To remain competitive, a Curtiss-Wright customer needed to upgrade an existing radar system that was deployed across multiple airborne platforms. A critical part of the upgrade was doubling the system’s signal processing throughput.

Curtiss-Wright developed a solution that increased memory capacity by 400% to solve sensor fusion challenges. Read the full details here.

A customer approached Curtiss-Wright with a requirement of upgrading to modern COTS hardware while keeping legacy proprietary infrastructure. Read about the SWaP solution Curtiss-Wright developed here.

This case study describes a solution to detect and locate SIGINT signals of interest quickly and meet SWaP-constraints of the airborne platform.

Through expertise in designing SWaP-optimized systems, Curtiss-Wright designed the flight control computer with alternate mounting technique, which resulted in significant improvements in thermal performance, system reliability, and system performance.

An extended-service marine patrol aircraft required a signal processing and display computer to provide an upgrade in capability and performance. Learn about the solution Curtiss-Wright provided.

SDR requires high-performance signal acquisition building blocks. Curtiss-Wright offers a wide range of rugged signal acquisition products ready for integration with processing and Radio Frequency (RF) electronics for deployment.

Fire Control and Vehicle Computer applications are more demanding than ever, performing tasks faster with extreme accuracy required as standard. Read the case study!

Capturing video feeds from several sensors and making that data available to the user is required for many applications. Usually, this data is critical for mission completion, post-mission analysis, and personal safety.

This case study describes Curtiss-Wright's optimized, scalable, flexible and affordable Advanced Mission Management System for the MQ-4C Triton Unmanned Aircraft System (UAS), designed and built to meet the U.S. Navy's maritime surveillance needs.

Electronic Warfare applications require systems to have substantial low latency processing performance tied to multiple high-resolution channels capable of input in gigasamples per second (GSPS) range.