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INSAT-4E/GSAT-6 India's First S-DMB Satellite For Defence & Strategic Applications Ready For Launch

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INSAT-4E/GSAT-6 India's First S-DMB Satellite

With its landmark achievements, ISRO is making rapid strides towards becoming a world leader in space technology. Sudhindra Haldodderi writes about one of its latest creations that promises to revolutionise mobile television.

Launching a satellite and positioning it in the right orbit is no big deal for ISRO. Space scientists of the country have mastered this art with a textbook perfection. The first launch successes in Chandrayaan-1 and Mars Orbiter Mission created world records and catapulted ISRO into the elite five-nation space league. Today, ISRO operates the largest constellation of communication satellites in the Asia-Pacific region, while its remote sensing satellites are largest in number in the world.

Ever-growing demand of communication needs of the country is largely met by the indigenous INSATs/GSATs, but still there is enough space for more number of satellites. About 10 years ago, ISRO planned to build an exclusive satellite for mobile television services with multimedia applications. Beaming digitally coded signals to moving automobiles and mobile phones was considered as a revolutionary idea.

Consequently, the satellite GSAT-6 was conceptualised with new technologies for data compression, on-board antenna (5-6 m diameter) and high power S-band communication system. The system was expected to broadcast more than 10 audio and video channels simultaneously. GSAT-6 was also designed to carry multiple transponders operating on the same frequency band to enhance the coverage.
Not an easy journey - The greatest challenge envisaged by ISRO was the deployment of 6.5 metre antenna in a rocket envelope, which cannot accommodate anything greater than 2.5 metre in girth. It was then that the concept of folding the antenna like an umbrella was designed. The folded umbrella would be placed in the rocket and unfurled in the orbit after the satellite was in position. What more, building the antenna system with perimeter truss consisting of composite tubes to support the front and rear webs with fibre reinforcement was attempted for the first time.​

Graphite or epoxy tubes connected by hinges that allow the furled antenna were to be stowed for launch to fit within the rocket fairing. Pyro-initiated release mechanisms were required to open launch restraints before the antenna gets deployed. This also involved development of highly accurate, synchronous and agile actuation system.

Another technological challenge for ISRO scientists was to raise the power onboard the satellite, four to five times the normal limits, to enable the omni-directional high-powered spot beam transmission and there was also the challenge of shrinking the bandwidth to a great extent.

When a satellite system is required to communicate with a very small earth receiver such as handheld mobile phone or a moving automobile-based unit, the flux density of the signal received should be of a high order. This provides a high quality Satellite Digital Multimedia Broadcasting (S-DMB) link. To achieve this, satellites usually operate on S-Band and provision is made for a combination of high power amplifiers and a large aperture reflector antenna on the satellite. A 6.5 metre projected aperture paraboloid reflector has been used on the GSAT-6 satellite to achieve high beam directivity over the desired coverage regions.

While GSAT-6 is designed to provide digital CD-quality audio, TV-quality video and data broadcasting services to the country, the radiation pattern was designed to be carefully controlled to avoid interferences with other Asiatic regions.

While conceiving this ingenious satellite, the scientists came across two major design challenges: one, the packaging of the stowed structure and two, controlling the reaction caused by the unfurled structure when operating in the orbit.

Extensive ground tests were carried out on the satellite system to ensure proper functioning. An acceptable process coupled with test results and analysis needs was developed to predict antenna performance, since direct measurement of the antenna radiation pattern of large aperture is impractical.

The Government of India approved the project of design, development and launch of GSAT-6/INSAT-4E to provide Satellite Digital Multimedia Broadcasting (S-DMB) at a total estimated cost of Rs. 269 crores with a foreign exchange component of Rs. 102 crores. The project provided a platform for technology demonstration of large unfurlable antenna in spacecraft, handheld ground terminals and large network management systems.


To encourage private participation, outside investment and to borrow the state-of-the-art technologies, Antrix, the commercial arm of ISRO signed a strategic agreement with DEVAS Multimedia Private Limited. The $300 million deal provided leasing of 90 per cent of the space signal capacity of two satellites for 12 years to DEVAS. The Cabinet also approved building of GSAT-6A satellite of similar capacity as GSAT-6 by ISRO.
Projects underway - ISRO envisaged development of technology and business of S-DMB services including interconnectivity of 2.5G/3G network. This would have enabled ISRO to become a leader in the growing world market of S-DMB services for mobile vehicles and cellular phones. DEVAS was expected to build the network of ground infrastructure, content providers and distribution channels.​

But sadly, the 2G-spectrum scan of 2010 cast a dark shadow on Antrix-DEVAS deal with controversies in the procedural lapses prior to signing the contract.

Subsequently, the Indian government cancelled the contract with DEVAS in February 2011, reserved satellite under development GSAT-6 for military use, thereby inviting a hefty arbitration case filed by DEVAS in the International Court at Hague. GSAT-6 project was shelved and GSAT-7 (Rukmini) was successfully launched as the first Indian military satellite in 2013.

But fortunately, with the clouds of controversy finally clearing up, GSAT-6 with five spatial transponders for multimedia services has completed all the ground tests including integration and thermovacuum tests. This 2100 kg satellite is expected to be launched on a GSLV rocket from Sriharikota in a month or two.

In addition to GSAT-6, ISRO shall be launching three more satellites in the Indian Regional Navigation Satellite System series and two satellites in the GSAT series this year. CARTOSAT-2C is also expected to be launched at the end of this year which possesses 62 cm spatial resolution camera on board. The astronomy satellite ‘Astrosat’ is also slated for its launch in 2015. But the ultimate feather in ISRO’s cap shall be the launching of five foreign satellites – three from Britain and two from Indonesia.

The dream launch vehicle of ISRO, GSLV-Mark III, which has an indigenous cryogenic engine and is capable of lifting 4000 kg , is still under readiness review. Hopefully, by end of 2016, this launcher can position ISRO into the heavy-lifter league.​

(The author is a former scientist of DRDO.)

Source:- Visionary dreams
 
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To simplify - S-DMB or Satellite based Digital Multimedia Broadcasting is a digital radio transmission technology developed in South Korea as part of the national IT project for sending multimedia such as TV, radio and datacasting to mobile devices such as mobile phones, laptops and GPS navigation systems. S-DMB is intended to deliver multimedia content to mobile handsets. The system can deliver real-time streaming TV-programs and multimedia services as well as non real-time push and store multimedia services to mobile users.

In 2005, South Korea became the first country in the world to start S-DMB service. Countries with S-DMB standards include -

(01) CMMB (China Mobile Multimedia Broadcasting) – China
(02) DVB-SH (Digital Video Broadcasting - Satellite for Handhelds) – European Union & United States
(03) S-DMB (Satellite Digital Multimedia Broadcast) – South Korea

With the launch of INSAT-4E/GSAT-6, India will be the fourth country (EU excluded) in world to indigenously deploy Satellite based Digital Multimedia Broadcasting which can be very well used for other social and strategic applications as designated by the government of India back in 2011.
 
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This was the satellite that was earmarked for the now Infamous DEVAS Multimedia Private Limited. :P
 
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To simplify - S-DMB or Satellite based Digital Multimedia Broadcasting is a digital radio transmission technology developed in South Korea as part of the national IT project for sending multimedia such as TV, radio and datacasting to mobile devices such as mobile phones, laptops and GPS navigation systems. S-DMB is intended to deliver multimedia content to mobile handsets. The system can deliver real-time streaming TV-programs and multimedia services as well as non real-time push and store multimedia services to mobile users.

In 2005, South Korea became the first country in the world to start S-DMB service. Countries with S-DMB standards include -

(01) CMMB (China Mobile Multimedia Broadcasting) – China
(02) DVB-SH (Digital Video Broadcasting - Satellite for Handhelds) – European Union & United States
(03) S-DMB (Satellite Digital Multimedia Broadcast) – South Korea

With the launch of INSAT-4E/GSAT-6, India will be the fourth country (EU excluded) in world to indigenously deploy Satellite based Digital Multimedia Broadcasting which can be very well used for other social and strategic applications as designated by the government of India back in 2011.

Great news
 
. . .
Visionary dreams
image001.jpg

INSAT-4E/GSAT-6 India's First S-DMB Satellite

With its landmark achievements, ISRO is making rapid strides towards becoming a world leader in space technology. Sudhindra Haldodderi writes about one of its latest creations that promises to revolutionise mobile television.
Launching a satellite and positioning it in the right orbit is no big deal for ISRO. Space scientists of the country have mastered this art with a textbook perfection. The first launch successes in Chandrayaan-1 and Mars Orbiter Mission created world records and catapulted ISRO into the elite five-nation space league. Today, ISRO operates the largest constellation of communication satellites in the Asia-Pacific region, while its remote sensing satellites are largest in number in the world.

Ever-growing demand of communication needs of the country is largely met by the indigenous INSATs/GSATs, but still there is enough space for more number of satellites. About 10 years ago, ISRO planned to build an exclusive satellite for mobile television services with multimedia applications. Beaming digitally coded signals to moving automobiles and mobile phones was considered as a revolutionary idea.

Consequently, the satellite GSAT-6 was conceptualised with new technologies for data compression, on-board antenna (5-6 m diameter) and high power S-band communication system. The system was expected to broadcast more than 10 audio and video channels simultaneously. GSAT-6 was also designed to carry multiple transponders operating on the same frequency band to enhance the coverage.

Not an easy journey - The greatest challenge envisaged by ISRO was the deployment of 6.5 metre antenna in a rocket envelope, which cannot accommodate anything greater than 2.5 metre in girth. It was then that the concept of folding the antenna like an umbrella was designed. The folded umbrella would be placed in the rocket and unfurled in the orbit after the satellite was in position. What more, building the antenna system with perimeter truss consisting of composite tubes to support the front and rear webs with fibre reinforcement was attempted for the first time.

Graphite or epoxy tubes connected by hinges that allow the furled antenna were to be stowed for launch to fit within the rocket fairing. Pyro-initiated release mechanisms were required to open launch restraints before the antenna gets deployed. This also involved development of highly accurate, synchronous and agile actuation system.

Another technological challenge for ISRO scientists was to raise the power onboard the satellite, four to five times the normal limits, to enable the omni-directional high-powered spot beam transmission and there was also the challenge of shrinking the bandwidth to a great extent.

When a satellite system is required to communicate with a very small earth receiver such as handheld mobile phone or a moving automobile-based unit, the flux density of the signal received should be of a high order. This provides a high quality Satellite Digital Multimedia Broadcasting (S-DMB) link. To achieve this, satellites usually operate on S-Band and provision is made for a combination of high power amplifiers and a large aperture reflector antenna on the satellite. A 6.5 metre projected aperture paraboloid reflector has been used on the GSAT-6 satellite to achieve high beam directivity over the desired coverage regions.

While GSAT-6 is designed to provide digital CD-quality audio, TV-quality video and data broadcasting services to the country, the radiation pattern was designed to be carefully controlled to avoid interferences with other Asiatic regions.

While conceiving this ingenious satellite, the scientists came across two major design challenges: one, the packaging of the stowed structure and two, controlling the reaction caused by the unfurled structure when operating in the orbit.

Extensive ground tests were carried out on the satellite system to ensure proper functioning. An acceptable process coupled with test results and analysis needs was developed to predict antenna performance, since direct measurement of the antenna radiation pattern of large aperture is impractical.

The Government of India approved the project of design, development and launch of GSAT-6/INSAT-4E to provide Satellite Digital Multimedia Broadcasting (S-DMB) at a total estimated cost of Rs. 269 crores with a foreign exchange component of Rs. 102 crores. The project provided a platform for technology demonstration of large unfurlable antenna in spacecraft, handheld ground terminals and large network management systems.


To encourage private participation, outside investment and to borrow the state-of-the-art technologies, Antrix, the commercial arm of ISRO signed a strategic agreement with DEVAS Multimedia Private Limited. The $300 million deal provided leasing of 90 per cent of the space signal capacity of two satellites for 12 years to DEVAS. The Cabinet also approved building of GSAT-6A satellite of similar capacity as GSAT-6 by ISRO.

Projects underway - ISRO envisaged development of technology and business of S-DMB services including interconnectivity of 2.5G/3G network. This would have enabled ISRO to become a leader in the growing world market of S-DMB services for mobile vehicles and cellular phones. DEVAS was expected to build the network of ground infrastructure, content providers and distribution channels.

But sadly, the 2G-spectrum scan of 2010 cast a dark shadow on Antrix-DEVAS deal with controversies in the procedural lapses prior to signing the contract.

Subsequently, the Indian government cancelled the contract with DEVAS in February 2011, reserved satellite under development GSAT-6 for military use, thereby inviting a hefty arbitration case filed by DEVAS in the International Court at Hague. GSAT-6 project was shelved and GSAT-7 (Rukmini) was successfully launched as the first Indian military satellite in 2013.

But fortunately, with the clouds of controversy finally clearing up, GSAT-6 with five spatial transponders for multimedia services has completed all the ground tests including integration and thermovacuum tests. This 2100 kg satellite is expected to be launched on a GSLV rocket from Sriharikota in a month or two.

In addition to GSAT-6, ISRO shall be launching three more satellites in the Indian Regional Navigation Satellite System series and two satellites in the GSAT series this year. CARTOSAT-2C is also expected to be launched at the end of this year which possesses 62 cm spatial resolution camera on board. The astronomy satellite ‘Astrosat’ is also slated for its launch in 2015. But the ultimate feather in ISRO’s cap shall be the launching of five foreign satellites – three from Britain and two from Indonesia.

The dream launch vehicle of ISRO, GSLV-Mark III, which has an indigenous cryogenic engine and is capable of lifting 4000 kg , is still under readiness review. Hopefully, by end of 2016, this launcher can position ISRO into the heavy-lifter league.

(The author is a former scientist of DRDO.)

Source:- Visionary dreams

Great developement !

Launch eagerly awaited ...

Uneventful and successful Unfurling of antenna will be a great challenge ...no amount of ground simulation can make you 100 % sure ...

i think ISRO will use same kind of antenna in one of the proposed JV with NASA....

we need to build upon our expertise in the field and hard sell it to the world wide customers ....
 
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Great developement !

Launch eagerly awaited ...

Uneventful and successful Unfurling of antenna will be a great challenge ...no amount of ground simulation can make you 100 % sure ...

i think ISRO will use same kind of antenna in one of the proposed JV with NASA....

we need to build upon our expertise in the field and hard sell it to the world wide customers ....

Indeed - The satellite design will make use of a large deployable mesh antenna and will operate on dual L-band and S-band. World's first dual frequency remote sensing satellite - Under the terms of the agreement, NASA will provide the mission's L-band synthetic aperture radar (SAR), a high-rate communication subsystem for science data, GPS receivers, a solid state recorder, and a payload data subsystem. ISRO will provide the satellite bus, an S band synthetic aperture radar SAR, the launch vehicle and associated launch services.

NISAR_artist_concept.jpg
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NISAR_Mission_Logo.png
 
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INSAT-4E/GSAT-6 will be launched in August '15 on-board GSLV Mark II (GSLV-D6). This will be the third flight of Mark II with the indigenous cryogenic engine CE-7.5 which would further validate the operational readiness of Mark II as well. Hyderabad-based Electronics Corporation of India Limited (ECIL) has formally handed over indigenously built Programmable Logic Controllers (PLC), which will be used in a critical final stage during rocket launches.
The controllers will play a vital role in filling aviation fuel in the satellite launch vehicles of ISRO’s -Polar Satellite Launch Vehicle (PSLV) and Geosynchronous Satellite launch Vehicle (GSLV).


A shot in the arm for Indian space programme
28hymsg01-ECIL__hy_2388994e.jpg

ECIL hands over vital control systems for PSLV vehicles to Satish Dhawan Space Centre. Customised PLC has undergone a series of validation exercises.

Hyderabad-based Electronics Corporation of India Limited (ECIL) has formally handed over indigenously built Programmable Logic Controllers (PLC), which will be used in a critical final stage during rocket launches, to Satish Dhawan Space Centre (SDSC), the satellite launching station of ISRO at Sriharikota.

The controllers will play a vital role in filling aviation fuel in the satellite launch vehicles of ISRO’s -Polar Satellite Launch Vehicle (PSLV) and Geosynchronous Satellite launch Vehicle (GSLV).

“We will use these indigenous control systems for a critical function, which is to load fuel at the final countdown stages of PSLV and GLSV rockets before they are launched. Our researchers and ECIL collaborated for nearly two years to build custom-made control systems for us,” said Director SDSC, Dr. M.Y.S. Prasad.

In another three to four years, all the critical mission systems, which are part of the ground control and used to launch rockets, will undergo complete indigenisation, he said. “We will phase-out the existing 20 imported control systems, which form the ground control at the space station. The value of the indigenous PLC is nearly Rs. 3 crore and we are going to get similar control systems from ECIL worth Rs. 15 to Rs. 20 crore in the coming years,” Dr. Prasad said.

The customised PLC has already undergone a series of validation exercises to meet the stringent requirements for the space centre. “By June, we will start the process of setting-up the control system in the space centre. We are planning to use control systems in real time in September-October when we launch a PSLV,” he said.

Giving more details on the role of the control systems, Dr. Prasad said that typically 40 tonnes of fuel is filled in a PSLV in two hours without spillage of even a single drop.

“This process is fully automated because nobody is allowed in the vicinity of the launch vehicles. It’s an achievement that Indian researchers have managed to develop systems that will ensure this complicated process without any hiccups,” he said. Top scientists including CMD, ECIL, Dr. P. Sudhakar were present in the handing over ceremony.

Source:- A shot in the arm for Indian space programme - The Hindu
 
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To simplify - S-DMB or Satellite based Digital Multimedia Broadcasting is a digital radio transmission technology developed in South Korea as part of the national IT project for sending multimedia such as TV, radio and datacasting to mobile devices such as mobile phones, laptops and GPS navigation systems. S-DMB is intended to deliver multimedia content to mobile handsets. The system can deliver real-time streaming TV-programs and multimedia services as well as non real-time push and store multimedia services to mobile users.

In 2005, South Korea became the first country in the world to start S-DMB service. Countries with S-DMB standards include -

(01) CMMB (China Mobile Multimedia Broadcasting) – China
(02) DVB-SH (Digital Video Broadcasting - Satellite for Handhelds) – European Union & United States
(03) S-DMB (Satellite Digital Multimedia Broadcast) – South Korea

With the launch of INSAT-4E/GSAT-6, India will be the fourth country (EU excluded) in world to indigenously deploy Satellite based Digital Multimedia Broadcasting which can be very well used for other social and strategic applications as designated by the government of India back in 2011.

Wooow .So we need 2G/3G for direct TV broadcast or like Dish TV ? Pay some fee and get TV channels aired via mobile without internet .

Because I use lots of Live TV show over mobile now itself . But sadly I need WiFi or 3G connection . Please conform :D Am excited

Jitenga Jitenga India Jitenga :-)
 
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Wooow .So we need 2G/3G for direct TV broadcast or like Dish TV ? Pay some fee and get TV channels aired via mobile without internet .

Because I use lots of Live TV show over mobile now itself . But sadly I need WiFi or 3G connection . Please conform :D Am excited

Jitenga Jitenga India Jitenga :-)

You need to have a separate S-DMB Supported Device - Samsung, Motorola and LG offer such devices but they aren't currently available in the Indian market for we have no such application in India as of now - The 2G/3G mobile network will also be used to exchange security and billing data, as well as to support the point-to-point selective retransmission.

Certain channels on S-DMB will be free of cost but some will have to be charged.
 
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