Jump to content

NASA’s Neurodiversity Network Interns Speak at National Space Development Conference


Recommended Posts

  • Publishers
Posted

2 min read

NASA’s Neurodiversity Network Interns Speak at National Space Development Conference

Two high school interns funded by NASA’s Neurodiversity Network (N3) presented their work from Summer 2023 at the recent National Space Society (NSS) International Space Development Conference (ISDC-2024), held in Los Angeles, CA (May 23-26, 2024). Both interns were mentored by Dr. Pascal Lee, Planetary Scientist at the SETI Institute and Chair of the Mars Institute, who accompanied them to the conference. Intern Finn Braun, who is now a high school junior, co-authored the paper “An ATV for the Moon” with Dr. Lee. He worked with a CAD program to develop the concept, which might be of interest to NASA’s Artemis Program in the future. Intern Krista Heinemann, who has now graduated high school, co-authored the paper “New location for the ‘Noctis Landing’ candidate human landing site on Mars” in which she used NASA data about the Noctis Landing site provided by Dr. Lee to refine a possible landing location for future human missions to the surface of Mars. In addition to the oral presentations they gave, Braun and Heinemann lead-authored technical publications reporting their research. Braun and Heinemann were part of the 2023 N3 intern cohort, which included 19 other high school students, each paired with a NASA Subject Matter Expert as a mentor. The N3 internship program is now beginning its fourth summer with a new cohort of 21 additional interns.

Dr. Lee noted, “Finn and Krista were outstanding interns, who now each have lead-authored scientific/technical publications while in high school. I am sure they will each do great things in the future.”

The references for the two papers are:

Braun, F. and P. Lee 2024. An ATV for the Moon. National Space Society International Space Development Conference, ISDC-2024, 23-26 May 2024, Los Angeles, CA, Moon Track, #2003.

Heinemann, K. and P. Lee 2024. New location for the ‘Noctis Landing’ candidate human landing site on Mars. National Space Society International Space Development Conference, ISDC-2024, 23-26 May 2024, Los Angeles, CA, Mars Track, #3002.

NASA’s Neurodiversity Network is supported by NASA under cooperative agreement award number 80NSSC21M0004 and is part of NASA’s Science Activation Portfolio. Learn more about how Science Activation connects NASA science experts, real content, and experiences with community leaders to do science in ways that activate minds and promote deeper understanding of our world and beyond: https://science.nasa.gov/learn

Finn Braun stands behind a lectern and to the left of Dr. Pascal Lee. Both are in front of a slide showing their design for a lunar ATV. A model of a lunar module is in front of them, on a table.
Finn Braun speaks about his design for a lunar ATV at the 2024 International Space Development Conference while his mentor Dr. Pascal Lee looks on.
NSS/Madhu Thangavelu

Share

Details

Last Updated
Jul 08, 2024
Editor
NASA Science Editorial Team

View the full article

Join the conversation

You can post now and register later. If you have an account, sign in now to post with your account.
Note: Your post will require moderator approval before it will be visible.

Guest
Reply to this topic...

×   Pasted as rich text.   Paste as plain text instead

  Only 75 emoji are allowed.

×   Your link has been automatically embedded.   Display as a link instead

×   Your previous content has been restored.   Clear editor

×   You cannot paste images directly. Upload or insert images from URL.

  • Similar Topics

    • By NASA
      5 min read
      Preparations for Next Moonwalk Simulations Underway (and Underwater)
      In this infrared photograph, the Optical Communications Telescope Laboratory at JPL’s Table Mountain Facility near Wrightwood, California, beams its eight-laser beacon to the Deep Space Optical Communications flight laser transceiver aboard NASA’s Psyche spacecraft.NASA/JPL-Caltech The project has exceeded all of its technical goals after two years, setting up the foundations of high-speed communications for NASA’s future human missions to Mars.
      NASA’s Deep Space Optical Communications technology successfully showed that data encoded in lasers could be reliably transmitted, received, and decoded after traveling millions of miles from Earth at distances comparable to Mars. Nearly two years after launching aboard the agency’s Psyche mission in 2023, the technology demonstration recently completed its 65th and final pass, sending a laser signal to Psyche and receiving the return signal, from 218 million miles away. 
      “NASA is setting America on the path to Mars, and advancing laser communications technologies brings us one step closer to streaming high-definition video and delivering valuable data from the Martian surface faster than ever before,” said acting NASA Administrator Sean Duffy. “Technology unlocks discovery, and we are committed to testing and proving the capabilities needed to enable the Golden Age of exploration.”
      This video details how the Deep Space Optical Communications experiment broke records and how the technology demonstration could pave the way for future high-bandwidth data transmission out to Mars distances and beyond. NASA/JPL-Caltech Record-breaking technology
      Just a month after launch, the Deep Space Optical Communications demonstration proved it could send a signal back to Earth it established a link with the optical terminal aboard the Psyche spacecraft.
      “NASA Technology tests hardware in the harsh environment of space to understand its limits and prove its capabilities,” said Clayton Turner, associate administrator, Space Technology Mission Directorate at NASA Headquarters in Washington. “Over two years, this technology surpassed our expectations, demonstrating data rates comparable to those of household broadband internet and sending engineering and test data to Earth from record-breaking distances.”
      On Dec. 11, 2023, the demonstration achieved a historic first by streaming an ultra-high-definition video to Earth from over 19 million miles away (about 80 times the distance between Earth and the Moon), at the system’s maximum bitrate of 267 megabits per second. The project also surpassed optical communications distance records on Dec. 3, 2024, when it downlinked Psyche data from 307 million miles away (farther than the average distance between Earth and Mars). In total, the experiment’s ground terminals received 13.6 terabits of data from Psyche.
      How it works
      Managed by NASA’s Jet Propulsion Laboratory (JPL) in Southern California, the experiment consists of a flight laser transceiver mounted on the Psyche spacecraft, along with two ground stations to receive and send data from Earth. A powerful 3-kilowatt uplink laser at JPL’s Table Mountain Facility transmitted a laser beacon to Psyche, helping the transceiver determine where to aim the optical communications laser back to Earth.
      Both Psyche and Earth are moving through space at tremendous speeds, and they are so distant from each other that the laser signal — which travels at the speed of light — can take several minutes to reach its destination. By using the precise pointing required from the ground and flight laser transmitters to close the communication link, teams at NASA proved that optical communications can be done to support future missions throughout the solar system.
      Another element of the experiment included detecting and decoding a faint signal after the laser traveled millions of miles. The project enlisted a 200-inch telescope at Caltech’s Palomar Observatory in San Diego County as its primary downlink station, which provided enough light-collecting area to collect the faintest photons. Those photons were then directed to a high-efficiency detector array at the observatory, where the information encoded in the photons could be processed.   
      “We faced many challenges, from weather events that shuttered our ground stations to wildfires in Southern California that impacted our team members,” said Abi Biswas, Deep Space Optical Communications project technologist and supervisor at JPL. “But we persevered, and I am proud that our team embraced the weekly routine of optically transmitting and receiving data from Psyche. We constantly improved performance and added capabilities to get used to this novel kind of deep space communication, stretching the technology to its limits.”
      Brilliant new era
      In another test, data was downlinked to an experimental radio frequency-optical “hybrid” antenna at the Deep Space Network’s Goldstone complex near Barstow, California. The antenna was retrofitted with an array of seven mirrors, totaling 3 feet in diameter, enabling the antenna to receive radio frequency and optical signals from Psyche simultaneously.
      The project also used Caltech’s Palomar Observatory and a smaller 1-meter telescope at Table Mountain to receive the same signal from Psyche. Known as “arraying,” this is commonly done with radio antennas to better receive weak signals and build redundancy into the system.
      “As space exploration continues to evolve, so do our data transfer needs,” said Kevin Coggins, deputy associate administrator, NASA’s SCaN (Space Communications and Navigation) program at the agency’s headquarters. “Future space missions will require astronauts to send high-resolution images and instrument data from the Moon and Mars back to Earth. Bolstering our capabilities of traditional radio frequency communications with the power and benefits of optical communications will allow NASA to meet these new requirements.”
      This demonstration is the latest in a series of optical communication experiments funded by the Space Technology Mission Directorate’s Technology Demonstration Missions Program managed at NASA’s Marshall Space Flight Center in Huntsville, Alabama, and the agency’s SCaN program within the Space Operations Mission Directorate. The Psyche mission is led by Arizona State University. Lindy Elkins-Tanton of the University of California, Berkeley is the principal investigator. NASA JPL, managed by Caltech in Pasadena, California, is responsible for the mission’s overall management.
      To learn more about the laser communications demo, visit:
      https://www.jpl.nasa.gov/missions/deep-space-optical-communications-dsoc/
      NASA’s Laser Comms Demo Makes Deep Space Record, Completes First Phase NASA’s Tech Demo Streams First Video From Deep Space via Laser Teachable Moment: The NASA Cat Video Explained News Media Contact
      Ian J. O’Neill
      Jet Propulsion Laboratory, Pasadena, Calif.
      818-354-2649
      ian.j.oneill@jpl.nasa.gov
      2025-120
      Share
      Details
      Last Updated Sep 18, 2025 Related Terms
      Deep Space Optical Communications (DSOC) Jet Propulsion Laboratory Psyche Mission Space Communications & Navigation Program Space Operations Mission Directorate Space Technology Mission Directorate Tech Demo Missions Explore More
      2 min read NASA Gateways to Blue Skies 2026 Competition
      Article 28 minutes ago 6 min read NASA’s Tally of Planets Outside Our Solar System Reaches 6,000
      Article 1 day ago 2 min read NASA Makes Webby 30s List of Most Iconic, Influential on Internet
      Article 2 days ago Keep Exploring Discover Related Topics
      Missions
      Humans in Space
      Climate Change
      Solar System
      View the full article
    • By NASA
      2 Min Read Building a Lunar Network: Johnson Tests Wireless Technologies for the Moon 
      From left, Johnson Exploration Wireless Laboratory (JEWL) Software Lead William Dell; Lunar 3GPP Principal Investigator Raymond Wagner; JEWL intern Harlan Phillips; and JEWL Lab Manager Chatwin Lansdowne. Credits: Nevada Space Proving Grounds (NSPG) NASA engineers are strapping on backpacks loaded with radios, cameras, and antennas to test technology that might someday keep explorers connected on the lunar surface. Their mission: test how astronauts on the Moon will stay connected during Artemis spacewalks using 3GPP (LTE/4G and 5G) and Wi-Fi technologies. 
      It’s exciting to bring lunar spacewalks into the 21st century with the immersive, high-definition experience that will make people feel like they’re right there with the astronauts.
      Raymond Wagner
      NASA’s Lunar 3GPP Project Principal Investigator
      A NASA engineer tests a backpack-mounted wireless communications system in the Nevada desert, simulating how astronauts will stay connected during Artemis lunar spacewalks. NSPG With Artemis, NASA will establish a long-term presence at the Moon, opening more of the lunar surface to exploration than ever before. This growth of lunar activity will require astronauts to communicate seamlessly with each other and with science teams back on Earth.  
      “We’re working out what the software that uses these networks needs to look like,” said Raymond Wagner, principal investigator in NASA’s Lunar 3GPP project and member of Johnson Space Center’s Exploration Wireless Laboratory (JEWL) in Houston. “We’re prototyping it with commercial off-the-shelf hardware and open-source software to show what pieces are needed and how they interact.” 
      Carrying a prototype wireless network pack, a NASA engineer helps test wireless 4G and 5G technologies that could one day keep Artemis astronauts connected on the Moon. NSPG The next big step comes with Artemis III, which will land a crew on the Moon and carry a 4G/LTE demonstration to stream video and audio from the astronauts on the lunar surface. 
       The vision goes further. “Right now the lander or rover will host the network,” Wagner said. “But if we go to the Moon to stay, we may eventually want actual cell towers. The spacesuit itself is already becoming the astronaut’s cell phone, and rovers could act as mobile hotspots. Altogether, these will be the building blocks of communication on the Moon.” 
      Team members from NASA’s Avionics Systems Laboratory at Johnson Space Center in Houston.NASA/Sumer Loggins Back at Johnson, teams are simulating lunar spacewalks, streaming video, audio, and telemetry over a private 5G network to a mock mission control. The work helps engineers refine how future systems will perform in challenging environments. Craters, lunar regolith, and other terrain features all affect how radio signals travel — lessons that will also carry over to Mars. 
      For Wagner, the project is about shaping how humanity experiences the next era of exploration. “We’re aiming for true HD on the Moon,” he said. “It’s going to be pretty mind-blowing.” 
      About the Author
      Sumer Loggins

      Share
      Details
      Last Updated Sep 18, 2025 Related Terms
      Johnson Space Center Artemis Explore More
      3 min read Aaisha Ali: From Marine Biology to the Artemis Control Room 
      Article 2 months ago 4 min read Mark Cavanaugh: Integrating Safety into the Orion Spacecraft 
      Article 2 months ago 3 min read Bringing the Heat: Abigail Howard Leads Thermal Systems for Artemis Rovers, Tools
      Article 6 months ago Keep Exploring Discover More Topics From NASA
      Missions
      Humans in Space
      Climate Change
      Solar System
      View the full article
    • By NASA
      NASA Prelaunch News Conference on Three New Space Weather Missions (Sept. 21, 2025)
    • By NASA
      NASA Science News Conference on Three New Space Weather Missions (Sept. 21, 2025)
    • By NASA
      NASA/Jonny Kim NASA astronaut Zena Cardman processes bone cell samples inside the Kibo laboratory module’s Life Science Glovebox on Aug. 28, 2025, as part of an experiment that tests how microgravity affects bone-forming and bone-degrading cells and explore potential ways to prevent bone loss. This research could help protect astronauts on future long-duration missions to the Moon and Mars, while also advancing treatments for millions of people on Earth who suffer from osteoporosis.
      Image credit: NASA/Jonny Kim
      View the full article
  • Check out these Videos

×
×
  • Create New...