Secretary General underlines the importance of NATO’s partnership with Serbia

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  17 janvier 2020 | International, C4ISR

  Four Nations To Be Protected With Lockheed Martins Next Generation Radar

  Moorestown, N.J., January 14, 2020 – Through partnerships with the U.S. Government, Spain, Japan, and Canada, Lockheed Martin's (NYSE: LMT) solid state radar (SSR) technology will provide front-line defense to nations around the world with cutting-edge air and missile defense capabilities. These nations are part of a growing SSR family of 24 platforms, ushering in the next generation of maritime and ground-based advanced radar technology. The basis of SSR is the Long Range Discrimination Radar (LRDR), which the Missile Defense Agency (MDA) selected Lockheed Martin to develop in 2015 with an on-track delivery set for 2020. In 2019 Lockheed Martin's SSR for Aegis Ashore Japan was designated by the United States Government as AN/SPY-7(V)1. What is SSR Technology? SPY-7's core technology is derived from the LRDR program, which has been declared Technical Readiness Level 7 by the U.S. Government. The technology consists of a scalable and modular gallium nitride (GaN) based “subarray” radar building block, providing advanced performance and increased efficiency and reliability to pace ever-evolving threats. As part of its investment into the advancement of SSR, Lockheed Martin built a Solid State Radar Integration Site to conduct detailed testing to prove the maturity of the system and reduce fielding risk. Scaled versions of the LRDR site will be utilized for future radar programs including Aegis Ashore Japan, Canadian Surface Combatant and MDA's Homeland Defense Radar in Hawaii. Solid state offers powerful capabilities to detect, track and engage sophisticated air and missile threats, including the very complicated task of discriminating – or picking out – and countering lethal objects present in enemy ballistic missiles. The Lockheed Martin SSR uses state-of-the art hardware and an innovative software-defined radar architecture to meet current requirements while providing extensibility features to pace evolving threats for decades to come. Its unique maintain-while-operate capability provides very high operational availability and enables continuous 24-hour/7-day week operation. Solid state radar is a multi-mission system providing a wide range of capabilities, from passive situational awareness to integrated air and missile defense solutions. The combined capability and mission flexibility of Lockheed Martin's SSR has gained the attention of new and current users of the Aegis Weapon System, the world's premier air and missile defense combat suite. Meeting the World's Most Demanding Missions While LRDR is the first program to utilize Lockheed Martin's new SSR building blocks, over the past three years Lockheed Martin has consistently been selected in open competitions to equip an additional 24 platforms in four nations. SPY-7 provides several times the performance of traditional SPY-1 radars and the ability to engage multiple targets simultaneously with the latest proven interceptors. Spain's Ministry of Defense stated its preference for Lockheed Martin's technology for its five F-110 class frigates in 2017 and awarded the ship construction order to Navantia in 2019. These ships will host the first-ever S-band variants of the SPY-7 radar for the Spanish Navy. Production will be a collaboration between Lockheed Martin and Spanish company, Indra. When the frigates deploy in 2026 our SPY-7 variant will be integrated as part of the Aegis Weapon System. The frigates will also incorporate the International Aegis Fire Control Loop (IAFCL) integrated with SCOMBA, the national combat system developed by Navantia. Canada's Department of National Defence also selected Lockheed Martin as the naval radar provider for its 15 Canadian Surface Combatant (CSC) ships. Lockheed Martin's IAFCL is integrated with Canada's combat management system, CMS 330, developed by Lockheed Martin Canada for the Royal Canadian Navy's HALIFAX Class ships. The program will make Canada the owner of the world's second largest Aegis fleet, and our SPY-7 radar variant will enable CSC to conduct highly advanced maritime missions for decades to come. Mature, Cost-Effective Systems Ready Now Including LRDR, the 24 Lockheed Martin SSR platforms selected to date represent a total of 91 antennas of varying sizes, collectively composed of over 15,000 subarrays. On LRDR alone, Lockheed Martin has produced an equivalent of eight Aegis shipsets to-date. The U.S. Government's LRDR has a planned service life for decades to come and will be supported and maintained throughout that period. This ensures the U.S. and its allies will have a large and stable base of cost-effective logistics and support for many years in the future. About Lockheed Martin Headquartered in Bethesda, Maryland, Lockheed Martin is a global security and aerospace company that employs approximately 105,000 people worldwide and is principally engaged in the research, design, development, manufacture, integration and sustainment of advanced technology systems, products and services. View source version on Lockheed Martin: https://news.lockheedmartin.com/2020-01-14-Four-Nations-to-Be-Protected-with-Lockheed-Martins-Next-Generation-Radar

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  21 avril 2020 | International, Naval

  NATO’s ‘startup’ charts a bold future in maritime unmanned systems

  By: Michael D. Brasseur , Rob Murray , and Sean Trevethan Last December, at their meeting in London, NATO leaders declared: “To stay secure, we must look to the future together. We are addressing the breadth and scale of new technologies to maintain our technological edge, while preserving our values and norms.” These two sentences were, in part, a nod to a significant piece of work the alliance is undertaking within the broader mandate of alliance innovation — NATO's Maritime Unmanned Systems Initiative. Granted, on its own this sounds both technical and narrow within the context of emerging technology, a context that includes: artificial intelligence, data, space, hypersonic weapons, bio technologies, quantum research, autonomy and more. So why are maritime unmanned systems relevant now? Simply put, developing the numbers of manned submarines, aircraft and ships required to keep pace with potential adversaries is simply not economically viable (almost $3 billion per Virginia-class U.S. submarine). Not since the Cold War has NATO needed the volume of maritime forces to protect our seas and oceans from would-be foes. NATO's areas of interest are expanding. As climate change affects the Arctic, new maritime routes are being created, which Russia in particular is exploiting with its submarines and ships. This matters because it exposes a new flank on NATO's high-north periphery, and if left unchecked is a potential vulnerability whilst also being a potential opportunity; this, coupled with an increasing need to protect our undersea data infrastructure means NATO's geostrategic responsibilities continue to grow. Therefore, if allies are to reinforce NATO's maritime posture, deter Russian aggression, guard against Chinese activity, and protect both critical national infrastructure and our sea lines of communication, NATO must do things differently and at the speed of relevance. NATO's Maritime Unmanned Systems Initiative was agreed by 13 defense ministers in October 2018. Since then, the initiative's success has attracted the participation of three more allies and garnered significant interest from all of NATO's maritime nations. The political agreement struck in 2018 provided the mandate for NATO to bring together disparate strands of common work ongoing within nations. NATO, acting as a network, enabled allies to become greater than the sum of their parts. The focus is threefold: utilize world-leading research to increase allied interoperability between conventional forces and unmanned drones; establish new tactics for our sailors to truly leverage these technologies; and develop secure digital communications for military drones across all domains (air, sea and land). Addressing these priorities together will enable this effort to be scaled across the alliance, at pace. To date, the speed of this effort has been breathtaking. So much so that even the United States and the United Kingdom — two allies who have invested the most in this area — are using the NATO initiative as a catalyst for their own national efforts. The last 12-plus months has seen the creation of a NATO project office, a governance body, as well as the planning and successful execution of the world's largest and most complex maritime unmanned systems exercise off the Portuguese coast in September 2019. This event brought together the very best from our navies, industry, scientific institutes and academia. The results were hugely impressive, with many “world firsts” including maritime unmanned systems augmenting conventional forces through multiple scenarios. We now have vast swaths of insight and information to start achieving those three goals of improving interoperability, enhancing our tactics and developing secure communications. The goal of improving allied interoperability is actually about enhancing standards. A topic often overlooked at the policy level but critical to the DNA of the NATO alliance. Standards drive interoperability, which in turn drives readiness, which ultimately aids deterrence. As NATO leads the development of new technologies, so too must come new standards that our industries and military can implement. Open architectures will be key, but allies and industry need to realize that we need to solve problems — not address requirements. No perfect solution will ever be delivered on the first attempt. The alliance will need to both innovate and iterate on operations in order to maintain advantage. This may be a cultural shift to some acquisition purists who are used to developing complex warships over 20-plus-year time frames. However, the challenge remains our ability to scale. With this project we have an agile global team functioning across multiple national and allied bureaucracies, each with their own culture and ways of working. Through engagement and investment, this team is yielding disproportionate results. Indeed, 2019 demonstrated what can be done with some imagination, effort and focus. But continual growth at speed will require faith by allies to maintain the course. Such is the nature of true change and innovation. There is a lot to do, and the stakes are high. Near-peer competitors are once again very real. Despite the global lockdown caused by the new coronavirus, COVID-19, the initiative continues to progress through synthetic networks and simulation, driven by passion and intent. Our economy, our data and its infrastructure still need protecting, now more than ever. This effort strives to accelerate maritime unmanned systems into NATO's arsenal to patrol the vast swaths of ocean and offset evolving threats. Success will be seen because it is being built on allied nations' shared values and norms, the same values and norms that NATO leaders recognized in London last year. Michael D. Brasseur is the director of naval armaments cooperation for the U.S. mission to NATO. He is also the first director of NATO's “startup,” the Maritime Unmanned Systems Innovation and Coordination Cell. Rob Murray is the head of innovation at NATO Headquarters. Sean Trevethan is the fleet robotics officer of the British Royal Navy, working in the future capability division at Navy Command Headquarters in Portsmouth, England. https://www.defensenews.com/opinion/commentary/2020/04/20/natos-start-up-charts-a-bold-future-in-maritime-unmanned-systems/

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  10 novembre 2024 | International, Aérospatial

  Sweden picks Embraer's C-390 as new military cargo aircraft