NASA Pi Day Challenge Serves Up a Mathematical Marvel

NASA Pi Day Challenge Serves Up a Mathematical Marvel

2 min read

Preparations for Next Moonwalk Simulations Underway (and Underwater)

Cartoon graphic of the annual NASA Pi Day Challenge
In celebration of the mathematical constant pi, JPL is releasing the annual NASA Pi Day Challenge: a set of illustrated math problems involving real-world science and engineering aspects of agency missions.
NASA/JPL-Caltech

Celebrate one of the world’s most famous numbers with a set of math problems involving real space missions, courtesy of the agency’s Jet Propulsion Laboratory.

March 14 marks the annual celebration of the mathematical constant pi, aka the Greek letter π. Its infinite number of digits is usually rounded to 3.14, hence the date of Pi Day. For some people, the occasion marks an annual excuse to eat pizza or pie (or both), but to truly honor this wondrously useful number, a serving of mathematics is in order, too. NASA is here to help.

Continuing a decade-long tradition, the Education Office at the agency’s Jet Propulsion Laboratory has cooked up a set of illustrated math problems involving real-life NASA science and engineering.

With the NASA Pi Day Challenge, students can use the mathematical constant to:

  • determine where the DSOC (Deep Space Optical Communications) technology demonstration aboard NASA’s Psyche spacecraft should aim a laser message containing a cat video so that it can reach Earth (and set a NASA record in the process)
  • figure out the change in asteroid Dimorphos’ orbit after NASA intentionally crashed its DART (Double Asteroid Redirection Test) spacecraft into its surface
  • measure how much data will be captured by the NISAR (NASA-ISRO Synthetic Aperture Radar) satellite each time it orbits our planet, monitoring Earth’s land and ice surfaces in unprecedented detail
  • calculate the distance a small rover must drive to map a portion of the lunar surface as part of NASA’s CADRE (Cooperative Autonomous Distributed Robotic Exploration) technology demonstration that’s headed to the Moon

Answers to all four challenge questions will be available on March 15.

The NASA Pi Day Challenge is accompanied by other pi-related resources for educators, K-12 students, and parents, including lessons and teachable moments, downloadable posters, and illustrated web/mobile backgrounds. More than 40 puzzlers from previous challenges are also available.

More about the NASA Pi Day Challenge:

https://go.nasa.gov/piday

News Media Contact

Melissa Pamer
Jet Propulsion Laboratory, Pasadena, Calif.
626-314-4928
melissa.pamer@jpl.nasa.gov

2024-023

Share

Details

Last Updated

Mar 07, 2024

Powered by WPeMatico

Get The Details…
Anthony Greicius

NASA Helps Emerging Space Companies ‘Take the Heat’

NASA Helps Emerging Space Companies ‘Take the Heat’

A capsule containing the first products manufactured in space by Varda Space Industries and protected by a heat shield made at NASA’s Ames Research Center in California’s Silicon Valley lands at the Utah Test and Training Range on Feb. 21, 2024.
Varda Space Industries/John Kraus

Things are heating up in the atmosphere, and NASA is helping space start-ups stay cool.  

NASA has decades of expertise in creating technology that protects spacecraft from the intense heat generated when entering an atmosphere. As emerging companies develop innovative ways to do business in space, they know where to turn – and the agency is responding by offering its know-how and the advanced materials invented here to help enable new uses for space with big benefits for humanity.

Since 1951, when Harvey Allen, an engineer at NASA’s Ames Research Center in California’s Silicon Valley, showed a blunt-shaped capsule helps deflect the heat of atmospheric entry, Ames has led the agency in designing, developing, and testing thermal protection systems (TPS). These heat shields protect re-entering spacecraft and their cargo, such as pieces of a 4.5-billion-year-old asteroid or astronauts who will travel in the Orion crew capsule.

“In the past, the government was the only entity that needed heat shields,” said David Hash, chief of the Entry Systems and Technology Division at Ames, “That’s changing dramatically today. Companies that see new opportunities for commercial activities in space now have a business case to launch spacecraft and bring them back to Earth. NASA is uniquely positioned to show them how to do it.”

NASA works to encourage commercial growth. With an increasing number of start-ups who have smart ideas but limited funding and spaceflight experience, NASA experts at Ames and Langley Research Center in Hampton, Virginia, are doing their part to help. And success is already in the air – or passing safely through it.

In the past, the government was the only entity that needed heat shields. That’s changing dramatically today.

David Hash

David Hash

Chief, Entry Systems and Technology Division, NASA’s Ames Research Center

On Feb. 21, Varda Space Industries of El Segundo, California, in partnership with Rocket Lab USA of Long Beach, California, returned to Earth the first product processed on its autonomous, free-flying, in-space manufacturing platform. The product is a pharmaceutical that may gain unique properties by forming in the near-absence of gravity. Ames made the spacecraft’s heat shield material, and Langley assisted Varda in developing their re-entry capsule through aeroscience expertise, systems design and analysis, and trade studies support.

Through a partnership agreement, Ames produced the thermal protection material, called C-PICA (Conformal Phenolic Impregnated Carbon Ablator), intended to bring down products from Varda’s factory in orbit for its first four missions. The material was originally developed at Ames, and February’s re-entry marked the first time a NASA-manufactured C-PICA heat shield ever returned from space.

“We performed extensive testing on the ground, in our arc jet facilities, where we can simulate the high temperatures of entry,” said Mairead Stackpoole, chief of the Thermal Protection Materials Branch at Ames, “but there’s nothing like a real spaceflight to test our systems. The Ames TPS team will soon take samples from the heat shield to analyze its performance in detail.”

NASA’s partnership with Varda will continue through a Tipping Point award from the agency’s Space Technology Mission Directorate (STMD). Managed by STMD’s Flight Opportunities program, this award will leverage technology transfer from Ames of the C-PICA production process, helping the small business establish its heat shield production and fully enter the space market, as well as a flight test to evaluate the material’s performance. A joint effort between NASA, the Air Force Research Laboratory, and Varda will also provide more flight tests of C-PICA, helping to fully mature this technology relevant for future Mars missions and more.

NASA’s thermal protection experts can work with any space company on tackling the complex challenges of re-entry. Current collaborations include two companies targeting flights in the coming year.

A heat shield made by NASA is visible on the blunt, upward-facing side of a space capsule after its landing in the Utah desert. Varda Space Industries returned to Earth the first product processed on its in-space manufacturing platform on Feb. 21, 2024.
Varda Space Industries/John Kraus

The first flight of Inversion Space of Torrance, California, will take place in 2024 with the goal of using space to transport cargo. Inversion’s vehicle will re-enter the atmosphere using a C-PICA heat shield and a backshell, which protects the “downstream” end of the vehicle, made of another material developed at Ames: silicone-infused refractory ceramic ablator (SIRCA).

Later, NASA will support the first private mission to Venus with Rocket Lab. The spacecraft will use NASA’s Heatshield for Extreme Entry Environment Technology, developed at Ames, and a SIRCA backshell.

These and other projects NASA is enabling are born of 21st-century innovation, yet Hash sees similarities with the formation of commercial airlines in the 1920s and 30s.

As the Smithsonian’s National Postal Museum explains, when Congress passed the Air Mail Act in 1925, it allowed the U.S. Postal Service to transport mail using commercial air carriers. Because  companies could not rely on paying passengers in the early years to survive, this government participation encouraged and enabled the development of commercial aviation. NASA’s predecessor, the National Advisory Committee for Aeronautics, had the important role of advancing technologies to enable this new market.

“We need to do the same thing they did for the airways, only for the spaceways,” said Hash. “That’s our job, now. It’s the perfect role for government, and it will increase economic prosperity for our country.”

For news media:

Members of the news media interested in covering this topic should reach out to the NASA Ames newsroom.

Powered by WPeMatico

Get The Details…
Abby Tabor

Apollo 9 Astronaut David Scott’s Spacewalk

Apollo 9 Astronaut David Scott’s Spacewalk

Earth is a deep blue backdrop to this photo of astronaut David Scott and the command module and lunar module of the Apollo 9 mission. The joined modules are a metallic silver. He stands in the open hatch of the command module while wearing a white spacesuit. A metallic visor tops his red helmet.
NASA/Russell L. Schweickart

Astronaut David R. Scott, command module pilot for the Apollo 9 Earth-orbital mission, stands in the command module’s open hatch during his stand-up spacewalk on March 6, 1969. Astronaut Russell L. Schweickart, lunar module pilot, took this photograph of Scott while also performing a spacewalk. He was positioned on the porch of the lunar module (LM), while astronaut James A. McDivitt, was inside the LM.

Apollo 9 was the first crewed flight of the command/service module along with the lunar module. The mission’s three-person crew tested several aspects critical to landing on the Moon including the lunar module’s engines, backpack life support systems, navigation systems, and docking maneuvers. Apollo 9 set the stage for the next step — Apollo 10 — a test mission that occurred about 70 miles above the Moon’s surface.

See more photos from Apollo 9.

Image Credit: NASA/Russell L. Schweickart

Powered by WPeMatico

Get The Details…
Monika Luabeya

NASA’s Network of Small Moon-Bound Rovers Is Ready to Roll

NASA’s Network of Small Moon-Bound Rovers Is Ready to Roll

5 min read

Preparations for Next Moonwalk Simulations Underway (and Underwater)

Construction and testing are complete on the CADRE rovers, which will map the lunar surface together as a tech demo to show the promise of multirobot missions.

A trio of small rovers that will explore the Moon in sync with one another are rolling toward launch. Engineers at NASA’s Jet Propulsion Laboratory in Southern California recently finished assembling the robots, then subjected them to a punishing series of tests to ensure they’ll survive their jarring rocket ride into space and their travels in the unforgiving lunar environment.

Part of a technology demonstration called CADRE (Cooperative Autonomous Distributed Robotic Exploration), each solar-powered rover is about the size of a carry-on suitcase. The rovers and associated hardware will be installed on a lander headed for the Moon’s Reiner Gamma region. They’ll spend the daylight hours of a lunar day – the equivalent of about 14 days on Earth – conducting experiments by autonomously exploring, mapping, and using ground-penetrating radar that will peer below the Moon’s surface.

The goal is to show that a group of robotic spacecraft can work together to accomplish tasks and record data as a team without explicit commands from mission controllers on Earth. If the project succeeds, future missions could include teams of robots spreading out to take simultaneous, distributed scientific measurements, potentially in support of astronauts.

Engineers have put in long hours test-driving rovers and working out bugs to finish the hardware, get it through testing, and prepare it for integration with the lander.

Clamped to a shaker table, one of NASA’s CADRE rovers gets shaken vigorously during a test in November 2023. This vibration test is designed to show that the rover can withstand the jarring rocket ride on its journey to the Moon aboard a lunar lander.

“We have been in overdrive getting this tech demo ready for its lunar adventure,” said Subha Comandur, CADRE project manager at JPL. “It’s been months of nearly round-the-clock testing and sometimes re-testing, but the team’s hard work is paying off. Now we know these rovers are ready to show what a team of little space robots can accomplish together.”

Shake and Bake

While the list of tests is extensive, the most brutal involve extreme environmental conditions to ensure the rovers can withstand the rigors of the road ahead. That includes being locked in a thermal vacuum chamber that simulates the airless conditions of space and its extreme hot and cold temperatures. The hardware also gets clamped to a special “shaker table” that vibrates intensely to make sure it will endure the journey out of Earth’s atmosphere.

A CADRE rover is prepared for electromagnetic interference
A CADRE rover is prepared for electromagnetic interference and compatibility testing in a special chamber at JPL in November 2023. Such testing confirms that the operation of the electronic subsystems do not interfere with each other nor with those on the lander.
NASA/JPL-Caltech

“This is what we submit our rovers to: ‘shake’ to simulate the rocket launch itself and ‘bake’ to simulate the extreme temperatures of space. It’s very nerve-wracking to witness in person,” said JPL’s Guy Zohar, the project’s flight system manager. “We’re using many carefully selected commercial parts on our project. We expect them to work, but we’re always a little worried when we go into testing. Happily, each test has ultimately been successful.”

Engineers also performed environmental testing on three hardware elements mounted on the lander: a base station that the rovers will communicate with via mesh network radios, a camera that will provide a view of the rovers’ activities, and the deployer systems that will lower the rovers to the lunar surface via a fiber tether fed slowly out from a motorized spool.

Putting Code to the Test, Too

Meanwhile, engineers working on CADRE’s cooperative autonomy software have spent many days in JPL’s rocky, sandy Mars Yard with full-scale versions of the rovers called development models. With flight software and autonomy capabilities aboard, these test rovers showed they can accomplish key goals for the project. They drove together in formation. Faced with unexpected obstacles, they adjusted their plans as a group by sharing updated maps and replanning coordinated paths. And when one rover’s battery charge was low, the whole team paused so they could later continue together.

Two full-scale development model rovers
Two full-scale development model rovers are tested in JPL’s Mars Yard in August 2023 as part of NASA’s CADRE tech demo. These tests confirmed the project’s hardware and software can work together to accomplish key goals.
NASA/JPL-Caltech

The project conducted several drives at night under large flood lamps so the rovers could experience extreme shadows and lighting that approximate what they’ll encounter during the lunar daytime.

After that, the team performed similar drive tests with flight models (the rovers that will go to the Moon) in a JPL clean room. When the spotless floor there proved a bit slippery – a texture different from the lunar surface – the robots got out of formation. But they stopped, adjusted, and proceeded on their planned path.

“Dealing with curveballs – that’s important for the autonomy. The key is the robots respond to things going off plan, then they replan and are still successful,” said JPL’s Jean-Pierre de la Croix, CADRE principal investigator and autonomy lead. “We’re going to a unique environment on the Moon, and there will, of course, be some unknowns. We’ve done our best to prepare for those by testing software and hardware together in various situations.”

Next, the hardware will ship to Intuitive Machines for installation on a Nova-C lander that will launch atop a SpaceX Falcon 9 rocket from NASA’s Kennedy Space Center in Florida.

More About the Project

A division of Caltech in Pasadena, California, JPL manages the CADRE technology demonstration project for the Game Changing Development program within NASA’s Space Technology Mission Directorate in Washington. CADRE is a payload under NASA’s CLPS (Commercial Lunar Payload Services) initiative, which is managed by the agency’s Science Mission Directorate. The agency’s Glenn Research Center in Cleveland and its Ames Research Center in Silicon Valley, California, both supported the project. Motiv Space Systems designed and built key hardware elements at the company’s Pasadena facility. Clemson University in South Carolina contributed research in support of the project.

For more about CADRE, go to:

https://go.nasa.gov/cadre

News Media Contact

Melissa Pamer
Jet Propulsion Laboratory, Pasadena, Calif.
626-314-4928
melissa.pamer@jpl.nasa.gov

2024-022

Powered by WPeMatico

Get The Details…
Anthony Greicius

Students Become FjordPhyto Volunteers and Discover that Antarctica Is Much Colder Than Texas

Students Become FjordPhyto Volunteers and Discover that Antarctica Is Much Colder Than Texas

2 Min Read

Students Become FjordPhyto Volunteers and Discover that Antarctica Is Much Colder Than Texas

Photo of a group of 10 people, most wearing blue winter jackets and red floatation vests, sitting on a boat in the Antarctic.

Texas A&M sent 31 students to the Antarctic this year—and they did some vital NASA science while they were there.

Meteorology students, oceanography students and education psychology students worked with Dr. Chrissy Wiederwohl to collect data for NASA’s FjordPhyto project. The data reveal how meltwater from glaciers affects phytoplankton, the base of the Antarctic food chain.

“We were actually collecting samples for them to look at these phytoplankton communities and how they are changing over time,” said Dr. Wiederwohl, an oceanographer at Texas A&M University.  “Phytoplankton are these tiny microscopic plants in the ocean that photosynthesize and produce about half of our oxygen worldwide. So every other breath we take is actually oxygen coming from the ocean.”

Photo of a young man and woman in blue winter jackets, red floatation vets and warm hats sitting on a boat in the Antarctic. The woman is writing
Korina Zhang and Adam Neuville collecting data for NASA’s FjordPhyto project. They are students with Texas A&M’s American Universities International Program in Antarctica.
Credit: Dr Chrissy Wiederwhol, Texas A&M

FjordPhyto has also recently involved students from Penn State University and Virginia Tech.

The students spent sixty days in a research vessel through the American Universities International Program (AUIP) limited study abroad program. The effort was coordinated with the FjordPhyto team at Scripps Institution of Oceaongraphy and Isidro Bosch of State University of New York in Geneseo, New York.

Going to Antarctica? You can join the FjordPhyto project, too.

Share

Details

Last Updated

Mar 07, 2024

Powered by WPeMatico

Get The Details…