Missile History

Rockets were invented in medieval China (Circa 1044 AD) but it's first practical use for serious purpose other then entertainment took place in 1232 AD by the Chinese against the Mongols at the siege of Kai-Feng-Fue. Thereafter from 1750 AD to 1799 AD Haider Ali and Tipu Sultan [1] (Sultan of Mysore, in south India) perfected the rocket's use for military purposes, very effectively using it in war against British colonial armies. Tipu Sultan had 27 brigades (called Kushoons) and each brigade had a company of rocket men called Jourks. In the Second Anglo-Mysore war, at the Battle of Pollilur (10 September 1780), Hyder Ali and Tipu Sultan achieved a grand victory, whereby the whole British detachment lead by Colonel Baillie was destroyed and 3820 soldiers were taken prisoner (including Colonel Bailli). the contributory cause being that one of the British ammunition tambrils was set on fire by Mysorean rockets.

At the Battle of Seringapatam in 1792, Indian soldiers launched a huge barrage of rockets against British troops, followed by an assault of 36,000 men. Although the Indian rockets were primitive by modern standards, their sheer numbers, noise and brilliance were said to have been quite effective at disorienting British soldiers. During the night, the rockets were often seen as blue lights bursting in the air. Since Indian forces were able to launch these bursting rockets from in front of and behind British lines, they were a tremendous tool for throwing the British off guard. The bursting rockets were usually followed by a deadly shower of rockets aimed directly at the soldiers. Some of these rockets passed from the front of the British columns to the rear, inflicting injury and death as they passed. Sharp bamboo was typically affixed to the rockets, which were designed to bounce along the ground to produce maximum damage [2]. Two of the rockets fired by Indian troops in 1792 war are on display at the Royal Artillery Museum in London [3].

Later at the battle of Srirangapattana (4th Anglo-Mysore war) in April 1799, British forces lead by Colonel Arthur Wellesley (Duke of Wellington) ran away from the battlefield when attacked by rockets and musket fire of Tipu Sultan's army. Unlike contemporary rockets whose combustion chamber was made of wood (bamboo), Tipu's rockets (weighing between 2.2 to 5.5 kg) used iron cylinder casings that allowed greater pressure, thrust and range (1.5 to 2.5 Km) [4]. The British were greatly impressed by the Mysorean rockets using iron tubes. At the end of war more then 700 rockets and sub systems of 900 rockets were captured and sent to England. William Congreve thoroughly examined the Indian specimens to reverse engineer and making its copies that were later used successfully in naval attack on Boulogne [5] (1806), siege of Copenhagen [6] (1807) and also against Fort Washington (New York) during the American Independence War, that is recounted as, rockets' red glare in the U.S. National Anthem, "The Star Spangled Banner." [7]

After the defeat of Tipu Sultan (04 May 1799) and other Indian kingdoms, major parts of India either fell to British colonialist or accepted British hegemony. Indian independence was largely compromised and the country was systematically exploited and suppressed by the British colonialism. Lack of political and economic independence stymied Indian science and military technology for 150 years till 1947 when it finally threw away the yoke of foreign occupation, to transition back as an independent sovereign nation state.

After regaining independence in 1947, India focused all its energy in nation building, primarily on economic and industrial development fully understanding the key role of science and technology. Indian rocketry was reborn thanks to the technological vision of Prime Minster Jawaharlal Nehru. Professor Vikram Sarabhai took the challenge of realizing this dream. Professor Sarabhai was an able leader and visionary who gave shape to modern Indian rocketry and space endeavours. President Dr A.P.J. Kalam, who played a key engineering role in realizing both the Indian SLV-3 space launcher as well as the Prithvi and Agni missiles, once said: "Many individuals with myopic vision questioned the relevance of space activities in a newly independent nation, which was finding it difficult to feed its population. Their vision was clear if Indians were to play meaningful role in the community of nations, they must be second to none in the application of advanced technologies to their real-life problems. They had no intention of using it as a mean to display our might."

Realization of economic development for Indian masses also requires safeguarding its borders and interests. During the 1971 War that saw India liberating Bangladesh, the US attempted coercion by force projection by sending the USS Enterprise of the 7th Fleet into the Bay of Bengal. This combined with nuclear weapon developments in China impaired Indian security and that accelerated Indian strategic weapon programs including indigenous missile programs. Initial missile programs like Project Devil (a theatre ballistic missile) and Project Valiant (an intercontinental ballistic missile) were scattered and stymied by many issues, which included technology development, financial resources and manpower.

Indian parliamentary democracy requires total civilian control of all defence forces and defence related organizations. The independent Comptroller & Auditor General (CAG) of India oversees financial accounting of all government expenses and serves as a watchdog which monitors the use of public funds for defence expenses.

The Integrated Guided Missile Development Program (IGMDP) was formed in 1983 with the aim of achieving self-sufficiency in missile development & production and today comprises of five core missile programs: the strategic Agni ballistic missile, the tactical Prithvi ballistic missile, the Akash and Trishul surface-to-air missiles and the Nag anti-tank guided missile. The program has given India the capability to produce indigenous missiles in other key areas as well. Indigenous development was required to overcome attempts by Western nations, to impose their will on developing nations, by enforcing pacts like the Missile Technology Control Regime (MTCR) to control access to and availability of advanced weapon systems. Undaunted, hats off to all the brilliant Indian scientists who have toiled so hard in their dedicated efforts to make the program successful and being on the cutting edge of missile technology.

In the Service of the Country
Frontline, Vol. 14 : No. 25 : 13 - 26 December 1997
By Anand Parthasarathy, a scientist who worked with Dr. Kalam on the IGMDP

Dr. APJ Abdul Kalam The call usually came late in the evening. "Kalam here," it always began, followed by the standard question, "What's happening?" One never knew how to respond, for a day's work at the missile-test bed, on the periphery of Hyderabad, meant a hectic 10 hours with everything seeming to go wrong. After preliminary queries came the real business, a key report had to be sent to the Government the next day. "Eat your dinner in peace and come after you have finished," Kalam always hastened to add. He himself had not yet left the laboratory for the day. This was how Kalam rounded up the usual suspects; an informal group of scientists and engineers, when some crucial work was at hand. It might be a no-holds-barred session to thrash out some issues of navigation and guidance before a Cabinet Committee on Political Affairs paper emerged, or to solve a problem dogging the elaborate quality assurance testing cycle to which a key missile component was being subjected.

The sessions were always held at a small round table - a table without a head, for protocol-free discussion. Sometimes the sessions would last till the next morning. For discussions during earthly hours, there was a bigger room across the corridor. But here too, failure to reach a decision was not a recognised option. Kalam attracted fierce loyalties from all those who came into contact with him. He was able to instil a sense of participation at every level, from the shop floor to the high-tech laboratory. His legion of admirers include some children to whose lives he added a special touch. For nine-year-old Swarna, a polio victim from birth, the Composites Production Centre of the Defence Research & Development Laboratory (DRDL) had designed an ultra lightweight, prosthetic foot support. Another child, a primary school student whose model of the Prithvi missile won the first prize in a contest in Secunderabad was taken to DRDL in Kalam's staff car so that he could see the real Prithvi being assembled.

Dr. Avul Pakir Jainulabdeen Abdul Kalam, who was awarded the Bharat Ratna - India's highest civilian honour on November 25th, was born on 15 October 1931 in the temple town of Rameswaram in the southern Indian state of Tamil Nadu. Kalam went to the Schwartz High School in Ramanathapuram. After graduating in science from St. Joseph's College in Tiruchi, he took a diploma in aeronautical engineering from the Madras Institute of Technology in the mid-1950s. The then Director of MIT, Professor K.A.V. Pandalai (whom Kalam acknowledged recently as one of his most valued teachers, the other being his school teacher, Siva Subramani Iyer), gave fascinating details about this phase in Kalam's life in a letter to The Hindu dated 15 March 1994. Kalam joined the Defence Research & Development Organisation (DRDO) in 1958 and served as a senior scientific assistant, heading a small team that developed a prototype hovercraft. Defence Minister Krishna Menon rode in India's first indigenous hovercraft with Kalam at the controls. But for reasons never explained, the project which would have been a considerable international achievement in those days, was not encouraged. This was probably one of the reasons why he moved out of DRDO in 1962 and joined India's space program. At the Indian Space Research Organisation (ISRO), Kalam initiated Fibre Reinforced Plastics activities, then after a stint with the aerodynamics and design group, he joined the satellite launch vehicle team at Thumba, near Trivandrum and soon became Project Director for the SLV-3. The project managed to put Rohini, a scientific satellite, into orbit in July 1980. He was honoured with a Padma Bhushan in 1981. Kalam was something of a curiosity at Thumba.

A bachelor, his spartan lifestyle as a vegetarian and teetotaller who lived in a single room in a lodge in Trivandrum earned him the nickname Kalam Iyer. He then moved back into the Defence Research Complex at Kanchanbagh, on the periphery of Hyderabad's Old City, as Director of DRDL. He had came to Hyderabad at a time when the morale was low at the laboratory as a result of the foreclosure of its ambitious missile project, codenamed Devil. He brought a whiff of ISRO informality to a laboratory that was used to an Army atmosphere. He refused to move into the bungalow allotted to the Director, preferring to stay in one of the 8 suites in the Defence Labs Mess. The suite, with a small study and a tiny bedroom, was his home for the next decade. He was instrumental in the re-emergence of DRDL. This was made possible, as Kalam and the then Scientific Adviser to the Defence Minister, Dr. V.S. Arunachalam (who brought him back to Defence Research), have always acknowledged, by the crucial role played by R. Venkataraman, who was then Defence Minister.

IGDMP Ballistic Missiles: Prithvi, Agni-I and Agni-II
Note: Please click on thumbnail, at right, to see a bigger picture

Kalam was asked to prepare a blueprint to make India into a missile nation. After working with DRDL veterans for over six months, followed by consultations with Dr. Arunachalam, Kalam gave a proposal to Venkataraman. It was a staggered scheme under which five missile development programs were to be taken up one after the other. "Take it back!" said Venkataraman who, though unfamiliar with the technical nitty gritty, had an instinctive feel for larger strategic issues. Venkataraman suggested that Kalam and Arunachalam recast the plan in such a way as to develop all five missile types under one program. They did it, as they now admit, by adding zeroes all over the place. Kalam's immediate concern was that he would have to tell his colleagues back in Hyderabad that he had committed them to five formidable tasks instead of one with a time frame of 10 years. Out of this audacious initiative was born the Integrated Guided Missile Development Program (IGMDP), India's most successful military research task to date.

Kalam's codenames for the program's five components were;

Nag, an anti-tank guided missile
Prithvi, a surface-to-surface battlefield missile
Akash, a swift, medium-range surface-to-air missile
Trishul, a quick-reaction surface-to-air missile with a shorter range
Agni, an intermediate range ballistic missile, the mightiest of them all

The Trishul has the unique distinction of being capable of serving all three services.

From his SLV-3 experience, Kalam had learned the advantages of team work and of sharing the tasks with partners in private and public sector industries. In the new management structure of the missile program, Kalam, as the Chairman of the Programme Management Board, delegated almost all executive and financial powers to five carefully selected Project Directors and kept himself free to address the core technology issues. His task was to inspire and monitor over 20 institutions and partners outside - ranging from large public and private sector suppliers to small specialist firms that needed seed money to take up the precision tasks. Kalam's contribution in this scheme has been acknowledged by all who worked with him. He set for himself a gruelling schedule. The first half hour of the day was reserved for what was called the morning meeting, where administrative heads met him to take decisions on routine functions. During this period any employee could walk in and discuss administrative problems, which were usually sorted out the same day. Rest of the day was devoted to hands-on interaction with project teams working on a campus spread over 40 hectares. The missiles went up more or less on schedule: Trishul in 1985, Prithvi in 1988, Agni in 1989 and the others in 1990. And the Kalam legend had grown. He is well-versed in Tamil and has written poetry. Seventeen of his poems were translated into English by Manidarshi, and published as a book titled My Journey in 1994.

Scientists greet Abdul Kalam after the successful launch of Agni on 22 May 1989.

The establishment of the Research Centre Imarat (RCI), a campus 8km from DRDL, in 1988 was perhaps the most satisfying achievement for Kalam during the missile years. He received generous funding from the Government to build the futuristic centre, which is totally geared for work in advanced missile technologies. Its state-of-the-art facilities are set in a unique ambience and the level of comfort accorded to the individual worker is matched by few R&D institutions. And Kalam's interest in the environment saw RCI emerge as an oasis in a rocky wasteland. It has a small farm that meets the food requirements of those who stay in the RCI quarters. Kalam was awarded the Padma Vibhushan in 1990. After 10 years in DRDL, he went to New Delhi to take over from Arunachalam as Scientific Adviser to the Defence Minister - reluctantly, many in DRDL missed his presence. But the system created by Kalam had taken a firm hold in that decade and the missile programme passed on smoothly into its final phase of production and induction. In Delhi, Kalam as head of the DRDO had to deliver other prestigious projects, such as the Arjun MBT and the Light Combat Aircraft (LCA) projects. While management practices he adopted for the missile program have inevitably rubbed off on these projects, there are no miracles to be had in strategic development areas. There have been technical problems. Even in the missile program, work on the SAMs and the ATM is slower than anticipated. But Trishul's recent multiple test flights have demonstrated that the system Kalam put in place has inherent strengths. As Dr. V.S. Arunachalam put it, "We are now mature, we learn from mistakes and push on ahead."

"Strength respects strength." This is Kalam's usual response to the question why India needs its own missiles or a battle tank or a combat aircraft. But Kalam is a technocrat. Although there are suggestions that he should use his status, which has been enhanced by the award of Bharat Ratna, to push for the active induction of Agni, it would be uncharacteristic of him to press his view too much in geopolitical matters. He is the happiest at the drawing board, in discussion with his scientists on how their dreams for the next millennium can be fulfilled. The projects envisaged include an air breathing hyper-plane spacecraft that draws oxygen from the atmosphere rather than carry it all the way from the ground, reusable missiles and stealth technology. Kalam has shown that with adequate funding, freedom from procedural hold-ups and a people-oriented management, India can make products of internationally acceptable technical standards in a demanding arena like defence. Kalam is by no means a miracle man. As the head of a vast network of laboratories - whose products include avalanche-controlling structures in Kashmir, water desalination kits for the Thar desert, a world class sonar submarine finder for the latest warship - INS Delhi, and infra-red night vision goggles for the Indian Army - Kalam's attention is necessarily a bit diffused. His self-effacing persona cloaks a formidable catalyst who can make people work.

[2] Remarkably, two of the rockets fired by Indian troops in 1792 are on display at the Royal Artillery Museum in London. One of these rockets is made up of an iron case 10 inches long by 2.3 inches wide. It is bound to a metal sword that is 40 inches long.

[4] The Story of Indian Rockets, From Srirangapattana to Sriharikota, (www.VigyanPrasar.com).

[5] More than 2000 derived versions of Mysorean rockets were fired against the city of Boulonge. These rockets reportedly so stunned the French that not one shot was returned. (http://www.spaceline.org/history/1.html)

[6] Ibid. In 1807, Copenhagen was severely damaged by fires caused by the launching of 25,000 Mysorean-derived versions of rockets.

[7] Ibid. On 13 & 14 September 1814, a 25-hour barrage of Congreve rockets (derived from the Mysorean rocket) was fired from the British ship Erebus against Fort McHenry in Baltimore. Each of the rockets fired against Fort McHenry weighed about 30 pounds, and carried an incendiary charge. A number of American ships were destroyed by Congreve rockets during the War of 1812 during the siege. The battle was witnessed by a young lawyer named Francis Scott Key, who mentioned the Congreve rockets' red glare in his song "The Star Spangled Banner". The song later became the U.S. National Anthem, paying tribute to the tenacity of the American forces under siege. Congreve rockets launched by British ground troops reportedly terrified the American soldiers. These rockets typically weighed 3 to 12 pounds each, and carried case-shot carbine balls that flew out like shrapnel when a charge of gunpowder exploded. The rockets surprised a rifle battalion led by U.S. Attorney General William Pinkney at the Battle of Bladensburg on 24 August 1814. After his victory at this battle, British Commander Lt. George R. Gleig wrote of the American soldiers, "Never did men with arms in their hands make better use of their legs."