April 20, 2020 | International, Aerospace, Naval, Land, C4ISR
Aaron Mehta
WASHINGTON — The U.S. and Japan need to expand their collaboration on defense technologies in the future, with a specific focus on four technologies that can help counter the rise of China, according to a new report released Friday by the Atlantic Council.
The report also highlights the ongoing discussions about U.S. involvement in Japan's next domestic fighter program as a high-stakes situation that could dictate industrial cooperation between the two nations for years.
“The most important component of cooperation on defense capabilities is direct coordination and collaboration on emerging technologies and capabilities,” write authors Tate Nurkin and Ryo Hinata-Yamaguchi, identifying unmanned systems, hypersonic/hyper-velocity missiles, and the defense applications of AI as three key areas where the U.S. and Japan need to start working together on.
“These three areas are at the center of the intensifying U.S.-China military-technological competition. They are key to challenging or upholding military balances and stabilizing imbalances in and across key domain-area competitions — strike versus air and missile defense or undersea — on which regional and, over time, global security is at least partly based,” the authors note.
Specifically, the authors identify four project areas that both fit into U.S. strategy and Japan's regional interests, while also matching industrial capabilities:
That all sounds good on paper, the authors acknowledge, but there are very real challenges to increasing technology development between the two countries.
Japan's modernization priorities are best viewed through a defensive lens, designed to protect the island nation. That's a contrast to America's posture in the region, which tends more towards force projection. In addition, Japan lags in military space and cyber operations compared to the U.S., making cross-domain collaboration challenging in several areas.
Those negotiations have also been impacted by “different perceptions of the nature of joint technology research,” the authors write. “U.S. defense officials have ‘emphasized operational concepts and capability requirements as the basis for collaboration,' while Japanese officials have ‘continued to focus on technology development and industrial base interests.'”
Other challenges include Japan's 1 percent-of-GDP cap on defense spending, as well as the state of Japan's defense industry, which until 2014 was focused entirely on serving the Japanese government's needs. Hence, the industry, while technically very competent, is also relatively small, with limited export experiences – and Tokyo has an interest in protecting that industry with favorable contracts.
Meanwhile, U.S. firms have concerns about “potentially losing revenue, transfer of sensitive technologies, and the potential replacement of US companies with Japanese ones in critical supply chains,” the authors write.
Some of those issues have come to the forefront in the ongoing discussions about what role American firms can play in Japan's ongoing fighter development program. Japan recently rejected an offer by Lockheed Martin of a hybrid F-22/F-35 design, stating that “developing derivatives of existing fighters cannot be a candidate from the perspective of a Japan-led development.”
Getting the F-3 deal right will have long term implications for how the two nations develop capabilities together, the authors warn, quoting defense analyst Gregg Rubinstein in saying “Successfully defining a path to U.S.-Japanese collaboration on this program could make the F-3 an alliance-building centerpiece of cooperative defense acquisition” while failure to do so could “undermine prospects for future collaboration in defense capabilities development.”
Putting aside the internal issues, any collaboration between the U.S. and Japan has to be considered through the lens it will be see in Beijing and, to a lesser extent, Seoul.
“Even marginal differences in perception produce limits to the parameters of U.S.-Japan joint development of, and coordination on, military capabilities. Especially provocative programs like joint hypersonic-missile development will be viewed as escalatory, and will likely generate a response from China,Russia, and/or North Korea that could complicate other trade or geopolitical interests that go beyond Northeast Asia,” the authors warn, noting that China could attempt to exert more pressure on the ASEAN nations as a counterweight.
Additionally, South Korea would likely “see substantial U.S.-Japan collaboration not through an adversarial lens, but certainly through the lens of strained relations stemming from both historical and contextual issues, further complicating U.S.-Japan-Republic of Korea trilateral cooperation.”
July 24, 2023 | International, C4ISR, Security, Other Defence
The 13th Marine Expeditionary Unit spent seven months in the vast region experimenting with different technologies and platforms.
September 29, 2020 | International, Aerospace, C4ISR
Nathan Strout A developmental robot pilot that transforms manned aircraft into unmanned systems is flying again after the Air Force Research Laboratory took its ROBOpilot out for a test flight at Dugway Proving Ground, Utah, Sept. 24. ROBOpilot's name belies the simplicity of the program. In order to turn a manned aircraft into an unmanned one, AFRL simply replaces the human pilot with a robot who interacts with the aircraft controls the same way a human would: it can pull the yoke, press pedals to control rudders and brakes, adjust the throttle and flip switches. In addition to the robot's own internal GPS and inertial measurement unit, the system scans the gauges on the dashboard for information about the aircraft and its position, processing that information with a computer to independently fly the plane. Importantly, ROBOpilot requires no permanent modifications. All operators need to do is remove the pilots' seats and replace them with ROBOpilot. And if users determine that they want to return the aircraft to a manned mission, ROBOpilot is simply removed and the pilots' seats are reinstalled. The robotic system is the result of a Small Business Innovative Research (SBIR) award granted to DZYNE Technologies by the AFRL's Center for Rapid Innovation (CRI). Despite a successful first flight in August 2019, the system was later grounded after it maintained damage during a landing mishap. “The CRI and DZYNE team analyzed the findings and incorporated the recommendations to ensure the success of this latest test,” said Marc Owens, CRI's program manager for ROBOpilot. “We determined the cause of the mishap, identified the best course of corrective action and we're very pleased to be flight testing again.” Since then, ROBOpilot has been cleared to fly again and installed in a new Cessna 206. On Sept. 24, the system returned to the skies for a 2.2 hour test flight over Utah. “Since this is a completely new build with a different Cessna 206, we re-accomplished the flight test points completed on our first flight last year,” Owen explained. “ROBOpilot is too good an idea to let the mishap derail the development of this technology.” https://www.c4isrnet.com/unmanned/2020/09/28/the-air-forces-robot-pilot-returns-to-the-skies/
May 29, 2020 | International, Aerospace
Berwyn, Pa., May 26, 2020 /PRNewswire/ - Triumph Group, Inc. [NYSE: TGI] announced that Triumph Systems & Support was recently awarded a six-year contract extension for maintenance, repair and overhaul (MRO) services on an international CH-47 Chinook fleet. Triumph's Systems, Electronics and Controls operating company will provide product repair and overhaul services for the fleet's EMC-32T hydromechanical fuel control, technical support and product investigations as part of the long-term agreement. The company will deliver the MRO services out of its West Hartford, Connecticut repair station. The site also designs and manufactures the EMC-32T hydromechanical fuel control unit in addition to offering MRO services for the engine component. "We are honored to be awarded another contract that demonstrates our repair and technical expertise on the Chinook engine fuel control," said Tony Ziotas, President of Triumph Systems & Support – Systems, Electronics and Controls. "Our fuel control products and services are designed to lower cost of ownership and increase time on wing for Chinook operators." Triumph has provided MRO services for engine components for the 60 Chinook aircraft in the customer's international fleet since 2014. This long-standing support of the platform reinforces the company's commitment to supporting the warfighter's mission both at home and abroad with best-in-class service. Triumph Systems & Support's Systems, Electronics and Controls (SEC) operating company designs, develops, manufactures and services fuel pumps, fuel metering units and electronic control systems. They maintain a unique capability for systems integration as well as hydromechanical and electronics in-house development. SEC designs, develops and tests a variety of actuators and thermal systems for use in both military and commercial aerospace applications. Triumph Group, Inc., headquartered in Berwyn, Pennsylvania, designs, engineers, manufactures, repairs and overhauls a broad portfolio of aerospace and defense systems, components and structures. The company serves the global aviation industry, including original equipment manufacturers and the full spectrum of military and commercial aircraft operators. More information about Triumph can be found on the company's website at www.triumphgroup.com CisionView original content: http://www.prnewswire.com/news-releases/triumph-awarded-engine-component-mro-contract-for-international-chinook-fleet-301065649.html View source version on Triumph Group, Inc.: https://ir.triumphgroup.com/news-events/news-details/2020/Triumph-Awarded-Engine-Component-MRO-Contract-For-International-Chinook-Fleet/default.aspx