Defence`s Feeds

The detection and identification of chemical, biological, radiological, nuclear and explosive (CBRNe) threats has traditionally been a costly and painstaking endeavour for the military and for other civilian actors such as protection forces (border police, fire brigades etc.). Aside from the obvious risk of exposure for counter-CBRNe personnel, neutralising the threats demands complex sampling and analysis procedures, particularly in the bio- and chemical areas, to avert or mitigate their effects. 

This article has first been published in EDA's 'European Defence Matters' magazine N° 19 published in June 2020. 

If the time, expense and personnel required to carry out such tasks could be telescoped, the world would be a far more secure place. Indeed, new technologies – and new combinations of existing technologies – hold great promise in that regard. 

The European Defence Agency (EDA) and the European Space Agency (ESA) aim to do just that with their novel approach to the CBRNe sector, one that promises high levels of deployability, safety, speed, accuracy and reliability for detecting and identifying threats. The two Agencies have supported European industry in developing a concept, which is only a step or two away from the industrial production stage, meaning it could be rolling out to Europe’s defence and civil first-responder communities in just a few years.

Welcome to AUDROS (‘Autonomous Drone Services in the CBRNe operations’), the joint EDA/ESA project that combines satellite-based services with Remotely Piloted Aircraft System (RPAS) technologies. The resulting capability would have a wide range of applications for many different users, ranging from defence forces to first responders (police, emergency response, firefighters, etc.) to industry (transport, energy, critical infrastructure security, etc.).
 

Joint call for proposals

AUDROS has evolved over several stages and is now poised to tackle the core of its development work. Its two sponsoring partners laid down the project’s initial groundwork with a preceding Implementing Arrangement, signed in March 2017. This was followed by a workshop open to defence and civil stakeholders and subsequent interactions in order to assess the requirements of all the interested Member States. EDA’s CBRN research and technology expert network played a central role in capturing defence specific needs and requirements. 

That, in turn, saw the definition of a joint call for proposals to study the design and function of a prototype system. “We received a solid number of proposals, matching our requirements for new CBRNe detection-identification-monitoring capabilities and services, making it a genuine success,” said Shahzad Ali, EDA moderator for CapTech CBRN & Human Factors1. 

AUDROS was one of the awarded teams of the one-year feasibility study contract worth €350,000. The Consortium was made up of four partners: the two Czech companies BizGarden (as prime) and GINA Software, the Polish company Cervi Robotics, and the Czech Ministry of Defence research institution known as VTU. “The main purpose of the study was to look at AUDROS’s technical analysis, economic viability, the added value brought by the space-based data, new possible applications and, of course, the crucial ability to deal with CBRNe threats,” observed Ali. 
 

RPAS hangar system

Starting in early 2018, the joint EDA/ESA team analysed the solutions proposed by industry to meet user needs for CBRNe countermeasures, with the study’s results assessed in December of that year. It laid out the definition of an RPAS hangar system. The ultimate goal? To enable fully autonomous beyond-visual-line-of-sight drone operations equipped to carry out day or night-time detection of persons and equipment, and search and map radiation sources, chemical warfare agents or toxic industrial pollution. 

The joint team then witnessed in late 2018 the successful demonstration of a proof-of-concept system for AUDROS. This comprised a modified off-the-shelf quadcopter RPAS with a maximum take-off weight of 25 kg (including payload of up to 9 kg) and a hangar. Equipped with lightweight sensors for radiation and gas detection, AUDROS’ test scenario focused on detecting a chemical near a large industrial site by sending the drone to ‘sniff out’ the agent’s molecules and location. This was demonstrated during the prototype system’s outdoor flights around the facilities of project partner VVU. 

“Space technologies are a crucial component of AUDROS”, said Beatrice Barresi, ESA’s Project Officer. “Satellite Navigation allows us to command the RPAS and to monitor the position of the rescue team in the field. That is not all: satellite imagery are needed to visualise the situation and to provide best available data to command the RPAS. Last but not least, satellite communication protects data transfer towards remote dispatch/command.” 

Just as important was the study’s recommendations for the design and construction of AUDROS’s drone hangar. The prototype’s portable hangar, which was connected to a fixed power source, was designed to enable the drone to autonomously re-charge its battery. Expanding on this design in future to enable auto-switching of detection suites, for example, would significantly increase the flexibility and duration of AUDROS-based missions, particularly if several drones and hangars were deployed at the same time. 
  

Towards deployment

That, however, is for the project’s next and crucial phase, namely the deployment of AUDROS in a fully operational scenario. The payload will be modular in design and industrially scalable for commercial production. 

The Czech-Polish consortium is expected to receive a new contract to build the pre-operational service, which will be financially supported by EDA and ESA.

“The Covid-19 pandemic has fortunately not adversely impacted the rolling out of the project, namely because AUDROS’s demonstration budget had been earmarked,” said Ali. “Thus, this 18-month contract will go ahead as planned, with the idea of signing off on it by the summer.” 

“Engaging projects swiftly is a critical means at our disposal to respond to the pandemic’s adverse effect on the economy at large and the space industry in particular. ESA, with its partner EDA, is therefore fully engaged to proceed as soon as possible with agreed projects in order to channel much needed resources to protect Europe’s essential industrial base in these unprecedented times”, added Florent Mazurelle, ESA’s Principal Security Strategy Officer.

The demonstration project will expand the prototype’s technical design by incorporating drone payloads for the mapping and visual day/night detection of persons, as well as situational awareness from integrated satellite services. Its hangar will be able to either recharge a drone’s battery or swap it out for a newly recharged one. Doing so would mean that a fleet of drones, combined with one or more hangars, could carry out 24/7 execution of CBRNe-missions across a relatively wide operational area. 

“Indeed, the combination of sophisticated detection-identification and monitoring suites with the diverse array of satellite services promises to produce a powerful dual-use CBRN-protection capability for Europe’s military and civil users. And it would have many cross-over links to other EDA research goals in the areas of counter-terrorism, harbour protection, protection of critical infrastructure, logistics and in-theatre medical surveillance, to name just a few. The spill over benefits, in other words, could radiate out in many directions”, concluded Ali. 
 

Fruitful cooperation

EDA’s research collaboration with ESA got off the ground in June 2011 when the two organisations signed their Administrative Arrangement on cooperation, which, above a tightly knit policy dialogue, has now given birth to cooperative projects in countless domains such as cyber defence, critical technologies for European non-dependence, Earth observation, secured satellite communications, to name but a few. 

AUDROS was a logical outgrowth of the EDA’s Joint Investment Programme on CBRN Protection, which it launched in 2012 to stimulate R&T work in the defence sector among its Member States and their industries. 

 

1 The European Defence Agency’s work in the Research & Technology domain is in line with the Agency’s mission to support Member States in their efforts to improve defence capabilities. EDA organises its R&T priorities in different Capability Technology Areas (CapTechs), which are networking fora for experts from government, industry, small and medium enterprises (SME) and academia, moderated by EDA.

Americas

Testers from the US Air Force’s 40th Flight Test Squadron and the 85th Test and Evaluation Squadron carried out the first four-ship F-16 formation test of the new APG-83 AESA radar on July 2. The mission objective was to determine if the jets experience interference when all four radars are active at the same time and to determine if there is signal improvement or degradation during the flight. According to the press release from Egline Air Force Base, the APG-83 is powerful enough that it allows the pilot to target a corner of a small building or the cockpit of an aircraft from beyond line-of-sight.

An Argentine Air Force A-4AR pilot was killed on August 5 when his fighter crashed south of the city of Cordoba during a training flight. Captain Gonzalo Fabian Britos Venturini ejected from his aircraft but did not survive. The A-4AR is an upgrade of the A-4M carried out by Lockheed Martin in the 1990s. The jets were modernized with new Douglas Escapac 1-G3 ejection seats, AN/APG-66V2 radars and HOTAS controls with CRT color displays.

Middle East & Africa

Kellogg Brown an Root Services son a $75 million job order contract for construction projects at Camp Lemonnier and Chabelley Air Field, Djibouti. No task orders are being issued at this time. The work to be performed provides for various renovations, repairs, maintenance, replacements, alterations, demolition and construction projects for Camp Lemonnier and Chabelley Air Field, Djibouti. The construction may include minor alteration, repair of real property (industrial and commercial) and utilities. The term of the contract is not to exceed 60 months. Work will take place in Djibouti, Africa. Estimated completion date will be by September 2025.

Europe

Reactivation of the US Army’s fabled V Corps establishes a forward command post in Poland, following announced plans to reduce US troop strength in Germany. The V Corps flag was unfurled on Tuesday in ceremonies in Krakow, Poland, with the promotion of commanding officer Maj. Gen. John Kolasheski to the rank of lieutenant general. About 200 Army personnel will form the post, beginning in Fiscal Year 2021, the US Embassy in Warsaw said. A new forward command post is part of an Enhanced Defense Cooperation Agreement between Poland and the United States, finalized on July 31.

The Belarus Air Force carried out an exercise on the M1 Minsk-Brest motorway on August 5. MiG-29, Su-25, Yak-130 and L-39 landed on a pre-prepared strip of the motorway before taking off to carry out ground attacks at the Ruzhany air range. The section was defended by Tor-M2 air defense system and Mi-24 and Mi-8MTV-5 helicopters patrolled the area. Su-30SM fighters flew overhead as well.

Asia-Pacific

According to Jane’s, Saab reaffirmed its intention to offer its GlobalEye platform for South Korea’s recently announced program to acquire additional airborne early warning and control aircraft for the Republic of Korea Air Force. Saab reportedly told Jane’s that it expects the procurement to feature an initial two aircraft acquired through either an open tender or a direct acquisition. South Korea’s Defense Acquisition Program Administration (DAPA) is expected to confirm the procurement method later this year. GlobalEye is Saab’s new airborne early warning and control solution. It provides air, maritime and ground surveillance in a single solution. GlobalEye combines Saab’s new Erieye Extended Range Radar and a range of additional advanced sensors with the ultra-long range Global 6000 aircraft from Bombardier.

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AN/APG-79 AESA Radar
(click to view full)

The AN/APG-79 Active Electronically Scanned Array (AESA) radar began life as a replacement. Initial F/A-18 E/F Super Hornet production batches installed Raytheon’s all-weather, multimode AN/APG-73, but the APG-79 has intrinsic technical features that offered revolutionary increases in capability, reliability, image resolution, and range.

Unlike the APG-73 that equipped the first Super Hornets, the APG-79’s AESA array is composed of numerous solid-state transmit and receive modules that are fixed in place, eliminating a common cause of breakdowns. To move their beams, they rely on electronic changes in each module’s transmissions, creating useful interference patterns in order to aim, focus and shape their output. Other system components include an advanced receiver/exciter, ruggedized commercial-off-the-shelf (COTS) processor, and power supplies. With its open systems architecture and compact COTS parts, it changes what both aircrews and maintenance staff can do with a fighter radar – and does so in a smaller, lighter package.

AN/APG-79 & The AESA Advantage The APG-79 Program

APG-79 usage concept
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The AN/APG-79 will replace Raytheon’s own AN/APG-73 on F/A-18 E/F Super Hornet Block II aircraft, and equips the derivative EA-18G “Growler” electronic warfare aircraft now entering service.

Since the original contract award in 2001, Raytheon employees say that the APG-79 program has met all its milestones on time. The system has performed well in flight tests, and is already in widespread use.

In April 2005, Boeing and Raytheon debuted an F/A-18F Block II Super Hornet equipped with the AN/APG-79 AESA radar system at a St. Louis ceremony. That was the first step toward fulfilling the Navy’s roadmap to expand the F/A-18E/F Super Hornet family’s future capabilities. In October 2006, the first Super Hornet Block II squadron attained the requisite “safe for flight” designation, certifying that they were ready for independent operations with the new equipment. Production installations and retrofits of older Super Hornets have continued, with the 300th radar delivered in November 2011.

The APG-79’s AESA Advantage AESA: Technical Advantages

Before: AN/APG-73
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The downside of AESA radars is that they cost more to buy. The cost of producing all those transmit/receive (T/R) modules has come down, but it’s still a more expensive choice initially. On the other hand, AESA radars offer a number of performance advantages, and appears to be a cheaper choice over the fighter’s entire lifespan.

American AESA radars feature a fixed array, with active electronic beam scanning that moves the beams rather than the radar array. That allows faster scans over a broader area. AESA radar can also commit clusters of T/R modules to each task, allowing pilots and crew to do something previous generation radars could not: conduct simultaneous air-to-air and air-to-surface operations, at a higher level of performance.

Raytheon personnel cited a 2-3x expected range improvement when moving from a mechanical phased array radar to Raytheon AESA radar with the same power input and the same aperture. This is due to better dynamics in the beams, and more efficient use of power by the array of individual T/Rs.

F-35B
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The final set of AESA technical advantages involves entirely new roles. AESA arrays’ depth of individually programmable T/R modules gives them the potential to send high-bandwidth communications, and even perform offensive electronic warfare functions. That latter capability suggests that the radar may start to become the fighter’s electronic warfare fulcrum, instead of relegating that role to drop in EW system “black boxes”. The dedicated EW systems would still be there, but emphasis would shift to coordination with the radar as both an emissions receiver and a compatible electro-magnetic emitter.

Raytheon sees this EW Center of Gravity role as more of a next-generation feature for integrated platforms, but the APG-79’s use in the EA-18G dedicated electronic warfare aircraft may give them some future development opportunities. That will be important, because Northrop Grumman’s APG-77 and APG-81 AESA radars have already been picked to equip the USA’s next-generation F-22 and F-35 fighters. The F-35 in particular features a lot more integration between its systems, and electronic warfare capabilities are among the top requests from F-35 customers. That creates demand-pull pressure on Northrop Grumman to move forward along these lines. If they do, it could create a competitive advantage for NGC that would affect Raytheon’s Electronic Warfare components business, as well as its radar orders.

AESA Advantages AESA: The Tactical Advantage

click for video

The tactical consequences are equally significant.

One is concealment. AESA radars also offer less emission “leakage” beyond their scanning cone, and can spread their signal emissions over a broad set of frequencies. Most people don’t think of the radar as part of a platform’s stealth level, but it is. Less side-lobe leakage improves the radar cross-section directly. “Agile beam” radars can both spread and switch frequencies as they go, which makes the radar very hard to detect, even when it’s on. Previous generation radars haven’t had that advantage, and turning on your fighter’s radar was kind of like the policeman who turns a flashlight on to find bad guys in a big warehouse. In all likelihood, they can see the light source before the policeman can use the beam to see them. Modern infantry solve this problem by using invisible infrared lights, which work with their night-vision goggles and allow them to see without being seen. Agile beam AESA radars offer the same advantage for a modern fighter jet.

In air-to-air mode, an AESA radar’s improved sensitivity can allow targets to be engaged at longer ranges. If political Rules of Engagement permit, fighters can launch at maximum range, taking full advantage of new longer-range air-air missiles and air-ground weapons. Raytheon employees could not comment on speculation that resolution improvements might allow APG-79 radars to lengthen the positive ID range for enemy aircraft. If that were true, however, it would solve a big problem. Rigid Rules of Engagement have often required positive identification, which has forced American planes to close to visual range before firing. This removes many of the benefits of having beyond visual range air-to-air missiles like Raytheon’s AIM-120 AMRAAM on board.

In air-to-surface mode, AESA radars offer a choice of same-resolution ground mapping at 2-3x longer standoff ranges, or improving the resolution “by faster than linear” margins (i.e. by more than 2-3x). Its SAR (synthetic aperture radar) images can be used to designate multiple targets at once, identify unplanned ground targets and engage them, and sort fast-moving naval targets despite the clutter created by waves and weather. With the previous APG-73 radar, only pre-planned ground targets, entered into the system before the mission began, could be attacked at full capability.

A US Navy R&D program called “Initiated Strike Accelerator” aims to “identify targets using Advanced Target Recognition,” using the AN/APG-79 radar and ATFLIR surveillance and targeting pod. If it succeeds, it could certainly help with ground strikes. The interesting question is whether these capabilities could also be used for air-to-air engagements, in order to break through the up-close visual identification Rules of Engagement.

APG-79: The Maintenance Advantage

APG-79 LRM removal
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Beyond the front lines, AESA radars offer a number of operational and maintenance advantages.

One set of advantages involves long-term costs. Unlike predecessor radars like the mechanically scanned APG-73, American AESA designs to date have no moving parts to serve as sources of failure. Better yet, AESA radars’ inherent redundancy allows them to fly and perform well even if some of the individual T/R modules need replacing. As a rule, therefore, failed modules are just left alone. Raytheon touts a 10x – 15x improvement in overall reliability, and an expected flight lifetime of 10,000 – 15,000 hours. That compares to a 6,000 flight hour lifetime for their fighters, or 10,000 with life-extension programs. Fighters can take 30 years to exhaust 10,000 flight hours, so the maintenance savings make AESA radars a cheaper long-term option, in exchange for higher up-front investment.

The APG-79 adds one more operations & maintenance innovation: Line Replaceable Modules (LRM). Most radars, up to and including Raytheon’s APG-63v3 AESA that flies on advanced F-15s, have Line Replaceable Unit “black boxes,” that must be sent back to depots for diagnostics and repair. It’s expensive, and time consuming. In contrast, the LRM philosophy has the radar do most internal monitoring and diagnosis. Once its recommendations are delivered, a field technician on the front lines can open a box that used to be a depot-only LRU, and swap out an LRM that looks like a circuit card. Doing this in the field, on the front lines, really lowers costs and improves readiness.

As a bonus, the LRM philosophy makes options like processor upgrades, etc. similarly modular. Money and time must still be spent on testing durability for the new LRMs, ensuring software compatibility, and testing it with other radar components. Once that’s done, however, the hardware swap is much faster and cheaper, saving money that can be used on development work to take advantage of the new capabilities.

The AN/APG-79 has a downside, however, and it’s a big one. Pentagon testing reports consistently cite software problems with the APG-79, including instability and issues with its Built-In Test (BIT) functions.

A Wider Market? Spinoffs and Spin-back

RAAF F/A-18F, armed
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The U.S. Navy plans to buy over 400 AN/APG-79 AESA systems, and potential foreign sales span future Super hornet family customers, as well as the 7 countries that fly earlier-model F/A-18A-D Hornets. Australia’s purchase of 24 F/A-18F Block II Super Hornets made them the radar’s first foreign customer.

At present, the AN/APG-79 appears destined to equip only F/A-18 Super Hornet family aircraft, but co-investment in the APG-79 by the US Navy and by Raytheon has paid wider dividends beyond the program itself. Related technologies will equip American F-15s, and may equip a wide variety of American and foreign fighters as retrofits. Once those products are sold, Raytheon’s Common Radar Roadmap’s emphasis on commonality and modularity means that the technology influence will begin to cut both ways.

One spinout has already paid dividends for the USAF. Technologies from the APG-79 have found their way into the AN/APG-82v1 radars that will be retrofitted to USAF F-15E Strike Eagles, and the new radars will also share the APG-79’s LRM approach.

RACR in F-16
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Raytheon’s resizable RACR AESA radar also owes the APG-79 a debt. RACR is aimed at a very large potential market, as a retrofit for F-16s and F/A-18 Hornets around the world, and as an option for new planes like the JAS-39 Gripen New Generation.

The essential idea of RACR is to leverage the AESA improvements described earlier, using APG-79 technologies. Keep the existing radars’ aperture and keep the same power requirement, allowing customers to just drop it in F-16 and F/A-18s without structural or power changes. The translation of received data is mostly handled within the RACR modules already, minimizing other changes to the receiving fighter. This same flexibility is possible for other platforms with previous-generation radars. Aperture sizes can be changed by changing the number and arrangement of T/R modules, and power back-ends can be varied. The continuum from the large APG-82, to the APG-79, to RACR, using closely related technology, demonstrates this. That makes RACR retrofits or forward-fits on other platforms equally plausible.

As related radars like the APG-82 and RACR are sold, they will bring benefits back to the APG-79. Raytheon employees told DID that it’s possible to develop a radar mode like RCDL high-bandwidth communications for a platform like the F/A-18E/F, and have it made available to RACR or APG-82 customers. The cost and effort would involve minimal engineering work, followed by LRM swap-in or software reprogramming, and check-out testing. The reverse would also be true, allowing innovations requested by RACR customers to find their way back to the APG-79 fleet.

Beyond the aerial domain, Raytheon employees added that the firm is involved in requests from other customers to bring the firm’s Common Radar Roadmap technologies and approach over to non-aircraft platforms. They won’t say who or what, yet. It’s worth noting, however, that Northrop Grumman’s G/ATOR multimode ground radar for the USMC uses technologies from its APG-81 AESA radar, so these kinds of conversions are very possible. Raytheon IDS’ President was the father of the APG-79, and that part of the firm is involved in systems like the USA’s Patriot missile system, as well as next-generation naval radars like DBR, and AMDR.

Contracts & Key Events

In many cases, the AN/APG-79 was bought by Boeing for its Super Hornet family planes, rather than being bought separately as Government-Furnished Equipment and given to Boeing. Direct contract exceptions are noted below, and radar retrofits do appear in Navy budget documents. With that said, many radar production contracts will be private and therefore unannounced. Based on Navy budget documents, recent costs per radar appear to be around $2.8 million.

FY 2014 – 2020

 

APG-79 maintenance
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August 7/20: Fomation Test Testers from the US Air Force’s 40th Flight Test Squadron and the 85th Test and Evaluation Squadron carried out the first four-ship F-16 formation test of the new APG-83 AESA radar on July 2. The mission objective was to determine if the jets experience interference when all four radars are active at the same time and to determine if there is signal improvement or degradation during the flight. According to the press release from Egline Air Force Base, the APG-83 is powerful enough that it allows the pilot to target a corner of a small building or the cockpit of an aircraft from beyond line-of-sight.

December 12/19: Spare Parts Raytheon won a $45.1 million delivery order for APG-79 Radar System spare parts. The AN/APG-79 active electronically scanned array (AESA) radar is an airborne radar made for F/A-18 E/F aircrafts. It is comprised of numerous solid-state transmit and receive modules to practically eliminate the possibility of mechanical breakdown. With a range of 150 km, the AN/APG-79 provides instantaneous track updates and multi-target tracking capabilities. The AN/APG-79 is strategically valuable because of its active electronic beam scanning. This feature allows the radar beam to be steered at nearly the speed of light, optimizing situational awareness and providing superior air-to-air and air-to-surface capabilities. Performance location will be California. Estimated completion date is December 30, 2022.

October 11/19: Spare Parts Raytheon won a $11.9 million delivery order for the procurement of 101 spare part units across nine assemblies used in support of the F-18 APG-79 Active Electronically Scanned Array radar system. The AN/APG-79 AESA radar is an airborne radar made for F/A-18 E/F aircrafts. It is comprised of numerous solid-state transmit and receive modules to practically eliminate the possibility of mechanical breakdown. With a range of 150 km, the AN/APG-79 provides instantaneous track updates and multi-target tracking capabilities. Its X-band radar allows for higher resolution imaging, helping with target identification and discrimination. The AN/APG-79 is the replacement radar for the AN/APG-73. Work will take place in Forest, Mississippi. Estimated completion date will be by December 2022.

March 29/19: Repair Services The US Navy awarded Raytheon Space Airborne Systems $58 million for repair services for the APG-79 active electronically scanned array radar system used on the F/A-18 Super Hornets. The deal has Raytheon fix 25 weapon repairable assemblies for the AN/APG-79. The APG-79 AESA radar system utilizes active electric beam scanning, which provides nearly instantaneous track updates and multi-target tracking capability. It features an entirely solid-state antenna construction, which improves reliability and lowers the cost compared to a traditional system. The radar allows the Super Hornet crew to fire the AIM-120 AMRAAM, while at the same time guiding several missiles to several targets widely spaced in azimuth, elevation or range. Its X-band radar allows for higher resolution imaging, helping with target identification and discrimination. Raytheon delivered the first low rate production APG-79 radar set to Boeing Integrated Defense Systems in Saint Louis on January 13, 2005. Up to 415 radar sets were expected to follow the first one to outfit US Navy’s Super Hornets beginning in September 2006. On 28 June 2005, Boeing awarded Raytheon a $580 million multi year procurement contract for 190 APG-79 radars to equip the US Navy’s F/A-18E/F and EA-18G aircraft. Raytheon will perform work in Forest, Mississippi and will approximately be finished by March 2022.

May 14/15: Raytheon announced that it has successfully flight-tested the APG-79(V) X AESA radar system, intended to extend the service lives of F/A-18C/D aircraft by 15 to 20 years. This latest test builds on a previous successful test in January, with new features such as Synthetic Aperture Mapping (SAR) announced with the company’s press release.

Sept 5/14: Support. Raytheon Co. in El Segundo, CA receives an $11.4 million firm-fixed-price delivery order, covering potential repairs to 288 radar component units consisting of 18 different weapons repairable assemblies (WRAs) used in support of the F/A-18 family’s AESA. All funds are committed immediately, using FY 2104 US Navy budgets.

Work will be performed in El Segundo, CA and is expected to be complete in March 27/15. This contract was not competitively procured in accordance with 10 U.S.C. 2304 (c)(l) nu US Navy NAVSUP Weapon Systems Support in Philadelphia, PA (N00383-10-G-005H, DO 7040).

June 12/14: Boeing in St. Louis, MO receives $10.2 million for cost-plus-fixed-fee delivery order to conduct an engineering change in the APG-79’s 5th and 6th Receiver Channel Wiring. Boeing is, of course, the F/A-18 Super Hornet family’s manufacturer.

One hopes NAVAIR will also get around to investing in a serious fix for the radar’s long-standing software issues (q.v. Jan 28/14).

All funds are committed immediately, using FY 2014 aircraft budgets. Work will be performed in Andover, MA (40%); Forest, MS (30%); El Segundo, CA (20%); and St. Louis, MO (10%), and is expected to be complete in January 2016. US Naval Air Systems Command in Patuxent River, MD manages the contract (N00019-11-G-0001, DO 0200).

Jan 28/14: DOT&E Testing Report. The Pentagon releases the FY 2013 Annual Report from its Office of the Director, Operational Test & Evaluation (DOT&E). The APG-79 is included, and the verdict isn’t great:

“AESA demonstrated marginal improvements during FOT&E from prior testing and provides improved performance relative to the legacy APG-73 radar. However, operational testing has yet to demonstrate a statistically significant difference in mission accomplishment between F/A-18E/F aircraft equipped with AESA and those equipped with the legacy [APG-73] radar.

….Though aircraft software has demonstrated acceptable suitability, the continued poor reliability of the AESA radar appears to be a result of software instability. The radar’s reliability and poor built-in test (BIT) performance remain deficient. The Navy did not attempt to address long-standing deficiencies in air warfare or AESA radar reliability with SCS H8E [the latest aircraft software build]. Overall, the F/A-18E/F/G is not operationally effective for use in certain threat environments, the details of which are addressed in DOT&E’s classified report issued following SCS H6E, SCS 23X, and AESA FOT&E.”

FY 2011 – FY 2013

300th radar delivered; 3rd & 4th radar retrofit contracts; Combat ID using AESA?

EA-18G: key systems
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Unless otherwise indicated, all contracts are issued by the Naval Air Systems Command (NAVAIR) in Patuxent River, MD to Boeing subsidiary McDonnell Douglas Corp. in St. Louis, MO. It’s Raytheon’s radar, but Boeing is the lead contractor for the aircraft, and assumes overall responsibility for buying the radars and integrating them into the aircraft. Workshare in “El Segundo, CA,” for instance, is actually Raytheon’s.

buying the radars and integrating them into the aircraft. Workshare in “El Segundo, CA,” for instance, is actually Raytheon’s.

Sept 26/13: ECP. Raytheon in El Segundo, CA receives a $34.7 million cost-plus-incentive-fee delivery order for AN/APG-79 Engineering Change Proposal 6381 Step 2’s flight test requirements. All funds are committed immediately.

Work will be performed in Andover, MA (50%); Forest, MS (30%); and El Segundo, CA (20%), and is expected to be completed in August 2016. US NAVAIR in Patuxent River, MD manages the contract (N00019-10-G-0006, 0047).

Sept 24/13: ECP. Boeing in St. Louis, MO receives a $6.9 million cost-plus-fixed-fee contract modification for engineering work associated with flight test requirements for AN/APG-79’s general purpose processor 3 upgrade. More computing power is always good, and it’s being conducted under Engineering Change Proposal 6381SOWR2 (see also June 20/12, though other ECPs have involved GPP-3), bringing its announced total to $38.1 million. All funds are committed immediately.

Work will be performed in El Segundo, CA (76%), and St. Louis, MO (24%), and is expected to be complete in February 2014. US Naval Air Systems Command, Patuxent River, Md., is the contracting activity (N00019-12-C-2006).

Sept 23/13: +15. Raytheon Co., El Segundo, CA, is being awarded $39 million for 15 AN/APG-79 AESA radar systems, as a firm-fixed-price delivery order. All funds are committed immediately. Note that FY 2013 fighter orders involve 38 radars (23 F/A-18E, 3 F/A-18F, 12 EA-18G), and final FY 2014 orders involve 21 radars (all on EA-18Gs).

Work will be performed in Forest, MS (80%), and El Segundo, CA (20%), and is expected to be complete in November 2015. US Naval Air Systems Command in Patuxent River, MD (N00019-10-G-0006, #0048).

15 radars

June 13/13: ECP. Raytheon in El Segundo, CA receives a $22.4 million order, covering 53 ECP-6279 retrofit kits for F/A-18 E/F and EA-18G aircraft. ECPs involve aircraft or component modifications, and the announcement doesn’t explain which one, but our coverage elsewhere (vid. Oct 07/09) shows that it involves improvements to the APG-79 AESA radar. All funds are committed.

Work will be performed in Forest, MS (80%), and El Segundo, CA (20%), and is expected to be completed in July 2015. US Naval Air Systems Command in Patuxent River, MD manages the contract (N00019-10-G-0006; delivery order 0036).

June 13/13: ECP. Boeing St. Louis, MO receives a $9 million firm-fixed-price delivery order for 30 ECP-6038 R2/R3 retrofit kits for the F/A-18 E/F aircraft, including radomes for the AN/APG-79 active electronically scanned array radar. A fighter’s radome nose cone is very specialized. It needs to allow the right radiation wavelengths to pass in and out easily, while remaining durable enough to handle the shocks and stresses of flight. All funds are committed immediately.

Work will be performed in Marion, VA (57%) and St. Louis, Mo. (43%), and is expected to be completed in January 2016. The Naval Air Systems Command, Patuxent River, MD manages the contract (N00019-11-G-0001).

June 27/12: Australia. Raytheon in El Segundo, CA receives a $6.7 million cost-plus-fixed-fee delivery order, for upgrades that will let the F/A-18 AN/APG-79 AESA radar commercial depot diagnose and validate repairs of RAAF APG-79s under the Foreign Military Sales Program.

Work will be performed in El Segundo, CA (70%), and Forest, MS (30%), and is expected to be complete in August 2014. US Naval Air Systems Command in Patuxent River, MD manages the contract on behalf of its Australian client (N00019-10-G-0006).

June 20/12: ECP. A $31.2 million cost-plus-fixed-fee, firm-fixed-price contract for APG-79 Engineering Change Proposal 6381SOW, for engineering related to the general purpose Processor 3 upgrade.

Work will be performed in El Segundo, CA (84%), and St. Louis, MO (16%), and is expected to be complete in May 2013. This contract was not competitively procured pursuant to FAR 6.302-1 (N00019-12-C-2006).

April 30/12: ECP. A $12 million firm-fixed-price delivery order for supplies and services associated with Super Hornet family Engineering Change Proposal 6038. Supplies include 42 R2/R3 retrofit kits for the AN/APG-79 radomes. Radomes are the “nose cone” of the aircraft, engineered to protect the radar and take the punishment that comes from their position on the aircraft, while letting radar waves through efficiently.

Work will be performed at the Marion, VA (57%), and St. Louis, MO (43%), and is expected to be complete in August 2015 (N00019-11-G-0001).

Feb 29/12: +16. Raytheon Space and Airborne Systems in El Segundo, CA receives a $45.3 million firm-fixed-price contract modification to fund 16 AN/APG-79 radars, to be retrofitted into F/A-18E/F Block I aircraft that were built with AN/APG-73 radars during production lots 26-29.

Work will be performed in Forest, MS (43%); Dallas, TX (29%); El Segundo, CA (27%); and Andover, MA (1%), and is expected to be complete in December 2014. $8.4 million will expire at the end of the current fiscal year, on Sept 30/12 (N00019-09-C-0003).

This is Raytheon’s 4th refit contract, and brings the order total to 73 of the planned 133 fighter refits in that sub-program. As one might guess, most APG-79s are fitted into new Super Hornet family fighters on the production line.

Refits: 16 radars

Feb 13/12: Combat ID? Pentagon budget documents (US Navy RDT&E BA1-3) show that in 2011-2012 the Initiated Strike Accelerator R&D program aimed to:

“…provide an advanced airborne capability to accurately identify targets using Advanced Target Recognition (ATR). These capabilities are utilizing the F/A-18 E/F, AESA (Active Electronically Scanned Array) Radar and ATFLIR (Advanced Targeting Forward Looking Infrared [pod]) sensors…”

It’s an interesting and logical extension of known AESA capabilities, and using the ATFLIR pod’s long-range cameras and geolocation as an additional input also makes sense. If it works, it would certainly help pilots strike ground targets with greater assurance. The big question is whether the resolution and algorithms would also be fine enough to remove the biggest obstacle to effective combat use of medium-range air-to-air missiles: Rules of Engagement that require close-in visual ID, because electronic IFF (Identification, Friend or Foe) systems aren’t considered reliable enough to avoid all friendly fire.

Nov 22/11: #300. Raytheon announces the delivery of its 300th AN/APG-79 radar to Boeing, for integration on U.S. Navy and RAAF Super Hornet family fighters.

#300

May 13/11: +42. Raytheon announces a contract from Boeing for 42 APG-79 radars, to equip Super Hornet family aircraft bought in the 2nd year of the 2010-2013 Multi-Year III program. Raytheon doesn’t always announce these contracts, but they can be assumed whenever Super Hornet family aircraft are ordered.

They don’t give cost figures. Work will be performed at Raytheon facilities in El Segundo, CA; Andover, MA; Forest, MS; and Dallas, TX.

42 radars – Boeing contract

May 2/11: ECP. A $12.6 million cost-plus-fixed-fee order for one-time engineering work associated with Engineering Change Proposal 6381 re: the AN/APG-79’s General Purpose Processor 3, and for the purchase of 12 engineering development modules.

Work will be performed in El Segundo, CA (65%); Forest, MS (20%); and St. Louis, MO (15%). Work is expected to be complete in January 2012 (N00019-11-G-0001).

Nov 30/10: Support. A $17 million ceiling priced order for AN/APG-79 radar repairs. Work will be performed in Forest, MS, and is expected to be complete by June 2012. This contract was not competitively procured by the US Naval Inventory Control Point in Philadelphia, PA (N00383-10-G-005H, #0001).

Nov 16/10: +19. Raytheon Space and Airborne Systems in El Segundo, CA receives a $52.25 million firm-fixed-price contract modification for 19 AN/APG-79 AESA radars, to be retrofitted into F/A-18E/F aircraft Lots 26-29.

Work will be performed in Forest, MS (43%); Dallas, TX (29%); El Segundo, CA (27%); and Andover, MA (1%). Work is expected to be complete in December 2013. Raytheon’s release adds that: “This third retrofit contract brings orders for the update of block II F/A-18s up to 57.”

Refits: 19 radars

FY 2009 – FY 2010

200th radar delivered; 2nd retrofit radars contract; Processor upgrade.

Raytheon diagram
(click to view full)

July 21/10: #200. Raytheon announces that it has delivered is 200th APG-79 AESA radar to Boeing.

#200

April 8/10: +2. Raytheon Co. Space and Airborne Systems in El Segundo, CA received an $5.8 million delivery order against a previously issued basic ordering agreement for procurement of 2 AN/APG-79 AESA test radars for the F/A-18E/F and EA-18G aircraft.

Work will be performed in Forest, MS (45%), El Segundo, CA (35%), and Andover, MA (15%), and Dallas, TX (5%) and is expected to be complete in November 2011 (N00019-05-G-0008).

2 test radars

April 5/10: ECP. A $13.6 million cost-plus-fixed-fee delivery order against a previously issued Basic Ordering Agreement (N00019-05-G-0026) to complete the AESA waveform generator DDS II die parts obsolescence redesign engineering change proposal for the F/A-18 E/F aircraft.

Work will be performed in El Segundo, CA (87.7%), and St. Louis, MO (12.3%), and is expected to be complete in March 2011.

March 24/10: GPP. From FedBizOpps, solicitation #20047-10 deals with a reality of modern equipment. The equipment lasts long after the underlying electronics are completely obsolete. Imagine if your computer went 15 years without an upgrade. The USAF experiences that as an ongoing reality, for even longer periods. For the APG-79:

“The Naval Air Systems Command has a requirement for an engineering change to the AN/APG-79 Active Electronically Scanned Array (AESA)… upgrades the general purpose processor in order to support additional capability requirements. The AESA prime integrator is The Boeing Company, St. Louis, MO. The Navy intends to negotiate the engineering change as a sole source firm fixed price delivery order to the F/A-18 & EA-18G Basic Ordering Agreement with Boeing. Boeing will be responsible for the non-recurring and recurring engineering changes. Award of the delivery order will be made with authority under FAR 6.302-1, only one responsible source and no other supplies or services will satisfy agency requirements. Boeing has the requisite RADAR knowledge, experience, and technical data required to respond to this requirement. This notice of intent is not a request for competitive proposals.”

The result will almost certainly be a sub-contract to the radar’s manufacturer, Raytheon, but as noted above, Boeing owns final engineering responsibility.

Oct 7/09: ECP. Raytheon Space and Airborne Systems in El Segundo, CA received a $5.7 million modification to a previously awarded firm-fixed-price contract to perform engineering change proposal 6279. This will enhance the AN/APG-79 active electronically scanned array radar on a number of Lot 33 production aircraft: 14 F/A-18Es, 9 of the 2-seat F/A-18Fs, and 22 EA-18G Growler electronic attack aircraft.

Work will be performed in Forest, MS (42%); El Segundo, CA (36.8%); and St. Louis, MO (21.2%), and is expected to be complete in September 2011 (N00019-04-C-0014).

April 2/09: +19. Raytheon Co., Space and Airborne Systems in El Segundo, CA receives a $54.5 million firm-fixed-price contract for 19 AN/APG-79 active array radars. The radars will be retrofitted into F/A-18E/F Super Hornet aircraft built during Lots 26-29, replacing Raytheon’s mechanically-scanned APG-73 phased array radars.

Work will be performed in Forest, MS (43%); Dallas, TX (29%); El Segundo, CA (27%); and Andover, MA (1%) and is expected to be complete in December 2010. This contract was not competitively procured (N00019-09-C-0003).

As of Raytheon’s May 26/09 release, the firm had delivered 134 APG-79 radars for use in F/A-18 Super Hornet and EA-18G Growler aircraft, most of which have been slated for new aircraft. With this latest contract, orders for the APG-79 retrofits now total 38 of the planned 133 fighters. See also the related Dec 21/07 entry.

Refits: 19 radars

Oct 17/08: Support. An $11.2 million firm-fixed-price, definite-delivery/ definite-quantity modification under a previously awarded delivery order contract. The US Naval Inventory Control Point is buying APG-79 radar system spares.

Work will be performed in St. Louis, MO (40%); and El Segundo, CA (60%), and is expected to be complete by May 2011. This contract was not competitively procured (N00383-06-D-001J-0005).

FY 2007 – FY 2008

1st retrofit contract; Australia orders; R&D to expand capabilities; 100th radar delivered; 1st USN Super Hornet block II squadron declared ready.

F/A-18Es over Afghanistan
(click to view full)

Sept 25/08: Support. An $8 million cost plus fixed fee delivery order under previously awarded contract to repair AN/APG-79 radars. Work will be performed at El Segundo, CA (90%) and St. Louis, MO (10%), and is expected to be complete by September 2009. This contract was not competitively procured by The Naval Inventory Control Point (N00383-06-D-001J, #0004).

July 1/08: #100. The US Navy and its industry partners, Raytheon and Boeing, mark the 100th delivery of the APG-79 Active Electronically Scanned Array (AESA) Radar at a celebration in Forest, MS. NAVAIR release.

#100

March 31/08: Support. A $38.5 million firm-fixed-price, definite-delivery/ definite-quantity contract modification under a previously awarded basic ordering agreement. The firm will deliver new spares to support the AN/APG-79 AESA radar. Work will be performed in El Segundo, CA (90%) and St. Louis, MO (10%), and is expected to be complete by August 2010. This contract was not awarded competitively by the Naval Inventory Control Point (N00383-06-D-001J, #0004).

Dec 21/07: +19. Raytheon Space and Airborne Systems in El Segundo, CA received a $54.8 million firm-fixed-price contract for the procurement of 19 AN/APG-79 active electronically scanned array radars to be retrofitted into F/A-18E/F aircraft Lots 26-29. The radars will replace the APG-73 radars currently installed in the aircraft.

Deliveries were: LOT-26: 48 aircraft, LOT-27: 45 aircraft, LOT-28: 42 aircraft, and LOT-29: 42 aircraft, for a total of 177 aircraft. A total of 42 Low Rate Initial Production (LRIP) APG-79 radars were delivered for installation in the aircraft production line, and the remaining 135 (now 133) aircraft will be retrofitted. This contract mentioned above is the 1st of 5 projected annual contracts to retrofit those 135 Lot-26 and above F/A-18 E/Fs with the APG-79.

Work will be performed in Forest, MS (43%); Dallas, TX (29%); El Segundo, CA (27%); and Andover, MA (1%) and is expected to be complete in Dec. 2009. This contract was not competitively procured (N00019-08-C-0001).

Refits: 19 radars

Oct 17/07: APG-79B An $11.2 million order against a previously issued basic ordering agreement for the nonrecurring engineering to upgrade 210 AN/APG-79 Active Electronically Scanned Array radar to the APG-79B configuration (includes 114 retrofit and 96 production upgrades). All Raytheon would say is that the B configuration is “an approved engineering change for a hardware modification.”

Work will be performed in El Segundo, CA (95%) and St. Louis, MO (5%), and is expected to be complete in September 2011 (N00019-05-G-0026).

Future RAAF F/A-18F
(click to view full)

July 11/07: Support. A $7.6 million firm-fixed-price, definite-delivery/ definite-quantity delivery order under previously awarded contract on July 10/07, for new spare parts to support the F/A-18 AN/APG-79 (AESA) radar. Work will be performed in El Segundo, CA (9%) and St. Louis, MO (10%), and is expected to be complete by October 2008. This contract was not awarded competitively by the Naval Inventory Control Point (N00383-06-D-001J, #0002).

July 5/07: ECP. Boeing received a $90.2 million modification to a previously awarded firm-fixed-price contract (N00019-04-C-0014) for a newly developed, additional capability for the AN/APG-79 Active Electronically Scanned Array radar. Work will be performed in El Segundo, CA (95%) and St. Louis, MO (5%), and is expected to be complete in September 2011

While these exact capabilities were not disclosed, DID’s top bets would be either the “big SAR” wide angle surface scans that will now be part of the production F-35 Lightning, or limited electronic warfare capabilities.

May 16/07: ECP. A $7.4 million modification to a previously awarded firm-fixed-price contract for the redesign of 5 monolithic microwave integrated circuits utilized in the AN/APG-79 AESA radar. Work will be performed in El Segundo, CA (95%) and St. Louis, MO (5%), and is expected to be complete in December 2008. Contract funds in the amount of $6 million will expire at the end of the current fiscal year (N00019-04-C-0014).

May 5/07: Australian order. Australia’s DoD announces a contract for 24 F/A-18F Block II Super Hornets and associated support systems. This will mean accompanying export orders for the AN/APG-79. Read “Australia Buying 24 Super Hornets As Interim Gap-Fillers” for full coverage.

Jan 8/07: F/A-18E/F Block II. Boeing announces delivery of the 11th F/A-18E/F Super Hornet Block II to Naval Air Station (NAS) Oceana, VA. Boeing is delivering AESA-equipped Super Hornet Block II aircraft to 2 squadrons at NAS Oceana: the Black Lions of VFA-213 and the Gladiators of VFA-106. In addition, there are two AESA-equipped Block 2 Super Hornets attached to VFA-122, the Flying Eagles Fleet Replacement Squadron (i.e. training squadron), at NAS Lemoore, CA.

Oct 27/06: F/A-18E/F Block II. The “Black Lions” of VFA-213 squadron have transitioned from their F-14D Tomcats, and become the first AESA-equipped F/A-18E/F Super Hornet operational squadron to attain “safe for flight” status, which clears it to independently fly and maintain its state-of-the-art Block II aircraft. Source.

Fully operational

FY 2005 – FY 2006

Sub-contract for 190 radars; LRIP-3 order; Super Hornet Block II rolled out; Tests with AMRAAM, JDAM, and APG-73 equipped Super Hornet cohorts demonstrate increased firing range, real-time targeting, and coordinate passing to non-AESA fighters.

“Black Lions” F-14D:
transitioning out
(click to view full)

Sept 21/06: Support. Raytheon Co. Space and Airborne Systems in El Segundo, CA received an $11 million delivery order against a previously issued basic ordering agreement for system test equipment (STE) for the AN/APG-79 AESA radar for the F/A-18E/F and EA-18G aircraft. The STE will be used to test radar modules returned for repair to determine root cause of failures and to return the radars to the Fleet in a ready for issue status.

Work will be performed in El Segundo, CA and is expected to be complete in September 2009. Contract funds in the amount of $6.4 million will expire at the end of the current fiscal year (N00019-05-G-0008).

April 18/06: Testing. Boeing announces a successful demonstration of the F/A-18E/F Super Hornet Block II’s to provide targeting coordinates to other aircraft using the Raytheon APG-79 Active Electronically Scanned Array (AESA) radar system:

“During the test at the Naval Air Weapons Center at China Lake, Calif., an AESA-equipped F/A-18F created a long-range, high resolution synthetic aperture radar map and designated four closely-spaced stationary targets. The aircraft then data-linked two target designations to non-AESA equipped Super Hornets, which successfully delivered four 2,000-lb. Joint Direct Attack Munitions (JDAM). All four weapons impacted the targets within lethal distance. The targeting Super Hornet then used the AESA to provide highly detailed bomb damage assessments to confirm the hits.”

AN/APG-79 AESA Radar

Dec 5/05: Testing. Raytheon states that its a Super Hornet equipped with its APG-79 radar successfully delivered multiple JDAM GPS-guided smart bombs on target, using real-time targeting coordinates derived from a high resolution SAR (synthetic aperture radar) image taken by the radar. The tests were conducted at the U.S. Navy’s China Lake facility. They add that the release of multiple precision-guided weapons from a single radar SAR map is a first, and note integration with other equipment as well:

“To further demonstrate the synergy of the onboard Raytheon sensors, the JDAM test also employed the ATFLIR (Advanced Targeting Forward-Looking Infrared) system to provide imagery of the targeting area. Interfacing seamlessly with the APG-79, ATFLIR recorded the impact of the weapons against two diverse targets, confirming simultaneous weapon delivery while providing post-impact bomb damage information…

The program has also been highly successful during the recent air-to-air live fire demonstrations last month in which an AMRAAM was successfully deployed. This proved that weapons delivery from an AESA equipped F/A-18 can now be executed at ranges not possible before. “In the past, the weapon’s capability exceeded that of the aircraft. The missile could reach the target, but the radar couldn’t see it. Now, with the APG-79 radar, the aircraft’s capability exceeds that of the weapon, and this gives us an enormous advantage when prosecuting a mission,” said Capt. Aaron “Slime” Bowman, U.S. Navy AESA program manager for the F/A-18.”

Oct 31/05: Testing. Raytheon discusses the results of multiple live firing tests this month using inert AMRAAM and JDAM weapons. Both AMRAAM (Advanced Medium-Range Air-to-Air Missile) and JDAM (Joint Direct Attack Munition) live fire tests were successful at proving out the radar’s air-to-air and air-to-ground targeting capabilities. How does this work? Raytheon explains:

“The AMRAAM engages long-range targets after launch by incorporating targeting data from the APG-79 AESA. During flight the AMRAAM receives updated tracking/targeting information from the APG-79 AESA radar via data link from the launch aircraft… The JDAM “Smart Weapon” uses the APG-79 AESA radar to provide precise targeting coordinates. The pilot uses a high resolution SAR (synthetic aperture radar) image to identify the intended target. The target is designated from the image; the target coordinates are passed to the JDAM weapon; the weapon is released and flies under GPS navigation to impact, thus completing the kill chain. Prior to the introduction of the APG-79 radar, it has only been possible for pre-mission planned ground targets to be attacked. Now, with the Active Electronically Scanned Array (AESA) APG-79, real time, time sensitive ground targets can be identified and engaged.”

The APG-79 radar is currently in developmental flight testing and initial operational assessment. The program is expected to transition into OPEVAL (operational evaluation) on schedule in early 2006.

June 28/05: Main sub-contract. Raytheon Co. announces a $580 million, multi-year subcontract to deliver 190 AN/APG-79 AESA net-centric enabled radar systems for the Boeing Co. over the next 5 years, for installation in production F/A-18 E/F Super Hornet fighter planes. This successfully concluded negotiations for 190 radars from low rate initial production (LRIP) lots 3 & 4, through full rate production lots 1-3. These radars will serve as retrofits and also equip new fighters on the production line.

The first low rate initial production APG-79 AESA radar designed for the F/A-18E/F was delivered to Boeing IDS (Integrated Defense Systems) in January 2005. Following successful installation and testing, Boeing plans to deliver the first AESA-equipped F/A-18F to the U.S. Navy in April 2006. Sources: Raytheon release, June 29/05.

Boeing APG-79 production sub-contract: 2005-2010

June 23/05: +22. a $102.4 million modification to a previously awarded firm-fixed-price contract, exercising exercise an option for 22 AN/APG-79 low-rate-initial-production III (LRIP III) Active Electronically Scanned Array (AESA) radar systems for the F/A-18E/F Super Hornet aircraft. Work will be performed in El Segundo, CA (88%); St. Louis, MO (6%) and Marion, VA (6%), and is expected to be complete in December 2007 (N00010-03-C-0054).

LRIP-3: 22 radars

April 21/05: Rollout. Boeing debuts the F/A-18E/F Block II Super Hornet equipped with the APG-79 AESA radar system at a ceremony at Boeing’s St. Louis, MO facilities. The aircraft will be used as part of the AESA radar flight test program prior to entering Operational Evaluation (OPEVAL) in 2006.

The AESA radar, built by the Raytheon Corporation of El Segundo, CA is part of the F/A-18E/F Block II upgrade, which includes integration of advanced mission computers, high speed data network, cockpit controls and displays, environmental control system upgrade and forward fuselage affordability improvements. It works with several existing elements of the weapon system, such as the stores management system, the gun director, and AIM-120 and AIM-9 missiles, to enhance the lethality, survivability and affordability of the F/A-18E/F. The AESA radar and the Block II upgrades are being delivered under 2 multi-year contracts. Sources: Boeing release, April 21/05.

Super Hornet Block II rollout

FY 2001 – FY 2004

From concept, to 20 LRIP orders.

F/A-18F
(click to view full)

Feb 5/04: +12. A $61.8 million modification to a previously awarded fixed-price-incentive contract (N00019-03-C-0054), exercising an option for 12 AN/APG-79 low-rate initial production II (LRIP II) AESA radar systems for the F/A-18E/F Super Hornet aircraft. Work will be performed in El Segundo, CA (70%); St. Louis, MO (25%); and Marion, VA (5%), and is expected to be complete in September 2006. Boeing’s release adds that:

“Production of the LRIP2 radar is scheduled to begin March 2004, with delivery of the first LRIP2 radar-equipped aircraft scheduled for December 2005. The radars will be installed in selected two-seat “F” model Super Hornets. The radar system currently is undergoing evaluation testing at Naval Air Systems Command, China Lake, Calif.”

LRIP-2: 12 radars

Sept 3/03: +8. A $49.5 million fixed-price-incentive contract for 8 AN/APG-79 low-rate-initial-production AESA radar systems for the F/A-18E/F Super Hornet aircraft (q.v. Jan 15/03). Work will be performed in El Segundo, CA (70%); St. Louis, MO (25%); and Marion, VA (5%), and is expected to be complete in September 2006 (N00019-03-C-0054).

Boeing’s release adds that: “Production of the LRIP1 radar could begin as soon as next month, with delivery of the first LRIP1 radar scheduled for early 2005.”

LRIP-1: 8 radars

June 30/03: Testing. An F/A-18 Super Hornet test aircraft carrying the APG-79 Active Electronically Scanned Array radar system completes several test flights with the radar operating at Naval Air Systems Command China Lake, CA. They are the first test flights with this AESA radar. Boeing release.

Jan 15/03: A $14 million ceiling-priced order against a previously awarded basic ordering agreement (N00019-97-G-0037) to buy Time Critical Parts for 8 low-rate initial production AN/APG-79 AESA radars for the F/A-18E/F Super Hornet. Work will be performed in El Segundo, CA (90%) and St. Louis, MO (10%), and is to be complete in June 2003.

Nov 20/02: Radar Rollout. Boeing and subcontractor Raytheon roll out integrated APG-79 Active Electronically Scanned Array (AESA) radar in a ceremony at Raytheon facilities in El Segundo, CA. Boeing release | Raytheon release.

AN/APG-79 rollout

Feb 8/01: A $324.5 million cost-plus-fixed-fee, award-fee contract for the design, development, fabrication, integration, installation and test of 5 full and 2 partial AN/APG-79 Active Electronically Scanned Array (AESA) radar engineering development models for the F/A-18E/F Super Hornet aircraft.

Work will be performed in St. Louis, MO (59%) and El Segundo, CA (41%), and is expected to be complete by January 2006. This contract was not competitively procured (N00019-01-C-0074).

APG-79 development contract

Additional Readings

DID would like to thank Raytheon personnel for their insights and interviews. Special thanks are due to Larry Seeley and Kevin Gabriel.

• Raytheon – AN/APG-79 AESA Radar. See also Raytheon AN/APG-79 Product brochure [PDF, 2007 capture]

• Raytheon – Raytheon’s Revolutionary AESA Technology. Includes links to their various AESA radar designs and capabilities, and adds as a list of related press releases at the bottom. Raytheon’s AESA fighter radars fly on the USA’s F/A-18 Super Hornet (APG-79) and F-15 Eagle/ Strike Eagle (APG-63v2-3, APG-82) fleet.

• Northrop Grumman – AESA Radar: Revolutionary Capabilities For Multiple Missions [PDF format]. Details a number of the radar type’s characteristics that make it special, and offers insights into some of the developments within the AESA field. NGC makes AESA fighter radars for the F-16 Block 60 (APG-80), F-22 (APG-77), and F-35 (APG-81) platforms.

• DID (Dec 18/05) – AESA Comlinks. Dr. Carlo Kopp has already done a fair bit of work in the field, beginning with his PhD thesis in Melbourne in 1999.

• Aviation Week & Space Technology (Dec 11/05) – Talking Radars.

• DID (Oct 24/05) – Supersonic SIGINT: Will F-35, F-22 Also Play EW Role?

• Australian Aviation (June 2002) – Active Electronically Steered Arrays: A Maturing Technology.

Related Super Hornet Contracts

• DID FOCUS Article – Super Hornet Fighter Family MYP-III: 2010-2013 Contracts.

• DID Spotlight Article – The USA’s 2005-2009 Multi-Year Hornet Procurement Contract.

• DID FOCUS Article – EA-18G Program: The USA’s Electronic Growler.

• DID Spotlight Article – Australia Buying 24 Super Hornets As Interim Gap-Filler to JSF. They will be 2-seat F/A-18F Block II aircraft, with the APG-79.

These photographs show some pretty interesting details of the iconic Stealth Jet. As often reported here at The Aviationist, some F-117 Nighthawk stealth jets out of Tonopah Test Range continue to zip through the Nevada [...]

Americas

Bell Textron won a $30.4 million order, which provides non-recurring engineering and integrated logistics support to produce and qualify the structural improvement and electrical power upgrade solution for the UH-1Y Venom and AH-1Z Viper aircraft. This order provides for the integration of structural improvements and power upgrades, as well as the development of technical data and supporting documentation as it pertains to reliability, maintainability, damage limits and tolerances.  Additionally, this order provides for the manufacture and delivery of two drives system accessory power quills, one modified combining gearbox, one test stand upgrade, as well as associated component qualification testing. The UH-1Y utility helicopter provides command & control and assault support under day/night and adverse weather conditions. The AH-1Z attack helicopter provides rotary wing close air support, anti-armor, armed escort, armed/visual reconnaissance and fire support coordination capabilities under day/night and adverse weather conditions. Work will take place in Texas, Michigan and Arizona. Estimated completion will be in December 2022.

The Navy and Marine Corps have found the amphibious assault vehicle that sank off the coast of California last week as well as the remains of those killed in the incident. The services used a remotely operated search and rescue system to find the vehicle, which sank July 30 during a training exercise, killing eight Marines and a Sailor. According to the Marine, According to the Marines, the Navy, Marine Corps and Coast Guard ships and aircraft had been working together to find the vessel. The AAV sank to a depth of 385 feet during a shore-to-ship maneuver about 1,500 meters off the coast of San Clemente Island.

Middle East & Africa

F-35As from the US Air Force have participated in the second joint exercise with Israeli F-35s on August 2. The training between the 421st Expeditionary Fighter Squadron and Israel’s 140th Squadron took place over southern Israel. The fighters were supported by a KC-10 from the 908th Expeditionary Air Refueling Squadron and a G550 from Israeli Air Force 122 Squadron.

Europe

Martin Baker won a maximum $150 million contract for T-6 and T-38 Sustainment. This contract provides for T-6 and T-38 replenishment spares. The T-6A Texan II is a single-engine, two-seat primary trainer designed to train Joint Primary Pilot Training, or JPPT, students in basic flying skills common to US Air Force and Navy pilots.The T-38 Talon is a twin-engine, high-altitude, supersonic jet trainer used in a variety of roles because of its design, economy of operations, ease of maintenance, high performance and exceptional safety record. Work will take place in Uxbridge, UK and is expected to be finished by December 31, 2026.

The first ever Luftwaffe Eurofighter training detachment while embedded with a Royal Air Force (RAF) contingent that is deployed to Lithuania as part of the NATO Baltic Air Policing Mission has concluded. Pilots from RAF Lossiemouth-based 6 Sqn RAF flew with pilots from the German Tactical Fighter Wing 71 Richthofen to practice air intercepts and basic fighter maneuvers together as a pair. Both sides will reverse roles in September when the British will embed with a German detachment in Amari, Estonia.

Asia-Pacific

Lockheed Martin won an $181.7 million contract modification, which provides for the production, delivery and integration of 24 Airborne Low Frequency Sonars (ALFS) for the government of India; eight ALFS for the Navy and seven ALFS for the government of Denmark, into MH-60R Seahawk aircraft. The ALFS is the primary undersea warfare sensor of the MH-60R multi-mission helicopter. This integrated dipping sonar system enables the MH-60R to accomplish the assigned ASW missions of submarine detection, tracking, localization and classification. It also performs missions relating to acoustic intercept, underwater communications and environmental data acquisition. Work will take place in Rhode Island and New York. Estimated completion will be by December 2024.

Today’s Video

Watch: U.S AIR FORCE IS READYING ‘GOLDEN HORDE’ SWARMING WEAPON TO TAKE OUT ENEMY TARGETS !

Chinese VME-102-40 Armored Recovery Vehicle

Chinese GCZ-110 Armored Engineer and Recovery Vehicle

Having to let go of something close, doesn’t need to have a sense of loss. When the European Defence Agency (EDA) sees its home-grown Helicopter Exercise Programme, its Helicopter Tactics Course and its Helicopter Tactics Instructors Course move to the new permanent Multinational Helicopter Training Centre (MHTC) in Portugal by the end of 2022, after many successful years at EDA, it does so with a feeling of ‘mission accomplished’.  

This article as well as the following interview with João Gomes Cravinho, the Defence Minister of Portugal, have first been published in EDA's 'European Defence Matters' magazine N° 19 published in June 2020. 

It is a basic principle underlying all training activities run by EDA: as soon as a programme reaches a sustainable level of support, maturity and output, the aim becomes to transfer it to a permanent facility hosted and managed by one of Member States involved. For the Agency’s ambition is not to become a permanent training institute but to serve as a catalyst and facilitator for collaborative training activities which later on will be taken care of by a Member State or an organisation – allowing the Agency to free resources and engage in other training projects.   The move in June 2017 of EDA’s European Air Transport Fleet training programme to the new permanent European Tactical Airlift Centre (ETAC) in Zaragoza/Spain, after six years of busy activities at EDA – 87 aircrews trained, 50 tactical instructor pilots graduate, 94 European transport aircraft involved – stands out as a shining example of this policy.   It will be followed soon by the Agency’s three multinational rotary-wing training programmes: the Helicopter Exercise Programme (HEP), the Helicopter Tactics Course (HTC) and the Helicopter Tactics Instructors Course (HTIC). Launched in 2009 and supported by 15 countries (Austria, Belgium, the Czech Republic, Germany, Greece, Finland, Hungary, Italy, Luxembourg, the Netherlands, Portugal, Sweden, Slovenia, Norway as well as the United Kingdom – up till Brexit), this trio has since become one of EDA’s most dynamic and successful training activities, highly appreciated in Europe’s rotary wing community.   By the end of 2022, their new home will be Sintra/Portugal: that’s what the Agency’s Steering Board decided in August 2019 when it green-lit the setting-up of a new Multinational Helicopter Training Centre (MHTC). 

 

A new permanent home 

The objective is to make this MHTC a permanent European centre of excellence for advanced helicopter training. It will deliver administrative and training functions to serve both as a central hub for the coordination of helicopter training across Europe, but also as the provider of the next iteration of the HEP, HTC and HTIC programmes currently run by the Agency.   

The centre is expected to reach initial operational capability (IOC) by the end of 2022, although the Covid-19 crisis impact may alter this date, and it is estimated it will operate for a period of 15 years, which can be extended to 30 years following the agreement of its contributing Member States. 

The next major milestone in the preparation is the harmonisation of the MHTC Technical Agreement, expected by the beginning of 2021, and the build-up of the infrastructures in Sintra which should be finished before the IOC MHTC. 
 

Gradual hand-over starting this summer 

The move to Sintra will be gradual, starting soon – this summer with the transfer of EDA’s helicopter training centre from its traditional location, RAF airbase Linton-on-Ouse in the United Kingdom (in the process of being dismantled), to Sintra Air Force airbase which will already be operational, on a provisional basis, between mid-2020 and the end of 2022 when it will fully take over its new MHTC role. The full set of training equipment will be moved from Linton-on-Ouse to Sintra, except the helicopter simulator which is being replaced with a new one.  

  

"An opportunity to strengthen European cooperation" 

Portugal is actively preparing to host the MHTC which it considers a priority and “strategic investment”, says the country’s Minister of Defence, João Gomes Cravinho, in an exclusive interview with European Defence Matters. 
 

How are preparations going for the transition of the current EDA helicopter programmes to Sintra in 2020 and for the creation of the MHTC in 2022? 

Currently, and until 2023, EDA helicopter programmes will take place in Sintra as part of a transition process for MHTC while ensuring the continuity of all EDA helicopter training. Portugal has received the helicopter simulator formerly based in the UK and will provide support for academic and simulator courses in existing infrastructures, specially adapted for that purpose, while the MHTC project is under development. Since November, multiple site surveys have been made in Sintra to check the current infrastructures. The flight simulator hardware is already in Portugal, waiting for INZPIRE representatives to be able to travel to Portugal and start the required assembly as soon as possible. Of course, we and all the other countries involved in the Agency’s helicopter training have also been affected by the Covid-19 pandemic which has required partial and full lockdowns, including in Portugal. This resulted in the cancellation of two courses, planned for May and June 2020. Nevertheless, Portugal has been actively engaged with EDA and Member States to mitigate the impact of Covid-19 in the helicopter programmes. In close coordination with Member States a contingency plan has been agreed that should allow these courses to take place in the future.  
 

What makes Sintra the perfect site for it? 

Sintra is being turned into the rotary wing hub of the Portuguese Air Force that is expected to be fully operational by 2023. We hope this will provide relevant synergies, and this is in itself proof that we believe Sintra is indeed a great location for this type of infrastructure. There are large modular spaces adapted to the needs of a structure like this. The accommodation, the courses and the simulator area will, of course, be in accordance with EDA’s requirements and will all be within easy walking distance of catering and leisure spaces. Additionally, because there is more to life than work, the air base is very close to the historic town of Sintra, to Lisbon and to the beaches of Cascais, meaning there is no lack of opportunities for leisure or physical exercise in the vicinity. 
 

How big an effort (infrastructure, staff, budget, etc.) is this for Portugal to become the host nation of this important training activity? 

The Portuguese government is committed to a responsible management of the State budget, but we are also committed to strategic investments. We see the MHTC project as an opportunity to strengthen European cooperation in addressing a key operational capability that has often been found lacking and is vital to provide support to ongoing and future CSDP missions. Once Full Operational Capability is achieved, Portugal has committed, through the Portuguese Air Force, to support not only the infrastructure exclusively dedicated to the MHTC academic and simulator courses, but also all student logistical support (lodging, meals). Regarding staff, the MHTC will have ten permanent positions, plus temporary personnel responsible for the academic and simulator courses. In principle, the Portuguese Air Force will be responsible for about 50% of these permanent posts, with full time dedicated personnel. We are currently assessing the best options for hosting our foreign partners involved in permanent posts in the MHTC. In conclusion, this is a significant effort, but we see it as a priority, as a strategic investment. 
 

How will this influence Portugal’s own involvement in EDA’s helicopter programme where it currently participates in the Helicopter Exercise Programme (HEP) and the Helicopter Tactics Course (HTC). Any plan to join the Helicopter Tactics Instructors Course (HTIC)? 

The involvement of the Portuguese Air Force in EDA’s helicopter programmes (HEP and HTC) has been very successful in developing and consolidating rotary wing operational capabilities. Portugal is currently not involved in the HTIC, but this is an interesting programme and will be considered in future discussions regarding available investment in this area.  
 

Portugal is a very regular host of the BLADE multinational helicopter exercises, at least during the 2012-2022 period. Will you remain central and host of this exercise even beyond 2022? 

We are working on it. As you know, we are the organiser of the BLADE exercise in 2021. And Portugal in fact holds the record as the host country for BLADE exercises. I believe this is the result of Portugal’s ability to organise these exercises effectively, as well as the fact that it has, in relative terms, a very flexible airspace and ideal meteorological conditions. Portugal has made clear its availability for hosting the BLADE helicopter exercises in 2024, 2027 and 2030. Now it is up to EDA and the other Member States to decide, but Portugal is very committed to continuing to invest in cooperation with its European allies and partners in this vital operational capability. 

 

 

 

Amid an ever-widening crackdown on opposition voices and activism in Hong Kong, city leaders met on Tuesday to discuss postponing September's legislative elections, as the University of Hong Kong (HKU) fired a democracy activist and prominent legal scholar for "misconduct."

Germany, as part of the European Union's reaction to China's national security law for Hong Kong, will stop exporting weapons and dual-use goods to the region, German Foreign Minister Heiko Maas said.

The US Consulate General in the Chinese city of Chengdu was shut down on 27 July following an order from Beijing, according to the country's Foreign Ministry.

US Secretary of State Mike Pompeo in an address in London last week proposed an international coalition against China. Meanwhile, considering India's border conflict with Beijing, Washington has offered steadfast support and cooperation to New Delhi over the past few weeks.

Disappeared for calling China's authoritarian leader Xi Jinping a "clown," Chinese property tycoon Ren Ziqiang has been kicked out of the Communist Party and now faces a criminal investigation that could end with prosecution.

Chinese President Xi Jinping on Tuesday reiterated China's support for the global multilateral system and commitment to pursue development with the rest of the world in the spirit of openness and mutually-beneficial cooperation, in what Chinese analysts called an apparent rebuttal of a rising tide of unilateralism and anti-globalization amid the COVID-19 pandemic.

Chinese State Councilor and Foreign Minister Wang Yi on Tuesday said that China will make firm and rational responses against the US whose behaviors are outrageous and unreasonable.

The increasing tensions between China and the US, the worsening COVID-19 epidemic situation, as well as the declining approval ratings of US President Donald Trump have raised concerns, among strategists and experts, of a military conflict between the two nuclear-armed powers caused by the dangerous US attempts.

New Zealand on Tuesday announced the suspension of its extradition treaty with Hong Kong, the fourth country to do so in the Five Eyes intelligence alliance, but Chinese analysts warned on Tuesday Wellington not to play petty tricks, hoping to show loyalty to the anti-China coalition without damaging bilateral ties with Beijing.

China on Tuesday expressed strong opposition to New Zealand's wrong move of suspending its extradition treaty with the Hong Kong Special Administration Region (HKSAR), which is based on the wrong interpretation of the national security law for Hong Kong, and reserves the right to further respond.

China's aircraft carrier-based J-15 fighter jets have now become capable of conducting nighttime buddy refueling, one of the most challenging tactical moves by carrier-borne fighter jets, the PLA Navy revealed after recent successful exercises.

China on Tuesday announced the suspension of extradition treaties and agreements on mutual assistance for criminal matters between the Hong Kong Special Administration Region (HKSAR) and Canada, Australia and the UK in response to the three countries' interference in China's domestic affairs.