To intensify extreme temperature resilience and mechanical durability without increasing pre-integration risk, cost and schedule, Mercury takes a modular open systems architecture (MOSA) approach to design subsystems that operate at the tactical edge. Our agnostic cooling approach applies the air, conduction, Liquid Flow-Through, Air Flow-Through, Air Flow-By™ and Liquid Flow-By™ architectures to a single OpenVPX board design. Applying MOTS+ rugged packaging and effective cooling technologies across a portfolio of OpenVPX™ building blocks, we create scalable, interoperable processing subsystems that easily move from the lab to the tactical edge.
Recommended
Blog: Durability begins with preparation
Welcome to fall! Just a few short hops from here to winter, and up here in the Northeast, we never know if the weather is going to be mild or wild. Either way, expect a lot of temperature...
White Paper: Durability Advantages of Mercury’s Modified Off-The-Shelf (MOTS) Product Approach
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.
Our servers are designed from the ground up for C5ISR and other mission-critical applications where performance, reliability and availability are crucial. View our entire rugged server offering.
Taking the Data Center to the Edge with High-Performance Embedded Edge Computing
Data center GPU coprocessing for aerospace and defense: High-performance computing has evolved into high-performance embedded edge computing.
White Paper: High-Performance OpenVPX Forced Air-Cooling Architectures
How the most innovative embedded cooling technologies compare, Embedding modern, powerful processors into rugged OpenVPX processing systems requires efficient cooling for reliable, full throttle, unre
White Paper: Accurate FPGA Power Modeling
Maximizing FPGA processing and channel density in SWaP-constrained EW applications through accurate thermal modeling.