Discover how Mercury helped Airbus achieve the world’s first safety-certifiable, fully automatic refueling system.
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Assurance of DAL flight-safety certification and systems security engineering (SSE) is required to protect systems and mitigate risk for future smart and autonomous platforms
Case Study: Boeing retrieves UAV flight data with a crash-survivable video recorder
Boeing used Mercury's crash-survivable FAERITO video recorder to gather critical data from test unmanned aerial vehicle flights
Podcast: Building strategic relationships to make commercial technology profoundly more accessible
Technology advances don’t happen overnight or in a bubble. That's why Mercury teams with the most innovative companies in the world, bringing the latest technologies to our customers.
Ready for take-off? Let’s set your electronics to airplane mode.
Most of us have heard an aircraft safety demonstration – a short pitch that reminds us to fasten seatbelts, locate emergency exits and set personal electronic devices to airplane mode....
Webinar: Enabling Tomorrow's Avionics with Multi-Core Certifiable Computing
Intel and Mercury discuss building rugged, open, DAL-certifiable processing boards and subsystems for mission systems and AI workloads.
Supporting Significant Avionics Market Trends
Discover how safety-certifiable computing is evolving to meet the application requirements of next generation platforms. Dr. Amela Wilson, senior vice president and general manager of Mission...
White Paper: Safety Certifiable Computing for Tomorrow's Avionics
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.
Intel and Mercury Talk DAL-Certifiable Computing for Future Avionics
Intel and Mercury Systems discuss their longstanding partnership and collaboration in building DAL-Certifiable DO-254 and DO-178C computing for future avionics
This paper investigates both the large area display architecture with available options to solve redundancy, as well as, beam steering techniques to limit canopy reflections in bubble canopy cockpits.
Editorial: Open architecture initiatives bolster unmanned sensors and systems
Unmanned platforms have become essential machinery on the battlefield. Discover how moving them away from platform-centric architectures encourages efficient operation in the field.
Webinar: Airworthiness Enablement with Multi-Core Processors
In this webinar, learn how Intel, Mercury and Lynx are approaching design assurance for avionics systems and how this collaboration benefits aircraft embedded developers.
Webinar: Mission Critical Solutions for Defense
Discover how powerful mission-computing and display solutions are addressing the challenges of future aerospace and defense applications.
Article: Navy SBIR/STTR Transitions Spring 2021, POC Acquisition Editorial
SBIR-to-transition successes include the Joint Avionics Reconfigurable Virtual Information System (JARVIS) mission computer and the Digital Data Set (DDS) Systems for the Navy's T-45, read more-
Are we ready for a flying car?
Are you ready for flying cars? The award-winning CIOE-1390 COM Express module from Mercury Systems addresses the demand for onboard avionics processing. The device is powered with Intel Atom...
Developing and Adapting Mission-Critical Displays
Our mission-critical displays are engineered to deliver unparalleled performance across multiple domains, in the most extreme environments. Hear how Mercury uses LG technology to tackle challenges...
White Paper: Selecting Optimal Avionic and Vetronic Displays for Your Application
This paper first discusses advanced capabilities that enhance LCD technology and then reviews business factors to consider when selecting or specifying display systems.
Only by understanding the mechanics of the various key management mode methodologies can the military system architect choose the optimal strategy for each mission or program.
On Demand: Mission Critical Solutions for Defense
Discover how powerful mission-computing and display solutions are addressing the challenges of future aerospace and defense applications.
In order to minimize cost and time-to-market, the hardware must be flexible and modular. To address this emerging-need, we have developed a multi-channel, coherent system architecture.
To handle extreme workload, system architects must design boards using the fastest FPGA devices & Intel multicore processors. These devices cannot provide peak performance with high-speed DDR4 memory.