\n<\/p>\n
by Tara Friesen<\/em><\/p>\n After ten months in orbit, the\u00a0Starling\u00a0spacecraft swarm successfully demonstrated its primary mission\u2019s key objectives, representing significant achievements in the capability of swarm configurations.\u00a0<\/p>\n Swarms of satellites may one day be used in deep space exploration. An autonomous network of spacecraft could self-navigate, manage scientific experiments, and execute maneuvers to respond to environmental changes without the burden of significant communications delays between the swarm and Earth.\u00a0<\/p>\n \u201cThe success of Starling\u2019s initial mission represents a landmark achievement in the development of autonomous networks of small spacecraft,\u201d said Roger Hunter, program manager for NASA\u2019s Small Spacecraft Technology program at NASA\u2019s Ames Research Center in California\u2019s Silicon Valley. \u201cThe team has been very successful in achieving our objectives and adapting in the face of challenges.\u201d\u00a0\u00a0<\/p>\n The Distributed Spacecraft Autonomy (DSA) experiment, flown onboard Starling, demonstrated the spacecraft swarm\u2019s ability to optimize data collection across the swarm. The CubeSats analyzed Earth\u2019s ionosphere by identifying interesting phenomena and reaching a consensus between each satellite on an approach for analysis.\u00a0\u00a0<\/p>\n By sharing observational work across a swarm, each spacecraft can \u201cshare the load\u201d and observe different data or work together to provide deeper analysis, reducing human workload, and keeping the spacecraft working without the need for new commands sent from the ground.\u00a0<\/p>\n The experiment\u2019s success means Starling is the first swarm to autonomously distribute information and operations data between spacecraft to generate plans to work more efficiently, and the first demonstration of a fully distributed onboard reasoning system capable of reacting quickly to changes in scientific observations.\u00a0<\/p>\n A swarm of spacecraft needs a network to communicate between each other. The Mobile Ad-hoc Network (MANET) experiment automatically established a network in space, allowing the swarm to relay commands and transfer data between one another and the ground, as well as share information about other experiments cooperatively.\u00a0\u00a0<\/p>\n The team successfully completed all the MANET experiment objectives, including demonstrating routing commands and data to one of the spacecraft having trouble with space to ground communications, a valuable benefit of a cooperative spacecraft swarm.\u00a0<\/p>\n \u201cThe success of MANET demonstrates the robustness of a swarm,\u201d said Howard Cannon, Starling project manager at NASA Ames. \u201cFor example, when the radio went down on one swarm spacecraft, we \u2018side-loaded\u2019 the spacecraft from another direction, sending commands, software updates, and other vital information to the spacecraft from another swarm member.\u201d\u00a0<\/p>\n Navigating and operating in relation to one another and the planet is an important part of forming a swarm of spacecraft. Starling Formation-Flying Optical Experiment, or StarFOX, uses star trackers to recognize a fellow swarm member, other satellite, or space debris from the background field of stars, then estimate each spacecraft\u2019s position and velocity.\u00a0<\/p>\n The experiment is the first-ever published demonstration of this type of swarm navigation, including the ability to track multiple members of a swarm simultaneously and the ability to share observations between the spacecraft, improving accuracy when determining each swarm member\u2019s orbit.\u00a0<\/p>\n Near the end of mission operations, the swarm was maneuvered into a passive safety ellipse, and in this formation, the StarFOX team was able to achieve a groundbreaking milestone, demonstrating the ability to autonomously estimate the swarm\u2019s orbits using only inter-satellite measurements from the spacecraft star trackers.\u00a0<\/p>\n The ability to plan and execute maneuvers with minimal human intervention is an important part of developing larger satellite swarms. Managing the trajectories and maneuvers of hundreds or thousands of spacecraft autonomously saves time and reduces complexity.\u00a0<\/p>\n The Reconfiguration and Orbit Maintenance Experiments Onboard (ROMEO) system tests onboard maneuver planning and execution by estimating the spacecraft\u2019s orbit and planning a maneuver to a new desired orbit.\u00a0<\/p>\n The experiment team has successfully demonstrated the system\u2019s ability to determine and plan a change in orbit and is working to refine the system to reduce propellant use and demonstrate executing the maneuvers. The team will continue to adapt and develop the system throughout Starling\u2019s mission extension.\u00a0<\/p>\n Now that Starling\u2019s primary mission objectives are complete, the team will embark on a mission extension known as Starling 1.5, testing space traffic coordination in partnership with SpaceX\u2019s Starlink constellation, which also has autonomous maneuvering capabilities. The project will explore how constellations operated by different users can share information through a ground hub to avoid potential collisions.\u00a0\u00a0<\/p>\n \u201cStarling\u2019s partnership with SpaceX is the next step in operating large networks of spacecraft and understanding how two autonomously maneuvering systems can safely operate in proximity to each other. As the number of operational spacecraft increases each year, we must learn how to manage orbital traffic,\u201d said Hunter.\u00a0<\/p>\n NASA\u2019s Small Spacecraft Technology program, based at Ames and within NASA\u2019s Space Technology Mission Directorate (STMD), funds and manages the Starling mission. Blue Canyon Technologies designed and manufactured the spacecraft buses and is providing mission operations support. Rocket Lab USA, Inc. provided launch and integration services. Partners supporting Starling\u2019s payload experiments have included Stanford University\u2019s Space Rendezvous Lab in Stanford, California, York Space Systems (formerly Emergent Space Technologies) of Denver, Colorado, CesiumAstro of Austin, Texas, L3Harris Technologies, Inc., of Melbourne, Florida.\u00a0Funding support for the DSA experiment was provided by NASA\u2019s Game Changing Development program within STMD.<\/em>\u00a0Partners supporting Starling\u2019s mission extension include SpaceX of Hawthorne, California, NASA\u2019s Conjunction Assessment Risk Analysis (CARA) program, and the Department of Commerce. SpaceX manages the Starlink satellite constellation and the Collision Avoidance ground system.<\/em><\/p>\n by Frank Tavares<\/em><\/p>\n The 3-Dimensional Multifunctional Ablative Thermal Protection System (3D-MAT) is a thermal protection material developed as a critical component of\u00a0Orion, NASA\u2019s newest spacecraft built for human deep space missions.\u00a0It is able to maintain a high level of strength while enduring extreme temperatures during re-entry into Earth\u2019s atmosphere at the end of Artemis missions to the Moon. 3D-MAT has become an essential piece of technology for NASA\u2019s Artemis campaign that will establish the foundation for long-term scientific exploration at the Moon and prepare for human expeditions to Mars, for the benefit of all.<\/p>\n The 3D-MAT project emerged from a technical problem in early designs of the Orion spacecraft. The compression pad\u2014the connective interface between the crew module, where astronauts reside, and the service module carrying power, propulsion, supplies, and more\u2014was exhibiting issues during Orion\u2019s first test flight, Exploration Flight Test-1, in 2014. NASA engineers realized they needed to find a new material for the compression pad that could hold these different components of Orion together while withstanding the extremely high temperatures of atmospheric re-entry. Using a 3D weave for NASA heat shield materials had been explored, but after the need for a new material for the compression pad was discovered, development quickly escalated.<\/p>\n This led to the evolution of 3D-MAT, a material woven with quartz yarn and cyanate ester resin in a unique three-dimensional design. The quartz yarn used is like a more advanced version of the fiberglass insulation you might have in your attic, and the resin is essentially a high-tech glue. These off-the-shelf aerospace materials were chosen for their ability to maintain their strength and keep heat out at extremely high temperatures. 3D-MAT is woven together with a specialized loom, which packs the yarns tightly together, and then injected with resin using a unique pressurized process. The result is a high-performance material that is extremely effective at maintaining strength when it\u2019s hot, while also insulating the heat from the spacecraft it is protecting.<\/p>\n Within three years, 3D-MAT went from an early-stage concept to a well-developed material and has now been integrated onto NASA\u2019s flagship Artemis campaign. The use of 3D-MAT in the Orion spacecraft\u2019s compression pad during the successful Artemis I mission demonstrated the material\u2019s essential role for NASA\u2019s human spaceflight efforts. This development was made possible within such a short span of time because of the team\u2019s collaboration with small businesses including Bally Ribbon Mills, which developed the weaving process, and San Diego Composites, which co-developed the resin infusion procedure with NASA.<\/p>\n The team behind its development won the NASA Invention of the Year Award, a prestigious honor recognizing how essential 3D-MAT was for the successful Artemis flight and how significant it is for NASA\u2019s future Artemis missions. The inventor team recognized includes Jay Feldman and Ethiraj Venkatapathy from NASA\u2019s Ames Research Center in California\u2019s Silicon Valley, Curt Wilkinson of Bally Ribbon Mills, and Ken Mercer of Dynovas.<\/p>\n 3D-MAT has applications beyond NASA as well. Material processing capabilities enabled by 3D-MAT have led to other products such as structural parts for Formula One racecars and rocket motor casings. Several potential uses of 3D-MAT in commercial aerospace vehicles and defense are being evaluated based on its properties and performance.<\/p>\n The 3D-MAT project is led out of NASA Ames with the support of various partners, including Bally Ribbon Mills, NASA\u2019s Johnson Space Center in Houston, and NASA\u2019s Langley Research Center in Hampton, Viginia, with the support of the Game Changing Development Program through NASA\u2019s Space Technology Mission Directorate.<\/p>\n The annual Presidential Rank & NASA Honor Awards Ceremony was held at Ames, and shown virtually, on May 22 in the Ames Auditorium, in N201. Seventy-three employees were selected for individual Presidential and NASA Honor awards and 27 groups were selected for NASA Group Achievement Awards. <\/p>\n Congratulations to all the recipients. Please see below for the list of awardees. <\/p>\n 2023 Presidential Rank and NASA Honor Award Recipients<\/strong>\u00a0\u00a0<\/p>\n \u202f\u00a0<\/p>\n Presidential Rank of Meritorious Senior Executive<\/strong>\u00a0\u00a0<\/p>\n Michael Hesse\u00a0<\/p>\n \u202f\u00a0<\/p>\n Distinguished Service Medal<\/strong>\u00a0 Huy K. Tran\u00a0<\/p>\n Diversity, Equity, Inclusion, and Accessibility Medal<\/strong>\u00a0 Parag A. Vaishampayan\u00a0<\/p>\n Early Career Achievement Medal<\/strong>\u00a0 Exceptional Achievement Medal<\/strong>\u00a0 \u202f<\/strong>\u00a0<\/p>\n Exceptional Engineering Achievement Medal\u202f<\/strong>\u00a0<\/p>\n Joseph L. Rios\u00a0<\/p>\n Mark M. Weislogel\u00a0<\/p>\n Joseph D. Williams\u00a0<\/p>\n \u202f<\/strong>\u00a0<\/p>\n Exceptional Public Achievement Medal<\/strong>\u00a0<\/p>\n Danielle K. Lopez\u00a0<\/p>\n Wade M. Spurlock\u00a0<\/p>\n Sasha V. Weston\u00a0<\/p>\n \u202f\u00a0<\/p>\n Exceptional Public Service Medal<\/strong>\u00a0\u00a0 Michael J. Hirschberg\u00a0<\/p>\n \u202f\u00a0<\/p>\n Exceptional Scientific Achievement Medal<\/strong>\u00a0\u00a0 Ju-Mee Ryoo\u00a0<\/p>\n \u202f\u00a0<\/p>\n Exceptional Service Medal<\/strong>\u00a0\u00a0 Robert A. Duffy\u00a0<\/p>\n Shawn A. Engelland\u00a0<\/p>\n Thomas P. Greene\u00a0<\/p>\n Paul W. Lam\u00a0<\/p>\n Bernadette Luna\u00a0<\/p>\n Andres Martinez\u00a0<\/p>\n Ramsey K. Melugin\u00a0<\/p>\n Owen Nishioka\u00a0<\/p>\n Kathryn B. Packard\u00a0<\/p>\n Andrzej Pohorille (Posthumously)\u00a0<\/p>\n Stevan Spremo\u00a0<\/p>\n Mark S. Washington\u00a0<\/p>\n \u202f\u00a0<\/p>\n Exceptional Technology Achievement Medal<\/strong>\u00a0\u00a0 Norbert P. Gillem\u00a0<\/p>\n Emre Sozer\u00a0<\/p>\n \u202f\u00a0<\/p>\n Outstanding Leadership Medal<\/strong>\u00a0\u00a0 William N. Chan\u00a0<\/p>\n Marilyn Vasques\u00a0<\/p>\n \u202f\u00a0<\/p>\n Silver Achievement Medal<\/strong>\u00a0\u00a0 Juan L. Torres-P\u00e9rez\u00a0(Langley Research Center Nomination)\u00a0<\/p>\n \u202f\u00a0<\/p>\n Group Achievement Award<\/strong>\u00a0\u00a0<\/p>\n ARCTIC 3 Simulation Team\u00a0<\/p>\n Artemis I Char Loss Anomaly Investigation Team\u00a0<\/p>\n CapiSorb Visible System Team\u00a0<\/p>\n Center Engagement Strategy\u00a0<\/p>\n Convective Processes Experiment-AW and -CV\u00a0<\/p>\n Design for Maintainability\u00a0<\/p>\n DIP Planning and Field Test Team\u00a0<\/p>\n Executive Wildfire Roundtable and Showcase\u00a0<\/p>\n Flight IACUC\u00a0<\/p>\n Long Static Pipe Manufacturing Team\u00a0<\/p>\n Moon to Mars SE&I Verification Compliance Tool\u00a0<\/p>\n N225 Arc Flash Mishap Investigation Team\u00a0<\/p>\n NASA Aeronautics Sample Recovery Helicopter Team\u00a0<\/p>\n NASA Ames SLS CFD Team\u00a0<\/p>\n Next Generation Life Sciences Data Archive Team\u00a0<\/p>\n OSHA VPP Recertification Team\u00a0<\/p>\n Planetary Aeolian Laboratory ROSES Proposal Team\u00a0<\/p>\n SOFIA Project Closeout Team\u00a0<\/p>\n Submesoscale Ocean Dynamics Experiment (S-MODE)\u00a0<\/p>\n The ACCLIP Team\u00a0<\/p>\n The DCOTSS Team\u00a0<\/p>\n The IMPACTS Team\u00a0<\/p>\n The Meteorological Measurement System (MMS)\u00a0<\/p>\n UAM eVTOL Vehicle Design and Analysis Team\u00a0<\/p>\n UAM Side-by-Side 2 Aeroperformance Test Team\u00a0<\/p>\n Western Diversity Time Series Data Collection Team\u00a0<\/p>\n Wide Field of View\u00a0<\/p>\n by Maria C. Lopez<\/p>\n As part of the Ames Veterans Committee (AVC) employee resource group, Brad Ensign, and James Schwab, who are both Army veterans, work to support other veterans and our local Afghan and Ukrainian war refugee communities.\u00a0The fall of Afghanistan to the Taliban was especially heart wrenching for Afghan war veterans and created a feeling of discouragement. The war in Ukraine only increased the level of disheartenment for many veterans. Importantly, the Ames Veterans Committee provides a forum to help veterans heal, and just as importantly, help our local community deal with the influx of Afghan and Ukrainian war refugees.\u00a0<\/p>\n Through the AVC Community Outreach Team, Brad Ensign coordinated to donate computers from the Ledios company, which is NASA\u2019s Workplace & Collaboration Services to The Jewish Family & Community Services \u2013 East Bay and The Jewish Family Services of Silicon Valley. Leidos was awarded the Advanced Enterprise Global Information Technology Solutions (AEGIS) contract by NASA. In addition to AEGIS, Leidos provides enterprise IT services to NASA through the NASA End-User Services and Technologies (NEST) contract. Both contracts support NASA\u2019s overall IT operation and mission. Once an end-user computer reaches the device\u2019s end-of-life cycle per the NEST contract, the computers are repurposed for local charity use. The computers are verified to be in good working condition by the Leidos\/NEST team.\u00a0<\/p>\n Brad Ensign periodically pings the Ames NEST Center Operations manager for available computer donations and the manager verifies that good working computers are available for donation. Brad then contacts various Afghan and Ukrainian war refugee assistance charities to determine their computer needs. Many of these local charities rely on donations and do not have an IT budget. Once a need is determined by local charities, Brad coordinates the number of computers available and a delivery date and time. James Schwab enthusiastically supports this effort and has provided incredible logistical support transporting the computers to the donation location.<\/p>\n Notably\u00a0<\/strong>in October 2023, Brad and James successfully delivered 25 laptop computers, five desktop computers, and 30 monitors to the Jewish Family & Community Services \u2013 East Bay.\u00a0<\/p>\n The support for the Jewish Family & Community Services continued and in December of 2023, Brad helped deliver groceries to Afghan war refugees. So far this year, Brad, James, the Ledios company, and the NASA Ames Veterans Committee have donated a total of 40 computers and 40 monitors. These computers are extremely helpful for Afghan and Ukrainian war refugees to write resumes, find jobs, communicate with loved ones left behind, assist with personal tasks, stay informed of world and local news, help their children with schoolwork, and for entertainment. Donated computers are a tremendous resource for local war refugees and this initiative helps NASA Ames Veterans ease feelings of distress by making a difference in their community.\u00a0<\/p>\n On May 9, 2024,\u00a0<\/strong>Brad and James received a Federal Employee of the Year Award from the San Francisco Federal Executive Board (SFFEB) for Volunteer Excellence based on their leadership on creating opportunities for the Ames Veterans Committee to work together during a trying time for veterans while making an ongoing, positive impact in the local community.\u00a0<\/p>\n After nearly 40 years of service to science, on May 15 the Ames community had a chance to bid a final farewell to the\u00a0DC-8 Flying Laboratory\u00a0as it made its way to retirement in Idaho. NASA Ames, in coordination with NASA Armstrong, had arranged for a low-pass flyover of Ames Research Center at approximately 11:10 a.m. PDT in honor of the staff, scientists, and engineers who enabled the DC-8 to make such a profound impact on Earth science around the globe. \u00a0<\/p>\n The History of Ames and the DC-8<\/strong><\/p>\n The NASA DC-8 is a world-class flying laboratory that has played a crucial role in answering fundamental questions across nearly every scientific discipline exploring Earth\u2019s interacting systems, and how they are changing. The versatile research aircraft was unprecedented for its ability to carry multiple instruments and thereby take simultaneous active, passive, and in-situ measurements, while also providing room for 42 investigators onboard and boasting an impressive range of more than 5,000 miles. \u00a0<\/p>\n Ames has been involved in the science operations of the DC-8 since its arrival at Moffett Field in 1987, including long after the aircraft moved to NASA Armstrong (then NASA Dryden) in the late 1990s. Scientists at Ames continued to lead air quality and climate investigations.\u00a0The Earth Science Project Office (ESPO)\u00a0managed complex DC-8 deployments all over the world. And the\u00a0National Suborbital Research Center (NSRC)\u00a0provided critical engineering for instrument integration and the upgrading of onboard IT systems and networks, providing global satellite communications to enable real-time science anywhere in the world.\u00a0<\/p>\n During its first scientific mission, the DC-8 helped to establish the primary cause of the ozone hole over the southern Pacific. Other early missions focused on atmospheric science and developing new instruments for remote sensing. This work ultimately led to the upcoming \u00a0NASA-ISRO Synthetic Aperture Radar (NISAR) mission, launching later this year, which will provide new insights into Earth\u2019s processes. \u00a0<\/p>\n The DC-8 went on to provide calibration and validation for numerous satellite missions, including the\u00a0Total Ozone Mapping Spectrometer (TOMS)\u00a0series of missions and later for the\u00a0Aura satellite. The DC-8 also provided critical measurements over both poles as part of\u00a0Operation IceBridge.<\/p>\n The DC-8 successfully completed its final mission in March of this year, flying atmospheric sampling instruments for the\u00a0Airborne and Satellite Investigation of Asian Air Quality (ASIA-AQ) campaign.\u00a0Over the last decade, the DC-8 has also served an important role in training the next generation of Earth scientists and engineers through the\u00a0Student Airborne Research Program (SARP).<\/p>\n As we bid farewell to this special aircraft, the DC-8 has cleared the runway for the next generation of flying laboratory: the B777. A study performed by the\u00a0National Academies of Science and Medicine\u00a0strongly endorsed the need for a NASA flying laboratory to replace the DC-8, resulting in the acquisition of the B777. The team at Ames is working together with NASA Langley and NASA HQ to ensure the B777 will continue to support the science community and exceed the capabilities of the DC-8 with longer range, endurance, and payload capacity: honoring and expanding its legacy for generations of scientists to come. \u00a0<\/p>\n The Historic Preservation Office at NASA Ames\u2019\u00a0Hangar 3 historical web site\u00a0is now live! \u00a0Ames Research Center and Planetary Ventures, in consultation with the National Park Service, California State Historic Preservation Office, and the Advisory Council on Historic Preservation created a website and film that documents the history and features of Hangar 3, provides valuable information for future researchers, and celebrates its local and global impact.<\/p>\n You also can find additional historical information at NASA Ames and Moffett Field here, including buildings and districts listed in the\u00a0National Register of Historic Places, information about\u00a0Hangar 1\u00a0and\u00a0Hangar 3, historical resources associated with the\u00a0Space Shuttle and NASA Ames, and much more!<\/p>\n It is with great sadness we share with you the news that\u00a0our good friend and colleague, Fred G. Martwick,\u00a0passed away on April 29, 2024,\u00a0after a brief illness. A\u00a0Celebration of Life service will be held on Tuesday, June 11, at 1 p.m. at the Calvary Church, 16330 Los Gatos Blvd, Los Gatos, California 95032.\u00a0 The event is open to all who wish to attend.\u00a0\u00a0In addition, everyone is invited to a\u00a0flag ceremony to honor Fred on Tuesday, June 25, at 10:30 a.m. PDT in front of the N-200 flagpole at NASA Ames.<\/p>\n Graduating\u00a0in 1985\u00a0with a BS in mechanical engineering from San Jose State, Fred began his career with IBM in south San Jose.\u00a0 After a few years, he came on-board at NASA Ames as a support service contractor in the Engineering Division. His abilities and personal work ethic were recognized, and he was quickly recruited for civil service (CS) conversion, first becoming an Army CS employee in the early 1990s, and later transitioning to NASA CS.<\/p>\n In the 1990s, Fred supported and then led\u00a0several successful space sciences projects.\u00a0 Concurrently, he served as one of the Ames representatives of the Aerospace Mechanisms Symposium organizing committee, consisting of representatives from the other NASA centers and Lockheed Martin. This group organized and sponsored the symposium on a set rotation within the NASA centers.\u00a0<\/p>\n In the late 1990s, after an offsite contractor failed to meet NASA\u2019s specifications and timeline, the successful partnership of Fred and Dave Ackard managed the onsite manufacture and assembly of the SOFIA Cavity Door.\u00a0 In the 2000s, Fred managed the planning, design, and prototype fabrication of a nano-satellite and deployment system in conjunction with Stanford.\u00a0 Fred then managed the challenging procurement and fabrication of an intricate powered wind tunnel model of the Orion Crew Escape System.\u00a0 The model and subsequent tests were key elements for the analysis test verification of the Escape System.<\/p>\n In the 2010s, Fred had established an intricate manufacturing documentation control system, creating a contracting \u201cwar room\u201d in the mezzanine above the N211 Fabrication Shop.\u00a0 From here, large amounts of space flight certified animal hardware were planned, contracted, tracked, assembled, and certified for flight to the International Space Station.\u00a0 Fred\u2019s procurement and documentation control system greatly impressed visiting customers from NASA\/JSC management. In 2014, Fred\u00a0was awarded the coveted Silver Snoopy Award in recognition of his\u00a0outstanding performance in space flight system development and manufacturing.<\/p>\n By the 2020s, Fred had moved to the Chief Engineers Office in Code D supporting project oversight while keeping an eye on his upcoming retirement.\u00a0 Fred\u2019s dedication to NASA had pushed his retirement out a few times but was well within sight with the purchase of a beautiful home near Spokane, Washington. He was very involved with the organization Assist International and enjoyed working with the project Caminul Felix in Romania. Additionally, he worked with the Calvary Church ministry with junior high school kids. He was bus driver for the kids at the ministry, taking them to Hume Lake Christian Camp where he was the waterskiing boat driver for the kids as they waterskied behind the boat around the lake.<\/p>\n Fred will be greatly missed by the many people who have worked with him over his 30 plus years of outstanding service.\u00a0 He will be remembered as a man of unwavering faith, a shrewd negotiator, an excellent project manager and systems engineer capable of diving into and clearly documenting the details while not losing sight of the big picture.\u00a0 His ability to \u201cget things done\u201d makes his passing a great loss for NASA.<\/p>\n All of Fred\u2019s many friends from his NASA family are welcome to attend the memorial service and flag ceremony.<\/p>\n<\/div>\nSharing the Work<\/em><\/h4>\n
Communicating Across the Swarm<\/em><\/h4>\n
Autonomous Swarm Navigation\u00a0<\/em><\/h4>\n
Managing Swarm Maneuvers\u00a0<\/em><\/h4>\n
Swarming Together<\/em><\/h4>\n
Milestones<\/em><\/h4>\n
\n
Partners<\/em><\/h4>\n
Bhavya Lal (A-Suite Nomination)\u00a0
Thomas R. Norman\u00a0<\/p>\n
Dora M. Herrera\u00a0<\/p>\n
Natasha E. Batalha\u00a0
Mirko E. Blaustein-Jurcan\u00a0
Athena Chan\u00a0
Kathryn M. Chapman\u00a0
Chad J. Cleary\u00a0
Christine E. Gregg\u00a0
Supreet Kaur\u00a0
James R. Koch\u00a0
Elizabeth L. Lash\u00a0
Terrence D. Lewis\u00a0
Garrett G. Sadler\u00a0
Meghan C. Saephan\u00a0
Jordan A. Sakakeeny\u00a0
Lauren M. Sanders\u00a0
Amanda M. Saravia-Butler\u00a0
Logan Torres\u00a0
Lauren E. Wibe\u00a0
Shannah N. Withrow\u00a0
Emina Zanacic\u00a0<\/p>\n
Lauren J. Abbott\u00a0
Parul Agrawal\u00a0
Steven D. Beard\u00a0
Janet E. Beegle\u00a0
Jose V. Benavides\u00a0
Divya Bhadoria\u00a0
Sergio A. Briceno\u00a0
Holly L. Brosnahan\u00a0
Karen T. Cate\u00a0
Fay C. Chinn\u00a0
William J. Coupe\u00a0
Frances M. Donovan (Langley Research Center Nomination)\u00a0
Diana M. Gentry\u00a0
Lynda L. Haines\u00a0
Pallavi Hegde\u00a0
Shu-Chun Y. Lin\u00a0
Carlos Malpica\u00a0
Jeffrey W. McCandless\u00a0
Joshua D. Monk\u00a0
Mariano M. Perez\u00a0
Nathan J. Piontak (OPS Nomination)\u00a0
Vidal Salazar\u00a0
David W. Schwenke\u00a0
Eric C. Stern\u00a0<\/p>\n
John J. Freitas (OCOMM Nomination)\u00a0<\/p>\n
Noah G. Randolph-Flagg\u00a0<\/p>\n
Soheila Dianati\u00a0<\/p>\n
Ruslan Belikov\u00a0<\/p>\n
Michael D. Barnhardt\u00a0<\/p>\n
Christine L. Munroe (MSEO \u2013 OSBP Nomination)\u00a0<\/p>\n