Carrier: A Guided Tour of an Aircraft Carrier
Part of the problem was the weather, which was the worst on record in the region. Because many of the bombing sorties required visual identification of the targets, some of these had to be aborted due to the cloud cover. There was also a requirement that bombs be delivered from medium altitude (above 10,000 feet/3,048 meters), making the accuracy of the results uncertain. Had the Hornet been armed with LGBs and other precision weapons, this problem would not have arisen. Unfortunately, the new version of the Nighthawk pod (with the laser designator and tracker) had not yet come into service.
There also was the fuel problem. Since most of the Hornets were based on carriers in the Red Sea, they required several in-flight refuelings in order to reach their targets in Iraq and Kuwait. This placed a severe burden on the limited airborne tanker resources of General Horner’s Central Command Air Force (CENTAF). This meant that the F/A-18’s were sometimes left off the daily Air Tasking Order (ATO) in favor of other aircraft, like USAF F-16’s, which were based closer to their targets. Eventually, the Navy moved a total of four carrier groups into the Persian Gulf itself, to bring the Hornets close enough to their targets to do some real good.
An AAQ-38 Nighthawk laser targeting pod, mounted on the starboard fuselage station of an F/A-18C Hornet. This pod allows Hornet crews to deliver laser-guided bombs and other precision munitions.
JOHN D. GRESHAM
By the time Hornets next went into combat (in Bosnia in 1995), a number of improvements had been made. The -C/D-model Hornets had been rearmed with new AIM-120 AMRAAM AAMs, SLAM ASMs, and Paveway LGBs guided by their new Nighthawk targeting pods. And this time, their carrier, the USS Theodore Roosevelt (CVN-71), operated closer to shore than was the practice in Desert Storm and they were given adequate tanker support from NATO/USAF resources. Now that they were properly supported and armed, the PGM-armed Hornets (including a squadron of Marine F/A-18D Night Attack variants) were the heart of Operation Deliberate Force in 1995, and did all that was asked of them. In fact, Navy and Marine Corps Hornets dropped and launched the bulk of the PGMs that were used during the Bosnia strikes.
Today the Hornet is the backbone of U.S. carrier aviation, and will remain that way for at least the next decade. Every CVW is being equipped with three F/A-18 squadrons (each with twelve aircraft), which means that fully half of the aircraft on U.S. carrier decks today are Hornets. There will soon be significant Hornet upgrades, with the introduction of new PGMs, as well as a new version of the classic AIM-9 Sidewinder. Even so, there can be little doubt that the F/A-18’s short legs, limited weapons load, and design compromises will continue to be a lightning rod for critics. Still, the folks who fly the Hornet love their mounts. Though it’s a flying compromise, it’s easy to fly, forgiving for new pilots, and capable of many different missions.
EA-6B Prowler: The Electric Beast
Looking like a flying metal tadpole, the EA-6B Prowler will probably be the last survivor of a long line of Grumman carrier aircraft that date back to before the Second World War. Its mission is electronic warfare (EW), which explains why the aircraft looks like a flying antenna farm. As many as thirty (or more) antennas are smoothly faired into the fuselage or packed into the “football” (actually, it looks more like a Brazil nut), a fiberglass radome at the top of the vertical stabilizer. These devices allow the Prowler to throw an invisible veil of protection over the aircraft and ships of the carrier battle group. They detect, classify, and locate enemy radar, electronic data links, and communications, then jam them with precisely crafted and targeted interference. And as an added bonus, since 1986 Prowlers have also been capable of making “hard kills” using the AGM-88 High-Speed Anti-Radiation Missile (HARM), which homes in on radar transmitters and shreds them with a blast-fragmentation warhead.53
Today, the Prowler is the finest tactical EW aircraft in the world. It’s so good that the USAF is quietly retiring its own fleet of EF-111 Raven EW aircraft and employing EA-6Bs in joint (USN/USAF) squadrons. All this is even more impressive when you consider that the thirty-year-old Prowler design has been around for almost half of the six decades that radar has been used in military operations; and with regular updates, it has at least another ten or fifteen years to go.
Electronic warfare (intercepting and jamming enemy signals) began with the first military use of radio in the Russo-Japanese War (1905), and reached a high degree of sophistication during the Second World War, as Axis and Allied scientists and technicians fought for control of the electromagnetic spectrum. EW aircraft have been in use since World War II, with modified USN TBF/TBM Avengers being among the first such aircraft. The start of the Vietnam War saw two carrier-capable EW birds in service with the Navy, though both were already getting old. The EA-1E was a modification of the classic Douglas AD-1 Skyraider, while the EKA-3B “Electric Whale” (which also served as a tanker aircraft) was a development of the Cold War-era A-3 Skywarrior attack bomber. As American aircraft began to fall to radar-controlled AAA guns, SAMs, and MiGs over Vietnam, the need for a third-generation EW aircraft became almost desperate. Out of this need came the development of what would become the EA-6 Prowler.
The original airframe of the Prowler was derived from the A-6 Intruder, which was the Navy’s first true all-weather, day or night, low-level medium-strike aircraft. The Intruder saw extensive combat in Vietnam, the Cold War, and Desert Storm, and was immortalized in Stephen Coonts’s 1986 novel, Flight of the Intruder. The Prowler’s immediate ancestor, the EA-6A, was a modified two-seat “Electric Intruder” developed to fill a Marine Corps requirement for a jammer aircraft that could escort strike missions into the high-intensity threat of North Vietnam’s integrated air defense system. Hard-won experience showed that what was really needed for such missions were more EW operators and jammers aboard the aircraft. From this came the all-new EA-6B Prowler, which is an all-weather, twin-engine aircraft manufactured by Northrop Grumman Aerospace Corporation as a modification of the basic A-6 Intruder airframe. The first flight of the EA-6B was on May 25th, 1968, and it entered operational service in July of 1971. Just a few months later, the Prowler entered combat over Vietnam with VAQ-132, based on aircraft carriers in the Gulf of Tonkin.
The Prowler is big for a “tactical” aircraft. The overall length is 59 feet, 10 inches/17.7 meters. It has a wingspan (with the wings unfolded) of 53 feet/15.9 meters, and sits 16 feet, 3 inches/4.9 meters high on the deck. It is also quite heavy, with a maximum gross takeoff weight of 61,000 lb/ 27,450 kg, much of which is fuel. The Prowler has a cruising speed of just over 500 knots/575 mph/920 kph, an unrefueled range of over 1,000 nm/ 1,150 mi/1,840 km, and a service ceiling of 37,600 feet/11,460 meters.
The EA-6B can hardly be called a “high performance” tactical aircraft. Although it is quite stable in flight and relatively easy to fly, the Prowler is somewhat underpowered. The two non-afterburning Pratt & Whitney J52-P408 turbojet engines lack the kind of thrust available to F-14 or F-18 crews (11,200 lb/5,080 kg of thrust each), which presents the pilot with a number of challenges during every mission (especially on takeoff and landing). Due to the complexity of its systems, the EA-6B is also a relatively high-maintenance aircraft—about one mission in three returns with a “squawk” or malfunction requiring unscheduled maintenance. On the plus side, the side-by-side twin cockpit arrangement gives maximum efficiency, visibility, and comfort for the four-person crew. This is important during long missions, which can last up to six hours with in-flight refueling. The canopies are coated with a microscopically thin (and very expensive) transparent layer of gold leaf, which reflects microwave energy and protects the crew from getting cooked by their own high-energy jammers.
The Prowler’s crew includes a pilot and up to three Electronic Countermeasures Officers (ECMOs). The senior officer on board—either the pilot or one of the ECMOs—is normally the mission commander. In fact, a Prowler squadron commander is often an ECMO rather than a pilot. ECMO-1, who mans the position to the pilot’s right, handles navigation and communications, while
ECMO-2 and -3 (they sit in the rear cockpit) manage the offensive and defensive EW systems. Within the squadron, there are normally more crews than aircraft, due to the workload of flying, administration, and mission planning. In a low-threat environment, a crew of three is considered sufficient—with one ECMO remaining behind on the boat to plan the next mission, catch up on paperwork, or perform any of the countless additional duties that Naval aviators must juggle when they are deployed.
The Prowler’s EW capabilities depend largely on the ALQ-99 electronic countermeasures system. This is not a single piece of equipment, but a complex and ever-changing mix of computers, jammers, controls and displays, receivers, and transmitters. Some of these components are built into the airframe, while others are packaged in pods. All are externally identical, but each is optimized for specific frequency bands. Up to five such pods can be carried—two under each wing and one under the fuselage. A more typical mission configuration is two or three pods, with the other stations occupied by fuel tanks or AGM-88 HARM missiles. Each pod generates its own electrical power, using a “ram air turbine” or RAT (a compact generator spun by a small propeller). To generate full power for jamming, the aircraft must fly above a minimum speed (225 knots). Using the RATs brings a slight drag penalty; the Prowler loses about 1 % of its maximum combat radius for each pod carried. Still, the pods and missiles are the reason why the Prowler exists. Without the electronic smoke screen provided by the EA-6B’s jamming pods, losses to enemy defensive systems would be many times greater than they have been.
Normally, the EA-6B is used to provide a combination of services for strike packages inbound to a target area. If active SAM sites are nearby, the ECMOs will use the ALQ-99 to provide targeting for the HARMs, which are deadly accurate when fired from a Prowler. Once the HARMs are gone, the EA-6B orbits away from the target area and uses the ALQ-99 jammer pods to “knock back” enemy radars and other sensors that might engage the strike group. Other missions include electronic surveillance, as the ALQ-99 is a formidable collection system for electronic intelligence (ELINT). Because they are considered “high value units” by enemy defenders, one or two fighters usually provide them with an escort, just in case the locals get nosey. In fact, no Prowler has ever been lost in combat, though about forty have been destroyed in accidents. The worst of these was a horrific crash while landing aboard the Nimitz (CVN-74) back in 1979, which killed the entire crew as well as a number of deck personnel in the ensuing fire.
EW is an unusual facet in the spectrum of warfare. For every measure there is a countermeasure, and the useful life span of a system in actual combat is often only a few months. Because a new “generation” of electronic warfare technology emerges every few years, if you fall a generation behind you are “out of the game.” This helps to explain the bewildering variety of upgrades and variants that mark the Prowler’s long career. Production of new-built Prowlers ended several years ago, but about 125 remain in active service today. This is just enough for twelve Navy, four Marine Corps, and four “joint” squadrons of EA-6Bs. Normally, each deploys with four aircraft. Navy and joint USAF/USN Prowler squadrons are home-based at NAS Whidbey Island, Washington, while the Marine units live at MCAS Cherry Point, North Carolina. The joint EA-6B squadrons are a new phenomenon in the post-Cold War world, an expression of budget realities that no longer allow the services to duplicate aircraft types with the same mission. Although the Navy and USAF developed very different EW concepts and doctrine over the years, the Air Force has agreed to retire its only tactical jammer aircraft, the EF-111 Raven. Now the two services will “share” five joint “expeditionary” Prowler squadrons, which will operate with mixed Navy and Air Force ground and flight crews. Despite the predictable concerns about USAF officers commanding Navy squadrons (or vice versa), this program is well under way and looks to be a real winner.
Like their brethren in the Tomcat community, EA-6B crews have learned some new tricks in recent years, like shooting AGM-88 HARM missiles at enemy radars. Prowlers have even been used as command and control aircraft, functioning as strike leaders for other planes on bombing missions. Other improvements include plans to start another upgrade program known as ICAP (Improved Capability) III. This will take the basic EA-6B package as it currently exists (known as Block 89) and add improved computers, signal processors, and jammers, as well as a GPS receiver, new radios and data links, and other new avionic systems. ICAP III-equipped Prowlers should begin to appear in a few years. As for future EW aircraft on carriers, long-range plans have been developed for a two-seat EW version of the new F/A-18E/F Super Hornet. A highly automated follow-on version of ALQ-99 would be fitted to this bird, as well as more advanced HARMs and other systems. However, since there is no money for this bird in the current budget, the old Prowlers will have to soldier on for at least another decade or two.
A cutaway view of a Raytheon AGM-88 HARM anti-radiation missile.
JACK RYAN ENTERPRISES, LTD., BY LAURA DENINNO
E-2C Hawkeye: Eyes of the Fleet
Put a sensor of sufficient resolution high enough, and you will see enemy forces before they can harm you. This is the guiding principal behind most early warning systems, from reconnaissance satellites to Unmanned Aerial Vehicles (UAVs). For naval leaders, there is no more important “high ground” than that occupied by Airborne Early Warning (AEW) aircraft. The first U.S. Navy AEW birds date back to World War II, when converted TBF/ TBM Avengers were modified to carry a small airborne radar and operator for the purpose of detecting incoming Japanese Kamikaze aircraft far enough out for fighters to be vectored to intercept them. After the war, special purpose-built AEW aircraft were developed. These were designed to deal with the new generation of jets and ASMs faced by Cold War-era Naval forces. The first of these was the Grumman E-1 Tracer, a development of the S-2F Tracker ASW aircraft. For almost a decade the E-1 worked as the primary carrier-based AEW aircraft for the USN; but the operational conditions of the Vietnam conflict showed the numerous shortcomings of the Tracer, including poor overland radar performance and limited endurance and service altitude. Though they served aboard modified Essex-class (SCB-27C/CV-9) carriers until 1976, there was a clear need for a more advanced AEW aircraft for the fleet. That aircraft was the E-2 Hawkeye.
The business end of a VRC-40 C-2A Greyhound COD aircraft on the deck of the USS George Washington (CVN-73). These aircraft are used to ferry personnel, cargo, and supplies to and from carrier battle groups.
JOHN D. GRESHAM
One of the last propeller-driven aircraft in the CVW, the E-2C Hawkeye is the Navy’s all-weather, carrier-based tactical AEW aircraft. The E-2C uses computerized sensors for early warning, threat analysis, and control against air and surface targets. It provides the carrier battle group with all-weather AEW services, as well as command, control, and communications (C3) functions for the carrier battle group. Additional missions include surface surveillance, strike and interceptor control, Combat Search and Rescue (CSAR) guidance, Over-the-Horizon (OTH) targeting, and communications relay. Designed to a 1955 specification, and upgraded through at least six generations of electronic technology, the Hawkeye remains in production today. The E-2C has also been adopted by the French Navy, and at least five other countries that do not even have aircraft carriers. This is a tribute to the cost-effective mix of robust airframe, compact sensor and avionics suite, and turboprop power plants. Unit cost: $51 million—cheap for the protection it provides. Before you gag on that number, consider that a new F/A-18E/F Super Hornet will cost you even more per copy, and I don’t know any battle group commander who would not like a few more of the precious E-2Cs.
One thing all that money does not buy is beauty. As you walk up to a Hawkeye, pieces of it seem to be going everywhere. Wings are folded back on the fuselage, with the big radar rotodome perched up top like a tethered flying saucer. Though it is not gorgeous to look at, the E-2C has a functional elegance, doing the same kind of mission as its larger USAF cousin, the Boeing E-3 Sentry. Tha
t it does this on an airframe a fifth the size, and off a carrier deck, is a measure of its sophistication and value. When the Grumman engineers designed the E-2, they started with a perfect cylinder. Into this they packed all the electronics, fuel, two pilots, and three radar controllers. The finishing touch came when they mounted the rotating radar dome (called a “rotodome”) on top, and attached a pair of long wings mounting a pair of Allison T-56-A427 turboprop engines with five thousand shaft horsepower each.
Dimensionally, the Hawkeye is 57 feet, 6 inches/17.5 meters long, with a wingspan of 80 feet, 7 inches/28 meters, and a height of 18 feet, 3 inches/ 5.6 meters to the top of the radar dome. Though it is the largest aircraft flying on and off carriers today, it is not the heaviest. At a maximum gross takeoff weight of 53,000 lb/23,850 kg (40,200 lb/18,090 kg “dry”), the E-2C is actually lighter than the F-14 Tomcat. The wings have the longest wingspan of any carrier aircraft in the world; and when folded, they use the classic Grumman “Stow-Wing” concept, which has them folding against the fuselage. The tail is composed of a horizontal stabilizer with four vertical stabilizers to give the Hawkeye the necessary “bite” to move the heavy bird around the sky. Though it has only ten thousand horsepower behind the twin props, the Hawkeye is capable of speeds over 300 knots/345 mph/552 kph, and can operate at altitudes of 30,000 feet/9,144 meters. Because Hawkeyes are unarmed, no battle group commander would be considered sane if there were less than two fighters protecting his E-2C. Hawkeyes are true “high value units” and are always a target for enemy fighters.
On board, the crew of five is busy, for they’re doing a job that on the larger E-3 Sentry takes several dozen personnel. The pilot and copilot fly precisely positioned and timed racetrack-shaped patterns, designed to optimize the performance of the E-2C’s sensors. In back, the three radar-systems operators are tasked with tracking and sorting the contacts detected by the Hawkeye’s APS-145 radar. This Westinghouse-built system is optimized for operations over water and can detect both aircraft and surface contacts out to a range of up to 300 nm/345 mi/552 km. To off-load as much of the workload as possible, a great deal of the raw data is sent back to the task force’s ships via a digital data link. With this off-board support, the three console operators are able to control a number of duties, including intercepts, strike and tanker operations, air traffic control, search and rescue missions, and even surface surveillance and OTH targeting.