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By NASA
4 min read
Preparations for Next Moonwalk Simulations Underway (and Underwater)
NASA and SpaceX are launching the company’s 32nd commercial resupply services mission to the International Space Station later this month, bringing a host of new research to the orbiting laboratory. Aboard the SpaceX Dragon spacecraft are experiments focused on vision-based navigation, spacecraft air quality, materials for drug and product manufacturing, and advancing plant growth with less reliance on photosynthesis.
This and other research conducted aboard the space station advances future space exploration, including missions to the Moon and Mars, and provides many benefits to humanity.
Investigations traveling to the space station include:
Robotic spacecraft guidance
Smartphone Video Guidance Sensor-2 (SVGS-2) uses the space station’s Astrobee robots to demonstrate using a vision-based sensor developed by NASA to control a formation flight of small satellites. Based on a previous in-space demonstration of the technology, this investigation is designed to refine the maneuvers of multiple robots and integrate the information with spacecraft systems.
Potential benefits of this technology include improved accuracy and reliability of systems for guidance, navigation, and control that could be applied to docking crewed spacecraft in orbit and remotely operating multiple robots on the lunar or Martian surface.
Two of the space station’s Astrobee robots are used to test a vision-based guidance system for Smartphone Video Guidance Sensor (SVGS)NASA Protection from particles
During spaceflight, especially long-duration missions, concentrations of airborne particles must be kept within ranges safe for crew health and hardware performance. The Aerosol Monitors investigation tests three different air quality monitors in space to determine which is best suited to protect crew health and ensure mission success. The investigation also tests a device for distinguishing between smoke and dust. Aboard the space station, the presence of dust can cause false smoke alarms that require crew member response. Reducing false alarms could save valuable crew time while continuing to protect astronaut safety.
Better materials, better drugs
The DNA Nano Therapeutics-Mission 2 produces a special type of molecule formed by DNA-inspired, customizable building blocks known as Janus base nanomaterials. It also evaluates how well the materials reduce joint inflammation and whether they can help regenerate cartilage lost due to arthritis. These materials are less toxic, more stable, and more compatible with living tissues than current drug delivery technologies.
Environmental influences such as gravity can affect the quality of these materials and delivery systems. In microgravity, they are larger and have greater uniformity and structural integrity. This investigation could help identify the best formulations and methods for cost-effective in-space production. These nanomaterials also could be used to create novel systems targeting therapy delivery that improves patient outcomes with fewer side effects.
Stem cells grown along the Janus base nanomaterials (JBNs) made aboard the International Space Station.University of Connecticut Next-generation pharmaceutical nanostructures
The newest Industrial Crystallization Cassette (ADSEP-ICC) investigation adds capabilities to an existing protein crystallization facility. The cassette can process more sample types, including tiny gold particles used in devices that detect cancer and other diseases or in targeted drug delivery systems. Microgravity makes it possible to produce larger and more uniform gold particles, which improves their use in research and real-life applications of technologies related to human health.
Helping plants grow
Rhodium USAFA NIGHT examines how tomato plants respond to microgravity and whether a carbon dioxide replacement can reduce how much space-grown plants depend on photosynthesis. Because photosynthesis needs light, which requires spacecraft power to generate, alternatives would reduce energy use. The investigation also examines whether using supplements increases plant growth on the space station, which has been observed in preflight testing on Earth. In future plant production facilities aboard spacecraft or on celestial bodies, supplements could come from available organic materials such as waste.
Understanding how plants adapt to microgravity could help grow food during long-duration space missions or harsh environments on Earth.
Hardware for the Rhodium Plant LIFE, which was the first in a series used to study how space affects plant growth.NASA Atomic clocks in space
An ESA (European Space Agency) investigation, Atomic Clock Ensemble in Space (ACES), examines fundamental physics concepts such as Einstein’s theory of relativity using two next-generation atomic clocks operated in microgravity. Results have applications to scientific measurement studies, the search for dark matter, and fundamental physics research that relies on highly accurate atomic clocks in space. The experiment also tests a technology for synchronizing clocks worldwide using global navigation satellite networks.
An artist’s concept shows the Atomic Clock Ensemble in Space hardware mounted on the Earth-facing side of the space station’s exterior.ESA Download high-resolution photos and videos of the research mentioned in this article.
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By NASA
NASA Deep Space Station 43 (DSS-43), a 230-foot-wide (70-meter-wide) radio antenna at NASA’s Deep Space Network facility in Canberra, Australia, is seen in this March 4, 2020, image. DSS-43 was more than six times as sensitive as the original antenna at the Canberra complex, so it could communicate with spacecraft at greater distances from Earth. In fact, Canberra is the only complex that can send commands to, and receive data from, Voyager 2 as it heads south almost 13 billion miles (21 billion kilometers) through interstellar space. More than 15 billion miles (24 billion kilometers) away, Voyager 1 sends its data down to the Madrid and Goldstone complexes, but it, too, can only receive commands via Canberra.
As the Canberra facility celebrated its 60th anniversary on March 19, 2025, work began on a new radio antenna. Canberra’s newest addition, Deep Space Station 33, will be a 112-foot-wide (34-meter-wide) multifrequency beam-waveguide antenna. Buried mostly below ground, a massive concrete pedestal will house cutting-edge electronics and receivers in a climate-controlled room and provide a sturdy base for the reflector dish, which will rotate during operations on a steel platform called an alidade.
When it goes online in 2029, the new Canberra dish will be the last of six parabolic dishes constructed under NASA’s Deep Space Network Aperture Enhancement Program, which is helping to support current and future spacecraft and the increased volume of data they provide. The network’s Madrid facility christened a new dish in 2022, and the Goldstone, California, facility is putting the finishing touches on a new antenna.
Image credit: NASA
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By NASA
Explore This Section Science Science Activation Findings from the Field: A… Overview Learning Resources Science Activation Teams SME Map Opportunities More Science Activation Stories Citizen Science 3 min read
Findings from the Field: A Research Symposium for Student Scientists
Within the scientific community, peer review has become the process norm for which an author’s research or ideas undergo careful examination by other experts in their field. It encourages each scientist to meet the high standards that they themselves, as writers and reviewers, have aided in setting. It has become essential to the academic writing practice.
Historically, the peer review process has been limited to higher education and scholars more established in their academic careers. It has been required by only the more reputable publications, which can mean that lesser-known journals that don’t require this rigorous peer review process contain lower quality or less reliable information.
In an effort to give scientists of all ages the opportunity to participate in and contribute to the advancement of human knowledge in a meaningful and reliable way, the Gulf of Maine Research Institute (GMRI) began publishing Findings from the Field, a journal of student ecological and environmental science, launched in 2017. Students conduct authentic scientific inquiry, subject their research to the peer review process, and submit their revised work for editorial board review before publication—the same process a NASA scientist must go through! This hands-on, real-world experience in scientific communication sharpens these young scientists’ skills and immerses them in the collaborative nature of research—an essential foundation for the next generation of scientists.
After 7 years and 7 published volumes, Findings from the Field was ready to expand, and the Findings Student Research Symposium was launched. The Symposium was a success from the start, with 65 student scientists joining the event the first year and attendance climbing to 95 for year two. On March 10, 2025, GMRI (the anchor institution for the NASA Science Activation program’s Learning Ecosystems Northeast (LENE) project) welcomed nearly 100 young scientists, ranging from grades 5-12. These students, representing eight schools across Maine and New Hampshire, came together to share their research and engage in an evolving, intergenerational scientific community—one that fosters curiosity, collaboration, and scientific discovery.
Students presented their research through posters and live presentations, covering topics ranging from invasive green crab species, to the changing landscapes of Ash and Hemlock trees, and more. By connecting students with professional researchers, fostering peer discussions, and providing a platform for publishing legitimate scientific work, the Findings Symposium is a launch pad for the future of the scientific community.
One important element of the Symposium is the opportunity for young scientists to dialogue with professional scientists. Students engaged with researchers from Markus Frederich’s lab at the University of New England, volunteers from local organizations like Unum and Avangrid, and expert staff from GMRI.
Student Madalyn Bartlett from Sacoppee Valley Middle School shared, “It makes me feel really proud, because I get to talk to professional scientists that have a lot of experience in this, and it make me feel like I am contributing to something bigger than my school and my community.”
These interactions emphasize that science isn’t confined to white coats and labs—it’s about curiosity, observation, and shared knowledge. The keynote speaker, Kat Gardner-Vandy from a former NASA Science Activation project team, Native Earth | Native Sky, reinforced this message, inspiring students to see themselves as vital contributors to science and our collective knowledge about the world.
The Learning Ecosystems Northeast project is supported by NASA under cooperative agreement award number NNX16AB94A and is part of NASA’s Science Activation Portfolio. Learn more about Learning Ecosystems Northeast: https://www.learningecosystemsnortheast.org/
Native Earth | Native Sky’s Kat Gardner-Vandy delivering the keynote speech to students at the Findings Symposium. Share
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By NASA
4 min read
Preparations for Next Moonwalk Simulations Underway (and Underwater)
The radio antennas of NASA’s Canberra Deep Space Communications Complex are lo-cated near the Australian capital. It’s one of three Deep Space Network facilities around the world that keep the agency in contact with dozens of space missions Located at Tidbinbilla Nature Reserve near the Australian capital city, the Canberra complex joined the Deep Space Network on March 19, 1965, with one 85-foot-wide (26-meter-wide) radio antenna. The dish, called Deep Space Station 42, was decommis-sioned in 2000. This photograph shows the facility in 1965.NASA Canberra joined the global network in 1965 and operates four radio antennas. Now, preparations have begun on its fifth as NASA works to increase the network’s capacity.
NASA’s Deep Space Network facility in Canberra, Australia celebrated its 60th anniversary on March 19 while also breaking ground on a new radio antenna. The pair of achievements are major milestones for the network, which communicates with spacecraft all over the solar system using giant dish antennas located at three complexes around the globe.
Canberra’s newest addition, Deep Space Station 33, will be a 112-foot-wide (34-meter-wide) multifrequency beam-waveguide antenna. Buried mostly below ground, a massive concrete pedestal will house cutting-edge electronics and receivers in a climate-controlled room and provide a sturdy base for the reflector dish, which will rotate during operations on a steel platform called an alidade.
Suzanne Dodd, the director for the Interplanetary Network Directorate at JPL, addresses an audience at the Deep Space Network’s Canberra complex on March 19, 2025. That day marked 60 years since the Australian facility joined the network.NASA “As we look back on 60 years of incredible accomplishments at Canberra, the groundbreaking of a new antenna is a symbol for the next 60 years of scientific discovery,” said Kevin Coggins, deputy associate administrator of NASA’s SCaN (Space Communications and Navigation) Program at NASA Headquarters in Washington. “Building cutting-edge antennas is also a symbol of how the Deep Space Network embraces new technologies to enable the exploration of a growing fleet of space missions.”
When it goes online in 2029, the new Canberra dish will be the last of six parabolic dishes constructed under NASA’s Deep Space Network Aperture Enhancement Program, which is helping to support current and future spacecraft and the increased volume of data they provide. The network’s Madrid facility christened a new dish in 2022, and the Goldstone, California, facility is putting the finishing touches on a new antenna.
Canberra’s Role
The Deep Space Network was officially founded on Dec. 24, 1963, when NASA’s early ground stations, including Goldstone, were connected to the new network control center at the agency’s Jet Propulsion Laboratory in Southern California. Called the Space Flight Operations Facility, that building remains the center through which data from the three global complexes flows.
The Madrid facility joined in 1964, and Canberra went online in 1965, going on to help support hundreds of missions, including the Apollo Moon landings.
Three eye-catching posters featuring the larger 230-foot (70-meter) antennas located at the three Deep Space Network complexes around the world.NASA/JPL-Caltech “Canberra has played a crucial part in tracking, communicating, and collecting data from some of the most momentous missions in space history,” said Kevin Ferguson, director of the Canberra Deep Space Communication Complex. “As the network continues to advance and grow, Canberra will continue to play a key role in supporting humanity’s exploration of the cosmos.”
By being spaced equidistant from one another around the globe, the complexes can provide continual coverage of spacecraft, no matter where they are in the solar system as Earth rotates. There is an exception, however: Due to Canberra’s location in the Southern Hemisphere, it is the only one that can send commands to, and receive data from, Voyager 2 as it heads south almost 13 billion miles (21 billion kilometers) through interstellar space. More than 15 billion miles (24 billion kilometers) away, Voyager 1 sends its data down to the Madrid and Goldstone complexes, but it, too, can only receive commands via Canberra.
New Technologies
In addition to constructing more antennas like Canberra’s Deep Space Station 33, NASA is looking to the future by also experimenting with laser, or optical, communications to enable significantly more data to flow to and from Earth. The Deep Space Network currently relies on radio frequencies to communicate, but laser operates at a higher frequency, allowing more data to be transmitted.
As part of that effort, NASA is flying the laser-based Deep Space Optical Communications experiment with the agency’s Psyche mission. Since the October 2023 launch, it has demonstrated high data rates over record-breaking distances and downlinked ultra-high definition streaming video from deep space.
“These new technologies have the potential to boost the science and exploration returns of missions traveling throughout the solar system,” said Amy Smith, deputy project manager for the Deep Space Networkat JPL, which manages the network. “Laser and radio communications could even be combined to build hybrid antennas, or dishes that can communicate using both radio and optical frequencies at the same time. That could be a game changer for NASA.”
For more information about the Deep Space Network, visit:
https://www.nasa.gov/communicating-with-missions/dsn/
NASA’s New Deep Space Network Antenna Has Its Crowning Moment NASA’s New Experimental Antenna Tracks Deep Space Laser VIDEO: How Do We Know Where Faraway Spacecraft Are? News Media Contact
Ian J. O’Neill
Jet Propulsion Laboratory, Pasadena, Calif.
818-354-2649
ian.j.oneill@jpl.nasa.gov
2024-048
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By NASA
13 min read
Preparations for Next Moonwalk Simulations Underway (and Underwater)
Getty Images University Student Research Challenge (USRC) seeks to challenge students to propose new ideas/concepts that are relevant to NASA Aeronautics. USRC will provide students, from accredited U.S. colleges or universities, with grants for their projects and with the challenge of raising cost share funds through a crowdfunding campaign. The process of creating and implementing a crowdfunding campaign acts as a teaching accelerator – requiring students to act like entrepreneurs and raise awareness about their research among the public.
The solicitation goal can be accomplished through project ideas such as advancing the design, developing technology or capabilities in support of aviation, by demonstrating a novel concept, or enabling advancement of aeronautics-related technologies.
Eligibility: NASA funding is available to all accredited U.S. institutions of higher education (e.g. universities, four-year colleges, community colleges, or other two-year institutions). Students must be currently enrolled (part-time or full-time) at the institution. NASA has no set expectations as to the team size. The number of students participating in the investigation is to be determined by the scope of the project and the student Team Leader.
The USRC solicitation is currently Closed with Proposals next due June 26, 2025. Please visit NSPIRES to receive alerts when more information is available.
A USRC Q&A/Info Session and Proposal Workshop will be held May 12, 2025, at 2pm ET ahead of the USRC Submission deadline in June 2025. Join the Q&A
Please email us at HQ-USRC@mail.nasa.gov if you have any questions or to schedule a 1 on 1.
USRC Awards
Context-Aware Cybersecurity for UAS Traffic Management (Texas A&M University)
Developing, testing, and pursuing transition of an aviation-context-aware network authentication and segmentation function, which holistically manages cyber threats in future UAS traffic control systems.
Student Team: Vishwam Raval (Team Lead), Michael Ades, Garett Haynes, Sarah Lee, Kevin Lei, Oscar Leon, McKenna Smith, Nhan Nick Truong
Faculty Mentors: Jaewon Kim and Sandip Roy
Selected: 2025
Reconnaissance and Emergency Aircraft for Critical Hurricane Relief (North Carolina State University)
Developing and deploying advanced unmanned aerial systems designed to locate, communicate with, and deliver critical supplies to stranded individuals in the wake of natural disasters.
Student Team: Tobias Hullette (Team Lead), Jose Vizcarrondo, Rishi Ghosh, Caleb Gobel, Lucas Nicol, Ajay Pandya, Paul Randolph, Hadie Sabbah
Faculty Mentor: Felix Ewere
Selected: 2025
Design and Prototyping of a 9-phase Dual-Rotor Motor for Supersonic Electric Turbofan (Colorado School of Mines)
Designing and prototyping a scaled-down 9-phase dual-rotor motor (DRM) for a supersonic electric turbofan.
Student Team: Mahzad Gholamian (Team Lead), Garret Reader, Mykola Mazur, Mirali Seyedrezaei
Faculty Mentor: Omid Beik
Selected: 2024
Project F.I.R.E (Fire Intervention Retardant Expeller) (Cerritos Community College)
Mitigating wildfires with drone released fire retardant pellets.
Student Team: Angel Ortega Barrera (Team Lead), Larisa Mayoral, Paola Mayoral Jimenez, Jenny Rodriguez, Logan Stahl, Juan Villa
Faculty Mentor: Janet McLarty-Schroeder
Selected: 2024
Learning cooperative policies for adaptive human-drone teaming in shared airspace (Cornell University)
Enabling new coordination and communication models for smoother, more efficient, and robust air traffic flow.
Student Team: Mehrnaz Sabet (Team Lead), Aaron Babu, Marcus Lee, Joshua Park, Francis Pham, Owen Sorber, Roopak Srinivasan, Austin Zhao
Faculty Mentor: Sanjiban Choudhury, Susan Fussell
Selected: 2024
Crowdfunding Website
Investigation on Cryogenic Fluid Chill-Down Time for Supersonic Transport Usage (University of Washington, Seattle)
Investigating reducing the boil-off of cryogenic fluids in pipes using vortex generators.
Student Team: Ryan Fidelis (Team Lead), Alexander Ala, Kaleb Shaw
Faculty Mentor: Fiona Spencer, Robert Breidenthal
Selected: 2024
Crowdfunding Website
Web Article: “Students win NASA grant to develop AI for safer aerial traffic“
Clean Forever-Flying Drones: Utilizing Ocean Water for Hydrogen Extraction in Climate Monitoring (Purdue University)
An ocean-based fueling station and a survey drone that can refuel in remote areas.
Student Team: Holman Lau (Team Lead), Nikolai Baranov, Andrej Damjanov, Chloe Hardesty, Smit Kapadia
Faculty Mentor: Li Qiao
Selected: 2023
Crowdfunding Website
Intelligent drone for detection of people during emergency response operation (Louisiana State University and A&M College)
Using machine learning algorithms for images and audio data, integrated with gas sensing for real-time detection of people on UAS.
Student Team: Jones Essuman (Team Lead), Tonmoy Sarker, Samer Tahboub
Faculty Mentor: Xiangyu Meng
Selected: 2023
Crowdfunding Website
Advancing Aerospace Materials Design through High-Fidelity Computational Peridynamic Modeling and Modified SVET Validation of Corrosion Damage (California State University, Channel Islands)
Modeling electrochemical corrosion nonlocally and combining efforts from bond-based and state-based theory.
Student Team: Trent Ruiz (Team Lead), Isaac Cisneros, Curtis Hauck
Faculty Mentor: Cynthia Flores
Selected: 2023
Crowdfunding Website
Swarm Micro UAVs for Area Mapping in GPS-denied Areas (Embry-Riddle Aeronautical University)
Using swarm robotics to map complex environments and harsh terrain with Micro Aerial Vehicles (MAVs)
Student Team: Daniel Golan (Team Lead), Stanlie Cerda-Cruz, Kyle Fox, Bryan Gonzalez, Ethan Thomas
Faculty Mentor: Sergey V. Drakunov
Selected: 2023
Crowdfunding Website
Web Article: “Student Research on Drone Swarm Mapping Selected to Compete at NASA Challenge“
AeroFeathers—Feathered Airfoils Inspired by the Quiet Flight of Owls (Michigan Tech University)
Creating new propeller blades and fixed wing design concepts that mimic the features of an
owl feather and provide substantial noise reduction benefits.
Student Team: William Johnston (Team Lead), Pulitha Godakawela Kankanamalage, Amulya Lomte, Maria Jose Carrillo Munoz, Brittany Wojciechowski, Laura Paige Nobles, Gabrielle Mathews
Faculty Mentor: Bhisham Sharma
Selected: 2023
Crowdfunding Website
Laser Energized Aerial Drone System (LEADS) for Sustained Sensing Applications (Michigan State University)
Laser based, high-efficiency optical power transfer for UAV charging for sustained flight and monitoring.
Student Team: Gavin Gardner (Team Lead), Ryan Atkinson, Brady Berg, Ross Davis, Gryson Gardner, Malachi Keener, Nicholas Michaels
Faculty Mentor: Woongkul Lee
Selected: 2023
Crowdfunding Website
LEADS team Website
UAM Contingency Diagnosis Toolkit (Ohio State University)
A UAM contingency diagnosis toolkit which that includes cognitive work requirements (CWRs) for human operators, information sharing requirements, and representational designs.
Student Team: Connor Kannally (Team Lead), Izzy Furl, Luke McSherry, Abhinay Paladugu
Faculty Mentor: Martijn IJtsma
Selected: 2023
Crowdfunding Website
Project Website
Web Article: “NASA Awards $80K to Ohio State students through University Research Challenge“
Hybrid Quadplane Search and Rescue Missions (NC A&T University)
An autonomous search and rescue quadplane UAS supported by an unmanned mobile landing platform/recharge station ground vehicle.
Student Team: Luis Landivar Olmos (Team Lead), Dakota Price, Amilia Schimmel, Sean Tisdale
Faculty Mentor: A. Homaifar
Selected: 2023
Crowdfunding Website
Drone Based Water Sampling and Quality Testing – Special Application in the Raritan River (Rutgers University, New Brunswick)
An autonomous water sampling drone system.
Student Team: Michael Leitner (Team Lead), Xavier Garay, Mohamed Haroun, Ruchit Jathania, Caleb Lippe, Zachary Smolder, Chi Hin Tam
Faculty Mentor: Onur Bilgen
Selected: 2023
Crowdfunding Website
Project Website
Development of a Low-Cost Open-Source Wire Arc Additive Manufacturing Machine – Arc One (Case Western Reserve University)
A small-scale, modular, low-cost, and open-source Wire Arc Additive Manufacturing (WAAM) platform.
Student Team: Vishnushankar Viraliyur Ramasamy (Team Lead), Robert Carlstrom, Bathlomew Ebika, Jonathan Fu, Anthony Lino, Garrett Tieng
Faculty Mentor: John Lewandowski
Selected: 2023
Crowdfunding Website
Web Article: “PhD student wins funding from NASA and develops multidisciplinary team of undergraduate students to build novel machine“
Low Cost and Efficient eVTOL Platform Leveraging Opensource for Accessibility (University of Nevada, Las Vegas)
Lowering the barrier of entry into eVTOL deployment and development with a low cost, efficient, and open source eVTOL platform
Student Team: Martin Arguelles-Perez (Team Lead), Benjamin Bishop, Isabella Laurito, Genaro Marcial Lorza, Eman Yonis
Faculty Mentor: Venkatesan Muthukumar
Selected: 2022
Applying Space-Based Estimation Techniques to Drones in GPS-Denied Environments (University Of Texas, Austin)
Taking real-time inputs from flying drones and outputting an accurate state estimation with 3-D error ellipsoid visualization
Student Team: James Mitchell Roberts (Team Lead), Lauren Byram, Melissa Pires
Faculty Mentor: Adam Nokes
Selected: 2022
Crowdfunding Website
Project Website
Web Article: “GPS-free Drone Tech Proposal Lands Undergrads Spot in NASA Challenge“
Underwing Distributed Ducted Fan ‘FanFoil’ Concept for Transformational Aerodynamic and Aeroacoustic Performance (Texas Tech University, Lubbock)
Novel highly under-cambered airfoils with electric ducted fans featuring ’samara’ maple seed inspired blades for eVTOL application
Student Team: Jack Hicks (Team Lead), Harrison Childre, Guilherme Fernandes, David Gould, Lorne Greene, Muhammad Waleed Saleem, Nathan Shapiro
Faculty Mentor: Victor Maldonado
Selected: 2022
Crowdfunding Website
Web Articles: “Improving Ducted-Fan eVTOL Efficiency” (AvWeek), “Sky Taxies“
Urban Cargo Delivery Using eVTOL Aircrafts (University Of Illinois, Chicago)
A bi-objective optimization formulation minimizing total run costs of a two-leg cargo delivery system and community noise exposure to eVTOL operations
Student Team: Nahid Parvez Farazi (Team Lead), Amy Hofstra, Son Nguyen
Faculty Mentor: Bo Zou
Selected: 2022
Crowdfunding Website
Web Article: “PhD student awarded NASA grant to investigate urban cargo delivery systems“
Congestion Aware Path Planning for Optimal UAS Traffic Management (University Of Illinois, Urbana-Champaign)
A feasible, provably safe, and quantifiably optimal path planning framework considering fully autonomous UAVs in urban environments
Student Team: Minjun Sung (Team Lead), Christoph Aoun, Ivy Fei, Christophe Hiltebrandt-McIntosh, Sambhu Harimanas Karumanchi, Ran Tao
Faculty Mentor: Naira Hovakimyan
Selected: 2022
Crowdfunding Website
Web Article: “NASA funds UAV traffic management research“
AeroZepp: Aerostat Enabled Drone Glider Delivery System / Whisper Ascent: Quiet Drone Delivery (University of Delaware)
An aerostat enabled low-energy UAV payload delivery system
Student Team: Wesley Connor (Team Lead), Abubakarr Bah, Karlens Senatus
Faculty Mentor: Suresh Advani
Selected: 2022
Crowdfunding Website
Sustainable Transport Research Aircraft for Test Operation (STRATO) (Rutgers University, New Brunswick)
An open source, efficiently driven, optimized Active Flow Control (AFC) enhanced control surface for UAV research platforms
Student Team: Daulton James (Team Lead), Jean Alvarez, Frederick Diaz, Michael Ferrell, Shriya Khera, Connor Magee, Roy Monge Hidalgo, Bertrand Smith
Faculty Mentor: Edward DeMauro
Selected: 2022
Crowdfunding Website
Web Articles: “SoE Students Eligible for NASA University Student Research Challenge Award“, “Senior Design Team Captures NASA Research Challenge“
A recorded STRATO USRC Tech Talk
Dronehook: A Novel Fixed-Wing Package Retrieval System (University Of Notre Dame)
Envisioning a world where items can be retrieved from remote locations in a simple fashion from efficient fixed-wing UAVs
Student Team: Konrad Rozanski (Team Lead), Dillon Coffey, Bruce Smith, Nicholas Orr
Faculty Mentor: Jane Cleland-Huang
Selected: 2021
Crowdfunding Website
Web Article: “Notre Dame student team wins NASA research award for drone scoop and grab technology“
Aerial Intra-city Delivery Electric Drones (AIDED) with High Payload Capacity (Michigan State University)
A high-payload capacity delivery drone capable of safely latching and charging on electrified public transportation systems
Student Team: Yuchen Wang (Team Lead), Hunter Carmack, Kindred Griffis, Luke Lewallen, Scott Newhard, Caroline Nicholas, Shukai Wang, Kyle White
Faculty Mentor: Woongkul Lee
Selected: 2021
AIDED Crowdfunding Website
AIDED Project Website or Team Website
Web Articles: “Spartan Engineers win NASA research award” and “NASA Aeronautics amplification“; “Ross Davis & Gavin Gardner on The Guy Gordon Show“; “MSU Students Create Delivery Drone for NASA“; “Student drone project flying high with help from NASA“
A recorded USRC Tech Talk
Robotic Fabrication Work Cell for Customizable Unmanned Aerial Systems (Virginia Polytechnic Institute & State University)
A robotic, multi-process work cell to autonomously fabricate topologically optimized UASs tailored for immediate application needs
Student Team: Tadeusz Kosmal (Team Lead), Kieran Beaumont, Om Bhavsar, Eric Link, James Lowe
Faculty Mentor: Christopher Williams
Selected: 2021
Crowdfunding Website
RAV-FAB Project Website
Web Articles: “Drones that fly away from a 3D printer: Undergraduates create science nonfiction” and “3D printing breaks out of the box / VTx / Virginia Tech“
NASA VT USRC Web Article: “USRC Students Sees Success with Crowdfunding, NASA Grants“
Publication: Hybrid additive robotic workcell for autonomous fabrication of mechatronic systems – A case study of drone fabrication – ScienceDirect
Team Social Media: Instagram: @ravfab_vt; LinkedIn: @rav-fab; YouTube
View RAV-FAB USRC Tech Talk #1 or USRC Tech Talk #2
Real Time Quality Control in Additive Manufacturing Using In-Process Sensing and Machine Learning (Cornell University)
A high-precision and low-cost intelligent sensor-based quality control technology for Additive Manufacturing
Student Team: Adrita Dass (Team Lead), Talia Turnham, Benjamin Steeper, Chenxi Tian, Siddharth Patel, Akula Sai Pratyush, Selina Kirubakar
Faculty Mentor: Atieh Moridi
Selected: 2021
Crowdfunding Website
AMAS Project Website
Web Article: “Students win NASA challenge with 3D-printer smart sensor“
A recorded USRC Tech Talk on this topic
AVIATA: Autonomous Vehicle Infinite Time Apparatus (University of California, Los Angeles)
A drone swarm system capable of carrying a payload in the air indefinitely
Student Team: Chirag Singh (Team Lead), Ziyi Peng, Bhrugu Mallajosyula, Willy Teav, David Thorne, James Tseng, Eric Wong, Axel Malahieude, Ryan Nemiroff, Yuchen Yao, Lisa Foo
Faculty Mentor: Jeff Eldredge
Selected: 2020
Crowdfunding Website
AVIATA Project Website
A recorded USRC Tech Talk on AVIATA
The recorded poster session at the TACP Showcase 2021
Redundant Flight Control System for BVLOS UAV Operations (Embry-Riddle Aeronautical University)
A redundant flight control system as a “back-up” to the primary flight computer to enhance safety of sUAS
Student Team: Robert Moore (Team Lead), Joseph Ayd, and Todd Martin
Faculty Mentor: John Robbins
Selected: 2020
Crowdfunding Website
Web Articles: “NASA Web Article“; “Drone Innovation Top Embry-Riddle Entrepreneurship Competition“
Follow the team’s progress at: https://www.facebook.com/Assured Autonomy
A recorded USRC Tech Talk on this topic
The recorded poster session at the TACP Showcase 2021
Multi-Mode Hybrid Unmanned Delivery System: Combining Fixed-Wing and Multi-Rotor Aircraft with Ground Vehicles (Rutgers University)
Extending drone delivery distance with a multi-mode hybrid delivery system
Student Team: Paul Wang (Team Lead), Nolan Angelia, Muhammet Ali Gungor
Faculty Mentor: Onur Bilgen
Selected: 2020
Crowdfunding Website
A recorded USRC Tech Talk on this topic
The recorded poster session at the TACP Showcase 2021
AVIS: Active Vortex Inducing System for Flow Separation Control to Improve Airframe Efficiency (Georgia Institute of Technology)
Use an array of vortex generators that can be adjusted throughout flight to increase wing efficiency
Student Team: Michael Gamarnik (Team Lead), Shiva Khanna Yamamoto, Noah Mammen, Tommy Schrager, Bethe Newgent
Faculty Mentor: Kelly Griendling
Selected: 2020
Go to AVIS team site
A recorded USRC Tech Talk on AVIS
The recorded poster session at the TACP Showcase 2021
NASA Web Article
Hybrid Airplanes – An Optimum and Modular Approach (California Polytechnic State University, San Luis Obispo)
Model and test powertrain to maximize the efficiency of hybrid airplanes
Student Team: Nicholas Ogden (Team Lead), Joseph Shy, Brandon Bartlett, Ryker Bullis, Chino Cruz, Sara Entezar, Aaron Li, Zach Yamauchi
Faculty Mentor: Paulo Iscold
Selected: 2019
A recorded USRC Tech Talk on this topic
The recorded poster session at the TACP Showcase 2021
ATLAS Air Transportation (South Dakota State University)
A multipurpose, automated drone capable of comfortably lifting the weight of an average person
Student Team: Isaac Smithee (Team Lead), Wade Olson, Nicolas Runge, Ryan Twedt, Anthony Bachmeier, Matthew Berg, Sterling Berg
Faculty Mentors: Marco Ciarcia, Todd Letcher
Selected: 2019
A recorded USRC Tech Talk #1 and USRC Tech Talk #2 on ATLAS
The recorded poster session at the TACP Showcase 2021
Software-Defined GPS Augmentation Network for UAS Navigation (University Of Oklahoma, Norman)
A novel solution of enhanced GPS navigation for unmanned aerial vehicles
Student Team: Robert Rucker (Team Lead), Alex Zhang, Jakob Fusselman, Matthew GilliamMentors: Dr. Yan (Rockee) Zhang (Faculty Mentor), Dr Hernan Suarez (Team Technical Mentor)
Faculty Mentors: Marco Ciarcia, Todd Letcher
Selected: 2019
Crowdfunding Website
A recorded USRC Tech Talk on this topic
The recorded poster session at the TACP Showcase 2021
UAV Traffic Information Exchange Network (Purdue University)
A blockchain-inspired secure, scalable, distributed, and efficient communication framework to support large scale UAV operations
Student Team: Hsun Chao (Team Lead) and Apoorv Maheshwari
Faculty Mentors: Daniel DeLaurentis (Faculty Mentor), Shashank Tamaskar
Selected: 2018
Web Article: “Student-developed communication network for UAVs interests NASA“
The recorded poster session at the TACP Showcase 2021
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Last Updated Apr 03, 2025 EditorLillian GipsonContactJim Bankejim.banke@nasa.gov Related Terms
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