{ "id": 14604, "url": "https://svs.gsfc.nasa.gov/14604/", "page_type": "Produced Video", "title": "NASA’s Roman Mission Gets Cosmic ‘Sneak Peek’ From Supercomputers", "description": "This graphic highlights part of a new simulation of what NASA’s Nancy Grace Roman Space Telescope could see when it launches by May 2027. The background spans about 0.11 square degrees (roughly equivalent to half of the area of sky covered by a full Moon), representing less than half the area Roman will see in a single snapshot. The inset zooms in to a region 300 times smaller, showcasing a swath of brilliant synthetic galaxies at Roman’s full resolution. Having such a realistic simulation helps scientists study the physics behind cosmic images –– both synthetic ones like these and future real ones. Researchers will use the observations for many types of science, including testing our understanding of the origin, evolution, and ultimate fate of the universe.Credit: C. Hirata and K. Cao (OSU) and NASA’s Goddard Space Flight Center || Roman_Simulation_Popout_2k_deg.jpg (2048x2048) [979.2 KB] || ", "release_date": "2024-06-12T10:00:00-04:00", "update_date": "2024-06-10T15:12:02.603511-04:00", "main_image": { "id": 1093182, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a014600/a014604/Roman_Simulation_Popout_2k_No_Labels.jpg", "filename": "Roman_Simulation_Popout_2k_No_Labels.jpg", "media_type": "Image", "alt_text": "Unlabeled version of the above.", "width": 2048, "height": 2048, "pixels": 4194304 }, "main_video": null, "main_credits": { "Written by": [ { "name": "Ashley Balzer", "employer": "eMITS" } ], "Produced by": [ { "name": "Scott Wiessinger", "employer": "eMITS" } ] }, "progress": "Complete", "media_groups": [ { "id": 374588, "url": "https://svs.gsfc.nasa.gov/14604/#media_group_374588", "widget": "Single image", "title": "", "caption": "", "description": "This graphic highlights part of a new simulation of what NASA’s Nancy Grace Roman Space Telescope could see when it launches by May 2027. The background spans about 0.11 square degrees (roughly equivalent to half of the area of sky covered by a full Moon), representing less than half the area Roman will see in a single snapshot. The inset zooms in to a region 300 times smaller, showcasing a swath of brilliant synthetic galaxies at Roman’s full resolution. Having such a realistic simulation helps scientists study the physics behind cosmic images –– both synthetic ones like these and future real ones. Researchers will use the observations for many types of science, including testing our understanding of the origin, evolution, and ultimate fate of the universe.

Credit: C. Hirata and K. Cao (OSU) and NASA’s Goddard Space Flight Center", "items": [ { "id": 430147, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 1093306, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a014600/a014604/Roman_Simulation_Popout_2k_deg.jpg", "filename": "Roman_Simulation_Popout_2k_deg.jpg", "media_type": "Image", "alt_text": "This graphic highlights part of a new simulation of what NASA’s Nancy Grace Roman Space Telescope could see when it launches by May 2027. The background spans about 0.11 square degrees (roughly equivalent to half of the area of sky covered by a full Moon), representing less than half the area Roman will see in a single snapshot. The inset zooms in to a region 300 times smaller, showcasing a swath of brilliant synthetic galaxies at Roman’s full resolution. Having such a realistic simulation helps scientists study the physics behind cosmic images –– both synthetic ones like these and future real ones. Researchers will use the observations for many types of science, including testing our understanding of the origin, evolution, and ultimate fate of the universe.Credit: C. Hirata and K. Cao (OSU) and NASA’s Goddard Space Flight Center", "width": 2048, "height": 2048, "pixels": 4194304 } } ], "extra_data": {} }, { "id": 374636, "url": "https://svs.gsfc.nasa.gov/14604/#media_group_374636", "widget": "Basic text with HTML", "title": "", "caption": "", "description": "Researchers are diving into a synthetic universe to help us better understand the real one. Using supercomputers at the U.S. DOE’s (Department of Energy’s) Argonne National Laboratory in Illinois, scientists have created nearly 4 million simulated images depicting the cosmos as NASA’s Nancy Grace Roman Space Telescope and the Vera C. Rubin Observatory, jointly funded by NSF (the National Science Foundation) and DOE, in Chile will see it.

For the first time, this simulation factored in the telescopes’ instrument performance, making it the most accurate preview yet of the cosmos as Roman and Rubin will see it once they start observing. Rubin will begin operations in 2025, and NASA’s Roman will launch by May 2027.

The simulation’s precision is important because scientists will comb through the observatories’ future data in search of tiny features that will help them unravel the biggest mysteries in cosmology.

Roman and Rubin will both explore dark energy –– the mysterious force thought to be accelerating the universe’s expansion. Since it plays a major role in governing the cosmos, scientists are eager to learn more about it. Simulations like OpenUniverse help them understand signatures that each instrument imprints on the images and iron out data processing methods now so they can decipher future data correctly. Then scientists will be able to make big discoveries even from weak signals.", "items": [], "extra_data": {} }, { "id": 374589, "url": "https://svs.gsfc.nasa.gov/14604/#media_group_374589", "widget": "Single image", "title": "", "caption": "", "description": "Unlabeled version of the above.", "items": [ { "id": 429988, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 1093182, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a014600/a014604/Roman_Simulation_Popout_2k_No_Labels.jpg", "filename": "Roman_Simulation_Popout_2k_No_Labels.jpg", "media_type": "Image", "alt_text": "Unlabeled version of the above.", "width": 2048, "height": 2048, "pixels": 4194304 } }, { "id": 429994, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 1093188, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a014600/a014604/Roman_Simulation_Popout_2k_No_Labels_searchweb.png", "filename": "Roman_Simulation_Popout_2k_No_Labels_searchweb.png", "media_type": "Image", "alt_text": "Unlabeled version of the above.", "width": 320, "height": 180, "pixels": 57600 } }, { "id": 429995, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 1093189, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a014600/a014604/Roman_Simulation_Popout_2k_No_Labels_thm.png", "filename": "Roman_Simulation_Popout_2k_No_Labels_thm.png", "media_type": "Image", "alt_text": "Unlabeled version of the above.", "width": 80, "height": 40, "pixels": 3200 } } ], "extra_data": {} }, { "id": 374590, "url": "https://svs.gsfc.nasa.gov/14604/#media_group_374590", "widget": "Single image", "title": "", "caption": "", "description": "This pair of images showcases the same region of sky as simulated by the Vera C. Rubin Observatory (left, processed by the Legacy Survey of Space and Time Dark Energy Science Collaboration) and NASA’s Nancy Grace Roman Space Telescope (right, processed by the Roman High-Latitude Imaging Survey Project Infrastructure Team). Roman will capture deeper and sharper images from space, while Rubin will observe a broader region of the sky from the ground. Because it has to peer through Earth’s atmosphere, Rubin’s images won’t always be sharp enough to distinguish multiple, close sources as separate objects. They’ll appear to blur together, which limits the science researchers can do using the images. But by comparing Rubin and Roman images of the same patch of sky, scientists can explore how to “deblend” objects and implement the adjustments across Rubin’s broader observations.

Credit: J. Chiang (SLAC), C. Hirata (OSU) and NASA's Goddard Space Flight Center", "items": [ { "id": 429989, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 1093183, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a014600/a014604/Rubin-Roman_Side-by-Side.jpg", "filename": "Rubin-Roman_Side-by-Side.jpg", "media_type": "Image", "alt_text": "This pair of images showcases the same region of sky as simulated by the Vera C. Rubin Observatory (left, processed by the Legacy Survey of Space and Time Dark Energy Science Collaboration) and NASA’s Nancy Grace Roman Space Telescope (right, processed by the Roman High-Latitude Imaging Survey Project Infrastructure Team). Roman will capture deeper and sharper images from space, while Rubin will observe a broader region of the sky from the ground. Because it has to peer through Earth’s atmosphere, Rubin’s images won’t always be sharp enough to distinguish multiple, close sources as separate objects. They’ll appear to blur together, which limits the science researchers can do using the images. But by comparing Rubin and Roman images of the same patch of sky, scientists can explore how to “deblend” objects and implement the adjustments across Rubin’s broader observations.Credit: J. Chiang (SLAC), C. Hirata (OSU) and NASA's Goddard Space Flight Center", "width": 3000, "height": 1500, "pixels": 4500000 } } ], "extra_data": {} }, { "id": 374591, "url": "https://svs.gsfc.nasa.gov/14604/#media_group_374591", "widget": "Single image", "title": "", "caption": "", "description": "Unlabeled version of the above", "items": [ { "id": 429990, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 1093184, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a014600/a014604/Rubin-Roman_Side-by-Side_No_Labels.jpg", "filename": "Rubin-Roman_Side-by-Side_No_Labels.jpg", "media_type": "Image", "alt_text": "Unlabeled version of the above", "width": 3000, "height": 1500, "pixels": 4500000 } } ], "extra_data": {} }, { "id": 374592, "url": "https://svs.gsfc.nasa.gov/14604/#media_group_374592", "widget": "Single image", "title": "", "caption": "", "description": "This full-resolution image highlights part of a new simulation of what NASA’s Nancy Grace Roman Space Telescope could see when it launches by May 2027. The image spans about 0.11 square degrees (roughly equivalent to half of the area of sky covered by a full Moon), representing less than half the area Roman will see in a single snapshot.

Credit: C. Hirata and K. Cao (OSU) ", "items": [ { "id": 429992, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 1093186, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a014600/a014604/sim_YHK_20x20arcmin.jpg", "filename": "sim_YHK_20x20arcmin.jpg", "media_type": "Image", "alt_text": "This full-resolution image highlights part of a new simulation of what NASA’s Nancy Grace Roman Space Telescope could see when it launches by May 2027. The image spans about 0.11 square degrees (roughly equivalent to half of the area of sky covered by a full Moon), representing less than half the area Roman will see in a single snapshot. Credit: C. Hirata and K. Cao (OSU) ", "width": 15360, "height": 15360, "pixels": 235929600 } }, { "id": 429993, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 1093187, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a014600/a014604/sim_YHK_20x20arcmin_half.jpg", "filename": "sim_YHK_20x20arcmin_half.jpg", "media_type": "Image", "alt_text": "This full-resolution image highlights part of a new simulation of what NASA’s Nancy Grace Roman Space Telescope could see when it launches by May 2027. The image spans about 0.11 square degrees (roughly equivalent to half of the area of sky covered by a full Moon), representing less than half the area Roman will see in a single snapshot. Credit: C. Hirata and K. Cao (OSU) ", "width": 7680, "height": 7680, "pixels": 58982400 } }, { "id": 429991, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 1093185, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a014600/a014604/sim_YHK_20x20arcmin.png", "filename": "sim_YHK_20x20arcmin.png", "media_type": "Image", "alt_text": "This full-resolution image highlights part of a new simulation of what NASA’s Nancy Grace Roman Space Telescope could see when it launches by May 2027. The image spans about 0.11 square degrees (roughly equivalent to half of the area of sky covered by a full Moon), representing less than half the area Roman will see in a single snapshot. Credit: C. Hirata and K. Cao (OSU) ", "width": 15360, "height": 15360, "pixels": 235929600 } } ], "extra_data": {} }, { "id": 374593, "url": "https://svs.gsfc.nasa.gov/14604/#media_group_374593", "widget": "Single image", "title": "", "caption": "", "description": "This photo displays Argonne Leadership Computing Facility’s now-retired Theta supercomputer. Scientists use supercomputers to simulate experiments they can’t conduct in real life, such as creating new universes from scratch.

Credit: Argonne National Laboratory", "items": [ { "id": 429996, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 1093190, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a014600/a014604/Theta-v1.jpg", "filename": "Theta-v1.jpg", "media_type": "Image", "alt_text": "This photo displays Argonne Leadership Computing Facility’s now-retired Theta supercomputer. Scientists use supercomputers to simulate experiments they can’t conduct in real life, such as creating new universes from scratch.Credit: Argonne National Laboratory", "width": 2100, "height": 1398, "pixels": 2935800 } } ], "extra_data": {} } ], "studio": "gms", "funding_sources": [ "NASA Astrophysics" ], "credits": [ { "role": "Science writer", "people": [ { "name": "Ashley Balzer", "employer": "eMITS" } ] }, { "role": "Producer", "people": [ { "name": "Scott Wiessinger", "employer": "eMITS" } ] }, { "role": "Scientist", "people": [ { "name": "Michael Troxel", "employer": "Duke University" } ] } ], "missions": [ "Nancy Grace Roman Space Telescope" ], "series": [ "Astrophysics Stills" ], "tapes": [], "papers": [], "datasets": [], "nasa_science_categories": [ "Universe" ], "keywords": [ "Astrophysics", "Galaxy", "Simulation", "Space", "Universe" ], "recommended_pages": [], "related": [ { "id": 14749, "url": "https://svs.gsfc.nasa.gov/14749/", "page_type": "Produced Video", "title": "OpenUniverse: Simulated Universe Views for Roman", "description": "This video begins with a tiny one-square-degree portion of the full OpenUniverse simulation area (about 70 square degrees, equivalent to an area of sky covered by more than 300 full moons). It spirals in toward a particularly galaxy-dense region, zooming by a factor of 75. This simulation showcases the cosmos as NASA’s Nancy Grace Roman Space Telescope could see it, allowing scientists to preview the next generation of cosmic discovery now. Roman’s real future surveys will enable a deep dive into the universe with highly resolved imaging, as demonstrated in this video.Credit: NASA’s Goddard Space Flight Center and M. Troxel || OpenUniverseFullZoom_4k_Best.00001_print.jpg (1024x576) [111.9 KB] || OpenUniverseFullZoom_4k_Good.mp4 (3840x2160) [101.9 MB] || OpenUniverseFullZoom_4k_Best.mp4 (3840x2160) [249.3 MB] || OpenUniverseFullZoom_ProRes_3840x2160_30.mov (3840x2160) [2.9 GB] || ", "release_date": "2025-01-14T10:00:00-05:00", "update_date": "2025-03-11T10:53:17.300160-04:00", "main_image": { "id": 1140877, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a014700/a014749/OpenUniverse_Roman_Field_Still_V2_searchweb.png", "filename": "OpenUniverse_Roman_Field_Still_V2_searchweb.png", "media_type": "Image", "alt_text": "Each tiny dot in the image at left is a galaxy simulated by the OpenUniverse campaign. The one-square-degree image offers a small window into the full simulation area, which is about 70 square degrees (equivalent to an area of sky covered by more than 300 full moons), while the inset at right is a close-up of an area 75 times smaller (1/600th the size of the full area). This simulation showcases the cosmos as NASA’s Nancy Grace Roman Space Telescope could see it. Roman will expand on the largest space-based galaxy survey like it – the Hubble Space Telescope’s COSMOS survey – which imaged two square degrees of sky over the course of 42 days. In only 250 days, Roman will view more than a thousand times more of the sky with the same resolution.Credit: NASA's Goddard Space Flight Center and M. Troxel", "width": 320, "height": 180, "pixels": 57600 } }, { "id": 14301, "url": "https://svs.gsfc.nasa.gov/14301/", "page_type": "Produced Video", "title": "Millions of Galaxies Emerge in New Simulated Images From NASA's Roman", "description": "This video begins by showing the most distant galaxies in the simulated deep field image in red. As it zooms out, layers of nearer (yellow and white) galaxies are added to the frame. By studying different cosmic epochs, Roman will be able to trace the universe's expansion history, study how galaxies developed over time, and much more.Credit: Caltech-IPAC/R. Hurt and M. Troxel || Roman_Zoom_still.jpg (1920x1080) [515.9 KB] || Roman_Zoom_still_searchweb.png (320x180) [106.4 KB] || Roman_Zoom_still_thm.png (80x40) [6.6 KB] || Roman_Zoom-HD2K.mp4 (1920x1080) [25.3 MB] || Roman_Zoom-HD2K.webm (1920x1080) [2.7 MB] || ", "release_date": "2023-03-08T10:00:00-05:00", "update_date": "2023-05-03T11:43:41.002855-04:00", "main_image": { "id": 765235, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a014300/a014301/Roman_Zoom_still.jpg", "filename": "Roman_Zoom_still.jpg", "media_type": "Image", "alt_text": "This video begins by showing the most distant galaxies in the simulated deep field image in red. As it zooms out, layers of nearer (yellow and white) galaxies are added to the frame. By studying different cosmic epochs, Roman will be able to trace the universe's expansion history, study how galaxies developed over time, and much more.\rCredit: Caltech-IPAC/R. Hurt and M. Troxel\r", "width": 1920, "height": 1080, "pixels": 2073600 } } ], "sources": [], "products": [], "newer_versions": [], "older_versions": [], "alternate_versions": [] }