New firepower
New firepower
T.S. SUBRAMANIAN
in Wheeler Island
With the success of the launch of its Agni-V missile, India has entered the exclusive club of countries having ICBM technology.
REUTERS/DRDO
IT was a remarkable sight to behold from the Vehicle Integration Building on Wheeler Island, off Dhamra village on the Odisha coast, in the evening of April 17. The 17.5-metre long, three-stage Agni-V missile, weighing 50 tonnes, was being slowly lowered onto a trailer in a horizontal position using slings. There was hectic activity everywhere, with the Defence Research and Development Organisation's (DRDO) missile technologists bustling about and technicians checking up the missile before the scheduled launch the next day. Everyone around exuded confidence. Among them were V.K. Saraswat, Scientific Adviser to the Defence Minister, Avinash Chander, Chief Controller (Missiles and Strategic Systems), DRDO, and V.G. Sekaran, Director, Advanced Systems Laboratory (ASL), DRDO, Hyderabad.
Saraswat said: “It will be a historic day for India's missile programme. Agni-V missile is a game-changer and a technological marvel. It can perform multiple functions. We are at the moment T minus 24 hours from the launch. All preparations are under way for the launch of Agni-V tomorrow between 6 p.m. and 9 p.m. The results of the performance of various systems in the missile during phase 3 and 4 checks were found to be good and satisfactory.”
But the plan for the launch of the most formidable missile in India's arsenal with the longest range and the capability to carry a nuclear warhead weighing 1.1 tonnes, on April 18 was spoilt by broad sheets of lightning over the tiny island's skies. The DRDO, which designed, developed and built it, did not want to take any chances. It rescheduled the launch to April 19 between 7-30 a.m. and 8-30 a.m.
On the morning of April 19, as Saraswat, Chander and Sekaran sat in front of their computer consoles in the Mission Control Centre (MCC) in the Block House, the air was thick with suspense and expectation. A few hundred missile technologists and scientists were in the adjacent hall. Half a kilometre away stood the Agni-V on a rail-mobile launcher, with its three-stages painted in white, an orange ribbon winding across its body, and the re-entry vehicle looking black. In the backdrop were casuarinas and eucalyptus plantations and the Bay of Bengal.
At 8-07 a.m., as the Agni-V shot out smoothly from its launch pad, roared into the sky and built up a powerful thrust, there was no doubt about the mission's success. The three stages ignited on time and their separation was clean and precise. The missile climbed to a height of about 600 km before starting to descend. The powered flight, with the three stages igniting and separating, lasted about 220 seconds. As each stage fired and decoupled, the MCC and the adjacent hall reverberated with applause. There was a long gap between the third stage separation and the re-entry vehicle knifing into the atmosphere at an altitude of 100 km. After the third stage separated and the re-entry vehicle was ejected at a velocity of about six km a second, the mood in the MCC was relaxed.
The DRDO's missile technologists were sure that “the re-entry vehicle will not go anywhere”. Even if no data were available after the powered flight phase got over, “we would have known precisely where the re-entry vehicle had gone”, they said. In fact, when the third stage ejected the re-entry vehicle at a velocity of 6 km a second, it became the fastest travelling object made by India, speeding at 25 Mach, or 25 times the speed of sound.
“The third stage separation was the determining point,” Sekaran explained later. “After that, gravity takes over. Subsequently, nothing will happen. Nothing can happen also. It [the re-entry vehicle] is a free body travelling under gravity. It becomes what you call a ballistic flight.”
The re-entry vehicle itself is a technological marvel, housing the missile's avionics and the nuclear warhead. Indeed, it houses all the electronics systems for navigation, guidance and control and the on-board computers. The avionics are within the missile's nose cone, which is made of carbon-carbon composites. The re-entry vehicle is protected by a heat shield, which is made out of carbon composite fibre. In this mission, the Agni-V carried a warhead that mimicked a nuclear bomb but without the radioactive material.
PHOTOGRPAH COURTESY: PALLAVA BAGLA
AT A LABORATORY in the DRDO's missile complex in Hyderabad, a man trains a welding gun on one side of a carbon composite tile to demonstrate how it resists the transfer of heat to the other side. The tiles, a few centimetres thick and used in the heat shield covering the re-entry vehicle of Agni-V, can withstand the 5,0000 Celsius temperature when the re-entry vehicle slices through the atmosphere and keep the inside at 500C, ensuring that the electronic systems are intact.
The re-entry itself is a critical manoeuvre for the vehicle should slice itself into the atmosphere at the correct angle. The levels of deceleration should be perfect although the loads acting on the re-entry vehicle are very high. Besides, the survival of the re-entry vehicle is important. Its carbon composite tiles, a couple of inches thick on its outer surface, should withstand scorching temperatures of more than 5,0000 Celsius as it slices into the atmosphere. But the temperature inside the re-entry vehicle should not be more than 500C so as not to harm the electronics equipment in the nose cone. “At that stage, the outer layer starts burning and the package inside should survive and be functional at 500C…. Over a few inches of thickness, the temperature drops from 5,0000C to 500C,” Chander explained.
After about 20 minutes of flight, when the dummy warhead carrying explosives erupted into a fireball and hit the waters of the Indian Ocean somewhere between Australia and Madagascar, another round of applause rang out in the MCC. The re-entry vehicle's impact point in the Indian Ocean was more than 5,000 km from Dhamra in the Bay of Bengal. The fireball was captured by cameras on three naval ships stationed downrange near the impact point. Agni-V was a spectacular success on its maiden flight itself.
Exclusive club
That moment signalled India's entry into the exclusive club of countries having the Inter-Continental Ballistic Missile (ICBM) technology. Other countries that can boast ICBM technology are the United States, Russia, France and China. (The yardstick for gaining entry into the ICBM club is that a country should possess the technology to build a missile that can travel a distance of 5,500 km.)
It was time for celebrations at the Block House. The air was filled with shouts of “DRDO zindabad, DRDO zindabad” as young engineers, including software specialists, carried Saraswat on their shoulders in a triumphal procession.
Immediately after the success of Agni-V's launch, Saraswat told Frontline, “Today, we have made history. We are a major missile power.” He asserted that India was now with the group of five countries that possessed the technology to “design, develop, build and manufacture long-range missiles of this class and technological complexity”. The countries are the U.S., Russia, France, China and the United Kingdom. He was sure that “the versatile capability of this missile will enable India to leapfrog into areas of MIRVs [Multiple Independent Re-entry Vehicles, or, to put it simply, multiple warheads], ASAT [Anti-Satellite] weapon capability and to launch mini and micro-satellites on demand. This will usher in a new era of missile development in India.”
With India having declared a “no first-use policy”, the significance of the success is that it will for the first time provide India with a true deterrence. It will also provide India with a powerful second-strike capability to retaliate if any other country attacks India with nuclear weapons, DRDO officials said.
The Army has already deployed Agni-I, Agni-II and Agni-III. India has Prithvi variants such as Prithvi-I, Prithvi-II and Dhanush, which are surface-to-surface missiles that can carry nuclear warheads. These are in the armed forces' employ.
In Saraswat's assessment, Agni-V “belongs to the 21st century not only in time frame but in technological complexity. It already compares with the missiles [of this long-range class] of the U.S., Russia, France and China.” In fact, Saraswat repeatedly referred to Agni-V as a long-range missile.
Chander, who is also the Programme Director for Agni-V, said, “It is a major achievement we have made today. We reached more than 5,000 km.”
Sekaran predicted that “Agni-V, for years to come, will be a workhorse”. R.K. Gupta was the Project Director for Agni-V. A.K. Chakrabarty, Director, Defence Research and Development Laboratory (DRDL), Hyderabad, said the missile's flight was so “fantastic” that “nothing can better it”.
Chander was proud that all the new systems used in Agni-V, such as the composite casings for the second- and third-stage motors; the composite motors contoured to suit the missile's shape; and the high-performance navigation systems, including the ring-laser gyroscope systems and micro navigation systems; were fully validated in the flight. “This gives us the confidence to go ahead with larger numbers [of missiles] and bigger ranges. A bigger range is not the issue. Our main focus is on induction [of Agni-V into the Army],” he added. The next launch of Agni-V will take place in early 2013 from a road-mobile launcher and a canister in the missile's final user configuration.
V.V. KRISHNAN
THE 17.5-METRE AGNI-V missile, weighing 50 tonnes, being lowered onto a trailer at the Vehicle Integration Building on Wheeler Island on April 17.
Sekaran argued that “the critical, deciding factor was the propulsion” system used in the three stages of the missiles. This was the first time that the DRDO was test-firing a three-stage missile, all powered by solid propellants. And it took just three years to design, develop and test-fire Agni-V, with the Union government sanctioning the project in 2008. “The time taken from designing the vehicle to flying it is only three years. It is a historic record. There is no doubt about that in my mind,” Sekaran said.
DRDO said that Agni-V “is not any country-specific”. “The Indian missile programme is built on our requirements and our strategic doctrine that India will never use any such [nuclear] weapon, and it has declared an NFU [no first-use of nuclear weapons]. The DRDO's capability and technology gives strength to our nation,” said Saraswat.
According to Chander, Agni-V was “a game-changer in many ways”. First, he said, “You can reach all targets of your interest from deep inside India. You have got a system which allows you to reach the farthest corners where you want to exert your influence while you have sufficient protection for yourself.” Secondly, it can be launched from a canister and a road-mobile launcher, that is, a massive truck with a trailer. “It will give you ‘a stop and launch' capability,” the DRDO Chief Controller said. The road-mobile launcher can stop at a roadside, fire the missile and go away. So it will be difficult to intercept it, beat it or defeat it during its launch phase because its mobility will be high.
Thirdly, the composite motors of the size used in Agni-V has given the DRDO the confidence to go for missiles with larger motors and manoeuvring warheads because the motor casings, made out of composites, will be light in weight but provide a higher performance.
Chander explained why Agni-V was a game-changer: “This is the first time that India has a true deterrence. We had a good deterrence with Agni-III and upgraded with Agni-IV. But Agni-V gives you a quantum jump with that capability. This test was important for us because we were proving our capability. Once it is proved, it will go into a carrier and it will become a deliverable system.”
Although the DRDO's missile complex in Hyderabad comprising the DRDL, the ASL and the Research Centre, Imarat (RCI) played important roles in developing the components, systems and subsystems for Agni-V, the ASL's contribution stood out. The ASL, which Sekaran heads, designed and developed the Agni-V, built the powerful propulsion systems for its three stages, developed the light-weight rocket-motor casings made of composites and the heat shield too. Chander praised Sekaran's role in designing and developing the heat shield.
While Agni-III missiles ejected the re-entry vehicle at a velocity of 4.2 km a second, Agni-V ejected it at a velocity of 6 km a second. “This is a new dispensation in terms of higher velocity. At the end of the day, you have to survive the re-entry and then only you can deliver. The particular heat shield we made for Agni-V is the strength of the ASL,” the ASL Director said.
As the re-entry vehicle comes down through the atmosphere from an altitude of 100 km to a lower altitude, the atmosphere's density keeps increasing. Once the density increases, the re-entry vehicle's deceleration breaks and the heat generated keeps shooting up. It is akin to speeding in a car when brakes are suddenly applied and people seated in the car lurch forward. “In this case, the systems are qualified for 100 G. The survivability of the re-entry vehicle is a critical area,” Sekaran said. (The re-entry phase lasts 40 seconds to 50 seconds.)
In a civilian mission – for instance a mission of the Indian Space Research Organisation (ISRO) – the heat shield protects the satellite from intense heat and friction during the rocket's ascent phase into the atmosphere and later splits down its seams and falls away. The role of a heat-shield protecting the re-entry vehicle of a missile is different. And, the satellite goes into empty space. But in a military mission, as the re-entry vehicle enters the atmosphere, the heat shield not only protects the re-entry vehicle but goes down with it. “The heat shield does not jettison at all,” a DRDO engineer said.
Although the ASL had made heat shields for previous Agni missions including that of Agni-III, the shape, size, diameter and angle of the heat shield for Agni-V was different. The heat shield's diameter in Agni-V was 1.5 metres, while it was 1.2 metres for Agni-III.
Another strength of the ASL lay in designing and developing motors propelled by solid fuel for Agni missions. For the Agni-V test flight also, the ASL designed and developed solid motors for its three stages. Besides, it developed the all-important light-weight composite for the second- and third-stage motors, which led to a reduction in their weight but far better performance. A crucial step towards developing Agni-V was taken when the ASL developed in 2007 a large rocket motor casing made entirely of carbon-filament wound composite. This casing, developed indigenously, formed the third upper stage of Agni-V. The casing went through full qualification trials in 2007.
“We never went out. The static testing of the motors was done in the same organisation [in various units of the ASL]. This is a formidable combination,” said Sekaran. The ASL also established its expertise in high-performance composites. It developed the composites for the missile motor casings and nose cone and established the process parameters for them. Then the technology was transferred to the industry for fabricating these composites. “The nose cone was fully made out of carbon composites developed by the ASL. It withstood a temperature of more than 5,0000C. You cannot make it out of metal. If you do so, the weight will shoot up,” he added.
Systems engineering is also one of the strengths of the ASL because it specialises in building up from what it already has. With the addition of a third upper stage and with minor modifications, the two-stage Agni-III metamorphosed into an awesome Agni-V. Yet the weight remained the same for both vehicles despite the addition of a third upper stage to Agni-V because the second- and third-stage motor casings were made out of light-weight composites. A lighter missile can be easily transported by rail or on road. Besides, it can carry a payload over a longer range.
In an interview to Frontline in May 2008, Chander pointed to the DRDO developing a large rocket motor casing made entirely of carbon-filament wound fibre and said, “This is a major breakthrough because it provides us the key technology for going into longer missions with light-weight missiles.... We have flight-tested Agni-III twice successfully. When we want to go in for missiles with higher ranges, one key technology is the rocket motor casing. That has been developed now” ( Frontline, June 06, 2008).
The RCI developed the navigation system for Agni-V, and its architect was the young G. Satheesh Reddy, Associate Director, RCI. “Our navigation for Agni-V was different from the one used for Agni-IV. It was a redundant, reliable system with high-performance and accuracy,” he said. Agni-V had two navigation systems: ring-laser gyro-based system and a micro-navigation system with good accuracy. Fault-tolerant features were incorporated into the navigation system and on-board computers. “Our on-board computers have been developed in such a way that they can recover transient failures. Besides, the entire data computation in avionics is highly reliable and robust,” he said.
The important technology of the inertial navigation system, guidance and control used in Agni-V was the brainchild of the RCI, said S.K. Chaudhury, its Director. All the systems were validated by advanced simulation at the RCI. The DRDL's role in the mission was to characterise the vehicle.
The DRDO's attention is now focussed on the next Agni-V launch from a canister and a road-mobile launcher in early 2013. The Shourya and the BrahMos missiles were launched many times from a canister. Chander said the DRDO had set up a facility at Shamirpet, near Hyderabad, for missile ejection tests using a gas-generator from a canister. The road-mobile launcher would be ready in May. With Agni-V scheduled to be inducted into the Army by 2015, there would be six flight tests, including three pre-induction trials.
Agni-V and neighbours
IN the aftermath of India successfully test-firing the Agni-V missile, a media report that received a lot of attention was of a Chinese researcher's observation that the missile “actually has the potential to reach targets 8,000 km away”. Du Wenlong, a researcher at the People's Liberation Army's Academy of Military Sciences, in an interview to the Global Times, said that “the Indian Government had deliberately downplayed the missile's capability in order to avoid causing concern to other countries”.
“No comments,” said a top missile technologist of the Defence Research and Development Organisation (DRDO), who played an important role in the Agni-V launch, when he was asked about Du's remark. The DRDO official, however, jokingly said, “If our enemy underplays our missile's range, it is good. If he overestimates its range, it is still better.”
India has only two missiles, Agni-III with a range of 3,500 km, and Agni-V, with a range of more than 5,000 km, which can target China. But China has several missiles aimed at India. They are DF-3 (Dong Feng), DF-4, DF-4A and DF-21. These are strategic, surface-to-surface missiles armed with nuclear warheads.
“China has deployed DF-3, DF-4A and DF-21 to target India,” says an assessment paper prepared in June 2010 and entitled “Missile Developments in India's Neighbourhood”. The paper was prepared by the International Strategic and Security Studies Programme at the National Institute of Advanced Studies (NIAS), Bangalore. The assessment was done by S. Chandrashekar, Rajaram Nagappa, N. Ramani, Manabrata Guha and Lalitha Sundaresan.
While DF-3A can carry a nuclear warhead weighing two tonnes over 2,842 km and thus can reach many parts of India up to Ahmedabad, DF-4A, with a range of about 5,000 km and the ability to carry a two-tonne warhead, can reach all of India, says the assessment paper. The DF-21 missile, with a payload of 700 kg and a range of 3,047 km, “can cover all of India and Pakistan”, it adds.
Rajaram Nagappa told Frontline that the DF-21 missile was a fully operational missile. It is a two-stage missile, with both the stages powered by solid propellants. DF-21 has a counterpart called JL-1 (JuLang), which is launched from a submarine. There are several variants of DF-21, and they have been used as interceptors or to shoot down satellites in orbit. The NIAS' assessment paper says: “On January 11, 2007, China carried out an Anti-Satellite (ASAT) test. A direct ascent missile launched from close to the Xi Chang Launch Centre hit and destroyed a defunct Chinese Fengyun polar orbiting satellite at an altitude of about 850 km. The missile that was used was apparently a modified version of the Chinese DF-21.”
China then conducted an anti-missile test on January 11, 2010. The target missile launched from Xi Chang in Sichuan province was intercepted and destroyed by a KT-2 variant (DF-21) test missile launched from a mobile launcher near Korla in Xinjiang province. “The interception apparently took place at an altitude of at least 700 km, indicating a substantial Ballistic Missile Defence (BMD) capability,” says the paper.
There is a DF variant called DF-21D, which can carry a 1,700 kg warhead over 3,000 km.
China has DF-31, an Inter-Continental Ballistic Missile (ICBM) with a range of about 7,000 km. Depending on the weight of the warhead it carries, its range can increase or reduce. “This is a totally operational missile. DF-31's submarine- launched version is called JL-2,” said Rajaram Nagappa. There is DF-31A too, which can carry a nuclear warhead weighing 700 kg over a distance of 13,000 km.
The paper says: “Coupled with a major space programme that includes space launchers, manned space flight, substantial radar and optical reconnaissance capabilities, communications, navigation, a small satellite programme and substantial investments in various ground-based surveillance and tracking systems, the Chinese seem to be intent on leveraging their substantial space capabilities into ‘strategic flexible assets' that can be used in different ways, depending on the situation it faces.” Elsewhere, the paper adds, “Aditionally, the Chinese ASAT and anti-missile tests suggest that they are actively moving towards acquiring capabilities to become a space weapons power.”
On April 25, Pakistan successfully test-fired Shaheen-1A, an intermediate range ballistic missile capable of reaching targets in India. It is a missile that can carry nuclear warheads. Pakistan's military officials declined to specify the range of the missile. Pakistan has the Ghaznavi missile, which can carry a one-tonne nuclear payload over a distance of 320 km.
A DRDO official said: “India felt the requirement for ballistic missile defence in the late 1990s when Pakistan test-fired Ghauri missile with ranges far enough to threaten our major cities.” So India conducted seven interceptor missile tests as part of its quest to build a credible BMD shield and protect its vital assets in the shortest possible time. Six out of these seven missiles have been successful.
According to the NIAS paper, “The range of the Ghauri missile with a 1,000 kg nuclear warhead, launched at an azimuth of 135 degrees from around Islamabad, is 953 km.” There are two configurations of Shaheen-1 missile, with ranges of 673 km and 735 km. Both can carry a payload of one tonne. Shaheen-2 has the longest range in Pakistan's arsenal and it is pegged at around 1,250 km with a one-tonne warhead. The study adds, “Pakistan's foray into the development of cruise missiles, especially the Babur missile, could have a direct impact on India.”
T.S. Subramanian
Agni-V and neighbours
Story of self-reliance
Story of self-reliance
V.V.KRISHNAN
V.K. Saraswat, Scientific Adviser to the Defence Minister and DRDO Director General, announces the successful launch of Agni-V. On his left is Avinash Chander, Chief Controller (Missiles and Strategic Systems), DRDO. Behind them is V.G. Sekaran, Director, Advanced Systems Laboratory , DRDO, Hyderabad.
A DAY prior to the launch, V.K. Saraswat, Scientific Adviser to the Defence Minister, declared, “After tomorrow's launch is successful, I can say that in terms of technology, all the scientists of the DRDO would have fulfilled the dream put into their eyes by Mr A.P.J. Abdul Kalam in 1990 for launching a long-range ballistic missile with a high indigenous content. I have received good wishes from Mr Kalam for this launch and I wish he was here [on Wheeler Island] with us. I am sure he is eager to listen to the good news of a successful launch.”
Saraswat attributes this confidence to the “pointed approach” and “professionalism” practised in the last 25 years by missile technologists, hardware and software engineers, and technicians of the Defence Research and Development Organisation (DRDO). It was no surprise, he said, that it was “a copybook flight”.
Saraswat, who is also Director General, DRDO, was proud that “the indigenous content in this missile was higher than 80 per cent” because of the DRDO's decision to join hands with industry and academic institutions. As many as 300 industries across India manufactured various components and subsystems for the missile, he said.
From a single-stage liquid-fuelled Prithvi with a range of 150 km, first launched in February 1988, to Agni-V in April 2012 with a range of more than 5,000 km, was a “giant leap in 25 years for India”, said Avinash Chander, Chief Controller (Missiles and Strategic Systems), DRDO. “We had the first Prithvi launch in 1988, the Agni Technology Demonstrator in 1989, the weaponised Agni in 1999, and what you see today is Agni-V,” he added.
This “symbolises a major, massive jump in the technologies and the capability” of the DRDO because “once you have a range of 5,000 km, the same missile [Agni-V] can go to a height of 2,500 km with a short range and you can hit any object and satellite at that height. The same modules can put small satellites in orbit and multiple warheads,” Chander said.
India now has a battery of powerful missiles, which include Agni-I, Agni-II, Agni-III, Agni-IV and Agni-V in the Agni series, and Prithvi with its Air Force and naval variants, all of which are surface-to-surface missiles. Besides, it has Akash, the surface-to-air missile; BrahMos, the supersonic cruise missile; Nag, the anti-tank missile; and the K-15 missile which is launched underwater and will be integrated with India's nuclear-powered submarine, Arihant. K-15, with a range of 700 km, has already gone into production. The DRDO has developed Shourya, which is the land version of K-15.
The DRDO is developing the K-4 missile, which will also be launched from a submarine. K-4 will have a range of more than 3,000 km. The first flight test of Nirbhay, the subsonic cruise missile with a range of 750 km to 1,000 km, will take place soon from the Integrated Test Range at Balasore, Odisha.
Missile development in India is a saga of self-reliance and sustained struggle, with the pioneers learning by reverse engineering and battling technology denial regimes such as the Missile Technology Control Regime (“Missile shield”, Frontline, February 13, 2009).
The MTCR, with the United States at its head, targeted India after the successful tests of the Prithvi missile in February 1988 and the Agni in May 1989. Supply of computer processor chips, radio frequency devices, electro-hydraulic components, maraging steel, magnesium alloy, gyroscopes, accelerometers, carbon fibre, glass fibre and, so on, was stopped to India.
Undaunted, the DRDO collaborated with public and private sector industries and academic institutions and developed maraging steel for rocket motors, carbon-carbon composites and resins for the re-entry vehicle of the Agni missiles, magnesium alloy, phase shifters for Rajendra radar for Akash missile, winding machines, and so on. The public sector undertaking, Mishra Dhatu Nigam Limited (MIDHANI), the Defence Metallurgical Research Laboratory (DMRL), and private industries together developed the magnesium alloy which was denied to India by Germany. When the first plate of magnesium alloy rolled out of MIDHANI, Germany said it would give India any amount of magnesium alloy. The DRDO wrote back saying it was prepared to export the alloy to Germany ( Frontline, February 13, 2009). “The DRDO always converted challenges into opportunities,” said Chander.
T.S. Subramanian