Category Archives: US Department of Defense

Israel’s Military Occupation: Fighting a weak for far too long

Israel’s growing security needs and recent moves is drawing harsh conclusions and asking difficult questions. Growing security concerns – dealing with Iran nuclear power, growing arsenal of Hamas and hizbollah, recent over throw of Egypt’s hosni Mubarak-1979 peace treaty between Israel and Egypt.

Furthermore, Arrival of Iranian war ships in Mediterranean since 1979, has sowed signs of Tehran’s determination to expand it’s influence within the Mediterranean region.

Recently Israel Air force has ordered 20 American F-35 fighter jets most advanced jets, navy will receive two new submarines, and Israel pouring money into missile defence systems (with Arrow 3 on it’s way) and spurring up the land force capabilities.

In years in israelis the army has lost some of it’s lustre after a string of scandals involving it’s leaders (example of some incidents major of all was the Attack on gaza aid flotilla. Some argue the threat today to israel is not invasion or battlefield defeat instead it’s a long term erosion of Israel legitimacy

Combination of conventional and non conventional warfare, new approach combination of political and military elements has made Israel to think differently which is forcing the nation to think aggressively. Military personnel are constantly engaged in deep thoughts and argument to extend military power within the region to address the nature of war Israel is about to face. So what exactly is in those mind, may be the following:

– Estimate of hizbollah’s rocket arsenal
– their target strength and Israel cities
– fighting a weak for far too long
– what is there to loose and to gain
– IDF room of manoeuvre is shrinking (fighting against weak)

So how effective is this fighter jets and submarines contracts If the threat is to the cities? One thing to look in things contracts and extent of Israel’s military budget is best taken by Comparing the military spending of Israel against it’s neighbours Egypt, Syria, Jordan, Iran lebanon. Best here is too have an Insight into the politics and the military -sheer number of former military leaders in politics, you will be surprised by the inclusion of high profile military officers in what’s called a typical civilian Market.

The Israel Navy is making advanced preparations to absorb two new German-made Dolphin-class submarines, IDF journal Bamachaneh reported in its latest issue. The number of soldiers selected for submarine warfare has grown by 30% in the latest IDF recruitment batches, in order to man the additional submarines.

The Navy currently has three submarines, also of the Dolphin class, so the addition of two subs means that the force is growing 66% bigger. “We are in mid-process and are slowly adding more crews to be trained for service in the submarines,” explained Naval Instruction Base Commander Col. Ronen Nimni. “We are also taking care to add crew commanders who closely mentor the soldiers.”

More officers are being trained for submarine posts as well. The number of cadets who will be trained for submarine command positions is rising by 35%.

“The missiles, part of Israel’s estimated 100-strong nuclear arsenal, reportedly have a range of up to 800 miles. The subs probably cannot hit Iran without passing through the Suez into the Red Sea and ultimately the Indian Ocean. The Red Sea is also the best route to the Gulf of Oman, where Israeli ships and submarines might enforce a blockade of Iran, during wartime.”

In November 2005, it was announced that Germany would allow the sale of two new Dolphin Class submarines to Israel. In July 2006, Israel placed a contract for two additional Dolphin submarines with an option on a third. The new submarines will have air-independent propulsion (AIP) systems, which allow them to stay submerged for a much longer period. Delivery of the first vessel is expected in 2012.

Dolphin Class Submarines

Based at Haifa, the Israeli Navy (IN) currently operates three modern, diesel-electric, Dolphin-class submarines. Two additional Dolphin-class submarines have also been ordered and are scheduled to be delivered before 2012. In December 2003, two of Israel’s three decommissioned Gal-class submarines arrived in Kiel for refits and modernization at Germany’s Howaldtswerke-Deutsche Werft. Although the original plan was to recommission the Gal-class, it was later decided to search for a potential buyer.

Israel in world’s Politics

Israel has never acknowledged publicly that it is a nuclear-weapons state, but it has also never signed the Nuclear Non-Proliferation Treaty (NPT). Now the Arabs, led by Egypt, are demanding that Israel do so or they will sabotage the future of the NPT regime

It is also abundantly clear that Israel’s nuclear capability has not kept its enemies from attacking. Iranian-backed terrorist groups Hezbollah in Lebanon and Hamas in Gaza and the West Bank have both fired rockets into Israel in two recent wars despite the country’s possession of nuclear weapons that could obliterate them all. This too is no surprise. Other atomic-weapons states, including America, have found that their nuclear deterrents do not prevent conventional war or terrorism. But they can prevent massive retaliation.

ISRAEL SEES its nuclear monopoly as a key factor in its security. Successive Israeli governments have thus ensured that no other state in the Middle East becomes nuclear armed.

The only exception to the rule is Pakistan—the one Muslim state which has developed a nuclear arsenal. But in this case we are talking about a geographically distant country, and one that has never participated in military operations against Israel. Islamabad developed its bomb primarily during the era of Mohammad Zia ul-Haq’s dictatorship in the 1980s, when it was closely allied with the United States and fighting the Soviets in Afghanistan. A. Q. Khan, the father of the Pakistani bomb, has claimed that Zia warned Israel that if it tried to interfere with Pakistan’s program he would destroy Tel Aviv. When Islamabad did test its bombs in 1998, it tried to argue that Israel was on the verge of attacking its nuclear facilities and the tests were in self-defense. The charade of blaming Israel fooled no one.

ISRAEL NOW faces the biggest-ever challenge to its monopoly on the bomb in the Middle East from Iran. For Israel, Tehran is a dangerous opponent, close and threatening. There is a virtually unanimous consensus in Israel that Iran cannot be allowed to acquire nuclear weapons. From left to right, Israelis see an existential threat to their very survival. Current Prime Minister Benjamin Netanyahu argued at the Brookings Institution’s Saban Forum in Jerusalem in 2007 that Iran is a “crazy,” even suicidal, state that will be prepared to sacrifice millions of its own citizens in a nuclear exchange with Israel.

It is clear from statements of Israeli military and intelligence officials and numerous press leaks that planning for a military operation to prevent Iran from acquiring nuclear weapons is well under way in Israel

It is certainly a challenging one. Distance alone makes Iran a much more difficult target than Iraq or Syria. The most direct route from Israel to Iran’s Natanz facility is roughly 1,750 kilometers across Jordan and Iraq. The alternatives via Turkish airspace (over 2,200 kilometers) or Saudi airspace (over 2,400 kilometers) would also put the attack force into the skies of American allies equipped with American fighter aircraft. Moreover, unlike Iraq and Syria, but like Pakistan, the Iranian program is dispersed throughout several facilities and sites around the country, some of which are underground and hardened

Iran will almost certainly retaliate against both U.S. and Israeli targets. To demonstrate its retaliatory prowess, Iran has already fired salvos of test missiles (some of which are capable of striking Israel), and Iranian leaders have warned they would respond to an attack by either Israel or the United States with attacks against Tel Aviv, U.S. ships and facilities in the Persian Gulf, and other targets. Even if Iran chooses to retaliate in less risky ways, it could respond indirectly by encouraging Hezbollah attacks against Israel and Shia militia attacks against U.S. forces in Iraq, as well as terrorist attacks against American and Israeli targets in the Middle East and beyond.

America’s greatest vulnerability would be in Afghanistan. Iran could easily increase its assistance to the Taliban and make the already-difficult Afghan mission much more complicated. Western Afghanistan is especially vulnerable to Iranian mischief, and NATO has few troops there to cover a vast area. President Obama would have to send more, not fewer, troops to fight that war.

Making matters worse, considering the likely violent ramifications, even a successful Israeli raid would only delay Iran’s nuclear program, not eliminate it entirely. In fact, some Israeli intelligence officials suspect that delay would only be a year or so. Thus the United States would still need a strategy to deal with the basic problem of Iran’s capabilities after an attack, but in a much more complicated diplomatic context since Tehran would be able to argue it was the victim of aggression and probably would renounce its NPT commitments. Support for the existing sanctions on Iran after a strike would likely evaporate.

Of course, Israel’s own nuclear arsenal should be sufficient to deter Iran, but an American nuclear guarantee would add an extra measure of assurance to Israelis. If the United States guarantees Israel a nuclear umbrella, then Iran knows no matter what damage it may inflict on Israel, Washington will be able to retaliate with overwhelming force. Iran would have no delivery system capable of striking back at the U.S. homeland. It would be the target of both whatever residual capability Israel retained and the vast American nuclear arsenal. That is a deterrent indeed.

Already the United States has been deeply involved in building Israel’s defense against an Iranian missile strike. For almost two decades the Pentagon has been working closely with Israel to perfect the Arrow anti-tactical ballistic-missile (ATBM) system. The two countries have shared extensive technology on the question of ATBMs, including integrating Israel into the most advanced American early-warning radar systems to provide the earliest possible alert of an incoming attack. This defensive cooperation should be continued and enhanced

How active USA needs to be?

The next step would be to ensure Israel has the delivery systems that would safeguard a second-strike capability. The F-15I probably already does so for the immediate future, but it is worth examining the wisdom of providing the F-22 stealth aircraft to the IDF as an even-more-sophisticated attack system that would be able to assure Israel’s deterrence far into the future. Prime Minister Barak raised this issue with President Clinton at the Camp David summit in 2000, and it too should be reexamined. We might look at providing Israel with advanced cruise-missile technology or even nuclear-powered submarines with missile capabilities to enhance its capacity to launch from platforms at sea.

THE ERA of Israel’s monopoly on nuclear weapons in the Middle East is probably coming to an end. Israel will still have a larger arsenal than any of its neighbors, including Iran, for years if not decades. It will face threats of terror and conventional attack, but it already faces those. With American help it can enhance its deterrence capabilities considerably. It has no reason to lose its self-confidence. But to avoid the potential for all-out war not only between Israel and Iran but also between the United States and the Islamic Republic, Washington needs to act now. Only by enhancing Israel’s nuclear capability will America be able to strongly and credibly deter an Israeli attack on Tehran’s facilities.


U.S. Central Intelligence Agency, Special National Intelligence Estimate: Prospects for Further Proliferation of Nuclear Weapons, SNIE Number 4-1-74, August 23, 1974, declassified DocID: 1472492.

This argument was made by the expert the London Sunday Times called in to debrief Vanunu, Frank Barnaby, in his book The Invisible Bomb: The Nuclear Arms Race in the Middle East (London: Taurus, 1989).

See Avi Shlaim, Lion Of Jordan: The Life of King Hussein in War and Peace (London: Penguin, 2007): 508.

Barton Gellman, “Israel Gave Key Help to UN Team in Iraq,” Washington Post, September 29, 1998.

Adaption (Bruce Riedel – a senior fellow in the Saban Center for Middle East Policy at the Brookings Institution. A career CIA officer, he has advised four presidents on Middle East and South Asian issues in the White House on the staff of the NSC.)

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Gulf to Impose No-fly-zone over Libya

Riad Kahwaji, chief executive of INEGMA, quotes retired United Arab Emirates air force chief Maj Gen Khaled Al-Bu Ainnain:

“The UAE Air Force can deploy couple of squadrons – one F-16 Block 60 and another Mirage 2000-9 – the Saudi Air Force can deploy a couple of F-15S squadrons and Egypt a couple of F-16 squadrons out of Mersi Matrouh Air Base in western Egypt,” Al-Bu Ainnain said. “This would provide 120 fighters and attack aircrafts that would be backed with airborne early warning planes like Egyptian E-2C Hawkeye or Saudi AWACS, some unmanned aerial vehicles (UAV) for reconnaissance, and air-refueling tankers from Saudi Arabia and couple of Egyptian or UAE helicopter squadrons composed of Apache Longbow gunships, Blackhawks and Chinook helicopters, for search and rescue missions.”

Crews and troops needed for the operation could be quickly airlifted to western Egypt, and even Algeria, within hours using a large fleet of UAE and Egyptian C-130 and Qatari C-17 transporters.

To some this may be a good idea, but I am certainly sure that there are some out there who see gulf states having no incentive for Libyan rebellion to succeed. To some extent they are right but I am not convinced that west has a positive incentive for this to succeed. NATO for sure is looking beyond and can achieve a lot by imposing no fly zone over Libya. Is Libya next Iraq? Or aren’t gulf state aware if potential threats this uprising can result within it’s own states? So who has most to achieve from this imposition, the west or gulf? Would gulf states like to see Qadafi going down by supporting rebels? It’s dodgy right?


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Agile Beams: Active Electronically Scanned Array Radars

AESAs aim their "beam" by broadcasting radio energy that interfere constructively at certain angles in front of the antenna. They improve on the older passive electronically scanned radars by spreading their broadcasts out across a band of frequencies, which makes it very difficult to detect over background noise. AESAs allow ships and aircraft to broadcast powerful radar signals while still remaining stealthy. Above is AESA on F22

The AN/APG-77 is a multifunction radar installed on the F-22 Raptor fighter aircraft. It is one of the most advanced radar today. More than 100 APG-77 AESA radars have been produced to date by Northrop Grumman, and much of the technology developed for the APG-77 is being used in the APG-81 radar for the F-35 Lightning II. The APG-77v1 was installed on F-22 Raptors from Lot 5 and on. This provided full air-to-ground functionality (high-resolution synthetic aperture radar mapping, ground moving target indication and track (GMTI/GMTT), automatic cueing and recognition, combat identification, and many other advanced features).

APG-77 is based on Active Electronically Steered Array (AESA) technology. The AESA includes multiple individual active transmit/receive (T/R) elements within the antenna. Depending upon the precise implementation, there may be anywhere between 1000 and 2000 of these individual T/R elements which, together with the RF feed, comprise the AESA antenna. As for the passive ESA, these elements are highly redundant and the radar can continue to operate with a sizeable percentage of the devices inoperative. This graceful redundancy feature means that the radar antenna is extremely reliable; it has been claimed that an AESA antenna will outlast the host aircraft. The fact that the transmitter elements reside in the antenna itself means there is no standalone transmitter – there is an exciter but that is all. As before, there is clearly a need for a receiver as well as an RDP and signal processor. The active T/R elements are controlled in the same way as the phase shifters on the passive ESA, either by using a beam-steering computer (BSC) or by embedding the beam-steering function in the RDP.

The ability to control many individual T/R modules by software means confers the AESA with immense flexibility of which only a few examples are: First each radiating element may be controlled in terms of amplitude and phase, and this provides superior beam-shaping capabilities for advanced radar modes such as terrainfollowing, synthetic aperture radar (SAR) and inverse SAR (ISAR) modes. Secondly Multiple independently steered beams may be configured using partitioned parts of the multidevice array. Thirdly If suitable care is taken in the design of the T/R module, independent steerable beams operating on different frequencies may be accommodated and Finally The signal losses experienced by the individual T/R cell approach used in the AESA also bring considerable advantages in noise reduction, and this is reflected in improved radar performance.

The AN/APG-80 system is described as "agile beam", and can perform air-to-air, search-and-track, air-to-ground targeting and aircraft terrain-following functions simultaneously and for multiple targets. As a SAR system utilizing NG's fourth-generation transmitter/receiver technologies, it has a higher reliability and twice the range of older, mechanically-scanned AN/APG-68 radar systems. Above is F-16 APG-80 Radar

One dramatic improvement is the noise figure; it is especially significant achieving such an improvement so early in the RF front end. This results in a remarkable range improvement for the AESA radar. A number of US fighter aircraft are being fitted or retrofitted with AESA radars, these are F-22 Raptor, F-18E/F (Upgrade version) fitted with AN/APG-79, F-16E/F (Block 60) fitted with AN/APG-80, F-15 and F-35 fitted with AN/APG-81. Taking for example F-16, it is interesting to see a dofference in performance between two batches (Block 50) and Block 60. Former had target detection radar range of 50 miles, which was improved to 70 miles with AESA radards (for reference F-22 covers 125miles range). The F-16 Block 60 (now the F-16E/F) shows an improvement from 45 to 70 nm (þ55%), while the F-15C range has increased from 60 to 90 nm (þ50%). Apart from the obvious improvement in range, it has been stated by a highly authentic source that AESA radar confers 10–30 times more in radar operational capability compared with a conventional radar (Report of the Defense Science Board Task Force, 2001).

The F-16E (single seat) and F-16F (two seat) are newer F-16 variants. The Block 60 version is based on the F-16C/D Block 50/52 and has been developed especially for the United Arab Emirates (UAE). It features improved AN/APG-80 Active Electronically Scanned Array (AESA) radar, avionics, conformal fuel tanks (CFTs), and the more powerful GE F110-132 engine. However the batch bought by Pakistan Air Force (F-16C/D) is equipped with AN/APG-68 (V)9 Radar Systems. Only the Block 60 aircraft, destined for the UAE, are to be equipped with a more advanced version – the Active Electronically Scanned Array (AESA) radar. The APG-68(V)9 offers 30 percent increase in detection range, improved search-while-track mode (four vs. two tracked targets) and larger search volume and improved track while scan performance. Its single target track performance has also been improved. On air/ground missions, the new radar becomes an effective sensor, utilizing its high-resolution synthetic aperture radar mode, which allows the pilot to locate and recognize tactical ground targets from considerable distances. Although previous radars had some Synthetic Aperture Radar (SAR) capabilities, the new version generates imagery-class (2 feet resolution) high resolutions pictures, comparable to pictures delivered by the most modern commercial satellites. These pictures can be acquired from very long range, at all weather conditions and provide an effective, real-time source for the targeting of long range, precision guided weapons. The radar also has increased detection range in sea surveillance mode, and enhanced ground moving target identification and mappinc capability. The radar features an inertial measurement unit that improves dynamic tracking performance and provides an auto-boresight capability, which increases accuracy.


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Intellegent Warfare: Electronic Support Measures and Application of HARM Missile

USS KITTY HAWK (CV 63), At Sea (November 9, 2005) – Aviation Ordnanceman prepare to load a CATM-88 Harm missile onboard the USS Kitty Hawk (CV-63). While at sea, Kitty Hawk and Carrier Strike Group 5 will be participating in an annual exercise with the Japanese Maritime Self Defense Force. Currently underway in the western Pacific Ocean, Kitty Hawk Carrier Strike Group demonstrates power projection and sea control as the Navy's only permanently forward-deployed aircraft carrier strike group, operating from Yokosuka, Japan. U.S. Navy photo by Photographer’s Mate 3rd Class (AW) Jonathan Chandler.

After writing few posts discussing the technological influence on defence stratagies of different nation, this time I thought to go slightly technical. A reader may use this information as an extension of my discussion on Electronic Warfare – Electronic Warfare Operations Warfare has always been conducted by adversaries who have been at great pains to understand their enemy’s strengths and weaknesses in order to minimise the risk to their own forces and territory. The detection and interception of messages and the efforts to deceive the enemy have long been the task of the ‘secret service. As methods of communication developed, so too did methods of interception become more effective. Radar has developed from a mere detection mechanism to a means of surveillance and guidance. This post is focuses on gathering information on immediate threats which is performed by Electronic Support Measures (ECM)

MH-53 Pave Low helicopters prepare to take off for their final combat mission on Sept. 27, 2008, in Iraq. The MH-53, the largest and most technologically advanced helicopter in the Air Force with a record dating back to the Vietnam War, was retired from the Air Force inventory on Sept. 30, 2008

Electronic Warfare (EW) planning requires a broad understanding of enemy and friendly capabilities, tactics, and objectives. Employment of EW assets must be closely integrated into, and supportive of, the commander’s overall planning effort. This planning requires a multidisciplined approach with expertise from operations (ground, airborne, space), intelligence, logistics, weather, and information. Application of this sort of EW planning and employment was seen in Operation Desert Storm in 1991. three US Air Force MH-53J PAVE LOW helicopters (shown above) led nine US Army AH-64 Apache helicopters across the Saudi Arabia-Iraq border to attack two Iraqi early warning radar sites. Taking down these two sites opened the door for attacks across Iraq by F-117s, other coalition aircraft and Tomahawk missiles (shown below).

Block IV Cutaway - Raytheon

After the F-117s and cruise missiles came conventional aircraft. From 0355L to 0420L (H+55 to H+1:20) large numbers of USAF, USN, USMC, RSAF, and RAF aircraft smashed Iraqi air defenses and fields from H-3, an airfield located in western Iraq, to Ahmed Al Jaber, an airfield in occupied Kuwait. Two packages of aircraft, one a USN package from the Red Sea carriers and the other a USAF package from the south pointed directly at Baghdad. These “gorilla” packages were intended to seem threatening enough to force the Iraqis to hurl their air resources in defense. Air Force ground-launched BQM-34 and Navy tactical air-launched decoys (TALD) mimicked the radar return of conventional aircraft to further arouse Iraqi radar operators, many already confused by the absence of central control from Kari. Finally, radar-jamming aircraft radiated blanketing electronic emissions that drove the Iraqi radar operators to go to full power in an attempt to break through the interference. Then, the two incoming coalition flights revealed their true nature and pounced in a shrewd and devastating ruse.

The newest upgrade is a joint venture by the Italian Ministry of Defense and the US Department of Defense: the AGM-88E Advanced Anti Radiation Guided Missile (AARGM), produced by Alliant Techsystems.

What was unique here that, instead of bomb-carrying fighter-bombers, they were radar-killing electronic warriors carrying AGM-88 high-speed antiradiation missiles (HARMS) designed to home in on SAM and AAA radar (shown above). The AGM-88 High-speed Anti-Radiation Missile (HARM) is a tactical, air-to-surface missile designed to home in on electronic transmissions coming from surface-to-air radar systems. Originally developed by Texas Instruments (TI) as a replacement for the AGM-45 Shrike and AGM-78 Standard ARM system. Production was later taken over by Raytheon Corporation (RAYCO) when they purchased TI’s defense business. The AGM-88 can detect, attack and destroy a radar antenna or transmitter with minimal aircrew input. The proportional guidance system that homes in on enemy radar emissions has a fixed antenna and seeker head in the missile’s nose. A smokeless, solid-propellant, dual-thrust rocket motor propels the missile at speeds over Mach 2. HARM, a Navy-led program, was initially integrated onto the A-6E, A-7 and F/A-18 and later onto the EA-6B. USAF F-4G Wild Weasels alone expended dozens of HARMS in twenty minutes, while USN/USMC F/A-18s fired one hundred for the night. HARMS filled the air over Baghdad, the site of over one-half of Iraq’s SAM and AAA batteries. Foolishly, the Iraqis did not turn off their radars, even when the HARMS fireballed in their midst; as one USAF flight leader averred, ‘the emitters came on and stayed on for the entire flight of the missiles.’ This deadly surprise not only destroyed many Iraqi radars, it also terrified their operators. For the rest of the war, they showed great reluctance to use radar and often chose to launch their SAMs with optical or even no guidance.

High-speed Anti-Radiation Missile (HARM) – A Little Overview

The initial HARM attack and the F-117 bombings of the Kari system left Iraq’s integrated air defense system shattered, opening up the country so completely that, within days, coalition air-to-air tankers regularly operated in Iraqi airspace. Other non-stealthy aircraft pummeled Iraqi airfields. An anti-radiation missile (ARM) is a missile which is designed to detect and home in on an enemy radio emission source. Typically these are designed for use against an enemy radar, although jammers and even radios used for communication can also be targeted in this manner. This sort of weapons are key to EW inventory. The word “Radiation” here refers to Electromegnetic radiation, not nuclear. The missile is the direct descendant of the Shrike and Standard ARM missiles used in Vietnam. Most ARM designs to date have been intended for use against ground-based radars. Commonly carried by specialist aircraft in the SEAD (Suppression of Enemy Air Defense) role (known to the USAF as “Wild Weasels”), the primary purpose of this type of missile is to degrade enemy air defenses in the first period of a conflict in order to increase the chances of survival for the following waves of strike aircraft. They can also be used to quickly shut down unexpected SAM sites during a raid. Aircraft which fly with strike aircraft to protect them from enemy air defences often also carry cluster bombs and are known as a SEAD escort. The cluster bombs can be used to ensure that after the ARM disables the SAM system’s radar, the command post, missile launchers, and other components or equipment are also destroyed to guarantee the SAM site stays down.

The R-27 is manufactured in infrared-homing (R-27T), semi-active-radar-homing (R-27R), and active-radar-homing (R-27AE) versions, in both Russia and the Ukraine. The R-27 missile is carried by the Mikoyan MiG-29 and Sukhoi Su-27 fighters, and some of the later-model MiG-23MLD fighters have also been adapted to carry it.

The above account of the First Night of Operation Desert Storm was taken from the Decisive Force: Strategic Bombing in the Gulf War by Richard G. Davis. More recently, air-to-air ARM designs have begun to appear, notably the Russian Vympel R-27P. Such missiles have several advantages over other missile guidance techniques; they do not trigger radar warning receivers (conferring a measure of surprise), and they can have a longer range (since battery life of the seeker head is the limiting factor on the range of most active radar homing systems).

Electronic Support Measures

Technically ESM consists of a collection of senstive antennas designed to detect signals in different frequency bands. Often these antennas are grouped at aircraft’s wing tip pod, which allows a wide angle view without causing too much obstruction as well as to enable a fix on the signal source to obtain an accurate Dircection of Arrival (DoA) of the signal. An effective ESM system rapidly identifies the signal band and location, and determines the signal characteristics. A signal analyser then examines the signal characteristics to identify the type of transmitter and the level of threat posed. Even the most cursory of analysis can establish whether the emitter is associated with surveillance, target tracking or target engagement. This analysis can compare the signal with known emitter characteristics obtained from an intelligence database or threat library and known signal types confirmed and new emissions identified and categorised. Every signal identification is logged with date, time and intercept coordinates, along with the known or suspected platform type, and the results are stored.

ESm Pods on Nimrod: As well as providing threat information, ESM is used by maritime and battlefield surveillance aircraft as a passive or listening sensor which adds important information to other sensors. It is especially useful when tracking submarines

Signals received by the electronic support measures system may in some cases be analysed instantaneously to produce an identity for the transmitter of each signal received. Pulse width, Pulse amplitude and carrier frequency are few important parameters. The nature of the pulse shape is used to determine the particular type of transmitter. The scan rate and the pattern of the scan also provide invaluable information about the mode of the transmitter. It is possible to detect the antennas changing from scanning mode to lock-on to tracking and hence determine the threat that the transmitting station poses. As well as providing threat information, ESM is used by maritime and battlefield surveillance aircraft as a passive or listening sensor which adds important information to other sensors.

The salient signal characteristics or discriminators identified during the ESM collection and identification process includes: Signal Frequency (this is to detect the radar type), Blip/Scan ratio (to get the estimate for scan rate, sector scan width and radar bandwidth), Scan Rate, Scan Pattern (Search, track, track-while-scan (TWS) and ground-mapping (GM) modes will exhibit particular characteristics), Signal Modulation (Pulse, pulse compression, pulsed Doppler (PD), a continuous wave (CW) and other more sophisticated forms of modulation are indicative of the emitter mode(s) of operation and likely threat level) and finally Pulse Repetition Frequency (PRF).

Technical details as well as the schemetic of the ESM system can found in any dedicated military systems book, however, those who are Interested to explore more, I will strongly recommend Military Avionics Systems by Ion Mior and Allen Seabridge.

The combination of analysis of all these modes of operation and when they are employed either singly or in combination is vital to establishing the likely capabilities and intentions of a threat platform, especially when used in combination with other intelligence information. Electronic Support Measures may be employed at a strategic intelligence-gathering level using an AWACS (airborne early warning and command system) or MPA aircraft to build the overall intelligence picture and electronic order of battle (EOB). Alternatively, such information may be gathered and utilised at a tactical level using radar warning receivers (RWR), whereby information is gathered and used at the strike platform level to enable strike aircraft to avoid the most heavily defended enemy complexes during the mission.

As I mentioned earlier, this (ESM) is one element of Electronic Warfare. This is because the nature of EW warfare and devices used. The operating frequency ranges for radars are usually very broad, and no single system can cover the whole range for transmission or reception. Hence, most communications and radar systems are designed for use in specific bands. These bands are usually designated by international convention. The main role of electronic warfare is to search these radio-frequency bands in order to gather information that can be used by intelligence analysts or by front-line operators. The information gained may be put to immediate effect to gain a tactical advantage on the battlefield; it may be used to picture the strategic scenario in peace time, in transition to war, or during a conflict. It may also be used to devise countermeasures to avoid a direct threat or to deny communications to an enemy. It must also be observed that such tactics are deployed by all sides in a conflict – in other words, the listeners are themselves being listened to.

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Nuclear Doctrine of Pakistan: Dilemmas of Small Nuclear Force in the Second Atomic Age

Dilemmas of Small Nuclear Forces, 4-series of articles highlighting the Nuclear Doctrine of Pakistan, its command and control system. The series contain 3 articles: First article (below) explore the Rise of Nuclear Deterrence, Second: is subjected to Post-1998 Doctrinal Contemplation, Third: Confidence-Building Measures between India and Pakistan, and Fourth: concludes with the military objectives of Pakistan’s nuclear weapons and highlights from the Nuclear Security Summit 2010.

Pakistan regards its nuclear weapons as its most precious strategic asset which constitutes the ultimate guarantor of nation's existence. This is encapsulated in an article by Gen Mirza Aslam Beg titled 'Pakistan's Nuclear Imperatives' wherein he wrote "Oxygen is basic to life, and one does not debate its desirability, nuclear deterrence has assumed that life-saving property for Pakistan.

A doctrine could be defined as a set of principles formulated and applied for a specific purpose, working towards a desired goal or aim. A nuclear doctrine would consequently consist of a set of principles, and instructions for the employment or non-employment of nuclear weapons and other associated systems. Until 2005, India and Pakistan were the only states outside the Nuclear Nonproliferation Treaty to declare, openly, their nuclear weapons capability. In 1998, they tested nuclear weapons and since then, deployed ballistic missiles, enunciated nuclear doctrine, and made organizational changes to their nuclear establishments. In 2002, they teetered on the brink of war in Kashmir. The second half of this article dilate somewhat the factors that have conceived the concept which has formulated the nuclear doctrine of Pakistan. I certainly believe that in South Asia a balance of power cannot be maintained by conventional means alone. This article endeavours to construct a proto Pakistani nuclear use doctrine from its declaratory and operational postures, in particular from the statements and interviews of the Pakistani political and military leaders and government officials. Initially reflecting upon its pre-1998 nuclear strategy, which has got critical implications for the post-tests doctrinal contemplation.

Pakistan is believed to have been developing a nuclear capability since the early 1970s. In May 1998, Pakistan responded to India’s nuclear tests by testing a series of nuclear weapons and declaring itself a nuclear weapon power. Pakistan, like India, has supported comprehensive disarmament proposals at the United Nations and Conference on Disarmament, but did not join the CTBT for similar reasons as India. Pakistan has proposed a number of bilateral or regional initiatives which India has not supported. These include a Nuclear Weapons Free Zone in South Asia and joining the NPT. India opposes these on the grounds that they do not address the nuclear threat India faces from China and the other NWS. Pakistan and India have concluded a number of bilateral confidence building measures including a hot-line agreement and an agreement not to attack each other’s nuclear power facilities.

While all these (including Pakistan, India, North Korea and Israel) small nuclear powers are in the process of developing their nuclear force structures, two key questions that have arisen are: How, when and for what purposes do they plan to use nuclear weapons? And what command. The word “small” here distinguishes these nation and their doctrines from U.S.A, UK, France and Russia. Prime focus is to understand the emerging structure of Pakistan’s Nuclear Doctrine.

President Barack Obama greets Pakistan's Prime Minister Yusuf Raza Gilani at the Nuclear Security Summit in Washington April 12, 2010. REUTERS/Kevin Lamarque

In The Myth of Independence, Zulfikar Ali Bhutto (president of Pakistan in December 1971) argued that modern wars should be conceived of as total wars, and in this type of war Pakistan needed nuclear weapons. Bhutto’s thinking, as will be analysed below, had far-reaching impacts on Pakistan’s nuclear strategy, and on its doctrinal contemplation. Soon after assuming Presidency of Pakistan on 20th December 1971 he took the decision to initiate a nuclear weapons project. This decision was taken against the backdrop of three specific factors: firstly, it was a direct consequence of the 1971 war where Pakistan’s conventional inferiority was demonstrated for the third time, at the cost of almost half of its territory; secondly, Pakistani leaders in general (particularly Bhutto) were convinced that India was determined to build a nuclear arsenal; and thirdly, Bhutto believed that only nuclear weapons could guarantee the national survival of Pakistan against the Indian threat.8 It is evident that Pakistan’s nuclear weapons project was initiated to deter Indian nuclear as well as conventional aggression, an aim that endured in the subsequent years and today constitutes one of the central pillars of Pakistan’s nuclear use doctrine.

Brass Tacks Crisis – First Nuclear Deterrence Posture [1986-1987]

After India and Pakistan held nuclear tests in 1998, experts have debated whether their nuclear weapons contribute to stability in South Asia. Experts who argue that the nuclear standoff promotes stability have pointed to the U.S.-Soviet Union Cold War as an example of how deterrence ensures military restraint.

First employment of Pakistan’s nuclear deterrent stratagy was during the 1986-1987 brasstacks crisis between India and Pakistan. With the crisis peaking in January 1987, India had deployed 400,000 troops, or about half the Indian army, within 100 miles of Pakistan. It began when India had launched the largest ever military exercises in the subcontinent, called Operation Brass Tacks. The exercise would take place not in India’s far north, where the always tense state of Kashmir is located, but in the desert area of Rajastan, a few hundred miles from the Pakistani border, which, a the Pakistani government was sure to note, was and ideal location from which to launch a cross border operation into the Pakistani state of Sindh that could cut Pakistan in half. The exercises included bulk of Indian Army, and was comprised of the nine infantry, three mechanised, three armoured and one air assault divisions, and three armoured brigades under four corps HQ with all theparaphernalia for a real war, concentrated on Pakistan’s sensitive border areas. This was bigger than any NATO exercise – and the biggest since World War II. Also planned was an ambitious amphibious operation by the Indian Navy with one division, in Korangi area of Karachi. Another feature of the exercise was a decision by General Sundarji to integrate Indias special weapons, including tactical nuclear into day-to day field maneuvers of the troops.

Pakistani military analysts saw Brass Tacks as a threatening exhibition of an overwhelming conventional force. Some even suspected that India wanted to launch swift surgical strikes at the Sikh terrorists’ training and planning sites inside Pakistan. Pakistan responded with maneuvers of its own that were located close to India’s state of Punjab. The crisis atmosphere was heightened when Pakistan’s premier nuclear scientist Abdul Qadir Khan revealed in a March 1987 interview that Pakistan had manufactured a nuclear bomb. Although Khan later retracted his statement, India stated that the disclosure was “forcing us to review our option.” Interview by Dr A.Q Khan’s interview to Indian journalist, Kuldip Nayar records:

what the CIA has been saying about our possessing the bomb is correct and so is the speculation of some foreign newspapers … They told us that Pakistan could never produce the bomb and they doubted my capabilities, but they now know we have done it … Nobody can undo Pakistan or take us for granted. We are there to stay and let it be clear that we shall use the 10 bomb if our existence is threatened.

Formal and impromptu talks between the leaders of the two countries finally resulted in a number of new CBMs between India and Pakistan. These were important and covered a number of areas. For example, the Agreement on the Prohibition of Attack against Nuclear Installations and Facilities was signed on December 31, 1988, in Islamabad by the two foreign secretaries and witnessed by the two prime ministers, Rajiv Gandhi and Benazir Bhutto, respectively. Earlier fears of impending attack on the facilities resulting in an all-out war fed the need for the agreement.

Kashmir – Second Nuclear Deterrence Posture [1990]

Kashmir has been a flashpoint since Indian and Pakistani independence in 1947. Many analysts have feared that nuclear weapons could be used if conventional hostilities over Kashmir were to spiral out of control, especially if, as in 1965 Indo-Pakistan conflict

Pakistan again advanced a nuclear deterrent posture in 1990 in the context of a spiralling crisis over the disputed territory of Kashmir, which developed against the backdrop of an acute separatist insurgency in the Indian. Reportedly, New Delhi planned for surgical air strikes against the militant training camps inside Pakistani territory, which prompted Islamabad to assemble a crude nuclear bomb and modify several American supplied F-16 aircrafts for its delivery. The crisis was eventually averted through diplomatic intervention from Washington, but Islamabad firmly believed that Pakistan’s deterrence posture prevented India from carrying out the planned strike. This crisis also marked the emergence of a nascent mutual nuclear deterrence in the Indo-Pakistani context.

Command and Control of Nuclear Deterrence

What did emerge during this period, primarily in the context of the 1986-87 Brasstacks crisis and the 1990 Kashmir episode, was a general notion of nuclear deterrence, which implied that Pakistan would use nuclear weapons to counter India’s nuclear as well as conventional aggression. to build a robust nuclear command structure. However, former Army chief of staff General Mirza Aslam Beg has claimed that the Pakistani leadership realised the necessity of establishing a command structure,

given the tension, mutual mistrust and suspicion between India and Pakistan, it is dangerously tempting for each to launch an attack before being attacked which could escalate to a nuclear level.

Bhutto had established a National Nuclear Command Authority (NNCA) in the 1970s, which institutionalised the nuclear decision-making and assumed the responsibility of developing a nuclear force structure and appropriate alert posture. (‘NNCA Responsible for Safeguarding Nuclear Programme, The News, 2 June 1998).

Pakistan Nuclear Capabilities and Thinking

Most observers (SIPRI Yearbook 1995, Bulletin of Atomic Scientists, 1998) estimate that Pakistan has enough nuclear material (highly enriched uranium and a small amount of plutonium) for 30 to 50 nuclear weapons. Like India, Pakistan is thought to have a small stockpile of nuclear weapons components and can probably assemble some weapons fairly quickly. Pakistan could deliver its nuclear weapons using F-16s (shown above) it purchased from the United States provided the appropriate “wiring” has been added to make them nuclear-capable. In the 1980s, Pakistan moved assiduously to acquire ballistic missile capabilities and now deploys short-range ballistic missiles and a small number of medium-range missiles. AQ Khan, former head of Khan Research Laboratories, maintained that only the medium-range Ghauri missiles would be usable in a nuclear exchange (given fall-out effects for Pakistan of shorter-range missiles). Other observers view the 30 to 50 Hatf2 short-range (300km) missiles (modified Chinese M-11s) as potential delivery vehicles for nuclear weapons. Ghauri missiles (1350 and 2300km), which reportedly are based on the North Korean No-Dong and Taepo-Dong-1, are capable of reaching New Delhi with large payloads.

It is believed that Because of its fears of being overrun by larger Indian forces, Pakistan has rejected the doctrine of no-first-use. In May 2002, Pakistan’s ambassador to the UN, Munir Akram, stated that “We have not said we will use nuclear weapons. We have not said we will not use nuclear weapons. We possess nuclear weapons. So does India ...We will not neutralize the deterrence by any doctrine of no first use

On June 4, 2002, President Musharraf went a step further then his UN ambassador sna stated that: “The possession of nuclear weapons by any state obviously implies they will be used under some circumstances. In recent years, Pakistan apparently has taken steps toward refining command and control of nuclear weapons. In April 1999, General Musharraf announced that the Joint Staff Headquarters would have a command and control arrangement and a secretariat, and a strategic force command would be established. With some experience and the passage of time a degree of sophistication will certainly be introduced in Pakistan’s nuclear doctrine of the first-use of nuclear weapons to provide the government more options in the use of nuclear weapons. This would also avoid unessential collateral damage to cities and other population centres in both countries. The object would be to employ nuclear weapons if attacked yet cause the least civilian casualties and damage to infrastructure.


Escalation Control in South Asia,’ in Escalation Control and Nuclear Option in South Asia, eds M. Krepon, R. W. Jones, and Z. Haider, The Henry L. Stimson Center, Washington, D.C., 2004, p. 89.
Z. A. Bhutto, The Myth of Independence, Oxford University Press, Lahore, 1969, p. 153.
B. Chakma, ‘Road to Chagai: Pakistan’s Nuclear Programme, Its Sources and Motivations, Modern Asian Studies, vol. 36, no. 4, 2002, p. 887.
P. Hoodbhoy, ‘Nuclear Deterrence – An Article of Faith,’ The News (Rawalpindi), 17 March 1993.
‘NNCA Responsible for Safeguarding Nuclear Programme, Says Beg,’ The News, 2 June 1998.
S. H. Hasan, ‘Command and Control of Nuclear Weapons in Pakistan,’ Swords and Ploughshares, vol. 9, no. 1, 1994, p. 13.

Images: Title: Nicholson cartoon (, and Reuters

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X-37B: Robotic Orbital Spy

This artist's rendition shows the X-37B as it might look like orbiting Earth

Mid 2010 has seen US Air Force to Launch unmanned and reusable X-37B to orbit from Florida. The Boeing X-37 Orbital Test Vehicle is an American unmanned spacecraft. It is operated by the United States Air Force for orbital spaceflight missions intended to demonstrate reusable space technologies. The Air Force has fended off statements calling the X-37B a space weapon, or a space-based drone to be used for spying or delivering weapons from orbit.

X-37B is roughly one fourth the size of the space shuttle. It’s onboard batteries and solar arrays (pictured at left from its NASA days) can keep it operating for up to nine months according to the Air Force. It is similar to the shuttle with payload doors exposing a cargo area, and uses a similar reentry procedure before gliding to a runway. In the case of the X-37B, the vehicle will autonomously return to earth and land itself using an onboard autopilot. The primary landing spot is Vandenberg Air Force Base in California.

The program was transferred to the Department of Defense in 2004. Since that time the X-37 has become a classified program, raising questions as to whether or not it would become the first operational military space plane. During the 1960s, the Air Force and Boeing conducted research on the X-20 Dyna-Soar space plane.

On 17 November 2006 the U.S. Air Force announced it would develop the X-37B from the NASA X-37A. The Air Force version is designated X-37B Orbital Test Vehicle (OTV). The OTV program builds on industry and government investments by DARPA, NASA and the Air Force. The X-37B effort will be led by the Air Force Rapid Capabilities Office, and includes partnerships with NASA and the Air Force Research Laboratory. Boeing is the prime contractor for the OTV program. The X-37B was originally scheduled for launch in the payload bay of the Space Shuttle, but following the Columbia accident, it was transferred to a Delta II 7920. It was subsequently transferred to a shrouded configuration on the Atlas V following concerns over the unshrouded spacecraft’s aerodynamic properties during launch.

So, what makes this vehicle different fron conventional satellite? To NASA, the X-37 was projected to be an orbital experimental vehicle to be lifted to orbit by the Space Shuttle or a reusable launch vehicle and returned to Earth under its own power. But, Air Force argues that a vehicle such as the X-37 could be a valuable platform for intelligence gathering with the advantage of a satellite’s point of view, but the flexibility of an aircraft that can be launched relatively quickly and maneuvered in orbit much easier than a traditional satellite. The service directly supports the Defense Department’s technology risk-reduction efforts for new satellite systems. By providing an ‘on-orbit laboratory’ test environment, it will prove new technology and components before those technologies are committed to operational satellite programs.” The X-37 is expected to operate in a velocity range of up to Mach 25 on reentry. Among the technologies to be demonstrated with the X-37 are improved thermal protection systems, avionics, the autonomous guidance system and an advanced airframe. The X-37 has a payload bay available for experiments and other space payloads. It features thermal protection systems that are improved from previous generations of spacecraft.

Is this another ambitious NASA project or SR-71 replacement for intelligence gathering or robotic spy?

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