BAE Systems offers advanced cryogenic solutions that enhance both tactical and scientific operations, providing significant advantages in military and space missions. Their cryogenic capabilities include liquid hydrogen storage tanks for high-altitude, long-endurance aircraft and systems for cryogenic control, refueling, and maintenance. BAE is also developing energy storage systems for unmanned underwater vehicles (UUVs) at cryogenic temperatures, doubling battery capacities. Additionally, their high-capacity mechanical cryocoolers are used for cooling infrared sensors in both military and civil space platforms, offering extended operation at temperatures below 25 Kelvin. BAE's cryogenic expertise has contributed to critical space missions, such as the Spitzer Space Telescope and NASA's James Webb Space Telescope, where they designed and built essential cryogenic systems to ensure extended mission durations and optimal performance.
The Fast Steering Mirrors are advanced optical components designed for precision in demanding applications. Built to meet rigorous specifications, these mirrors offer exceptional performance for systems requiring rapid and precise beam control. Ideal for use in a variety of defense and aerospace systems, they ensure superior accuracy and reliability in challenging environments. The Fast Steering Mirrors are engineered to support cutting-edge technology, making them essential for a wide range of high-performance applications. For more details, visit [BAE Systems Fast Steering Mirrors](www.baesystems.com/en-us/product/fast-steering-mirrors).
The STP-SIV (Space Test Program Standard Interface Vehicle) is a flexible and standardized spacecraft platform designed to accommodate a variety of payloads and instruments, enabling rapid and cost-effective satellite launches. Developed under the U.S. Air Force's Space Test Program, the STP-SIV series allows payload teams to design and integrate specific experiments with minimal additional cost. With its versatile platform, the STP-SIV can support multiple payloads, reducing non-recurring costs and shortening acquisition timelines. This adaptability allows for launches on a wide range of vehicles, including the Evolved Expendable Launch Vehicle Secondary Payload Adapter, and it has successfully supported various space missions, such as STPSat-2 and STPSat-3.
The OMPS (Offensive Multi-Platform System) is a cutting-edge precision targeting system designed for long-range, multi-mission applications. Developed to enhance the operational capabilities of advanced airframes like the B-1B Lancer, it enables exceptional weapon accuracy and strike effectiveness in diverse combat environments. The OMPS integrates seamlessly with the aircraft's avionics and weapons systems, ensuring maximum operational efficiency and precision. This system is crucial in delivering superior strike capability, especially in complex combat scenarios where high precision is essential. With continuous upgrades, the OMPS is poised to remain a vital asset for modern aerial warfare. [More details](www.baesystems.com/en-us/product/omps)
NOAA-20, launched in November 2017 as part of the Joint Polar Satellite System (JPSS), is one of the most advanced environmental satellites ever created. Designed to enhance weather forecasting and climate monitoring, NOAA-20 delivers critical satellite data and imagery that aids in predicting severe weather events such as tornadoes, floods, and wildfires. Equipped with a suite of advanced remote sensing instruments, including the Visible Infrared Imager Radiometer Suite (VIIRS), Cross-track Infrared Sounder (CrIS), and the Ozone Mapping and Profiler Suite (OMPS), NOAA-20 provides more accurate and timely weather predictions. Managed by NOAA and built by BAE Systems, this satellite plays a key role in improving long-term climate monitoring and forecasting capabilities, ensuring a safer, more informed world.
The Green Propellant Infusion Mission (GPIM) is a groundbreaking project by BAE Systems that aims to develop environmentally friendly propulsion technology for spacecraft. By testing a "green" alternative to traditional chemical propellants, GPIM seeks to enhance the efficiency and sustainability of future space missions. This innovative system uses a safer, more efficient propellant, reducing toxic environmental impacts while ensuring high performance. The GPIM initiative aligns with BAE's commitment to advancing space technology and sustainability, providing a crucial step toward greener, more sustainable space exploration.
The Global Precipitation Measurement Microwave Imager (GMI) is an advanced satellite-based instrument developed by BAE Systems for NASA's Global Precipitation Measurement (GPM) mission. It is designed to measure small particles of ice, snow, and rain from space, providing crucial data for weather prediction and climate monitoring. The GMI collects high-resolution observations of global precipitation patterns, enabling improved forecasting accuracy. Its advanced microwave imaging capabilities play a vital role in understanding weather systems, enhancing the ability to predict severe weather events and their impact on the environment and communities worldwide.
Cameras from BAE Systems offer exceptional day and night imaging capabilities for space and science missions, along with superior quality, reliability, and high performance for tactical operations. These advanced cameras are engineered to meet the demands of both scientific exploration and critical defense applications, providing clear and accurate imaging in diverse conditions. Ideal for space missions and tactical surveillance, they ensure optimal performance in a range of environments. For more information, visit [BAE Systems Cameras](www.baesystems.com/en-us/product/cameras). .
Dynamic Vision is an advanced sensor integration system developed by General Dynamics Mission Systems, designed to significantly enhance situational awareness and mission effectiveness. By synchronizing multiple sensors across platforms, it provides a comprehensive 360-degree view and merges data into an intuitive 3D display for operators. The system is capable of integrating with legacy systems, connecting non-link platforms to navy grids, and offering superior sensor fusion for precise target tracking. Dynamic Vision improves operator awareness and decision-making, especially in high-threat or congested environments, delivering seamless navigation and visual assistance.
General Dynamics Mission Systems' Military Aircraft Radomes are designed to meet the needs of next-generation air dominance platforms and collaborative combat aircraft. These advanced radomes provide optimal performance for integrated sensors and multi-function arrays across ultra-wideband frequency ranges, supporting critical military applications such as fire control, electronic warfare, SatCom, and radar systems like AESA. Built with expertise in RF design, structural engineering, lightning protection, and non-destructive testing, these radomes ensure exceptional reliability. The radomes are manufactured using state-of-the-art facilities, including large autoclaves and RF test ranges, for platforms such as the F-35, C-130, and EA-18G.
CACI’s multi-mission payload technologies connect sensors and deliver converged effects. We optimize platforms with electro-optical/infrared (EO/IR) sensors and multi-mission EW payloads – helping customers sense, listen, jam, communicate, and apply cross-domain effects.Learn More
CACI’s line of high-performance, low size, weight, and power (SWaP), gyro-stabilized electro-optical (EO) and infrared (IR) imaging systems are built for missions such as ISR, target acquisition, C-UAS, long-range detection, recognition, and identification (DRI), and navigation safety.
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Drawing on more than 30 years of experience in NVIS-compliant light filtering, we have engineered Korry Nightshield plastic NVIS filters for reliable, cost-effective new installations and retrofits in commercial aviation, medical evacuation, search and rescue, law enforcement, and defense. Nightshield filters are a simple way of keeping users of night-vision devices (NVDs) safe. Our filters can be applied to any light source to regulate its infrared emissions, preventing interference with a pilot's or ground-equipment operator's goggles.
Korry Electronics is an industry leader in developing aircraft data collection, conversion, control, computing, and routing solutions. Korry airborne computing systems deliver the technology you need to implement rugged, scalable, fault-tolerant airborne data computing, data networks, and data gateway solutions.
Korry Control Products feature industry-leading HMI performance that provides high-reliability control and display solutions for flight deck and crew stations in the Aerospace and Defense market.
