Modern US endurance UAVs

RQ-3A Darkstar UAV / classified Darkstar follow-on

The Gnat 750 and Predator were the first in a series of "Tier UAVs" considered by the US Air Force. In the USAF plan, the Gnat 750 was known as "Tier 1", while the Predator was known as "Tier 2". The original expectation was that the series would then move on to a very large and powerful long-range UAV known as "Tier 3", something along the lines of a B-2 Stealth bomber, but Tier 3 proved overambitious and was cancelled.

In place of Tier 3, the USAF decided to develop a smaller "Tier 3-" UAV designated the "Darkstar", and a "Tier 2+" UAV, something like a "super Predator", the Teledyne-Ryan "Global Hawk".

The Lockheed Martin / Boeing Tier 3- Darkstar was a stealthy design that resembled a big pumpkin seed with a long straight wing at the rear. It was to send real-time still images produced by either SAR or EO sensors, though it didn't have the capacity to carry both sensors at the same time. Data was to be returned using a satellite communications link with a bandwidth of 1.5 megabits per second. The Darkstar was intended to penetrate protected airspace to observe high-value targets for a limited amount of time. Range and endurance were intended to be similar to that of the Predator, though the Darkstar's sensor suite could cover over twice the area, and of course it was harder to detect.

The Darkstar was powered by a Williams Research FJ-44-1A turbofan engine with 8.46 kN (862 kgf / 1,900 lbf) thrust, and could carry a 450 kilogram (1,000 pound) payload. The UAV was to cost about $10 million USD each.

The Darkstar was unlucky. On its second takeoff in the spring of 1996, it stood up on one wing and slammed into the runway, bursting into fire and smoke. An analysis of the failure showed flight software and takeoff procedures to be faulty.

The Air Force and the contractors didn't give up right away, and a redesigned Darkstar, now formally designated "RQ-3A", flew in the early summer of 1998. However, the program was still unhealthy, and the Darkstar was cancelled in early 1999. Although flight tests were generally satisfactory, the Darkstar was by no means close to being a useful operational system. Building an actual operational UAV based on the Darkstar would have required major redesign and improvement, and the costs were more than the Air Force was willing to spend.

The unnamed UAV's payload was described as less than that of a Lockheed U-2, featuring a "low probability of intercept (LPI)" SAR and electro-optic sensors, along with a satcom datalink. Range was less than that of the Global Hawk, described below, though cost is described as several times greater. The Air Force wanted to conduct the operational evaluation to see if putting the new machine into production was worthwhile. The most likely operational base for the UAV was Al Udeid Air Base in Qatar, which has extensive and well-developed facilities, is near to Iraq, and was off-limits to reporters during the invasion of Iraq.

Sources have also leaked information about a roughly comparable Boeing effort to develop a stealth UAV test bed. This particular machine is said to have been flown in a wide range of configurations, with different tails, noses, and wings, to validate stealth concepts.

This UAV was declassified in 2006 as the Lockheed Martin Polecat.

Northrop Grumman RQ-4A Global Hawk/sensor craft

With the death of the Darkstar, the Ryan RQ-4A Global Hawk became the Air Force's great hope for a strategic UAV reconnaissance platform. With the purchase of Ryan by Northrop Grumman in July 1999, the aircraft became the Northrop Grumman Global Hawk.

The Global Hawk is not particularly stealthy, but it has sophisticated long-range sensors to allow it to operate outside of hostile air defenses, and can survey as much as 100,000 square kilometers (39,000 sq mi) of terrain a day. In comparison to the Predator, if a Global Hawk were flown out of San Francisco, it would be able to operate in Maine for 24 hours, observe a 370 x 370 kilometer (230 x 230 mile) grid, and then fly back home.

The Global Hawk costs about $10 million USD each in full production, is powered by an Allison Rolls-Royce AE3007H turbofan engine with 31.4 (3,200 kgf / 7,050 lbf) thrust, and carries a payload of 900 kilograms (2,000 pounds). The fuselage is mostly of conventional aluminum airframe construction, while the wings are made of carbon composite.

The Global Hawk carries the "Hughes Integrated Surveillance & Reconnaissance (HISAR)" sensor system. HISAR is a lower-cost derivative of the ASARS-2 package that Hughes developed for the Lockheed U-2. HISAR is also fitted in the US Army's RC-7B Airborne Reconnaissance Low Multifunction (ARLM) manned surveillance aircraft, and is being sold on the international market. HISAR integrates a SAR-MTI system, along with an optical and an infrared imager. All three sensors are controlled and their outputs filtered by a common processor. The digital sensor data can be transmitted at up to 50 Mbit/s to a ground station in real time, either directly or through a communications satellite link.

The SAR-MTI system operates in the X-band and provides a number of operational modes:

The visible and infrared imagers share the same gimballed sensor package, and use common optics, providing a telescopic close-up capability. The Global Hawk is also fitted with a "self-protection" countermeasures suite to help it frustrate adversary air defenses, and can be optionally fitted with an auxiliary SIGINT package.

First flight of the Global Hawk was on 28 February 1998. Five prototypes were built, and put through a thorough flight test program. Beginning in the spring of 1999, the Global Hawk performed a series of operational evaluation flights, some of which were remarkable demonstrations of the aircraft's capability. One of the prototypes flew from Eglin Air Force Base in Florida to Alaska and back again, nonstop, in just under 25 hours.

In May 2000, a prototype flew up the Atlantic coast of the US from Eglin AFB, transmitting radar images to a US Army ground station at Fort Bragg, North Carolina, and the aircraft carrier USS George Washington, at dock at Norfolk, Virginia. The RQ-4A then proceeded across the Atlantic, monitoring shipping movements, and reached its final target, an amphibious landing exercise near Setubal, Portugal. Once done, the Global Hawk retraced its steps and landing at Eglin, 28 hours after its departure.

The program has suffered some setbacks. On 29 March 1999, the second prototype fell out of the sky over the US Navy China Lake military training area in California and was destroyed. The third prototype was badly damaged during a landing on 6 December 1999 when a software bug told the aircraft to taxi at 290 km/h (180 mph), leading to the grounding of the survivors for three months.

The Global Hawk was scheduled to reach operational service in late 2001, and this timeframe coincided with the US intervention in Afghanistan. Four Global Hawks were available at the time, though only three were regarded as suitable for operations. These three UAVs were operated in the war, though specific details of their missions are unclear. One crashed on 30 December 2001 due to a malfunction.

Global Hawks also served in the invasion of Iraq in the spring of 2003. Although details of their service there are sketchy for the moment, apparently their SAR payload came in very handy for pinning down targets during intense sandstorms. Ironically, despite the service of the Global Hawks in these conflicts, none of them that flew these operations were actually regarded as production machines. The first production RQ-4A, the eighth Global Hawk built, was finally rolled out in the summer of 2003.

The improved self-protection suite includes an AN/ALE-50 towed decoy, an AN/ALR-89 radar-warning receiver, and a new self-defense jammer being designed by Raytheon. The UAV will autonomously act on the information from the self-protection system, deciding whether to abort the mission, take evasive action, or continue with the towed jammer deployed. The remote operator can override whatever decision is taken.

MP-RTIP originally started out as an upgrade program for the "E-8 Joint-STARS" manned battlefield reconnaissance aircraft, which is based on the Boeing 707-320 jetliner, but the scope of the program expanded to envision the development of an AESA that could be adapted for use on a range of platforms.

An AESA can be thought of as a radio-frequency (RF) "array processor", composed of a grid of interconnected "transmit-receive" modules, each with its own RF, processing, and control electronics. The modules can work with each other to perform a wide variety of tasks. The AESA is scalable, allowing the fit of more or fewer modules as allowed by the size of the platform, with capability proportional to size. The AESA can perform communications, jamming, and sensing functions in parallel through juggling the use of its modules. Current thinking on the Global Hawk AESA is also placing increased emphasis on providing airborne search functions to the system to allow the UAV to operate as an "airborne early warning (AEW)" platform.

Raytheon and Northrop Grumman were awarded a contract for the MP-RTIP system in late 2000, with Raytheon to build the AESA and the Northrop Grumman to perform systems integration. The Global Hawk was selected as the initial target system for MP-RTIP, with initial flight tests in 2005.

The 1969 shootdown of an EC-121 SIGINT aircraft by the North Koreans led to the development of the "Combat Dawn" Firefly variant, and the 2001 incident led to widespread discussion of adopting a similar strategy to ensure that the problem would not arise again. While the Global Hawk does not have the payload capability to replace a large SIGINT aircraft like the EP-3, it would provide an interim solution if nothing else were available. The Global Hawk SIGINT payload is now a high priority.

Other upgrades are also being considered, such as a fast-track effort to add stores pylons for external payloads, including improved electro-optic / infrared and multispectral sensors; or jamming pods. While a Global Hawk configuration carrying two 225 kilogram (500 pound) or four 112 kilogram (250 pound) GPS-guided bombs has been considered, senior Air Force brass are not enthusiastic about arming the type, since that would make it politically more difficult to use in peacekeeping operations or to obtain overflight permission from friendly nations.

Another possible role is for "Information Warfare (IW)", picking up and penetrating enemy voice, video, and data communications, but currently no miniaturized IW payload suitable for the Global Hawk is available. Northrop Grumman is promoting schemes where several Global Hawks with different but complementary payloads could be used to perform a single mission.

Current USAF plans project 40 to 45 Global Hawks in service by 2010 and 78 in service by 2020, with 40 carrying electro-optic payloads and the other 38 carrying SIGINT payloads. The Air Force expects to retire their aging U-2 reconnaissance aircraft no later than 2011, and are hesitantly considering the Global Hawk as the replacement. Lockheed Martin has been promoting a UAV version of the U-3 designated the "U-2U" as an alternative to the Global Hawk, though so far with little success in the face of current Air Force commitments.

Northrop Grumman is now building the "Block 20" or "RQ-4B" Global Hawk. This variant features an uprated engine; a wingspan stretch from 35.4 meters (116 ft) to 39.9 meters (130.9 ft); and a fuselage stretch from 13.5 meters (44 ft) to up to 14.5 meters (47.6 ft). The RQ-4B provides 50% more electrical power than the RQ-4A and carry a larger payload, of up to 1,360 kilograms (3,000 pounds) as opposed to 910 kilograms (2,000 pounds), and also has an improved communications system and an "open architecture" that makes updates simpler. An even bigger Global Hawk derivative, designed to carry a jamming payload of up to 2,720 kilograms (6,000 pounds), is under consideration.

The Navy wants BAMS to have an operational radius of 2,775 kilometers (1,500 nmi) and an on-station time of 12 hours. It would carry an extensive payload suite, with EO/IR imaging sensors; a radar with sea-air-land wide-area search, high-resolution spot beam, MTI, and SAR imaging modes; and a SIGINT package with emitter identification and targeting capabilities. Payload systems will be modular, and it may not be possible to carry a complete suite on a single machine.

BAMS would operate from land bases, but it could be controlled by airborne and maritime platforms as well. Navy officials say they have not selected the Global Hawk for the application, but have also indicated they basically want to modify an off-the-shelf UAV instead of building one from scratch, and so the Global Hawk is a high-profile candidate. However, General Atomics and Lockheed Martin are aggressively pursuing the BAMS requirement as well, offering a "Predator B-ER (Extended Range)" known as the "Mariner" with more power, payload, and endurance, and with the capability to carry an AESA radar up to 16 air-dropped sensors or munitions. The BAMS requirement remains completely up in the air for the moment.

Northrop Grumman has been trying to sell the Global Hawk internationally, and has had European interest in a EuroHawk and Middle Eastern interest in a "GulfHawk". Japan and Australia are considering the type as well, but nobody expects international sales any time soon.

Sensor Craft appears to be a purely experimental program, but the confrontation between the US and China over the EP-3 SIGINT aircraft in the spring of 2001 helped increase interest in a new, large surveillance UAV. Many defense officials are now promoting acquisition of a large, capable UAV designated the "U-X" with stealthy characteristics that can fly at altitudes above the ceiling of a piloted interceptor.`

The UAV would not necessarily be designed to overfly protected airspace. One or two dozen such UAVs would be bought at a minimum total price of $1.5 billion USD. Ironically, if the new UAV is built, it will bring the US full circle, back to the "Tier 3" UAV that was cancelled early in the 1990s.

References

This article contains material that originally came from the web article Unmanned Aerial Vehicles by Greg Goebel, which exists in the Public Domain.

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