = 0.21R – 0.52G + 0.31B0.31B

The positive polarity of the Q signal is purple while the negative polarity is yellow green

CHROMINANCE SIGNALS

ANALOG COLOR TV SYSTEMS IN THE WORLD (ASPECT RATIO, 4:3)

NTSC

National Television Standards Committe

e (American

)

Phase Alteration

by Line (British, German)

PAL

Sequential Color and Memory (French)

SECAM

SIMILARITYSIMILARITYThey separate the luminance and chrominance information and

transmit the chrominance information in the form of 2 color difference signals which modulate a color subcarrier frequency

transmitted within the sideband of the luminance signal.

DIFFERENCEDIFFERENCE

COLOR TRANSMISSION STANDARDS

The processing of the chrominance informationNTSC – subcarrier frequency is amplitude modulated

PAL – subcarrier frequency is phase modulatedSECAM – subcarrier frequency is frequency modulated

COLOR COMBINATIONS

GREEN + RED =

GREEN + BLUE =

BLUE + RED =

GREEN + BLUE + RED =

YELLOW

MAGENTA

CYAN

WHITE

Retransmit the signals of TV broadcast station by

frequency conversion and amplification without

significantly altering any characteristic except the amplitude and frequency.

1. TRANSLATORS1. TRANSLATORS

OTHER TV SERVICES

2. CATV – CABLE TELEVISION2. CATV – CABLE TELEVISION

A communications system that gathers local , remote, playbacks and satellite

signals and sent by coaxial cables to the subscribers.

OTHER TV SERVICES

A. A. HEADENDHEADENDThe main hub of the CATV system where the signals from all

sources originate, then processed, amplified and distributed to the subscribers.

PARTS OF THE CATV SYSTEM

B. OUTSIDE PLANTB. OUTSIDE PLANTPart of the CATV system that provides the distribution of the

TV signals from the head end to the paying subscribers.

C. SUBSCRIBER PREMISE EQUIPMENTC. SUBSCRIBER PREMISE EQUIPMENTThe end of the line of the CATV system, where the cable signals were delivered from its origin to the subscriber.

PARTS OF THE CATV SYSTEM

PARTS OF THE CATV SYSTEM

3. MATV – MASTER ANTENNA TELEVISION3. MATV – MASTER ANTENNA TELEVISION

The means by which many apartments, houses, hotels, schools and other multi-unit buildings distribute TV and FM signals to a

number of receivers.

OTHER TV SERVICES

DIVISIONSDIVISIONS

1. Head end

2. Distribution System

A. A. HEADENDHEADENDNormally consists of an antenna installation to receive the

desired signals, processing equipment to filter the signals and remove interference, and a distribution amplifier to amplify the signals to the level required to provide an adequate signal to

every receiver in the system.

PARTS OF THE MATV SYSTEM

B. DISTRIBUTION SYSTEMB. DISTRIBUTION SYSTEM

Provides a clean signal to the sets by isolating each receiver from the system and by delivering the proper amount of

signal to each set

4. CCTV – CLOSED CIRCUIT TELEVISION4. CCTV – CLOSED CIRCUIT TELEVISION

A TV system that operates on a closed loop basis; CCTV images

are only available to those connected to the closed loop.

OTHER TV SERVICES

Applications: educational, business, industry, medicine, traffic control, surveillance

Components: Camera and lens, Coaxial cables, Monitors, Video

Cassette/Tape Recorders

This process produces much clearer picture and sound

quality than analog systems, similar to the difference between a compact disc recording (using digital

technology) and an audiotape or long-playing record.

DIGITAL TELEVISION

A device that receives, decodes, and displays

digital video broadcasts (in both high-definition and standard-definition formats) for consumer

viewing.

Digital television uses technology that records, transmits, and decodes a signal in digital form—that is, as a series of ones and

zeros.

It also permits additional features to be embedded

in signals including program and consumer information as well as

interactivities.

There are three types of broadcast digital television (DTV), each with progressively better

picture and sound quality:

TYPES OF DIGITAL TELEVISION

Digital technology is being developed

that will offer sharper pictures on wider screens, and HDTV with cinema-

quality images. High-Definition TV (HDTV)

Standard-Definition TV (SDTV)

Enhanced-Definition TV (EDTV)

480i 480 lines by 720 pixels

wide, displayed in interlaced format.

Committee established by the FCC to define new standards for publicly regulated broadcast television in

the United States

Advanced Television Systems Committee (ATSC)

STANDARD DEFINITION TELEVISION

It has a 4:3 or 16:9 aspect ratio, 29.97-Hz frame rate, as defined

by the ATSC standard.

High-definition television (HDTV) image that is 480

vertical lines by 720 horizontal pixels displayed in progressive

format

480p

ENHANCED DEFINITION TELEVISION

It has a 4:3 or 16:9 aspect ratio, 59.94 Hz, 29.97 Hz, and

23.98 Hz frame rates, as defined by the ATSC standard

HIGH DEFINITION TELEVISION

High-definition video formats that have 16:9 aspect ratio. Generally refers to 1080i or 720p images.

1,080 vertical lines by 1,920

horizontal pixels wide, displayed in

an interlaced format.

It has a 16:9 aspect ratio, 29.97

Hz frame rate,

1080i 720 vertical lines

by 1,280 horizontal pixels wide, displayed in

progressive format.

It has a 16:9 aspect ratio, 59.94 Hz, 29.97 Hz, and

23.98 Hz frame rates,

720p

Many flat panel TVs use liquid-crystal display (LCD) screens that make use of a special substance that changes properties when a

small electric current is applied to it.

LCD technology has already been used extensively in laptop

computers. LCD television screens are flat, use very little electricity, and work well for small, portable television sets.

FLAT PANEL TELEVISION

Flat panel TVs made from gas-plasma displays can be much

larger. In gas-plasma displays, a small electric current stimulates an inert gas sandwiched between

glass panels, including one coated with phosphors that emit

light in various colors. While just 8 cm (3 in) thick,

plasma screens can be more than 150 cm (60 in) diagonally.

FLAT PANEL TELEVISION