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'India's manned moon mission by 2020' .:. NewKerala - India's Top Online Newspaper

Guwahati, Dec 6: India would be able to send a manned mission to the moon by 2020, while the second unmanned spacecraft would be ready by 2012, said a top space scientist who was involved in the successful launch of Chandrayaan-1.

"If everything goes as per the plan, we will be ready to send a man to moon by 2020," said Jitendranath Goswami, director of the Physical Research Laboratory (PRL), Ahmedabad.

PRL is the laboratory that helped build a payload called the high energy X-ray spectrometer that will look for water ice in the polar regions of the moon.

Goswami, who hails from Assam, was Saturday interacting with students, journalists, and academics, in Guwahati.

"Maybe in 50 years from now, there will be an alternate space to live in Mars," the space scientist said.

Goswami said he felt proud to be part of the historic moon mission and spelt out other programmes in the pipeline.

"As a scientist I have miles to go," Goswami was modest in his reply to a question as to how he felt being part of Chandrayaan-1.

"But we're not in any great hurry. We're hoping to get data (from Chandrayaan-1) for a long time."

He stressed on the need to help children get attracted towards science and space technology by urging parents to do something inspirational. "Parents and guardians can inspire their children to achieve something in life," Goswami said.
 
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Indian-built satellite goes global
Bangalore (PTI): In a major commercial achievement for the ISRO, its 'W2M satellite' built for Europe's leading satellite system specialist EADS Astrium is set to be launched from Kourou in French Guyana on December 20.

Weighing 3462 kg at lift-off, W2M is the heaviest spacecraft built by the Indian space agency till date and will be launched on board an Ariane rocket.

"That has reached Kourou...W2M for Eutelsat Communications," ISRO chairman G Madhavan Nair told PTI. W2M has been built by Bangalore-headquartered ISRO in 26 months, the agency's spokesperson S Satish said.

"ISRO has been able to meet the stringent time and quality schedule demanded by the customer," he said. Antrix, the commercial arm of ISRO, and EADS Astrium, signed contracts in February 2006 to provide communication satellites for the international market.

The first success of the alliance is demonstrated by the award of the W2M satellite contract by Eutelsat, the holding company of Eutelsat SA Group, a leading satellite operator. Nair said, "one more satellite is being built (under Antrix/EADS Astrium alliance). By next year, that will also be shipped."

Satish said W2M, designed for an operational lifetime of 15 years, would carry 32 transponders. Under the W2M contract, EADS Astrium was prime contractor in charge of overall programme management and built communication payload. Antrix/ISRO built the satellite bus, integrated and tested the spacecraft.

Satish said ISRO would also be in charge of early in-orbit operations. ISRO got a "good rate" as prevailing internationally for its work, officials said.

http://www.hinduonnet.com/thehindu/h...0812091662.htm

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Russia to take Indian astronaut on space mission in 2013-India-The Times of India

Russia to take Indian astronaut on space mission in 2013
10 Dec 2008, 1219 hrs IST, PTI


NEW DELHI: An Indian astronaut will embark on a mission to space in a Russian spacecraft within the next five years, nearly three decades after Rakesh Sharma undertook the historic flight.

This mission, tentatively scheduled for 2013, will be the precursor to Indian Space Research Organisation's (ISRO) maiden human spaceflight planned to be launched in 2015.

India and Russia signed a Memorandum of Understanding on Joint Activities in the Field of Human Spaceflight Programme during the recent visit of Russian President Dmitry Medvedev.

"As per the agreement, an Indian astronaut will first go on a space mission on a Russian spacecraft. This will be followed by an Indian manned mission to space in 2015," ISRO Chairman G Madhavan Nair said.

Under the MoU signed by Nair and his Russian counterpart Anatoly Perminov, ISRO and Russian space agency Roskosmos will jointly build the spacecraft for the Indian manned mission.

"We will be redesigning the Soyuz space capsule of the Russian agency for our mission," Nair said. Government has already sanctioned Rs 95 crore to study all aspects of the manned space mission under which ISRO plans to send a two-member crew on a week-long sojourn in space.

The spacecraft, to be placed in a low earth orbit, will splash in the Indian ocean after completion of the mission.

ISRO is setting up an astronaut training centre in Bangalore. For the two-member mission, a batch of 200 would be initially selected and trained before opting for four persons out of which two would go on the mission.
 
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The Space Review: Technical ego: India and Germany in space

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TerraSAR-X is a relatively inexpensive radar imaging satellite developed by the German space agency DLR. (credit: DLR)

Technical ego: India and Germany in space
by Dwayne A. Day
Monday, December 8, 2008

On December 3 the American Institute for Aeronautics and Astronautics (AIAA) Baltimore Section held a talk at the Johns Hopkins University’s Applied Physics Laboratory titled “Space Program Updates: Germany and India.” The featured speakers were Counsellor Devi Prasad Karnik of the Indian Consulate, and Dr. Jürgen Drescher of the German Center for Aeronautics and Spaceflight. The two men discussed the current activities and future goals of their respective space programs.

India in space

The first speaker was Devi Prasad Karnik, who first started working for the Indian Space Research Organisation (ISRO) in 1984 and now represents ISRO in the United States. Karnik provided a detailed overview of India’s space program that was quite similar to a panel discussion on the same topic held in nearby Washington in October (see: “The new path to space: India and China enter the game”, The Space Review, October 13, 2008). India’s space research has transitioned through four eras: the initiation phase of the 1960s, the experimental phase of the 1970s and ’80s, the operational phase of the 1990s, and the expansion phase of today, which is gaining the country more attention on the international stage.

Unlike the space programs of the Cold War superpowers, or even Japan, Europe, and China, India’s space program was always very closely tied to the developing country’s social needs. Satellites were developed to provide communications and telemedicine with isolated areas, weather forecasting, and remote sensing for vital needs such as agriculture assessment.

Today the Indian space program is funded at 40.74 billion rupees, or over $800 million, and includes 16,500 people spread all over the country. Karnik showed a map of India indicating the various space-related research centers located throughout the country. There are a large number of them well dispersed geographically. Although Karnik did not discuss it, an interesting question would be the degree to which the location of these research centers was intended to spur local economic development. Lyndon Johnson sought to site NASA centers in the American south in order to spur economic development. Has India followed a similar approach?

Much of Karnik’s talk covered the same ground as the October panel discussion in Washington. However, when Karnik took questions his responses provided additional insight into India’s space program, including the impetus behind its newest developments. One questioner asked if India’s space program was publicly popular because of its linkage to social problems, and also asked if projects like the Chandrayaan lunar spacecraft and the human spaceflight program had come under criticism.

Karnik confirmed that India’s space program was very popular with the public. Its results, like telemedicine, meteorology, and telecommunications, have long been visible and the public “recognize the value of space.” He noted that cell phone access is inexpensive in India and even the lower classes can afford mobile phones—the public attributes this to space development. But he conceded that Chandrayaan and the human spaceflight plans had recently received some public criticism as wasteful and unnecessary.

Karnik stressed that India was not planning on discontinuing any of its existing programs and had plans to develop follow-on satellites for the current remote sensing and other programs. The reason that India is now branching out into space science and human spaceflight has little to do with prestige, he said, and more to do with maintaining the interest and involvement of the current space workforce who had become bored with developing the same systems over and over. These programs are about “satisfying the technical ego of the younger generation,” he explained.

Another questioner asked about the possibility of using satellites for coastal monitoring, a shortfall highlighted by the recent Mumbai terrorist attack. Karnik said that India has a vast coastline but does not have any plans for satellite surveillance of the coast—a daunting task. He said that a particular shortfall for India was the lack of a dedicated satellite for “disaster monitoring.” In response to a question about using satellites to warn of tsunamis, Karnik explained that at the moment India’s scientists are seeking to correlate the data they have to the satellites that could provide such warning. They still don’t understand what the data means, but they do hope to eventually develop a tsunami warning system using satellites.

Germany in space

Dr. Jürgen Drescher is the head of the Washington office of the Deutsches Zentrum für Luft und Raumfahrt (DLR). Drescher is a medical doctor by education and his background is in aeromedicine, but his current job makes him the primary representative of the German Center for Aeronautics and Spaceflight in the United States, acting as a liaison both to the American government and to industry. The person who introduced him referred to the DLR as the “German NASA,” but as Drescher explained, the DLR is actually significantly different than NASA in scope and function. Germany currently spends 572 million euros on European Space Agency programs and 191 million euros on its national program. In addition, the country spends 124 million euros on “research and technology,” which includes funding for various institutes throughout Germany.

Although the largest portion of DLR’s funding is spent on space, the agency also sponsors research in four other areas: aviation, energy, transportation, and the newest focus, security. Aviation funding includes basic research to support the aviation industry, including wind tunnel testing, advanced materials and composites research, as well as aviation safety and air traffic management research.

The DLR’s energy projects include work on things like solar cells and fuel cells. Drescher explained that one of the agency’s current projects is developing a fuel cell to replace the auxiliary power units (APUs) used by commercial jetliners to run their electronics and start their engines on the ground. APUs burn jet fuel and contribute to noise and pollution while the jets are at an airport. The fuel cell that DLR has developed produces up to 80 kilowatts of power, sufficient to replace an APU, and its only byproduct is water. The ultimate goal of the project is to couple the fuel cell’s electric power to the landing gear, enabling the plane to back away from the gate and taxi without the assistance of a tractor, thereby eliminating the pollution from two combustion engines—the APU and the tractor. The audience’s interest was clearly piqued by this device and anybody who has ever stepped out of an airplane into a fume-filled jetway can attest that this could definitely improve the environment.

The DLR is also responsible for studying the aerodynamics of high speed trains like the Inter City Exchange (ICE), and is working on various research projects associated with combustion technology.

The agency’s newest focus is security technology, a broad field that includes not only national security technologies, but things like airport screening devices. Like the United States, they have developed airport scanners that can peer through a person’s clothes and accurately reveal the presence of weapons and explosives on the body of a passenger transiting through a terminal. But, like the United States, they are also facing issues of personal privacy because the device effectively produces a high-resolution picture of a naked human being.

According to Dr. Drescher, other aviation projects sponsored by the DLR include an effort to integrate unmanned aerial vehicles (UAVs) into commercial airspace. Drescher explained that, unlike the United States, Europe does not have separate military and civilian air corridors. European airspace is so crowded that it is nearly impossible to test fly UAVs in restricted airspace. This has provided incentive for the DLR to develop systems that allow UAV operations in Germany’s airspace, with the aircraft monitoring its local airspace and coordinating with the ground in order to avoid straying too close to manned aircraft.

Much of Dr. Drescher’s talk was devoted to spaceflight. Approximately forty percent of Germany’s 572 million euro contribution to ESA goes to the International Space Station and Germany played a major role in the development of the Columbus space laboratory and plans to conduct research there once the station becomes fully operational. Germany’s role in developing systems has been self-limited, however, and the country has primarily focused on the development of high quality space subsystems.

In recent years, Germany has substantially expanded its space capabilities. Although Drescher did not make the connection, nearly ten years ago the Bosnian conflict provided the impetus for a change in German defense policy. Numerous European countries found themselves in the unfortunate position of having limited ability to deal with a security threat in their own backyard and had to rely heavily upon the United States for important national security resources such as satellite intelligence. Today the situation has changed dramatically. In only the past few years Germany has acquired both a highly capable space-based synthetic aperture radar imaging capability and a low-resolution, quick response photoreconnaissance capability. In addition with the French Helios 2 medium resolution (better than one-meter) reconnaissance capability, and Italian space assets, Europe now has the ability to monitor both its own backyard as well as the rest of the world.

The German radar capability consists of two satellites known as TerraSAR-X and TanDEM-X, producing 3-D elevation models with one-meter ground resolution imagery and also stereo imaging of non-moving targets. Using the Doppler effect, the satellites can also estimate the velocity of moving ground targets. According to Drescher, TerraSAR-X was a relatively inexpensive program, costing approximately 180 million euros, including launch and the ground station. He said that DLR is in discussion with the Jet Propulsion Laboratory to build more such satellites with additional frequencies.

The five-satellite photoreconnaissance constellation known as RapidEye can produce quick overviews of terrain features. The images are low resolution, but because of the constellation size the satellites have the ability to cover a lot of territory and revisit targets relatively quickly. The products of both TerraSAR-X and RapidEye are sold commercially and the United States military is a customer. Drescher explained that the next major step for the DLR is the development of EnMap, a hyperspectral Environmental Mapping system.

The DLR is also involved in two future space science projects, the eROSITA x-ray spacecraft, and the BepiColumbo Mercury orbiter. In addition, the DLR is focusing attention on “satellite maintenance and services,” which includes everything from space situational awareness—monitoring the environment around its satellites—to protecting them from malfunction or attack.

Drescher also discussed the DLR’s work on the Lunar Exploration Orbiter, or LEO, and showed a computer animation of the spacecraft. LEO could be launched by 2013 atop a Soyuz rocket and sent to an initial 100-kilometer orbit around the Moon. It would be equipped with two subsatellites for gravity mapping of the Moon. The spacecraft would carry a number of instruments, including a synthetic aperture radar sounder and a primary payload of an advanced high-resolution stereo imaging camera developed at DLR Berlin Adlershof. After operating in its initial 100-kilometer orbit, LEO would descend to 50 kilometers where it would be able to map the Moon in multispectral ranges at better than one meter resolution—better even than NASA’s Lunar Reconnaissance Orbiter scheduled for launch in spring of next year.

Lunar Exploration Orbiter would be an entirely German mission, without ESA or foreign involvement. Unfortunately, this past summer the German government decided not to fund the spacecraft, only the instruments. The DLR will continue instrument development and if it does not receive funding to build the spacecraft in the future, it may then offer the instruments to other nations to fly on their own lunar spacecraft.

Although Drescher did not address the overall trends in German space funding, aerospace budgets took a substantial hit after reunification in the early 1990s. As the German government pumped money into the former East Germany, it drastically cut back other programs, including space. One thing clear from Drescher’s talk is that the DLR is actively looking for both partners and markets, undoubtedly to continue to justify the agency’s funding.

As Dr. Drescher emphasized during his talk, both the United States and Germany share a number of technology development and policy interests: decreased airport pollution, integrating UAVs into civilian airspace, and even the problems of airport security and personal privacy. But ITAR remains a major impediment for future space cooperation between the DLR and NASA. Surprisingly, the DLR has been able to engage in a number of cooperative efforts with the US Air Force and the Missile Defense Agency, “but with NASA it’s impossible for us,” he joked.
Different countries, similar interests

At first look it might seem rather odd to include both India and Germany in a discussion of space programs. After all, India remains a developing country, only now venturing out to do the kinds of space projects that Germany has been involved in for decades. But upon closer examination, the two countries’ space programs share many characteristics. Neither India nor Germany has flashy space programs. Unlike the United States, prestige plays a limited role in determining what they do. Instead, their space programs are closely linked to a relatively narrow definition of their societal needs. Germany is the more mature space power, and deeply entwined with numerous partners. But it still maintains a limited national space program.

From a policy standpoint, India is the more interesting of the two. Whereas China is branching into space science and human spaceflight both to satisfy a domestic audience and to demonstrate Chinese technological capabilities on the international stage, India’s motivations are more internal and bureaucratic. Although India certainly responds to the actions of other countries in space, as Counsellor Karnik hinted, claims of an “Asian moon race” are probably overrated. India has been successful at using its space program to meet social needs, but has found that this is not enough; in order to attract and keep people in its space program—to meet their “technical ego”—India has had to set its sights higher.
 
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From a policy standpoint, India is the more interesting of the two. Whereas China is branching into space science and human spaceflight both to satisfy a domestic audience and to demonstrate Chinese technological capabilities on the international stage, India’s motivations are more internal and bureaucratic. Although India certainly responds to the actions of other countries in space, as Counsellor Karnik hinted, claims of an “Asian moon race” are probably overrated. India has been successful at using its space program to meet social needs, but has found that this is not enough; in order to attract and keep people in its space program—to meet their “technical ego”—India has had to set its sights higher.

Very good assessment.
 
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Airliners.net | Airplanes - Aviation - Aircraft- Aircraft Photos & News...

India Wants Global Space Partners

Friday, December 12, 2008

The Indian Space Research Organisation hopes to fast-forward some of its ambitious space plans.

BENGALURU, India - Flush with the ongoing success of its Chandrayaan-1 lunar mission, the Indian Space Research Organisation (ISRO) is looking for international partners as a way to fast-forward some of its ambitious space plans.

"There will be challenging opportunities for industries in India and abroad to provide equipment and services," says ISRO Chairman G. Madhavan Nair, addressing the recent Bengaluru (former Bangalore) Space Expo 2008 organized by the Confederation of Indian Industry in association with ISRO and its marketing arm, the Antrix Corporation. "These include many small and medium enterprises."

The latest Geosynchronous Space Launch Vehicle - the GSLV Mk III (LVM3) under development with a $500 million budget and a Russian cryogenic stage - is now moving to an indigenous cryogenic stage, with two variants set to be ready in 2009.

"The objective is to have a self-reliant cost-effective new launch vehicle capable of launching the 4-ton class of communication satellites in Geo-synchronous Transfer Orbit (GTO) and up to 10-ton satellites in low Earth orbit by 2010/2011," says N. Narayanamoorthy, the SLV3 project director at the Vikram Sarabhai Space Center (VSCC). The LVM3 development also includes improved operability, he says.

Reducing the cost of access to space is a prime goal. And some potential international partners may be willing to help. "We're not in India to sell any hardware," says Alan De Luna, Project Director, Space Flight Programs, United Space Alliance. "What we bring is our experience on how to totally scope your program."

In land remote sensing - long a focus of India's help-the-villages space policy - "international cooperation will be the cornerstone," Antrix Director C.V.S. Prakash says.

"Building, launching, operating and pursuing the program is very expensive," Prakash says. "It is a 'dammed if you do and dammed if you don't' situation once you have stepped in to such a program. You require investment for processing systems, software to use the remote sensing data of a satellite, which takes about three to four years to start yielding results. If the program is not continued after the normal life of a satellite, the ground investment comes to naught."

That conundrum may be a way for India to find common cause with other national space programs, much as NASA has joined the European Space Agency to stretch limited resources with a collaborative Mars exploration plan.

"For small countries, there is no other way than collaboration," says Zvi Kaplan, director-general of the Israel Space Agency (ISA).

The ISA is waiting for India to launch its Tel Aviv University Ultra-Violet Experiment (TAUVEX) instrument, started in the 1990s, on the GSAT-4 satellite next year. That mission also will test the ISRO-developed cryogenic engine for the GSLV upper stage.

But challenges remain as India's long-isolated space program struggles to join the international mainstream. A senior official told Aviation Week that while the Chandrayaan-1 mission had raised India's image, some countries are not ready to share technology.

ISRO plans six launches by the end of 2009, and also plans to launch a small probe named Aditya - "Sun" in Sanskrit - in 2012 to study the solar corona during the next solar-maximum period.
 
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M3 Science Blog Data


First Peek at M3 Data!

We are thrilled to finally be able to share with our colleagues and the public a look at the first set of data that our Moon Mineralogy Mapper (M3) instrument collected! M3’s first look at the Moon occurred on November 22, 2008 when we acquired some new data for the Orientale Basin.



The first image is a “context” image, whose purpose is to allow you to get a feel for where on the Moon the long, narrow M3 data strips are located. It shows part of one orbit of Moon Mineralogy Mapper (M3) data superimposed on Lunar Aeronautical Chart (LAC) 108. This LAC sheet covers the southern portion of the Orientale Basin, a large impact structure on the Moon’s western limb. North is up. Major geological features in this orbit of M3 data include basaltic materials in the basin center, impact melt related to basin formation, Orientale basin massifs (mountains), and dark pyroclastic volcanic materials in the south. The LAC sheet background image is the 750 nm Clementine UVVIS basemap. The M3 strip is 40 km wide, and was acquired in the instrument’s lower-resolution mode at a spatial resolution of 140 m/pixel. The blue box identifies the subset region shown in later figures.



This second image is a subset of a longer M3 “image-cube” acquired across the Oriental Basin. To create this image using a two-dimensional detector, one line of spatial information (40 km in width with 300 elements) is acquired simultaneously with all channels in the spectral dimension. As the Chandrayaan-1 spacecraft moves along an orbit from pole to pole, the second dimension of spatial information is obtained line by line forming the image shown. A full spectrum from 420 to 3000 nm is thus acquired for every spatial element within the scene ( altogether 182,000 spectra for this subset!). These M3 low-resolution data consist of 86 spectral channels continuously spaced from 420 to 2980 nm. Example spectra for four small areas are shown in the next image. The areas are located just to the left of the numbers in the figure above which correspond to the spectra labeled in the next image.



Our third image (really a figure) is a plot that shows some example visible to near-infrared spectra extracted from the M3 subset across the Orientale Basin. Number labels refer to the location of each spectrum in the previous image. Prominent absorption features (arrows) are seen near 1000 and 2000 nm for the two small craters #2 and #4. These spectral features are due to iron-bearing pyroxene at those locations. Subtle differences between the shape and wavelength of these pyroxene features indicate differences in pyroxene composition associated with magnesium, calcium, and iron content. Most lunar soil spectra, such as spectrum #3, have very weak absorption features, but exhibit an overall trend in which reflectance increases toward longer wavelengths (we call this trend a red-sloped continuum). Spectrum #1 exhibits no evidence for the presence of iron-bearing minerals but is very bright. This mountain, and several like it in this scene, is composed almost entirely of the mineral plagioclase forming a rock called anorthosite. The presence of anorthosite plays a central role in the early “magma ocean” formation of the lunar crust.



Finally, we have a set of three images of the subset of M3 data for the Orientale region. These images contain 300 spatial elements (pixels) across the 40 km field of view, providing 140 m resolution. On the left is one spectral band at 750 nm in which the signal is entirely reflected solar light. The middle figure is a color composite of processed data that accentuates compositional differences. The blue to red colors represent the slope of the lunar continuum in the near-infrared. The green color is an indication of the abundance of iron-bearing minerals such as pyroxene ( as measured by an integrated band depth derived from 26 channels of continuum removed data between 790 and 1290 nm). The image on the right is a single M3 spectral band at 2940 nm. This image contains significant thermal emission in the signal and is particularly sensitive to small variations in local morphology. These new data provide mineralogical constraints on geologic processes that occur within the Orientale Basin. The dark mare region in the north-east part of the image contains the greatest abundance of iron-rich minerals and is basaltic in composition. Although a few small areas of iron-bearing minerals occur within the impact melt formed by the basin impact (seen along the left and bottom of the image), this material is very plagioclase rich, and several mountains and blocks are essentially pure anorthosite.

Please check back to this site for updates! New results will be released periodically!
 
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Good news guys:

The New Indian Express - No. 1 site for South India News, Breaking News, Cinema, Business successfully tests Cryogenic rocket engine

India successfully tests Cryogenic rocket engine


IANS
First Published : 20 Dec 2008 05:06:00 PM IST
Last Updated : 20 Dec 2008 05:24:27 PM IST

BANGALORE: The Indian Space Research Organisation (ISRO) has successfully conducted a test of its indigenous cryogenic (supercooled fuel) engine to be used in the next geosynchronous launch vehicle (GSLV-D3) mission, the space agency said here Saturday.

"The flight acceptance hot test of the Cryogenic engine was carried out at the liquid propulsion systems centre at Mahendragiri in Tamil Nadu Thursday. This engine will be used in the next GSLV launch in April 2009 for carrying the 2.3-tonne geo-stationary experimental satellite (GSAT)," ISRO said in a statement.

Cryogenic engines are rocket motors designed for liquid fuels that have to be held at very low 'cryogenic' temperatures, as they would otherwise be gas at normal temperatures.

Typically, hydrogen and oxygen are used which need to be held respectively below 20 degrees Kelvin (-253 degrees Celsius) and 90 degrees Kelvin (-183 degrees Celsius) to remain in liquid form.

ISRO plans to use its own first cryogenic engine in place of the Russian-made engine in the upper stage of the rocket that will deploy the satellite with navigation and technology payloads into the geosynchronous transfer orbit (GTO).

The cryogenic engine develops a thrust of 73 kilo Newtons (kN) in vacuum with a specific impulse of 454 seconds (7.56 minutes) and can carry 2.2 tonnes.

Working on a staged combustion cycle with an integrated turbo-pump, the engine will have 42,000 rotations per minute (rpm). It also has two steering engines developing a thrust of 2 kN each to enable three-axis control of the launch vehicle during the flight mission.

"The hot test was carried out for 200 seconds (3.33 minutes) during which the engine was operated in the nominal and 13 percent up-rated thrust regimes. All the propulsion parameters were satisfactory and matched with predictions," the statement mentioned.

The cryogenic engine will be integrated with propellant tanks, stage structures and associated feed lines of the launch vehicle for the flight mission in April next from the spaceport at Sriharikota, about 80 km north of Chennai.

The central government Friday approved the development of semi-cryogenic engines for space transportation at a cost of Rs.1,798 crore (approx Rs.18 billion) with a foreign exchange component of Rs.588 crore (Rs.5.88 billion).

"This will be an important step towards self-reliance in advanced space transportation technology," Home Minister P. Chidambaram told reporters in New Delhi.

Cryogenic engine technology is currently present only in Russia and the US.

The semi-cryogenic engines will facilitate applications for future space missions like the reusable launch vehicle, the unified launch vehicle and the vehicle for inter-planetary missions, Chidambaram added.
 
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India lunar craft problem 'fixed'

By Swaminathan Natarajan
BBC Tamil service

Indian space scientists say they have corrected a major heat problem that threatened India's first unmanned lunar craft Chandrayaan 1.

They say that the craft is now functioning normally after the heat was brought down.


India launched its first lunar mission on 22 October. It reached lunar orbit in the first week of November.

But soon after that the temperature inside the probe went up to 50C, endangering the mission.

Project director M Annadurai told the BBC: "Due to various measures we took, now the temperature has come down below 40C.

"All the 11 instruments carried on board are working normally."

The heat rise had prompted scientists to take urgent measures.

The problem arose because of very hot temperatures during lunar orbit.

A lot of onboard equipment was switched off and the satellite was tilted by 20 degrees. "The lunar probe has also been brought back to its original position," M Annadurai added.

The Indian lunar mission aims to map the Moon's surface, look for traces of water and the presence of helium.

The mission is regarded as a major step for India as it seeks to keep pace with other space-faring nations in Asia.

BBC NEWS | South Asia | India lunar craft problem 'fixed'
 
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Union Cabinet sanctions financial package for ISRO - www.ddinews.com

Saturday 20 December, 2008

ISRO's efforts to develop a semi-cryogenic engine to power future inter-planetary missions got a boost as the government sanctioned Rs 1,798 crore for the initiative to be completed within six years.

India will become the third country, after the US and Russia, to have developed the advanced propulsion system which will be used to launch space shuttles and future space missions.

The Union Cabinet, at a meeting chaired by Prime Minister Manmohan Singh, approved development of semi-cryogenic engine technology at an estimated cost of Rs 1,798 crore with a foreign exchange component of Rs 588 crore, Home Minister P Chidambaram said reporters in New Delhi on Friday.

The objective is designing, fabricating and testing this advanced technology in India in six years time, which will be a key step towards self-reliance in advanced space transportation technology for the country, he said.

"The semi-cryogenic engine will facilitate applications for future space missions such as the Reusable Launch Vehicle, Unified Launch Vehicle and vehicle for interplanetary missions," Chidambaram said.

The semi-cryogenic engines using liquid oxygen and kerosene are considered relatively environment friendly, non-toxic and non-corrosive.

The propellants for such engines are safer to handle and store and also reduce the cost of launch operations.

After the successful launch of Chandrayaan-I, ISRO is now planning to send an Indian in space, a mission to Mars, flyby mission to asteroids and comets.
 
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The Hindu News Update Service

ISRO's commercial Communication Satellite launched

A state of the art communication satellite, W2M, built by ISRO on a commercial basis in partnership with EADS-Astrium of Europe, was successfully launched on Sunday at 0405 hrs (IST) by the European Ariane-5 launch vehicle. The launch took place from the Guiana Space Centre at Kourou in French Guiana, says ISRO release.

32 minutes after its lift-off, W2M separated from Ariane-5, after reaching its intended Geosynchronous Transfer Orbit (GTO). Radio signals transmitted by W2M were successfully received by ISRO’s Master Control Facility (MCF) at Hassan in Karnataka and the satellite’s health is normal.

W2M project was undertaken in the context of an accord signed during the visit of the President of France on February 20, 2006, at New Delhi between Antrix Corporation Ltd., the commercial arm of the India’s Department of Space and EADS Astrium to jointly build and deliver a communication satellite (W2M) to Eutelsat Communications, which is a global satellite communications provider based in Paris.

Astrium had the responsibility for overall program management and delivery of the communications payload and Antrix/ISRO provided the satellite bus and also performed W2M's integration and testing at ISRO's facilities in Bangalore.

W2M satellite, weighing 3,463 kg at lift-off, is the heaviest satellite built by ISRO and is capable of operating for over 15 years. The satellite's solar panels generate a maximum of about 7000 Watts of power.

Subsequent to its placement in Geosynchronous Transfer Orbit by Ariane 5, W2M is to be positioned finally at the orbital slot of 16 degree East in the Geostationary Orbit.

It carries 32 high power Ku band transponders for telecommunications and broadcasting services over Europe, Middle East and North Africa.

Antrix/ISRO is also responsible for the Launch and Early Orbit Phase (LEOP) operations of W2M, which is being conducted from Master Control Facility.

The operations include 3-axis stabilisation of the satellite, repeated firing of its Liquid Apogee Motor to reach the satellite to its final orbital slot and deployment of its appendages.
 
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ISRO makes $40 million profit out of W2M satellite - Technology - livemint.com

ISRO makes $40 million profit out of W2M satellite

Weighing 3,462 kg at lift-off, W2M is the heaviest spacecraft built by the Indian space agency till date

Bangalore: India’s space programme is all set to achieve a major milestone when European space consortium Arianespace launches over the weekend the W2M satellite built by ISRO for a foreign customer for the first time fetching it $40 million profit.
Building W2M for satellite operator Eutelsat under the ISRO-EADS Astrium alliance has signalled the Bangalore- headquartered space agency’s foray into the satellite-manufacturing market.

While W2M was built under a $80 million (Rs400 crore) contract by ISRO, officials said it was a good deal for the space agency which made a profit of $40 million (Rs200 crore) in this venture.

“ISRO builds such spacecraft without payloads for less than Rs200 crore. That way we made a good profit”, an ISRO official said.

“It (W2M) is comparable to INSAT-4 series. For the first time, we have built a satellite for a foreign customer. So, that’s why the launch is important for us”, ISRO Chairman G Madhavan Nair told PTI.

Nair would be at the Europe’s spaceport of Kourou in French Guiana when the W2M spacecraft is launched, along with HOT BIRD satellite built by EADS Astrium, Europe’s leading satellite system specialist, by an Ariane rocket early Sunday Indian time.
ISRO spokesperson S Satish said “weighing 3,462 kg at lift-off, W2M is the heaviest spacecraft built by the Indian space agency till date. It was built in 26 months”.
 
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Raytheon's Chandrayaan-1 Sensor Successfully Activated

Raytheon's Chandrayaan-1 Sensor Successfully Activated

by Staff Writers
El Segundo CA (SPX) Dec 23, 2008

Raytheon has received confirmation from NASA and the Indian Space Research Organization that a water-detecting sensor system on the Chandrayaan-1 lunar-orbiting spacecraft has been activated and is fully functional.

The assurance extends Raytheon's perfect 40-year record of start-up success. Data collected during an initial checkout will be used to calibrate the sensor.

Under contract to the Naval Air Warfare Center Weapons Division, Raytheon provided the antenna, transmitter, analog receiver and software for the sensor system to Johns Hopkins University Applied Physics Laboratory, which then integrated the sensor system with the spacecraft.

The company also supplied system engineering, integration and test support.

The main mission of the system is to detect water at depths up to several meters in the frozen regions of the lunar poles.

Operational data retrieval will begin several months after initial calibration to allow other on-board optical payloads to take advantage of favorable solar illumination conditions during the early phase of the program.

"We are proud to be supporting this highly important Indian space mission and of our company's unblemished record of on-orbit sensor activation," said Brian Arnold, vice president for the Space Systems group of Raytheon.
 
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The Hindu News Update Service

'Bhuvan' to be launched in March

New Delhi (PTI): Bhuvan, India's response to Google Earth, will be launched in March 2009 and will provide high resolution imagery data of the order of five metre which would be of great relevance for real-time exercises, including disaster management and military operations.

"The Google Earth is providing high resolution data in the order of less than a metre. But the data is two to three years old. It cannot be of much use for any real-time exercise. But Bhuvan will provide the relevant data for any real-time exercise," S K Pathan, Head, Geo Informatics Data Division, ISRO, said.

Bhuvan, to be launched by Indian Space Research Organisation (ISRO), will be a better alternative to Google Earth in terms of quality of data, he said.

"Bhuvan, which means earth, will get the images from the satellites and provide high resolution imagery data of the order of five metre. This can be of use for real-time exercises like disaster management and military operations," he said.

For real-time exercises, the latest data is a guiding force, he said. It can show the topography, altitude, depth and other features of any specific location.

"This information will be required when you are undertaking a massive exercise like flood management or post-cyclone disaster mitigation," he said.

The data could be of use to manage public services, internal security, town planning and infrastructure development activities.
 
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News and Events, NAL, Bangalore

AERODYNAMIC CHARACTERISATION OF RLV-TD

NAL trisonic wind tunnel facility is being used extensively to characterize the aerodynamics of Reusable Launch Vehicle Technology Demonstrator (RLV-TD) configuration during various phases of flights as well as to generate very important data viz. FADS calibration coefficients, hinge moments, unsteady aerodynamics, flow visualization and dynamic derivatives of RLV-TD HEX-1 mission, which is planned in the middle of next year. The descent phase aerodynamic characterization (TDV alone) was completed and the huge data generated was of immense use for the design and simulations. The aerodynamic community has lauded the voluminous data, which runs into 1196 tables that was followed for the first time, as practiced in aircraft industry.

In order to meet RLV-HEX-1 mission target of May-June 2009, the complete aerodynamic characterization during ascent phase as well as FADS calibration data were essential by November, 2008. On the request from ISRO, the test program was undertaken on priority by the NTAF team. Also during the course of the tests, the test data were made available in real time to the Project and design teams that facilitated making a first cut assessment on the result and to carry forward the remaining program. The total number of blowdowns was more than 450 and the whole test program went smooth. The NTAF team rose to meet the crises, like power problems and put extra effort in order to ensure timely completion of the program.

On behalf of the project, Dr K Sivan Project Director, RLV-TD, VSSC has appreciated the NTAF team for putting their best efforts to complete the RLV-TD ascent phase aerodynamic characterization and FADS calibration test for providing the data within the targeted schedules . Dr K Sivan has also mentioned that he is looking forward to the continued support and cooperation from NAL for the further test programs.
 
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