John Cockerill announces exclusive negotiations with Volvo Group for the acquisition of Arquus, a frontrunner in France’s military vehicle manufacturing

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  October 31, 2019 | International, Aerospace

  As Era Of Laser Weapons Dawns, Tech Challenges Remain

  Steve Trimble As the U.S. Air Force comes within weeks of the first operational laser weapons, the Defense Department is hatching new concepts to address the power and thermal management limits of the state-of-the-art in the directed energy field. In a largely secret dress rehearsal staged last week at Fort Sill, Oklahoma, the Air Force performed another round of tests of the deploying Raytheon High Energy Laser Weapon System (HEL-WS), as well as other directed energy options, such as the Air Force Research Laboratory's Tactical High Power Microwave Operational Responder (THOR), says Kelly Hammett, director of AFRL's Directed Energy Directorate. “All I can say is there were multiple systems. From my reading of the reports, it looked like a very successful exercise,” says Hammett, who addressed the Association of Old Crows annual symposium Oct. 29. The Fort Sill experiment was intended to put the weapons through their paces in a realistic operational environment. AFRL's Strategic Development, Planning and Experimentation (SDPE, which, despite its spelling, is pronounced “Speedy”) office called on the HEL-WS and THOR to engage swarms of small unmanned aircraft systems (UAS). The experiments also demonstrated new diagnostic tools, allowing AFRL testers to understand the atmosphere's effect on energy propagation in real time. SDPE awarded Raytheon a contract in August to deliver a “handful” of systems to the Air Force for a one-year deployment scheduled to conclude in November 2020. The HEL-WS will be used to defend Air Force bases from attacks by swarming, small UAS and cruise missiles, Hammett says. The Air Force is not releasing the location of the deployed sites for the HEL-WS. AFRL also is grooming THOR for an operational debut. Instead of blasting a UAS with a high-energy optical beam, THOR sends powerful pulses of radio frequency energy at a target to disable its electronics. Hammett describes THOR as a second-generation directed energy weapon. It is designed to be rugged for operational duty and compact enough to be transported inside a single container loaded into a Lockheed Martin C-130. Upon unloading from the aircraft, THOR can be activated within a couple hours, or broken down and moved within the same period, he says. Despite decades of basic research on directed energy systems, such operational capabilities have evolved fairly rapidly. The Air Force finally consolidated its strategy for developing directed energy weapons in the 2017 flight plan, Hemmett said. The document narrowed a once-fragmented research organization that attempted to address too many missions. “Directed energy zealots like myself have been blamed, rightly so, of saying directed energy can do almost anything you want it to do. And we pursued multiple applications to the effect that we were diffusing some of our efforts,” he says. The 2017 flight plan selected three initial use cases: Air base defense, precision strike and self-protect. The HEL-WS and THOR are addressing the first mission. The Joint Navy-Air Force High Power Electromagnetic Non-Kinetic Strike (Hijenks) program is developing a missile to address the precision strike requirement, as a follow-on to the Counter-electronics High Power Microwave Advanced Missile Project (Champ) that concluded five years ago. In the long-term, AFRL also plans to demonstrate the Self-Protect High Energy Laser Demonstrator (Shield), a podded defensive weapon for aircraft. Although such technology has come far, researchers are still grappling with fundamental issues to make them practical. Namely, the power generation and thermal management requirement for high-energy lasers and high-power microwaves remains a challenge. “If you're willing to have very limited duty-cycle, very limited magazine, the power and thermal management aren't very challenging,” Hemmett says. “Of course, that's not what we want from directed energy weapons. We want deep magazines. We want to be able to handle wave attacks as favorably or more favorably that kinetic weapons.” The “rule of thumb” for a high-energy laser is an efficiency of about one-third, meaning a 300-kW generator is necessary to create a 100-kW laser beam, resulting in 200 kW of waste heat that must be dealt with in some way, says Frank Peterkin, a senior technologist on directed energy for the U.S. Navy who spoke at the same event. On Navy ships, that puts the laser in competition with the electronic warfare and radar subsystems for power and thermal management loads, he adds. “The challenge for the directed energy community is we don't really own the solution,” Peterkin says. “It does need to be a more holistic solution for the Navy. We are a customer, but we're not driving the solution, per se.” Although directed energy researchers cannot design the power grids for bases, ships and aircraft, they can help the requirement in other ways, says Lawrence Grimes, director of the Directed Energy Joint Transition Office within the Defense, Research and Engineering directorate of the Office of the Secretary of Defense. The development of special amplifier diodes for fiber optic lasers are breaking the “rule of thumb” for high-energy systems, Grimes says. “They actually operate at higher temperatures and higher efficiency, so they can reduce the requirement necessary for the prime power and thermal management, and we're not throwing away 200 kW.” Other Defense Department organizations are pursuing more ambitious options. The Strategic Capabilities Office is selecting suppliers to demonstrate small, 10 MW-size nuclear reactors, as a power generation option for directed energy weapons at austere forward operating bases. Meanwhile, AFRL also is considering space-based power generation. Under the Space Solar Power Incremental Demonstrations and Research program, AFRL will investigate using high-efficiency solar cells on a spacecraft to absorb the solar energy. The spacecraft then would convert the solar energy into a radio frequency transmission and beam it to a base to supply energy. AFRL has awarded Northrop Grumman a $100 million contract to begin developing the technology. If those seem like long-term options, the Air Force is not immediately concerned. The HEL-WS and THOR are designed to use “wall-plug” power or the military's standard electric generators, Hammett says. https://aviationweek.com/defense/era-laser-weapons-dawns-tech-challenges-remain

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  June 12, 2019 | International, Aerospace, Security, Other Defence

  Air Force gets new stopgap system for GPS 3 satellites

  By: Nathan Strout The U.S. Air Force's first next-generation GPS satellite launched in December and the second GPS III satellite is slated to liftoff in July. But there Air Force has a problem: The ground system currently in use isn't fully capable of controlling GPS III satellites. Worse, a new ground system that can, formally known as the next-generation operational control system (OCX), is five years behind schedule and won't be delivered until June 2021 at the earliest, according to the Government Accountability Office. Enter the GPS III Contingency Operations (COps) software—a critical stop gap measure that will update the current ground control system and allow it to access some of the more advanced features of the GPS III satellites until the next-generation operational control system is ready. On July 11, primary contractor Lockheed Martin announced that it had delivered the COps upgrade to the Air Force. “Positioning, navigation and timing is a critical mission for our nation and COps will allow the Air Force to gain early access to its new GPS III satellites,” said Johnathon Caldwell, Lockheed Martin's vice president for Navigation Systems. “We just finished final qualification testing and delivery on COps, and it will be integrated and installed on the [Architecture Evolution Plan Operational Control System] over the summer. We look forward to the Air Force ‘flying' a GPS constellation on the COps OCS which includes the new GPS III satellites, later this year.” The new GPS III satellites are built to be more robust and accurate than their predecessors and come with advanced features such as the ability to use M-Code, an encrypted GPS signal for use by the military. The COps upgrade will allow the current ground system to control the GPS III satellites as well as the legacy GPS satellites. It will also allow the current system to access M-code Early Use, an encrypted GPS signal with improved anti-jamming and anti-spoofing capabilities, beginning in 2020. The Air Force contracted with Lockheed Martin to deliver the patch in 2016, the same year that the OCX program triggered a Nunn-McCurdy cost breach—a type of violation caused by significant cost growth that requires a program to be shut down unless the Department of Defense intervenes and approves a new cost estimate. The $6.2 billion OCX program is already five years behind schedule, and a May 21 Government Accountability Office report warned that the OCX program could be delayed even further. In addition, the Air Force has acknowledged that delays are possible during the seven-month testing period following delivery. Raytheon, the primary contractor behind OCX, rejected the GAO report, claiming that its findings were inaccurate. https://www.c4isrnet.com/battlefield-tech/c2-comms/2019/06/11/air-force-gets-new-stopgap-system-for-gps-3-satellites/

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  August 19, 2019 | International, Naval

  Lockheed nets $80M contract for Aegis system upgrades

  By Ed Adamczyk Aug. 16 (UPI) -- Lockheed Martin received an $80 million contract from the U.S. Navy for electronic equipment upgrades to the Aegis missile system, the Pentagon announced. The new contract modification, announced Thursday by the Department of Defense, calls for Lockheed Martin's Rotary and Mission Systems division to cover the production, test and delivery of multi-mission signal processor equipment sets, electronic equipment fluid coolers, AEGIS Weapon System AMOD [Aegis Modernization] upgrade equipment and Kill Assessment System equipment and spare parts. The deal calls for the Navy to underwrite 78.1 percent of the expenses, with Australia and Japan, where some of the equipment is located, to pay for 21.9 percent. The Aegis Combat System is an integrated naval weapons system using radar and computer technology to track and guide weapons in destroying enemy targets. The project was started by the U.S. Navy in 1964 to defend ships from missile threats, and with constant upgrades is now a feature on over 100 U.S. and NATO ships, as well as those of Australia, Norway and South Korea. It is also an integral part of NATO's European missile defense system. In July, Lockheed Martin was awarded a $22.5 million modification to a prior contract for integration and delivery of the Aegis Baseline 9 weapons system. It called for the modernization of existing U.S. Navy systems using open architecture principles and software upgrades to increase the lethality of the surface Navy. Through the improvements, newer and more powerful missiles can be fired from ships, and the use of the latest Aegis weapons systems capabilities can be used against air and missile threats, the Navy said. Work on the contract is expected to be finished by 2023. https://www.upi.com/Defense-News/2019/08/16/Lockheed-nets-80M-contract-for-Aegis-system-upgrades/6591565971398/