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India Ready to Install Ballistic Missile Defence

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India Ready to Install Ballistic Missile Defence
1. June 2020



J C Menon

India is likely to expedite the installation process of its Ballistic Missile Defence (BMD) system, aimed at protecting its important cities, vital installations and critical assets from being targeted by missiles from hostile nations. India’s BMD programme is structured as a two-layered missile defence system consisting of two land and sea-based interceptor missiles, namely the PRITHVI Air Defence (PAD) missile for high altitude interception and the Advanced Air Defence (AAD) missile for interception at low altitude. The Defence Research and Development Organisation (DRDO), which has developed the system and the Indian Air Force (IAF), which has carried out the tests, have submitted a final induction strategy to the government.

“All tests and trials carried out so far have been successful, including the radars and missiles,” a DRDO official said. The first BMD will be installed in the national capital, New Delhi, and the second one could be in the financial capital Mumbai, the official notes. DRDO had earlier stated that the first phase of the BMD shield would be ready by 2013 to protect New Delhi from hostile missiles with a 2000 km range. It had also said that by 2016, the second phase would be operational with the capability to kill hostile missiles within a 5000 km range.

Ambitious Project
India has been working on a two-tiered BMD system since 1999, with the PRITHVI Air Defence (PAD) Pradyumna and PRITHVI Defence Vehicle (PDV) interceptors designed to destroy missiles at exo-atmospheric altitudes of 50–180 kilometres. PAD has the capability to engage the 300 km to 2,000 km class of ballistic missiles at speeds of 5 Mach and is guided by an inertial navigation system with mid-course updates from the Long-Range Tracking Radar (LRTR) and active radar homing in the terminal phase. India has specifically developed a LRTR named SWORDFISH as part of its BMD programme which helps in tracking and providing fire control to interceptor missiles. Currently, the SWORDFISH LRTR has a range of 600 to 800 km and can spot objects two inches in diameter and India has upgraded this radar to increase its range to 1500 km. This will be used along with upgraded variants of the PAD and AAD missiles.

Tests and Trials
The first PAD exercise was conducted in November 2006, in which a PAD missile successfully intercepted a modified PRITHVI-II at an altitude of 50 km, which was modified successfully to mimic the trajectory of Pakistan’s M-11 missile. On 6th March 2009, DRDO carried out a second successful test of the PAD interceptor missile against a ship-launched DHANUSH missile, which followed the trajectory of a missile with a range of 1500 km. The target was tracked by SWORDFISH LRTR radar and destroyed by the PAD at a 75 km altitude. With that test of the PAD missile, India became the fourth country to have successfully developed an anti-ballistic missile system, after United States, Russia, and Israel. The PDV is to eventually replace the older PAD/PRADYUMNA Ballistic Missile Interceptor and among other features, this new two-stage, solid-fuelled PDV interceptor is fitted with an Imaging Infrared (IIR) seeker, developed by DRDO to distinguish between incoming warheads and decoys. The PDV was first tested in April 2014 and the missile interceptor had a “near miss” at an altitude of 120 km. However, on 12th February 2017, PDV was able to successfully destroy a ballistic missile target launched from over 2000 km at an altitude of 97 km.

On December 6, 2007, the first AAD successfully intercepted a modified PRITHVI-II missile at an altitude of 15 km after which several tests were conducted before on 1st March 2016, an AAD missile was able to destroy the target missile, meeting all the mission objectives successfully, according to the DRDO official. The AAD system is a single-stage, solid-fuel missile named ASHVIN, designed to intercept incoming endo-atmospheric ballistic missiles at an altitude of 20-40 km. The interceptor is 7.5 m tall, weighs around 1.2 tonnes and has a diameter of less than 0.5 m, using guidance similar to that of PAD, with an inertial navigation system, mid-course updates from ground-based radar and active radar homing in the terminal phase.

Combined Defence
India is already set to receive the Russian S-400 TRIUMPH air defence system and DRDO is also developing BARAK-8, a long-range anti-air and anti-missile naval defence system jointly with Israel Aerospace Industries (IAI). The Indian Army is considering induction of a variant of the BARAK 8 missile to meet its requirement for a medium-range surface-to-air air defence missile while the naval version has the capability to intercept incoming enemy cruise missiles and combat jets targeting its warships at sea. It would also be inducted into the Indian Air Force, followed by the Army and DRDO is also hoping to soon induct its short range Quick Reaction Surface-to-Air Missile (QRSAM) into the country’s military after it was tested successfully last year. The sophisticated all-weather and all-terrain missile with a strike range of 25-30 km (16-31 mi.) has been developed by the DRDO for the Indian Armed Forces, with search and track on-the-move capability, in a short reaction time. The missile can be mounted atop a truck and stored in a canister, uses solid-fuel propellant, and is equipped with electronic counter measures against jamming by aircraft radars. It is also equipped with an indigenously-developed phased array radar, inertial navigation system, data link and RF seeker. The missile will give a boost to the ballistic missile defence system and there are also plans to develop a laser based weapon system to intercept and destroy missiles soon after they are launched towards the country.
https://euro-sd.com/2020/06/news/17401/india-ready-to-install-ballistic-missile-defence/
 
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Another important component in the BMD may be the DRDO built Navy operated Missile Tracking Ship which is yet to be commissioned
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India Ready to Install Ballistic Missile Defence
1. June 2020



J C Menon

India is likely to expedite the installation process of its Ballistic Missile Defence (BMD) system, aimed at protecting its important cities, vital installations and critical assets from being targeted by missiles from hostile nations. India’s BMD programme is structured as a two-layered missile defence system consisting of two land and sea-based interceptor missiles, namely the PRITHVI Air Defence (PAD) missile for high altitude interception and the Advanced Air Defence (AAD) missile for interception at low altitude. The Defence Research and Development Organisation (DRDO), which has developed the system and the Indian Air Force (IAF), which has carried out the tests, have submitted a final induction strategy to the government.

“All tests and trials carried out so far have been successful, including the radars and missiles,” a DRDO official said. The first BMD will be installed in the national capital, New Delhi, and the second one could be in the financial capital Mumbai, the official notes. DRDO had earlier stated that the first phase of the BMD shield would be ready by 2013 to protect New Delhi from hostile missiles with a 2000 km range. It had also said that by 2016, the second phase would be operational with the capability to kill hostile missiles within a 5000 km range.

Ambitious Project
India has been working on a two-tiered BMD system since 1999, with the PRITHVI Air Defence (PAD) Pradyumna and PRITHVI Defence Vehicle (PDV) interceptors designed to destroy missiles at exo-atmospheric altitudes of 50–180 kilometres. PAD has the capability to engage the 300 km to 2,000 km class of ballistic missiles at speeds of 5 Mach and is guided by an inertial navigation system with mid-course updates from the Long-Range Tracking Radar (LRTR) and active radar homing in the terminal phase. India has specifically developed a LRTR named SWORDFISH as part of its BMD programme which helps in tracking and providing fire control to interceptor missiles. Currently, the SWORDFISH LRTR has a range of 600 to 800 km and can spot objects two inches in diameter and India has upgraded this radar to increase its range to 1500 km. This will be used along with upgraded variants of the PAD and AAD missiles.

Tests and Trials
The first PAD exercise was conducted in November 2006, in which a PAD missile successfully intercepted a modified PRITHVI-II at an altitude of 50 km, which was modified successfully to mimic the trajectory of Pakistan’s M-11 missile. On 6th March 2009, DRDO carried out a second successful test of the PAD interceptor missile against a ship-launched DHANUSH missile, which followed the trajectory of a missile with a range of 1500 km. The target was tracked by SWORDFISH LRTR radar and destroyed by the PAD at a 75 km altitude. With that test of the PAD missile, India became the fourth country to have successfully developed an anti-ballistic missile system, after United States, Russia, and Israel. The PDV is to eventually replace the older PAD/PRADYUMNA Ballistic Missile Interceptor and among other features, this new two-stage, solid-fuelled PDV interceptor is fitted with an Imaging Infrared (IIR) seeker, developed by DRDO to distinguish between incoming warheads and decoys. The PDV was first tested in April 2014 and the missile interceptor had a “near miss” at an altitude of 120 km. However, on 12th February 2017, PDV was able to successfully destroy a ballistic missile target launched from over 2000 km at an altitude of 97 km.

On December 6, 2007, the first AAD successfully intercepted a modified PRITHVI-II missile at an altitude of 15 km after which several tests were conducted before on 1st March 2016, an AAD missile was able to destroy the target missile, meeting all the mission objectives successfully, according to the DRDO official. The AAD system is a single-stage, solid-fuel missile named ASHVIN, designed to intercept incoming endo-atmospheric ballistic missiles at an altitude of 20-40 km. The interceptor is 7.5 m tall, weighs around 1.2 tonnes and has a diameter of less than 0.5 m, using guidance similar to that of PAD, with an inertial navigation system, mid-course updates from ground-based radar and active radar homing in the terminal phase.

Combined Defence
India is already set to receive the Russian S-400 TRIUMPH air defence system and DRDO is also developing BARAK-8, a long-range anti-air and anti-missile naval defence system jointly with Israel Aerospace Industries (IAI). The Indian Army is considering induction of a variant of the BARAK 8 missile to meet its requirement for a medium-range surface-to-air air defence missile while the naval version has the capability to intercept incoming enemy cruise missiles and combat jets targeting its warships at sea. It would also be inducted into the Indian Air Force, followed by the Army and DRDO is also hoping to soon induct its short range Quick Reaction Surface-to-Air Missile (QRSAM) into the country’s military after it was tested successfully last year. The sophisticated all-weather and all-terrain missile with a strike range of 25-30 km (16-31 mi.) has been developed by the DRDO for the Indian Armed Forces, with search and track on-the-move capability, in a short reaction time. The missile can be mounted atop a truck and stored in a canister, uses solid-fuel propellant, and is equipped with electronic counter measures against jamming by aircraft radars. It is also equipped with an indigenously-developed phased array radar, inertial navigation system, data link and RF seeker. The missile will give a boost to the ballistic missile defence system and there are also plans to develop a laser based weapon system to intercept and destroy missiles soon after they are launched towards the country.
https://euro-sd.com/2020/06/news/17401/india-ready-to-install-ballistic-missile-defence/
The establishment of a credible Ballistic Missile Defense system within South Asian war theater is far more challenging than that of USA, Europe or Russia.

At best, it will provide a false sense of security to Indian establishment which it self will have destabilizing impact over regional security.
 
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DRDO involved in it at any stage!!

Nope. Not going to work, guaranteed.

Once again money down the drain Indians.
 
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DRDO involved in it at any stage!!

Nope. Not going to work, guaranteed.

Once again money down the drain Indians.

Perhaps hoping for an election boost, India’s Prime Minister Modi announces that Indian scientists shot down a live satellite at a low-earth orbit. Jaipal Singh / AAP
India destroys its own satellite with a test missile, still says space is for peace
April 1, 2019 5.02pm AEDT
Author
  1. Bin Li

    Lecturer, University of Newcastle
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Bin Li does not work for, consult, own shares in or receive funding from any company or organisation that would benefit from this article, and has disclosed no relevant affiliations beyond their academic appointment.

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On March 27, India announced it had successfully conducted an anti-satellite (ASAT) missile test, called “Mission Shakti”. After the United States, Russia and China, India is now the fourth country in the world to have demonstrated this capability.

The destroyed satellite was one of India’s own. But the test has caused concerns about the space debris generated, which potentially threatens the operation of functional satellites.

There are also political and legal implications. The test’s success may be a plus for Prime Minister Narendra Modi, who is now trying to win his second term in the upcoming election.

Read more: India's WhatsApp election: political parties risk undermining democracy with technology

But the test can be viewed as a loss for global security, as nations and regulatory bodies struggle to maintain a view of space as a neutral and conflict-free arena in the face of escalating technological capabilities.

According to the official press release, India destroyed its own satellite by using technology known as “kinetic kill”. This particular technology is usually termed as “hit-to-kill”.

A kinetic kill missile is not equipped with an explosive warhead. Simply put, what India did was to launch the missile, hit the target satellite and destroy it with energy purely generated by the high speed of the missile interceptor. This technology is only one of many with ASAT capabilities, and is the one used by China in its 2007 ASAT test.

Power and strength
Since the first satellite was launched in 1957 (the Soviet Union’s Sputnik), space has become – and will continue to be – a frontier where big powers enhance their presence by launching and operating their own satellites.

There are currently 1,957 satellites orbiting Earth. They provide crucial economic, civil and scientific benefits to the world, from generating income to a wide range of services such as navigation, communication, weather forecasts and disaster relief.

The tricky thing about satellites is that they can also be used for military and national security purposes, while still serving the civil end: one good example is GPS.

So it’s not surprising big powers are keen to develop their ASAT capabilities. The name of India’s test, Shakti, means “power, strength, capability” in Hindi.

Danger of space debris
A direct consequence of ASAT is that it creates space debris when the original satellite breaks apart. Space debris consists of pieces of non-functional spacecraft, and can vary in size from tiny paint flecks to an entire “dead” satellite. Space debris orbits from hundreds to thousands of kilometres above Earth.

The presence of space debris increases the likelihood of operational satellites being damaged.

Although India downplayed the potential for danger by arguing that its test was conducted in the lower atmosphere, this perhaps did not take into account the creation of pieces smaller than 5-10 cm in diameter.

In addition, given the potential self-sustaining nature of space debris, it’s possible the amount of space debris caused by India’s ASAT will actually increase due to the collision.

Aside from the quantity, the speed of space debris is another worrying factor. Space junk can travel at up to 10km per second in lower Earth orbit (where India intercepted its satellite), so even very small particles pose a realistic threat to space missions such as human spaceflight and robotic refuelling missions.

Regulatory catch-up
As we’re seeing clearly now in social media, when technology moves fast the law can struggle to keep up, and this leads to regulatory absence. This is also true of international space law.

Five fundamental global space treaties were created 35-52 years ago:

  • Outer Space Treaty (1967) – governs the activities of the states in exploration and use of outer space
  • Rescue Agreement (1968) – relates to the rescue and return of astronauts, and return of launched objects
  • Liability Convention (1972) – governs damage caused by space objects
  • Registration Convention (1967) – relates to registration of objects in space
  • Moon Agreement (1984) – governs the activities of states on the Moon and other celestial bodies.
Read more: I've Always Wondered: could someone take ownership of a planet or a moon?

These were written when there were only a handful of spacefaring nations, and space technologies were not as sophisticated as they are now.

Although these treaties are binding legal documents, they leave many of today’s issues unregulated. For example, in terms of military space activities, the Outer Space Treaty only prohibits the deployment of weapons of mass destruction in space, not conventional weapons (including ballistic missiles, like the one used by India in Mission Shakti).

In addition, the treaty endorses that outer space shall be used exclusively for peaceful purposes. However, the issue is how to interpret the term “peaceful purposes”. India claimed, after its ASAT test:

we have always maintained that space must be used only for peaceful purposes.

When terms such as “peaceful” seem to be open to interpretation, it’s time to update laws and regulations that govern how we use space.

New approaches, soft laws
Several international efforts aim to address the issues posed by new scenarios in space, including the development of military space technologies.

For example, McGill University in Canada has led the MILAMOS project, with the hope of clarifying the fundamental rules applicable to the military use of outer space.

Read more: We're drafting a legal guide to war in space. Hopefully we'll never need to use it

A similar initiative, the Woomera Manual, has been undertaken by Adelaide Law School in Australia.

Though commendable, both projects will lead to publications of “soft laws”, which will have no legally binding force on governments.

The UN needs to work much harder to attend to space security issues – the Disarmament Commission and Committee on the Peaceful Uses of Outer Space can be encouraged to collaborate on the issues regarding space weapons.

It is in everyone’s best interests to keep space safe and peaceful.
 
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is it good against mirv?

India does not even have MIRV. So the less we talk about any tech that can counter MIRV the better. :-)

Indians have been in great pain ever since Pakistan demonstrated MIRV capable Ababeel missile. :rofl:
 
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Indian Ballistic Missile Shield Programme is there since 1970 and that was 40 Kms Range Rohini Missile Project and by 1990, the Range increased to 150 Kms and now that Range is enough to knock down Enemy Ballistic Missiles as well as Mobile Launchers and Transport Planes !!!! Welcome to Hindustan !!!!
 
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