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Get Ready, Pakistan: India Is Developing Its Own Missile-Defense Shield

Why should Pakistan Get Ready, does India wants Pakistan to send Missile to test their defense?
 
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That maybe the case but no ABM is 100% accurate. BM and BMD technology moves in sync. I would venture to say that actually its cheaper to make advancements to BM technology (MIRV, dummy warheads etc.) than it is to get a working BMD at scale to protect multiple VPs. Israel's case is a different one where it is targeted by less sophisticated missiles (not even BMs) and over an area where a few batteries of layered defence can cover the entire country. Even there, the protection does not guarantee survivability.

The ONLY answer is to sit down and talk and resolve issues. Even if India has overwhelming superiority against Pakistan, there will be instability and tensions along the border due to fairly significant asymmetric capabilities fielded as a result of festering issues.

It's quite the opposite actually, at this particular juncture ABMs are actually progressing faster than BMs.
This is why many countries are undertaking ABM R&D at such a rapid pace, they do not want to be left behind when the top countries have succeeded in making a deterrence that absolutely negates MAD.

Contrary to popular belief MIRVs and MaRVs are very old tech and the basic concept has remained the same since the 70s.

ABMs were rather unfeasible after MIRVs were invented, and made the 'cost-exchange ratio' scale tip towards the attackers side, whereas they were all the rage before MIRVs.
The early 90s saw repeated tests of THAAD failing; by the end of 1990s the inception of advanced sensors, fast microprocessors and the over all engineering side of ABMs had taken off at a very fast pace resulting in the THAAD having a bevy of successful tests post 99 and as if on cue US pulled out of the ABM treaty on 01.

Here's the time line.
Initial stages of Cold War - ABMs are cheaper than BMs and the cost-exchange ratio favors the party with ABMs.
1970 - LGM 30G is made MIRV capable and USSR responds with making R 36 MIRV capable.
1972 - Cost-exchange ratio favors the attacker now, unlike before where it was the opposite and US and USSR sign the ABM treaty.
Sometime in the 70s - MaRVs come into play
From then till 99 - ABMs more or less have nothing new to offer.
1999 - After a string of failures, armed with new subsystems THAAD hits targets in and outside the atmosphere.
2001 - Seeing the progress of THAAD and realizing the fast evolution of guidance and other ABM sub-systems is imminent US backs out of the ABM treaty and every other country follows suit and initiates the R&D of their own respective ABMs.


Since then till 2017 now, THAAD has had a range of successes and will achieve even better cost-exchange ratio making ABMs very feasible and popular in the future, BMs on the other hand are in a rut and its roles are being relegated to cruise missiles and Hypersonic cruise vehicles like the X 51, WU 14, HSTDV, etc
 
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http://nationalinterest.org/blog/th...-tank-now-has-its-own-shields-22719?page=show

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Ballistic missile defense systems have exploded in prominence across the globe since the United States withdrew from the 1972 Anti-Ballistic Missile (ABM) Treaty in 2002. Designing integrated radar warning systems and interceptor batteries that can shoot down a ballistic missile in flight is often described as akin to knocking down a bullet with another bullet, but the technology to perform such a feat is now entering service in countries like Japan, South Korea and Saudi Arabia.

India’s acute interest in missile defense predates the demise of the ABM treaty, however, as it came uncomfortably close to a full-scale conflict with a nuclear-armed Pakistan during the 1999 Kargil War. This led New Delhi to begin early development of an ABM system which accelerated after the Washington vetoed a bid to acquire the Israeli Arrow-2 interceptor in 2002. With the successful testing of the Prithvi Air Defense missile in 2007, India became only the fourth country to have developed a functioning ballistic missile defense system, ahead even of China.

A decade later, New Delhi has finally begun setting up a two-layer ballistic missile defense shield that initially will protect New Delhi and Mumbai. The Prithivi Air Defense (PAD) system will provide long-range high-altitude ballistic missile interception during an incoming missile’s midcourse phase, while the Advanced Air Defense system offers short-range, low-altitude defense against missiles in the terminal phase of their trajectory. Reportedly the first batteries have begun installation in two villages in Rajasthan.


Together the two systems offer only patchy protection of certain key cities. The Indian Defense Research and Development Organization (DRDO) is currently testing a successor to the PAD—the Prithvi Vehicular Defense—with greater range and speed, and a maximum interception altitude approaching that of the U.S. THAAD system.


The Indian ABMs are cued onto their targets by giant Swordfish Long-Range Tracking Radars, an indigenously built derivative of the Israeli Green Pine radar, which is used in BMD systems in both Israel and South Korea. The Swordfish currently has a range of 500 miles, though there are plans to upgrade it to over 900 miles. It can track up to 200 targets simultaneously, and is claimed to have the resolution to detect an object the size of a cricket ball.

At first glance, the Prithvi Air Defense missile seems quite capable, with a range of 1,250 miles and a maximum altitude of 260,000 feet, making it an exospheric interceptor. The missile is programmed prior to launch by the BMD command center on an intercept trajectory, which it maintains using an inertial navigation system. It receives midcourse updates to its trajectory using data from the Swordfish radar, and then in the terminal approach phase switches to its own active radar seeker and destroys the target with a proximity-fused warhead.

In multiple tests, the PAD has successfully shot down Indian Prithvi short-range ballistic missiles (same name, different system) at altitudes as high as 246,000 feet. Traveling at speeds of Mach 5, the PAD in theory is fast enough to hit speedier, higher-flying medium-range ballistic missiles, but would struggles versus intermediate-range types.

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However, a major limitation of the PAD is that the second phase of the two-stage rocket uses liquid fuel. As liquid rocket fuel corrodes fuel tanks when stored for long, the PAD could not be on standby 24/7. Instead, it would need to be gassed up during a period of crisis in anticipation of trouble. This is less than ideal for a weapon intended to defend against an attack which might come at any moment.

For defense at low-altitudes, the solid-fuel Advanced Air Defense system, or Ashwar, uses an endospheric (within the Earth’s atmosphere) interceptor that knocks out ballistic missiles at a maximum altitude of 60,000 to 100,000 feet, and across a range between 90 and 125 miles for local defense. The AAD has performed successfully in most tests against targets at altitudes of 50,000 feet, though an improved model failed a test in April 2015 before succeeding in subsequent attempts. It is claimed the Mach 4.5 missile might also have application against cruise missiles and aircraft.

The new Prithvi Defensive Vehicle looks to be a promising “Phase 2” replacement for the PAD. This new two-stage exo-atmospheric interceptor uses only solid-fuel rockets, and can theoretically hit targets nearly as high as 500,000 feet at a range that may be as far 3,100 miles. Upon leaving the earth’s atmosphere, the interceptor ditches its heat shields and activates an infrared seeker that helps it discriminate between decoys and its target.

The PDV’s first test in 2014 missed its target but was still proclaimed a success. A second test on February 2017 succeeded in striking a Prithvi II missile. The PDV is believed to be faster than the PDA, possibly giving it IRBM-interception capability.

India also has several additional forthcoming systems with application to ballistic missile defense: an extended-range variant of the Barak-8 naval surface-to-air missile currently under development with Israel called the LR-SAM or Barak-8ER (projected range: 93 miles), and five Russian S-400 surface-to-air missiles systems, capable of firing Mach 8-plus missiles over a range of 200 miles. These will supplement S-300Vs already in Indian service that have some ABM capability.

A final note regarding the testing track records of the Prithvi and AAD: ABM tests are often conducted under ideal conditions more forgiving than those that would be encountered in a realistic combat scenario. The tests appear to have been conducted against slower SRBMs that do not employ evasive maneuvers or decoys. Therefore, claims that the BMD system would have a 98 percent hit probability rate should not be taken too literally.

More ABMs, More Security?

India’s ballistic missile defenses are intended to defend against two states: China and India. China has a large and mature ballistic missile force, including intercontinental ballistic missiles which the Indian defenses are not designed to counter. Thus, India’s BMD system could only protect against a limited ballistic missile attack from China, not a full-scale onslaught. Fortunately, both Beijing and New Delhi adhere to a no-first-use policy regarding nuclear weapons.

India’s defenses are of greater significance to countering Pakistan’s rapidly growing arsenal of short- and medium-range ballistic missiles—and Pakistan’s policy amounts to “First Use!” In fact, India’s ballistic missile defenses add an ambiguous new dimension to one of the scariest arms races on the planet.

On several occasions, groups connected to the Pakistani state have committed violent attacks on Indian soil such as the Pakistani Army infiltration of Kargil in 1999, the attack on the Indian parliament in New Delhi in 2001, and the Mumbai terror attacks in 2008. Frustrated by these incidents, New Delhi claims that if sufficiently provoked by a future attack, it would swiftly retaliate by launching a mechanized assault into Pakistan per the Cold Start doctrine. However, Islamabad maintains that it would retaliate with nuclear weapons against a conventional ground attack—thus effectively claiming a nuclear trip-wire along the Line of Control between the two states.

India’s BMD program would only counter a portion of Pakistan’s nuclear capabilities. Many of Pakistan’s nukes are in fact smaller, shorter-range tactical weapons for targeting frontline forces that may not enter within reach of Indian interceptors positioned to protect key cities.

Furthermore, not all of Pakistan’s roughly 140 nuclear warheads are mounted on ballistic missiles. There are also nuclear gravity bombs slung under F-16 fighters, Ra’ad nuclear-tipped cruise missiles on Mirage IIIs and JF-17s, and possibly in the future Babur submarine-launched cruise missiles.

Other critics fear that the existence of ballistic missile defenses may simply prompt Pakistan and China to devise even deadlier nuclear missiles employing decoys, evasive trajectories and multiple reentry vehicles (MIRVs) to shower warheads over several targets. These would pose a formidable challenge for any ABM system. Alternately, Pakistan might simply produce more missiles and warheads, and plan saturate the Indian defense system, with the possible consequence of inflicting even more damage than would have been the case.

A short article in the Dawn newspaper implies that India’s growing defenses will indeed engender such a reaction in Islamabad. Fearing that the system will “negate” Pakistani strategic strike abilities, the columnist concludes India’s ABM interceptors will “force the armed forces to counter it, a solution which would prove to be both costly and time consuming.” Indeed, in January 2017 the Pakistani military tested an Ababeel medium-range ballistic missile its claim can deploy MIRVs.

This highlights the tendency of adversaries to perceive ballistic missile defenses as a means to enable offensive schemes, rather than simply to preserve the lives of the populace. There is indeed concern that BMD systems may embolden national leaders to pursue military options based on an inaccurate perception that their nation will be impervious to nuclear retaliation. In truth, no BMD system anywhere is a hundred percent reliable; for example, the United States’ SM-3 and GMD interceptors have averaged 50–60 percent success rates in tests. India’s system will only protect a few major cities in the coming decade, and does not counter all possible vectors of nuclear attack.

New Delhi’s rapid development of an indigenous BMD system remains a remarkable technical achievement. As the PDV and AAD batteries are installed and expanded, they may serve to protect major Indian cities against a limited nuclear strike, or discourage attempts to launch one in the first place. However, it remains to be seen whether the defensive benefits afforded by the missile interceptors will not be rapidly counterbalanced by improvements to offensive capabilities they spur in India’s adversaries.

Sébastien Roblin holds a Master’s Degree in Conflict Resolution from Georgetown University and served as a university instructor for the Peace Corps in China. He has also worked in education, editing, and refugee resettlement in France and the United States. He currently writes on security and military history for War Is Boring.

Nice step. Maza aaeyga. :guns:
 
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Well BMDs or Missile shields are they even effective in Pak-India scenario?
 
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