This paper describes the engineering considerations and design techniques used to develop a small form factor rugged recorder that can handle the extremely high data rates associated with very wide bandwidth RF signal recording. It is intended to provide engineers with ideas on how to bring this capability into confined and often extreme environments while focusing on military specification compliance, SWaP and ease of use with confidence.
Xilinx's new RFSoC brings a powerful and unique solution for addressing some of the most demanding requirem...
Learn about ACAP technology and how it's contributing to faster, stronger and more capable systems at the tactical edge.
A flexible design approach integrates individual intellectual property (IP) blocks called chiplets. The IP in a chiplet performs a specific function.
Today's pace of technology development means the traditional approach of custom-designed modules and subsystems is too slow, but Modular Open System Architecture (MOSA) approaches can deliver on...
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.
Online panel discussions regarding the future of radar in the defense community.
COTS Software Defined Radio for 5G Development
Xilinx'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.
Recording solutions accelerate system development, performance and deployment. Capturing RF signals with precise timing over long sessions is both a necessity and a challenge for success.
Use the latest technology that allow real-time recording systems to keep up with the ever-increasing speed requirements of wide-bandwidth data capture in modern military systems.
Using technologies like high-bandwidth memory, high-bit-rate optical interfaces and gigabit serial protocols to address processing and memory demands in modern military systems
Bringing trust and supply chain security to the latest commercial semiconductor solutions requires innovation at chip scale. High density 2.5D system-in-package technology solves industry challenges.
Heterogeneous 2.5D system-in-package (SiP) technology is proving to be an excellent match for sensor-edge processing requirements, integrating high-performance chiplets to support direct digitization.
In this webinar, we discuss four decades of innovative 2D and 2.5D microelectronics packaging and integration, then review the latest trends in microelectronics.
Mercury Systems is a next-generation defense electronics company making commercial technologies profoundly more accessible to aerospace and defense. Watch the interactive virtual conversation with...
Our latest innovation is game-changing. Our proven microelectronics and trusted manufacturing processes when applied to chiplets will bring cutting-edge commercial silicon technology to the DOD.
We leverage HD 2.5D system-in-package technology, custom silicon interposers, 2D die stacking integration, leading semiconductor manufacturers, and trusted manufacturing in harsh environments.
In this episode, podcast host Ken Miller sits with Dr. William Conley, Chief Technology Officer and discuss how Microelectronics holds significant importance to EMSO.
By working at the chip level and leveraging new 2.5D system-in-package capabilities, designers can combine complex semiconductor dies into a single component while maintaining trust and security.
At the epicenter of modern 3D and 2.5D package design is through-silicon-via (TSV) technology. TSVs facilitate the vertical integration of multiple die.