Commercial-Off-The-Shelf (COTS) Software-Defined-Radio (SDR) products have been traditionally used for Military RADAR and communication applications because of their high performance, and design flexibility. The latest SDR products offer SoC solutions with integrated I/O, ARM processors, and large FPGAs that include intellectual property (IP) for accessing, routing, and processing digital data. Combining these attributes with superior signal integrity, phase-coherent sampling, and multi-channel transceivers a COTS SDR system is an ideal choice for your 5G development platform. This article is designed to familiarize a new user about Software Defined Radio in a multi-purpose COTS platform that can reduce the time to market their 5G products.
AMD's new RFSoC brings a powerful and unique solution for addressing some of the most demanding requirement...
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AMD's new RFSoC brings a powerful and unique solution for addressing some of the most demanding requirements of high bandwidth and high channel count systems.
Learn how commercial technology companies and the aerospace and defense industry are merging their innovations to help government organizations enable on-orbit sensor fusion.
This white paper describes next generation direct RF to redefine what’s possible in radar and software radio, from jamming to electronic intelligence to significant bandwidth performance.
PCIe 5.0 protocol benefits a new generation of rugged, deployable application platforms with doubled bandwidth and is an integral part of the latest devices from industry giants, Intel and NVIDIA.
Mercury and VAST make cutting-edge data center technology available for defense and other harsh-environment applications, enabling low-latency processing, scalability and data security in the field.
Optimized to solve the most advanced radar, cognitive EW and AI challenges, learn how Mercury ’s ACAP-engineer-to-engineer designer’s journey is intended to assist other development teams.
SWaP-optimized and ruggedized for operation in harsh environments, learn how Mercury ’s ACAP-based solutions will bring new levels of application capability to the tactical edge.
Learn how Mercury and Intel collaborate to scale and deploy composable data center capabilities across the fog and edge layers with high performance embedded computing (HPEC)
Optimized networked-attached GPU distributed processing architecture delivers NVIDIA A100 GPU parallel computing resources over dual 100 Gbit Ethernet network connections without requiring an x86 host
Development Tactics and Techniques for Small Form Factor RF Signal Recorders
Electronic battlefield complexity is a growing challenge. New, more sophisticated RF processing capabilities must be rapidly developed and deployed to operate successfully in contested environments.
Technology is evolving faster than ever. Mercury's business model leverages open standards, commercial technology and R&D investment to drive innovation at a lower cost.
This white paper focuses on a dynamic new answer to the RF edge processing challenge, an adaptation of system-in-package (SiP) technology: the RFSiP.
Learn about the SOSA Consortium and the VITA organization, how they interact to address challenges and define successful strategies, along with illustrative examples of SOSA-aligned products.
Learn how Mercury builds products with varying degrees of enhanced durability to operate under extreme environmental conditions, including repeated temperature cycling over wide temperature ranges.
DAL (design assurance) flight-safety certification and systems security engineering (SSE) is required to protect systems and mitigate risk for future smart and autonomous platforms
Discover how technologies developed by Mercury Systems and NVIDIA scale the best AI-enabling data center processing capabilities to the edge for real-time decision-making.
Cloud-scalable cross-domain solution methodologies, challenges and implementations for rapid, secure and correct information transfer between multiple security domains.
Modern sensors and AI need powerful flight-ready computing, but creating safe multi-core processing systems is difficult to achieve. Learn why Intel-based solutions are suited for AI and FVL.
Today's space imaging systems require radiation-tolerant NAND flash components with advanced error correction, packaged in lightweight, rugged VPX form factors.