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Information on Satellite TV: Satellite television is television delivered by the means of communications satellite and received by a satellite dish and set-top box. In many areas of the world it provides a wide range of channels and services, often to areas that are not serviced by terrestrial or cable providers. History The first satellite television signal was relayed from Europe to the
Telstar satellite over North America in 1962. The first geosynchronous
communication satellite, Syncom 2, was launched in 1963. The world's
first commercial communication satellite, called Intelsat I (nicknamed
Early Bird), was launched into synchronous orbit on April 6, 1965.
The first national network of satellite television, called Orbita,
was created in Soviet Union in 1967, and was based on the principle
of using the highly elliptical Molniya satellite for re-broadcasting
and delivering of TV signal to ground downlink stations. The first
domestic North American satellite to carry television was Canada’s
geostationary Anik 1, which was launched in 1972.[1] ATS-6, the world's
first experimental educational and Direct Broadcast Satellite, was
launched in 1974. The first Soviet geostationary satellite to carry
Direct-To-Home television, called Ekran, was launched in 1976. Satellites used for television signals are generally in either naturally highly elliptical (with inclination of +/-63.4 degrees and orbital period of about 12 hours, also known as Molniya orbit) or geostationary orbit 37,000 km (22,300 miles) above the earth’s equator. Satellite television, like other communications relayed by satellite, starts with a transmitting antenna located at an uplink facility. Uplink satellite dishes are very large, as much as 9 to 12 meters (30 to 40 feet) in diameter. The increased diameter results in more accurate aiming and increased signal strength at the satellite. The uplink dish is pointed toward a specific satellite and the uplinked signals are transmitted within a specific frequency range, so as to be received by one of the transponders tuned to that frequency range aboard that satellite. The transponder 'retransmits' the signals back to Earth but at a different frequency band (a process known as translation, used to avoid interference with the uplink signal), typically in the C-band (4–8 GHz) or Ku-band (12–18 GHz) or both. The leg of the signal path from the satellite to the receiving Earth station is called the downlink. A typical satellite has up to 32 transponders for Ku-band and up to 24 for a C-band only satellite, or more for hybrid satellites. Typical transponders each have a bandwidth between 27 MHz and 50 MHz. Each geo-stationary C-band satellite needs to be spaced 2 degrees from the next satellite (to avoid interference). For Ku the spacing can be 1 degree. This means that there is an upper limit of 360/2 = 180 geostationary C-band satellites and 360/1 = 360 geostationary Ku-band satellites. C-band transmission is susceptible to terrestrial interference while Ku-band transmission is affected by rain (as water is an excellent absorber of microwaves at this particular frequency). The downlinked satellite signal, quite weak after traveling the great distance (see inverse-square law), is collected by a parabolic receiving dish, which reflects the weak signal to the dish’s focal point. Mounted on brackets at the dish's focal point is a device called a feedhorn. This feedhorn is essentially the flared front-end of a section of waveguide that gathers the signals at or near the focal point and 'conducts' them to a probe or pickup connected to a low-noise block downconverter or LNB. The LNB amplifies the relatively weak signals, filters the block of frequencies in which the satellite TV signals are transmitted, and converts the block of frequencies to a lower frequency range in the L-band range. The evolution of LNBs was one of necessity and invention. The original C-Band satellite TV systems used a Low Noise Amplifier connected to the feedhorn at the focal point of the dish. The amplified signal was then fed via very expensive and sometimes 50 ohm impedance gas filled hardline coaxial cable to an indoor receiver or, in other designs, fed to a downconverter (a mixer and a voltage tuned oscillator with some filter circuitry) for downconversion to an intermediate frequency. The channel selection was controlled, typically by a voltage tuned oscillator with the tuning voltage being fed via a separate cable to the headend. But this design evolved. Designs for microstrip based converters for Amateur Radio frequencies were adapted for the 4 GHz C-Band. Central to these designs was concept of block downconversion of a range of frequencies to a lower, and technologically more easily handled block of frequencies (intermediate frequency). The advantages of using an LNB are that cheaper cable could be used to connect the indoor receiver with the satellite TV dish and LNB, and that the technology for handling the signal at L-Band and UHF was far cheaper than that for handling the signal at C-Band frequencies. The shift to cheaper technology from the 50 Ohm impedance cable and N-Connectors of the early C-Band systems to the cheaper 75 Ohm technology and F-Connectors allowed the early satellite TV receivers to use, what were in reality, modified UHF TV tuners which selected the satellite television channel for down conversion to another lower intermediate frequency centered on 70 MHz where it was demodulated. This shift allowed the satellite television DTH industry to change from being a largely hobbyist one where receivers were built in low numbers and complete systems were expensive (costing thousands of Dollars) to a far more commercial one of mass production. Direct broadcast satellite dishes are fitted with an LNBF, which integrates the feedhorn with the LNB. In the United States, service providers use the intermediate frequency ranges of 950-2150 MHz to carry the signal to the receiver. This allows for transmission of UHF band signals along the same span of coaxial wire at the same time. In some applications, (DirecTV AU9-S and AT-9) ranges the lower B-Band and upper 2250-3000 MHz, are used. Newer LNBFs in use by DirecTV refereed to as SWM, use a more limited frequency range of 950-1800 MHz. The satellite receiver demodulates and converts the signals to the
desired form (outputs for television, audio, data, etc.). Sometimes,
the receiver includes the capability to unscramble or decrypt; the
receiver is then called an Integrated receiver/decoder or IRD. The
cable connecting the receiver to the LNBF or LNB should be of the low
loss type RG-6, quad shield RG-6 or RG-11, etc. RG-59 is not recommended
for this application as it is not technically designed to carry frequencies
above 950 MHz, but will work in many circumstances, depending on the
quality of the coaxial wire. Analog television distributed via satellite is usually sent scrambled or unscrambled in NTSC, PAL, or SECAM television broadcast standards. The analog signal is frequency modulated and is converted from an FM signal to what is referred to as baseband. This baseband comprises the video signal and the audio subcarrier(s). The audio subcarrier is further demodulated to provide a raw audio signal. If the signal is a digitized television signal or multiplex of signals, it is typically QPSK. In general, digital television, including that transmitted via satellites, are generally based on open standards such as MPEG and DVB-S or ISDB-S. The conditional access encryption/scrambling methods include BISS,
Conax, Digicipher, Irdeto, Nagravision, PowerVu, Viaccess, Videocipher,
and VideoGuard. Many conditional access systems have been compromised. There are three primary types of satellite television usage: reception direct by the viewer, reception by local television affiliates, or reception by headends for distribution across terrestrial cable systems. Direct to the viewer reception includes direct broadcast satellite
or DBS and television receive-only or TVRO, both used for homes and
businesses including hotels, etc. Direct broadcast satellite, (DBS) also known as "Direct-To-Home" is a relatively recent development in the world of television distribution. “Direct broadcast satellite” can either refer to the communications satellites themselves that deliver DBS service or the actual television service. DBS systems are commonly referred to as "mini-dish" systems. DBS uses the upper portion of the Ku band, as well as portions of the Ka band. Modified DBS systems can also run on C-band satellites and have been used by some networks in the past to get around legislation by some countries against reception of Ku-band transmissions. Most of the DBS systems use the DVB-S standard for transmission. With Pay-TV services, the datastream is encrypted and requires proprietary reception equipment. While the underlying reception technology is similar, the Pay-TV technology is proprietary, often consisting of a Conditional Access Module and smart card. This measure assures satellite television providers that only authorised,
paying subscribers have access to Pay TV content but at the same time
can allow free-to-air (FTA) channels to be viewed even by the people
with standard equipment (DBS receivers without the Conditional Access
Modules) available in the market. The term Television receive-only, or TVRO, arose during the early days of satellite television reception to differentiate it from commercial satellite television uplink and downlink operations (transmit and receive). This was before there was a DTH satellite television broadcast industry. Satellite television channels at that time were intended to be used by cable television networks rather than received by home viewers. Satellite TV receiver systems were largely constructed by hobbyists and engineers. These TVRO systems operated mainly on the C band frequencies and the dishes required were large; typically over 3 meters (10 ft) in diameter. Consequently TVRO is often referred to as "big dish" or "Big Ugly Dish" (BUD) satellite television. TVRO systems are designed to receive analog and digital satellite feeds of both television or audio from both C-band and Ku-band transponders on FSS-type satellites. The higher frequency Ku-band systems tend to be Direct To Home systems and can use a smaller dish antenna because of the higher power transmissions and greater antenna gain. TVRO systems tend to use larger rather than smaller satellite dish antennas, since it is more likely that the owner of a TVRO system would have a C-band-only setup rather than a Ku band-only setup. Additional receiver boxes allow for different types of digital satellite signal reception, such as DVB/MPEG-2 and 4DTV. The narrow beam width of a normal parabolic satellite antenna means
it can only receive signals from a single satellite at a time. Simulsat
or the Vertex-RSI TORUS, is a quasi-parabolic satellite earthstation
antenna that is capable of receiving satellite transmissions from 35
or more C- and Ku-band satellites simultaneously. Today, most satellite TV customers in developed television markets get their programming through a direct broadcast satellite (DBS) provider, such as DISH TV or DTH platform. The provider selects programs and broadcasts them to subscribers as a set package. Basically, the provider’s goal is to bring dozens or even hundreds of channels to the customers television in a form that approximates the competition from Cable TV. Unlike earlier programming, the provider’s broadcast is completely digital, which means it has high picture and stereo sound quality. Early satellite television was broadcast in C-band - radio in the 3.4-gigahertz (GHz) to 7 GHz frequency range. Digital broadcast satellite transmits programming in the Ku frequency range (10 GHz to 14 GHz ). There are five major components involved in a direct to home (DTH) satellite system: the programming source, the broadcast center, the satellite, the satellite dish and the receiver. Programming sources are simply the channels that provide programming
for broadcast. The provider (the DTH platform) doesn’t create
original programming itself; it pays other companies (HBO, for example,
or ESPN or STAR TV or Sahara etc.) for the right to broadcast their
content via satellite. In this way, the provider is a reseller of the
programming sources. (Cable television networks also work on the same
principle.) The broadcast center is the central hub of the system.
At the broadcast center or the Playout & Uplink location, the television
provider receives signals from various programming sources, compresses
these signals using digital compression (scrambling if necessary),
and beams a broadcast signal to the proper satellite. The satellite
receive the signal from the broadcast station and rebroadcast them
to the ground. The viewer’s dish picks up the signal from the
satellite (or multiple satellites in the same part of the sky) and
passes it on to the receiver in the viewer’s house. The receiver
processes the signal and passes it on to a standard television. These
are the steps in greater detail: Satellite TV providers get programming from two major sources: International
turnaround channels (such as HBO, ESPN and CNN, STAR TV, SET, B4U etc)
and various local channels (SaBe TV, Sahara TV, Doordarshan, etc).
Most of the turnaround channels also provide programming for cable
television, so sometimes some of the DTH platforms will add in some
special channels exclusive to itself to attract more subscriptions.
Turnaround channels usually have a distribution center that beams their
programming to a geostationary satellite. The broadcast center uses
large satellite dishes to pick up these analog and digital signals
from several sources. The broadcast center converts all of this programming into a high-quality,
uncompressed digital stream. At this point, the stream contains a vast
quantity of data — about 270 megabits per second (Mbit/s) for
each channel. In order to transmit the signal from there, the broadcast
center has to compress it. Otherwise, it would be too big for the satellite
to handle. The providers use the MPEG-2 compressed video format — the
same format used to store movies on DVDs. With MPEG-2 compression,
the provider can reduce the 270-Mbit/s stream to about 3 or 10 Mbit/s
(depending on the type of programming). This is the crucial step that
has made DTH service a success. With digital compression, a typical
satellite can transmit about 200 channels. Without digital compression,
it can transmit about 30 channels. At the broadcast center, the high-quality
digital stream of video goes through an MPEG-2 encoder, which converts
the programming to MPEG-2 video of the correct size and format for
the satellite receiver in your house. After the video is compressed, the provider needs to encrypt it in
order to keep people from accessing it for free. Encryption scrambles
the digital data in such a way that it can only be decrypted (converted
back into usable data) if the receiver has the correct decoding satellite
receiver with decryption algorithm and security keys. Once the signal
is compressed and encrypted, the broadcast center beams it directly
to one of its satellites. The satellite picks up the signal, amplifies
it and beams it back to Earth, where viewers can pick it up. A satellite dish is just a special kind of antenna designed to focus
on a specific broadcast source. The standard dish consists of a parabolic
(bowl-shaped) surface and a central feed horn. To transmit a signal,
a controller sends it through the horn, and the dish focuses the signal
into a relatively narrow beam. The dish on the receiving end can’t
transmit information; it can only receive it. The receiving dish works
in the exact opposite way of the transmitter. When a beam hits the
curved dish, the parabola shape reflects the radio signal inward onto
a particular point, just like a concave mirror focuses light onto a
particular point. The curved dish focuses incoming radio waves onto
the feed horn. In this case, the point is the dish’s feed horn,
which passes the signal onto the receiving equipment. In an ideal setup,
there aren’t any major obstacles between the satellite and the
dish, so the dish receives a clear signal. In some systems, the dish
needs to pick up signals from two or more satellites at the same time.
The satellites may be close enough together that a regular dish with
a single horn can pick up signals from both. This compromises quality
somewhat, because the dish isn’t aimed directly at one or more
of the satellites. A new dish design uses two or more horns to pick
up different satellite signals. As the beams from different satellites
hit the curved dish, they reflect at different angles so that one beam
hits one of the horns and another beam hits a different horn. The central
element in the feed horn is the low noise blockdown converter, or LNB.
The LNB amplifies the signal bouncing off the dish and filters out
the noise (signals not carrying programming). The LNB passes the amplified,
filtered signal to the satellite receiver inside the viewer’s
house. The end component in the entire satellite TV system is the receiver.
The receiver has four essential jobs: It de-scrambles the encrypted
signal. In order to unlock the signal, the receiver needs the proper
decoder chip for that programming package. The provider can communicate
with the chip, via the satellite signal, to make necessary adjustments
to its decoding programs. The provider may occasionally send signals
that disrupt illegal de-scramblers, as an electronic counter measure
(ECM) against illegal users. It takes the digital MPEG-2 signal and
converts it into an analog format that a standard television can recognize.
Since the receiver spits out only one channel at a time, you can’t
tape one program and watch another. You also can’t watch two
different programs on two TVs hooked up to the same receiver. In order
to do these things, which are standard on conventional cable, you need
to buy an additional receiver. Some receivers have a number of other
features as well. They pick up a programming schedule signal from the
provider and present this information in an onscreen programming guide.
Many receivers have parental lock-out options, and some have built-in
Digital Video Recorders (DVRs), which let you pause live television
or record it on a hard drive. While digital broadcast satellite service
is still lacking some of the basic features of conventional cable (the
ability to easily split signals between different TVs and VCRs, for
example), varied programming selection and extended service areas are
features now seen as an alternative. South African-based Multichoice's DStv is the main digital satellite television provider in sub-Saharan Africa, broadcasting principally in English, but also in Portuguese, German and Afrikaans. Canal Horizons, owned by France's Canal+, is the main provider in French-speaking Africa. Another entrant into the satellite television circuit in Africa is MyTvAfrica, a subsidiary of Dubai based Strong Technologies. Satellite television has been far more successful in Africa than cable, primarily because the infrastructure for cable television does not exist and would be expensive to install since majority of Africans cannot afford paid cable television. Furthermore, maintaining a cable network is expensive due to the need to cover larger and more sparsely populated areas though there are some terrestrial pay-TV and MMDS services. The launch of Free2view has made satellite TV available to the masses in Africa. Free2view currently broadcasts MSNBC as its exclusive news channel and is about to roll out additional channels. GTV, a British-based company, has become the second in sub-saharan
Africa providing digital satellite television with the focus first
on Kenya Uganda, Tanzania, Zimbabwe, Congo ETC. Traditionally DStv had held a monopoly over Nigeria's Satellite television
sector but three new companies, HiTVmytv and trend tv are starting
to compete in this sector Sudan TV, the government-owned national network, is available by satellite
as well as broadcast.[2] Currently, there are two primary satellite television providers of subscription based service available to United States consumers: Dish Network and DirecTV. Over the past three decades, various U.S. satellite services have come and gone or combined to form the current primary services. In 1975 RCA created Satcom 1, the first satellite built especially for use by the then three national television networks (CBS, NBC, and ABC). Later that same year, HBO leased a transponder on Satcom 1 and began transmission of television programs via satellite to cable systems. Owners of cable systems paid $10,000 to install 3-meter dishes to receive TV signals in C-band. In 1976 Taylor Howard built an amateur system, which consisted of a converted military surplus radar dish and a satellite receiver designed and built by Howard, for home satellite reception. Taylor's system could be used for receiving TV programs both from American and Soviet communication satellites. In 1977 Pat Robertson launched the first satellite-delivered basic cable service called the CBN Cable Network. In 1979, the Satellite Home Viewers Act allowed homeowners in the US to own and operate their own home satellite system, consisting of C-band equipment from a multitude of manufacturers who were making parts for systems such as Taylor Howard's, and began a large controversy of which channels could be received by whom. USSB was a direct-to-home service founded in 1981. In the early 1990s they partnered with Hughes and continued operation until purchased in 1998 by DirecTV. In 1991 Primestar launched as the first North American DBS service. Hughes’s DirecTV, the first national high-powered upper Ku-band DBS system, went online in 1994. The DirecTV system became the new delivery vehicle for USSB. In 1996, EchoStar’s Dish Network went online in the United States and has gone on to similar success as DirecTV’s primary competitor. The AlphaStar service launched in 1996 and went into bankruptcy in 1997. Dominion Video Satellite Inc's Sky Angel also went online in the United States in 1996 with its DBS service geared towards "faith and family". Primestar sold its assets to Hughes in 1999 and switched from DBS to an IPTV platform. In 2004, Cablevision’s Voom service went online, specifically
catering to the emerging market of HDTV owners and aficionados, but
folded in April 2005. The service’s “exclusive” high-definition
channels were migrated to the Dish Network system. Commercial DBS services
are the primary competition to cable television service, although the
two types of service have significantly different regulatory requirements
(for example, cable television has public access requirements, and
the two types of distribution have different regulations regarding
carriage of local stations). The majority of ethnic-language broadcasts in North America are carried on Ku band free-to-air. The largest concentration of ethnic programming is on Galaxy 19 at 97° W. Pittsburgh International Telecommunications and GlobeCast World TV offers a mix of free and pay-TV ethnic channels in the internationally-standard DVB-S format, as do others. Home2US Communications Inc. also offers several ethnic channels on AMC-4 at 101° W, as well as other free and pay-TV channels. Several U.S.-English language network affiliates (representing CBS, NBC, ABC, PBS, FOX, the CW (formerly the WB and UPN), ION Network and MyNetworkTV) are available as free-to-air broadcasts, as are the three U.S.-Spanish language networks (Univisión, Telefutura and Telemundo). The number of free-to-air specialty channels is otherwise rather limited. Specific FTA offerings tend to appear and disappear rather often and typically with little or no notice, although sites such as LyngSat do track the changing availability of both free and pay channels worldwide.[3] On October 7, 2009, NAB TV Board chair Paul Karpowicz planned to testify before the Senate Communications Subcommittee that broadcasters would be willing to allow subscribers of distant signals to continue to do so even if the digital transition resulted in those subscribers receiving stations that they could not before. The NAB did oppose offering new distant signals if a digital signal was available. The Satellite TV Modernization Act had to be passed by the end of 2009. The House bill also allowed Dish Network to offer distant signals.[4] On November 5, Senate Judiciary Committee chairman Patrick Leahy said he hoped for a "short-time agreement" on the bill passed out of committee September 24. If the Senate approves, the House will have to approve the bill, and if the two versions cannot be reconciled, the license to import signals that expires at the end of the year could be extended.[5] The House version included an agreement with Echostar that, where possible, all 210 markets could receive signals, and Echostar could once again deliver distant signals. The Senate Commerce Committee approved a version of the bill on November 19, without an amendment requiring local signals in all markets in three years, though a study would be conducted on why 30 markets still had a problem. Before Senate approval, the two versions of the bill will have to be reconciled; the Judiciary Committee had a short market fix, while the Commerce committee bill required PBS in HD sooner.[6] The House approved the Satellite Home Viewer Reauthorization Act December 3. It included both the House Commerce Committee and House Judiciary Committee versions and renewed the ability to use distant signals for five years, allowed Dish Network to offer distant signals again, and required 28 markets to receive signals not available locally. The bill also dealt with some copyright issues and required Dish Network to offer HD noncommercial signals by 2011 instead of 2013.[7] One potential problem: determining who cannot receive a signal is still based on analog rather than digital TV.[8] On February 11, 2010, Senate Majority Leader Harry Reid said the satellite
reauthorization was part of a jobs bill. Rick Boucher, House chairman
for communications and the Internet, believed the bill would pass.
The deadline is March, since it has been extended 60 days.[9] Sen.
Jim Bunning blocked the legislation in the Senate on Feb. 25, even
though it passed the House.[10] On March 1, 2010, The Satellite Television
Extension and Localism Act of 2010, scheduled to expire in 2014, became
part of a jobs bill with help from Sen. Patrick Leahy.[11] Currently, there are two primary satellite television providers of
subscription based service available to Canadians consumers: Bell TV
and Shaw Direct.The CRTC has refused to license American satellite
services, but nonetheless hundreds of thousands (up to a million by
some estimates) of Canadians access or have accessed American services[12] — usually
these services have to be billed to an American address and are paid
for in U.S. dollars, although some viewers receive American signals
through pirate decryption. Whether such activity is grey market or
black market is the source of often heated debate between those who
would like greater choice and those who argue that the protection of
Canadian firms and Canadian culture is more important. In October 2004,
Quebec Judge Danièle Côté ruled Canada's Radiocommunication
Act to be in direct violation of the Canadian Charter of Rights and
Freedoms, insofar as it bans reception of unlicensed foreign television
services. The judgment gave the federal government a one-year deadline
to remedy this breach of the Constitution. However, this contradicts
prior Supreme Court of Canada decisions and, at last word in late 2004,
was expected to be appealed.[citation needed] In addition, Canadian
satellite providers continue to be plagued by the unquestionably black
market devices which "pirate" or "steal" their
signals as well as by a number of otherwise completely lawful devices
which can be reprogrammed to receive pirate TV. Although there are
no official statistics, the use of American satellite services in Canada
appears to be declining as of 2004 Some would claim that this is probably
due to a combination of increasingly aggressive police enforcement
and an unfavourable exchange rate between the Canadian and U.S. currencies.
As the U.S. dollar has been declining as of 2005 versus other international
currencies, the decline in DirecTV viewership in Canada may well be
related not to a cost difference as much as to the series of smart
card swaps which have rendered the first three generations of DirecTV
access cards (F, H and HU) all obsolete. Latin America’s main satellite system are SKY Latin America, which has approximately 1.4 million subscribers in each of Brazil and Mexico and DirecTV Latin America, which provides service to the rest of the Americas, with a total of approximately 1.3 million subscribers. Pay-TV is not popular among Latin Americans because fees are expensive in PPP terms. The service offered in Brazil includes Digital TV with full Dolby
Digital surround support, mts and multiple subtitle options, a first
for the Brazilian market. A recent update to Sky's services in Brazil
is Sky+ which allows the customer to record a program while watching
another one and also Sky HD which currently provides up to 29 high
definition channels. Services are however relatively expensive, therefore
market penetration is still limited. There are several satellite providers in Bangladesh. The main ones are listed below: 1. Bangla Vision resume Kazakhstan The first satellite TV channel in Kazakstan, CaspioNet, was launched
by the Khabar news agency in 2002. Malaysia's sole satellite television operator, Measat Broadcast Network
Systems (a subsidiary of Astro All Asia Networks plc) launched Astro
in 1996. It currently holds exclusive rights from the Malaysian government
to offer satellite television broadcasting services in the country
through the year 2017. The medium-scale Broadcasting Satellite for Experimental Purposes
(BSE) was planned by Ministry of Posts and Telecommunications (MOPT)
and developed by the National Space Development Agency of Japan (NASDA)
since 1974. After that, the first Japanese experimental broadcasting
satellite, called BSE or Yuri, was launched in 1978. NHK started experimental
broadcasting of TV program using BS-2a satellite on May, 1984. The
satellite BS-2a was launched in preparation for the start of full scale
2-channel broadcasts. Broadcasting Satellite BS-2a was the first national
DBS (direct broadcasting satellite), transmitting signals directly
into the home of TV viewers. Attitude control of the satellite was
conducted using the 3 axial method (zero momentum), and design life
was 5 years. The TV transponder units are designed to sufficiently
amplify transmitted signals to enable reception by small, 40 or 60
cm home-use parabolic antennas. The satellite was equipped with 3 TV
transponders (including reserve units). However, one transponder malfunctioned
2 months after launch (March 23, 1984) and a second transponder malfunctioned
3 months after launch (May 3, 1984). So, the scheduled satellite broadcasting
had to be hastily adjusted to test broadcasting on a single channel.
Later, NHK started regular service (NTSC) and experimental HDTV broadcasting
using BS-2b on June, 1989. Some Japanese producers of home electronic
consumer devices began to deliver TVsets, VCRs and even home acoustic
systems equipped by built-in satellite tuners or receivers. Such electronic
goods had a specific BS logo. On April, 1991, Japanese company JSB
started pay TV service while BS-3 communication satellite was in use.
In 1996 total number of households that receive satellite broadcasting
exceeded 10 million. The modern two satellite systems in use in Japan
are BSAT and JCSAT; the modern WOWOW Broadcasting Satellite digital
service uses BSAT satellites, while other system of digital TV broadcasting
SKY PerfecTV! uses JCSAT satellites. Over 300 TV Satellite television channels are broadcast in India.
This includes channels from the state-owned Doordarshan, News Corporation
owned STAR TV, Sony owned Sony Entertainment Television, Sun Network
and Zee TV. Direct To Home service is provided by DishTv India, Airtel
Digital Tv, BIG TV, DD Direct Plus, DishTV, Sun Direct DTH and Tata
Sky. These services are provided by locally built satellites from ISRO
such as [15] INSAT 4CR, INSAT 4A, INSAT-2E, INSAT-3C and INSAT-3E as
well as private satellites such as the Dutch-based SES, Global-owned
NSS 6, Thaicom-2 and Telstar 10. In the recent years, there has been a lot of investment in television
industry in Pakistan. There are more than 90 Satellite channels operating
directly inside Pakistan and about 40 operating their broadcasting
from Dubai, Thailand, Bangkok and UK.[citation needed] * Dream Satellite TV is pay DTH service of Philippine Multimedia
Service Inc. (PMSI) resume Thailand TrueVisions is the leading pay TV service of Thailand which operate
cable TV in Bangkok and satellite TV across the country. TrueVisions
is owned by True Corporation. VIet Nam sat is just launched in 4/2008
and GMM Grammy is the second pay TV service of Thailand. Satellite television in Australia has proven to be a far more feasible
option than cable television, due to the vast distances between population
centres. The first service to come online in Australia was Galaxy,
which was later taken over by Cable Television giant Foxtel, which
now operates both cable and satellite services to all state capital
cities (except Darwin and Hobart) and the whole of Western Australia.
Its main metropolitan rival was Optus Vision, while rural areas are
served by Austar, both of which just rebroadcast Foxtel as of 2005.
In 2006 SelecTV began operating, aiming at providing comparatively
low cost packages and catering to specialised market segments. In New Zealand, SKY Network Television offers multichannel digital
satellite TV, in addition to its non-digital terrestrial UHF service.
The newly released Freeview service is also available on the Optus
D1 satellite, as well as a High Definition digital terrestrial service. In Europe, DBS satellite services are found mainly on Astra satellites and Hotbird (operated by Eutelsat.) BSkyB (known as Sky) serves the UK. SKY Italia, Canal Digitaal and UPC being the main providers in Italy, the Netherlands and Central Europe. The overall market share of DBS satellite services in 2004 was 21.4%
of all TV homes, however this highly varies from country to country.
For example, in Germany, with many free-to-air TV-stations, DBS market
share is almost 40%, and in Belgium and the Netherlands, it’s
only about 7%, due to the widespread cable networks with exclusive
content. The first Soviet communication satellite, called Molniya (??????, or "Lightning"), was launched in 1965. By November, 1967 the national system of satellite television, called Orbita was deployed. The system consisted of 3 highly elliptical Molniya satellites, Moscow-based ground uplink facilities and about 20 downlink stations, located in cities and towns of remote regions of Siberia and Far East. Each station had a 12-meter receiving parabolic antenna and transmitters for re-broadcasting TV signal to local householders. However, a large part of Soviet central regions were still not covered by transponders of Molniya satellites. By 1976 Soviet engineers developed a relatively simple and inexpensive system of satellite television (especially for Central and Northern Siberia). It included geostationary satellites called Ekran equipped with powerful 300 W UHF transponders, a broadcasting uplink station and various simple receiving stations located in various towns and villages of Siberian region. The typical receiving station, also called Ekran, represented itself as a home-use analog satellite receiver equipped with simple Yagi-Uda antenna. Later, Ekran satellites were replaced by more advanced Ekran-M series satellites. In 1979 Soviet engineers developed Moskva (or Moscow) system of broadcasting and delivering of TV signal via satellites. New type of geostationary communication satellites, called Gorizont, were launched. They were equipped by powerful onboard transponders, so the size of receiving parabolic antennas of downlink stations was reduced to 4 and 2.5 meters (in comparison of early 12- meter dishes of standard orbital downlink stations). By 1989 an improved version of Moskva system of satellite television has been called Moskva Global'naya (or Moscow Global). The system included a few geostationary Gorizont and Express type of communication satellites. TV signal from Moscow Global’s satellites could be received in any country of planet except Canada and North-West of the USA. Modern Russian satellite broadcasting services based on powerful geostationary buses such as Gals, Express, Yamal and Eutelsat which provide a large quantity of free-to-air television channels to millions of householders. Pay-TV is growing in popularity amongst Russian TV viewers. The NTV Russia news company, owned by Gazprom, broadcasts the NTV Plus package to 560,000 households, reaching over 1.5 million viewers. Tricolor TV (Russian: ???????? ??) the biggest satellite television operator. It broadcasts a pack of TV channels in the European part of Russia and most of Siberian, Ural and Far East regions. Broadcasting in the European part has been held since December 2005 from esv Eutelsat W4. Broadcasting in the Eastern regions began in December 2007. The principle difference between Tricolor TV and other Russian salellite TV operators is a pack of free channels broadcasts by Tricolor TV. There are 12 federal channels including "Pervy", "Rossiya", "NTV", "STS", "Bibigon" and others in the free "Basic" pack. Except these, there are 19 more TV channels for the whole family. The budget pack of satellite channels turned to be very popular among Russian viewers. The number of Tricolor TV's subscribers is the largest in Russia. In December 2009 the audience of Tricolor TV has reached a number of 6 000 000 households. [13] - The first commercial DBS service in the United Kingdom, Sky Television, was launched in 1989 and used the newly launched ASTRA satellite, providing 4 analogue TV channels. The channels and subsequent VideoCrypt video encryption system used the existing PAL broadcast standard. This gave Sky a distinct advantage over the winner of the UK state DBS licence, BSB. In the following year, after many delays, BSB was launched, broadcasting five channels (Now, Galaxy, The Movie Channel, The Power Station and The Sports Channel) in D-MAC format and using the EuroCypher video encryption system which was based heavily on the General Instruments VideoCipher system used in the USA. While the BSB system was technologically more advanced than the PAL system and one of the main selling points of the BSB offering was the Squarial, an expensive flat plate antenna and LNB. Sky's system used conventional and cheap dish and LNB technology. The competition between the two companies was fierce and bidding wars over the UK rights to movies. Sky kept costs to a bare minimum, operating from an industrial park in Isleworth in West London. BSB had expensive offices in London (Marco Polo House). The two services subsequently merged to form British Sky Broadcasting (BSkyB) though the new BSkyB was really Sky. The technologically more advanced BSB D-MAC/EuroCypher system was gradually replaced with Sky's VideoCrypt video encryption system. In 1994 17% of the group was floated on the London Stock Exchange (with ADRs listed on the New York Stock Exchange), and Rupert Murdoch’s News Corporation owns a 35% stake. By 1999, following the launch of several more satellites (at 19.2°E by SES Astra), the number of channels had increased to around 60 and BSkyB launched the first subscription-based digital television platform in the UK, offering a range of 300 channels broadcast from the ASTRA satellites at 28.2°E under the brand name Sky Digital. BSkyB’s analogue service was discontinued on 31 December 2001 and all customers have migrated to Sky Digital. In May 2008, a free-to-air satellite service from the BBC and ITV
was launched under the brand name Freesat, carrying a variety of channels,
including some content in HD formats. The first satellite service specifically set to the Nordic region was TV3 which launched in 1987. With the launch of Astra 1A, getting the TV3 channel got easier. The first Nordic-specific satellite, Tele-X, was launched in 1989. The services directed at Scandinavia were then scattered among several satellites. In 1993, the former BSB satellites were bought by a Swedish and a Norwegian company, respectively. These two satellites were renamed Thor 1 and Sirius 1, moved to new positions and started broadcasting services intended for people in the Nordic region. With the launch of additional Thor and Sirius satellites later in the 1990s, Astra and other satellites were abandoned by the Nordic services with almost all Nordic satellite television migrating to the Sirius and Thor satellites. Initially the basic channels were free-to-air. This caused several
rights problems since viewers throughout Europe were able to see very
much acquired English language programming as well as sports for free
on the Nordic channels, although the channels only held broadcasting
rights for specific countries. One way of avoiding that was to switch
from PAL to the D2-MAC standard, hardly used anywhere outside the Nordic
region. An unencrypted channel could still be seen in all the Nordic
satellite homes, so eventually all channels went encrypted (several
of them only being available in one country). There are two competing
satellite services: Canal Digital (Norwegian Telenor) and Viasat (Kinnevik).
Canal Digital launched in 1997 and was digital from the start, broadcasting
from Thor. Kinnevik had been operating an analogue subscription service
since the late 1980s, but waited until the year 2000 before launching
a digital service. All analogue services from Thor and Sirius will
have ceased in 2006, when the three remaining Danish channels go digital-only.
The competition between Viasat and Canal Digital has caused some homes
in Scandinavia to have to buy two set-top boxes and have two subscriptions
to get the full range of channels. Viasat doesn't provide their own
channels (TV3, TV3+, ZTV, TV1000 and the Viasat-branded channels) on
the Canal Digital platform. Canal Digital does however have exclusive
distribution of channels from SBS Broadcasting, Discovery, TV2 Denmark
and Eurosport; for several years the Swedish SVT and TV4 channels were
also exclusive to Canal Digital. The Middle East has a high penetration of homes receiving TV channels via DTH satellite. One of the pioneers of free-to-air digital satellite television is considered to be MBC, which began broadcasting in c band through [Arabsat] and is the first network in the world to offer a free-to-air Western based English language movie channel to the Middle East audience via its spinoff channel MBC 2. Its direct rival is considered to be Dubai, UAE based One TV, earlier called Channel 33, which was the first channel in the Middle East to provide English language general entertainment programming for the expatriate community. Nourmina Channel is the first satellite channel owned by a Jordanian national of the private sector, which broadcasts on Nile Sat reluctantly 12303H, which covers all the Arab countries, Africa and most parts of Europe - The first digital DTH pay-TV network to provide Indian Entertainment was Orbit Satellite Television and Radio Network broadcasting via Eurobird 2 (Ku band), later on Showtime Arabia a joint venture between Viacom (21% stake) and KIPCO (79% stake) started broadcasting, via PanAmSat (C band), but later switched over to Nilesat (KU band). Arab Radio and Television Network(ART) now known as Arab Digital Distribution although a late comer, gained ground by broadcasting exclusive sports events. Most of the popular channels are transmitting from these satellites and orbital positions: Arabsat at 26°E, AsiaSat at 100.5°E and 105.5°E, Eutelsat Hot Bird at 13°E, Nilesat at 7°W, and PanAmSat at 68.5°E. + Currently, there are two primary satellite television providers of subscription based service available to Canadians consumers: Bell TV and Shaw Direct. In Israel, Satellite TV services were introduced by YES! company, using Israeli based Amos (satellite). The Wikipedia article on this page is released under CC-BY-SA. |
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