DIGAR™ is an advanced GPS anti-jam and anti-spoof technology designed for airborne systems. It integrates industry-leading electronics to provide robust protection for GPS signals, ensuring accurate and secure navigation even in the most challenging environments. With applications across military platforms, DIGAR™ supports multiple aircraft flying over a battlefield, offering enhanced reliability and performance for precision-guided systems. Its cutting-edge technology plays a critical role in maintaining the integrity of navigation systems in contested or adversarial conditions.
The Chandra X-Ray Observatory, developed by BAE Systems, is a leading space-based telescope designed to study high-energy astrophysical phenomena such as black holes, supernovae, and galaxies. Positioned in orbit around Earth, it captures X-ray emissions from distant cosmic sources, offering valuable insights into the universe's most energetic and mysterious components. This observatory plays a pivotal role in expanding our understanding of space, providing scientists with data that is essential for advancing astrophysics. With its advanced imaging and observational capabilities, Chandra contributes significantly to the field of space research. For more information, visit [BAE Systems - Chandra X-Ray Observatory](www.baesystems.com/en-us/product/chandra-x-ray-observatory).
The GEMS (Geostationary Environment Monitoring Spectrometer) and TEMPO (Tropospheric Emissions: Monitoring of Pollution) are advanced geostationary ultraviolet-visible spectrometers designed to enhance global air quality monitoring. Launched in 2020 and 2023, respectively, GEMS monitors trans-boundary pollution events in the Asia-Pacific region, while TEMPO tracks pollutants like ozone, nitrogen dioxide, and sulfur dioxide across North America. These instruments provide high-resolution, hourly measurements that aid in climate change research and pollution forecasting. Developed through collaborations with institutions such as NASA and the Korea Aerospace Research Institute, both instruments are part of a global satellite constellation aimed at improving environmental monitoring and air quality prediction.
The Solar Backscatter Ultraviolet Radiometer (SBUV/2) is a key instrument used for monitoring the ozone layer, essential for protecting life on Earth from harmful ultraviolet (UV) rays. It operates aboard NOAA weather satellites and measures the density and distribution of ozone in the atmosphere by analyzing reflected wavelengths from Earth. This data helps determine the total ozone between the instrument and the ground, as well as the vertical distribution of ozone. SBUV/2 was instrumental in discovering the ozone hole over Antarctica in 1987 and continues to play a crucial role in monitoring ozone levels globally. Since its first launch in 1984, nine SBUV/2 instruments have been built for NASA and NOAA, with the latest launched in 2009. [Learn more](www.baesystems.com/en-us/product/sbuv-2-solar-backscatter-ultraviolet-radiometer)
The Deep Space Climate Observatory (DSCOVR), developed by BAE Systems, is a pioneering satellite designed to monitor and provide early warnings of space weather phenomena that could impact Earth. Positioned at the L1 Lagrange point, it observes solar winds, cosmic rays, and provides real-time data about Earth's climate. With advanced sensors and technology, DSCOVR enhances our understanding of the environment and plays a critical role in safeguarding communication systems, satellites, and power grids from solar storms. This innovative space system supports future space research and climate monitoring for better global preparedness. For more details, visit [DSCOVR](www.baesystems.com/en-us/product/dscovr).
MethaneSAT, launched on March 4, 2024, is a groundbreaking satellite mission designed to precisely locate and measure methane emissions worldwide. With the ability to monitor emissions from oil and gas production, industrial agriculture, and other human-made sources, MethaneSAT aims to provide critical data to reduce methane emissions, a significant contributor to climate change. The mission features advanced dual spectrometers that measure methane absorption in the shortwave infrared spectrum with unprecedented accuracy, helping decision-makers track, quantify, and mitigate these harmful emissions. Developed by MethaneSAT LLC and supported by BAE Systems, this mission offers a powerful tool for fostering a more sustainable world.
The Roman Space Telescope, developed by NASA with support from BAE Systems, is set to revolutionize our understanding of the universe. As part of the mission, BAE Systems is designing and developing the Wide Field Instrument (WFI) Opto-Mechanical Assembly, which will play a critical role in capturing high-resolution images of distant galaxies, exoplanets, and other cosmic phenomena. The telescope will provide invaluable data to explore dark energy, map the distribution of matter in the universe, and contribute to the search for habitable planets. With cutting-edge technology, the Roman Space Telescope aims to deepen humanity’s exploration of space.
The Hubble Space Telescope, one of the most important tools in modern astronomy, has significantly advanced our understanding of the universe. BAE Systems played a key role in the development of the telescope's five science instruments, which continue to provide breathtaking images and invaluable data. These instruments are used to study distant galaxies, black holes, and the structure of the universe, offering insights into the cosmos that were previously unimaginable. The Hubble Space Telescope remains a vital asset for scientific exploration, contributing to groundbreaking discoveries in space science.
Landsat/OLI, part of the longstanding NASA Landsat program, provides crucial Earth observation data to inform decisions on environmental management and natural resources. BAE Systems designed and built the Operational Land Imager (OLI) on Landsat 8, which has provided high-performance imaging since its launch in 2013. The OLI enables detailed monitoring of Earth's surface, helping to assess droughts, track wildfires, evaluate agriculture, and understand ecosystems. In 2021, BAE Systems also delivered the OLI-2 for Landsat 9, continuing the legacy of providing exceptional calibration and cost-effective solutions. The program represents a vital collaboration between government and industry, advancing the science of Earth observation.
The CALIPSO (Cloud-Aerosol Lidar and Infrared Pathfinder Satellite Observation) is a satellite system developed by BAE Systems, designed to enhance climate and atmospheric research. It uses advanced lidar and infrared technology to observe and measure cloud and aerosol properties, providing invaluable data for weather forecasting and environmental monitoring. CALIPSO operates with a high degree of precision, collecting detailed information about the Earth's atmosphere and contributing to climate studies and global environmental efforts. This state-of-the-art technology is critical for understanding the impact of aerosols and clouds on the Earth's climate and weather patterns.
The Suomi National Polar-orbiting Partnership (Suomi NPP) is a cutting-edge Earth observation satellite designed to provide critical data for weather forecasting, environmental monitoring, and climate research. Equipped with advanced sensors, Suomi NPP captures high-resolution images and measurements, offering invaluable insights into atmospheric, oceanic, and land conditions. This satellite serves as a key component in the National Oceanic and Atmospheric Administration's (NOAA) Earth observation program, helping scientists track global climate change, monitor natural disasters, and improve weather prediction accuracy. Suomi NPP is a vital tool for enhancing our understanding of the Earth's changing environment. For more information, visit [BAE Systems Suomi NPP](www.baesystems.com/en-us/product/suomi-npp).
HiRISE (High Resolution Imaging Science Experiment), mounted on NASA’s Mars Reconnaissance Orbiter (MRO), provides unparalleled high-resolution images of the Martian surface, offering up to five times the resolution of previous Mars imagery. It captures features as small as a coffee table, revealing detailed views of Martian terrain, including layered materials, gullies, and channels. The images are crucial for understanding the planet's surface and evaluating potential landing sites for future robotic and human missions. Developed with advanced imaging technologies, HiRISE continues to expand our knowledge of Mars with its superior resolution and contrast. For more information, visit [NASA](www.baesystems.com/en-us/product/hirise) and [University of Arizona](www.baesystems.com/en-us/product/hirise).
The EPOXI Deep Impact is a cutting-edge space exploration mission designed to enhance our understanding of comets. As part of the Deep Impact spacecraft program, this mission features advanced imaging and data collection technologies that allow scientists to study the surface composition and interior structure of comets. It successfully impacted the comet Tempel 1, providing vital information about the origins of our solar system. With its high-resolution imagery and scientific instrumentation, the EPOXI Deep Impact mission continues to play a critical role in space research, offering unprecedented insight into cometary science and the early solar system.
New Horizons/Ralph is a NASA mission designed to explore the dwarf planet Pluto, its moons, and other objects in the Kuiper Belt. The Ralph instrument aboard the spacecraft plays a pivotal role in capturing detailed images and spectral data, enhancing our understanding of Pluto’s surface composition and its atmosphere. This mission provides unprecedented insights into the outer reaches of the solar system, offering valuable data for planetary science and paving the way for future exploration of distant celestial bodies. For more information, visit [New Horizons/Ralph on BAE Systems](www.baesystems.com/en-us/product/new-horizons-ralph).
Kepler's K2 mission, launched in 2009, revolutionized our understanding of exoplanets by surveying over 150,000 stars, resulting in more than 3,600 planetary candidates and numerous groundbreaking discoveries. After its primary mission ended due to a technical issue, engineers developed a new K2 mission that continued Kepler's groundbreaking work using innovative solar pressure management techniques. K2's additional research focused on planet formation, stellar evolution, and extragalactic science, significantly expanding the Kepler spacecraft's contribution to astrophysical observations. Despite its retirement in 2018, Kepler's legacy includes more than 2,600 planet discoveries, many of which are potential candidates for life.
