Next-gen Combat Aircraft Development Gains Momentum

On the same subject

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  April 22, 2024 | International, Security

  Countering Chinese cyber threats of tomorrow demands we prepare today

  Opinion: For decades, the Chinese Communist Party has focused on espionage, stealing IP from our companies, and collecting private data.

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  November 17, 2020 | International, Land

  Iron Dome batteries activated to fill cruise missile defense gap

  By: Jen Judson WASHINGTON — The Army has activated two air defense artillery batteries at Fort Bliss, Texas, that will evaluate the Iron Dome system for possible integration into the Army's air-and missile defense architecture, according to a Nov. 13 statement from the service. The Iron Dome batteries will serve as an interim capability to fill a cruise missile defense gap. The change was mandated by Congress while the Army determines a long-term solution to combat such threats in addition to countering rockets, artillery, mortars and drones. The Army took receipt of the first Iron Dome battery in Israel in October. The Fort Bliss-based units are expected to receive one Iron Dome system in December followed by the second in January. To stand up the two batteries, the Army is converting a Terminal High Altitude Area Defense (THAAD) battery and realigning resources from the U.S. Army Air Defense Artillery School — which is a part of the Army's force realignment initiative — according to the statement. The move is expected to be complete by Nov. 16 and will result in 26 additional personnel at Fort Bliss. The Army chose Fort Bliss because of its proximity to White Sands Missile Range, New Mexico, where the systems will be tested and evaluated. The units will spend the next year training, testing and working with the systems to prepare Iron Dome for operation deployment by late 2021. Part of the effort, according to the statement, will include integration of Iron Dome into the Army's Integrated Battle Command System, which is the command-and-control element of the service's future Integrated Air and Missile Defense architecture. The IBCS system is expected to reach a production decision this month and will undergo an initial operational test and evaluation in 2021. Northrop Grumman is the prime contractor on the program. The Army plans to make a final stationing decision on where and how to employ the systems “through either a forward stationing decision and/or Dynamic Force Employment concept in response to contingency operations” when the batteries reach operational deployment capability, the statement notes. The service plans to hold a shoot-off to determine an enduring capability for its Indirect Fires Protection Capability Increment 2 system — designed to defend against C-RAM, UAS and cruise missile threats — in the spring of 2021. Elements of the Iron Dome system will be part of that shoot-off. Iron Dome has a long track record of operational success in Israel and is produced through a partnership with Israeli-based Rafael and Raytheon. Those companies are making plans to produce Iron Dome systems in the United States and are expected to pick a location for production by the end of the year. https://www.defensenews.com/land/2020/11/13/iron-dome-batteries-activated-to-fill-cruise-missile-defense-gap/

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  September 20, 2018 | International, Aerospace, C4ISR

  The new critical capabilities for unmanned systems

  By: Ryan Hazlett With unmanned systems becoming ever more ubiquitous on the battlefield, the question of where unmanned systems and accompanying technologies, such as autonomy, are headed is in the limelight. First, to better understand the future direction of the unmanned field, it is instructive to note some important trends. The number of uses for unmanned systems on the battlefield has increased significantly in the post-9/11 conflicts in Afghanistan and Iraq, with the U.S. Army's Shadow® Tactical Unmanned Aircraft System (UAS) program having logged nearly 1 million flight hours in those areas of operation. The proliferation and commoditization of UAS capabilities is a global phenomenon, as demonstrated by both the widespread possession of UAS hardware as well as the ability to indigenously produce at least rudimentary unmanned systems. Growth of the nascent commercial unmanned systems market has added to this trend, as has the government's emphasis on a greater use of commercial off-the-shelf solutions. But while commoditization has occurred at the platform level — particularly among smaller airborne vehicles — overcoming the challenges of adversaries employing anti-access area-denial (A2AD) military strategies requires far more capable solutions than simply having hordes of cheap drones. In this environment, how will U.S. and allied forces retain their advantage? Critical capabilities and technologies are necessary. These include the ability to dynamically swarm, conduct automatic target recognition, possess on-board autonomy and artificial intelligence, as well as have interoperable communications capabilities. First, future platforms — manned or unmanned — will increasingly need better collaboration between the sensors and payloads they carry and with allied forces. This growing level of collaboration and autonomy is already happening. Driven by advances in onboard computing power, as well as smaller and less power-intensive sensors and advanced algorithms, tomorrow's unmanned systems will be able to better communicate among themselves and make their own decisions on basic functions, such as navigation, to enable dynamic swarming or to identify areas of interest during intelligence, surveillance and reconnaissance missions. Next, systems that can seamlessly operate and communicate with other military platforms across domains will be the most successful. Gone are the days when largely mission-specific platforms dominated the force composition. With platforms needing to be highly capable to meet A2AD threats, a mission-specific approach will simply be unaffordable. Instead, increasingly we see platforms that can act as highly capable but also flexible “trucks” that can easily swap payloads designed for specific missions, while the overall platform serves many needs. Multi-domain abilities for conducting command and control (C2) and other tasks will also be vital as technologies move from remote-control type operations to more of a “man monitoring the loop” concept. Technological progress in providing secure communications and a level of onboard artificial intelligence are necessary enablers, as will be data fusion technologies. Initial versions of these multi-domain C2 solutions for unmanned systems are already here. For example, the U.S. Army has years of experience operating the Universal Ground Control Station and One System Remote Video Terminal that allow soldiers in tactical units to access overhead sensor video from unmanned aircraft. Next-generation, multi-domain control and collaboration technologies to take the concept to a new level are mature, allowing a single user to simultaneously operate multiple vehicles and sensors, including the ability to control numerous types of aircraft and other multi-domain unmanned systems from different manufacturers. In addition, these systems are ready to incorporate the best available software applications as “plug-ins” to an open architecture. Industry is also investing in additional technology to ensure that tomorrow's unmanned systems continue to meet U.S. and allied needs. Among them are advanced power generation, systems with improved maneuverability, and vehicles designed to deploy with lighter support and operational footprints. Done smartly, the application of technologies such as autonomy can be better integrated into unmanned systems to enable improved navigation, intelligence, surveillance and reconnaissance, as well as other tasks, while leaving a man in the loop for the use of weapons. Moreover, defense users can rightly leverage the commercial sector's work on areas such as self-driving cars and unmanned taxis that are at the forefront of artificial intelligence for navigation. But while the military can leverage such commercial developments, there are, and will remain, cyber hardening, survivability and other specific requirements that are unique to the defense marketplace and require experienced industrial partners with deep knowledge of national security needs. The ongoing move away from only long-term programs of record to the embrace of the “buy, try, and decide” model, as well as greater uses of funded prototyping, is helping to fast-track many of these promising new technologies. Companies can now match their internal research and development funding to move that innovation along and ensure the United States and its allies remain at the forefront of unmanned technologies. Ryan Hazlett is senior vice president at Textron Systems. https://www.c4isrnet.com/thought-leadership/2018/09/19/the-new-critical-capabilities-for-unmanned-systems