Arizona State University student Marco Lalonde stows the DORA solar panels in preparation for flight. Photo credit: Danny Jacobs
NASA’s CubeSat Launch Initiative soon will send two CubeSats to the International Space Station as cargo on the 21st Northrop Grumman commercial resupply mission.
CySat-1, designed and built by students from Iowa State University, measures Earth’s soil moisture content from low Earth orbit. The measurements will be taken with a software-defined radiometer, a system that uses software to process analog radio signals. Students will create computer programs to analyze those signals to determine levels of moisture in the soil present on the Earth. As Iowa State University’s first CubeSat, CySat-1 will be a technology demonstrator for future CubeSat missions.
Students at Arizona State University and NASA’s Jet Propulsion Laboratory (JPL) in Southern California developed DORA (Deployable Optical Receiver Aperture), a new technology CubeSat.
In the past, small satellites required precision pointing and only achieved low data transmissions in gathering information. The technology will demonstrate new optical communications without precision pointing and use a solid-state photon detector to gather high data rates using wide-field optical receivers. To test the detector’s performance, DORA will measure the background light from reflected sunlight, moonlight, and city lights when deployed from the space station into low Earth orbit.
The two demonstrations, CySat-1 and DORA, are both 3U CubeSats, a class of small satellites. The cube-shaped spacecraft are sized in standardized units, or Us, typically up to 12U. One CubeSat unit is defined as a volume of about 10x10x10 cm in size and typically weighs less than 2 kilograms.
The satellites will be released from the International Space Station using the Nanoracks CubeSat Deployer. One of the space station’s arms grabs and points the deployer in the proper direction to release the CubeSats into orbit.
Launch of the Cygnus spacecraft is targeted at 11:28 a.m. EDT Saturday, Aug. 3, on a SpaceX Falcon 9 rocket from Space Launch Complex 40 at Cape Canaveral Space Force Station in Florida.
Technicians from the University of Maine prepare CubeSat MESAT-1 for integration at Firefly’s Payload Processing Facility at Vandenberg Space Force Base, California on Monday, April 22, 2024. MESAT-1, along with seven other payloads, will be integrated into a Firefly Aerospace Alpha rocket for NASA’s Educational Launch of Nanosatellites (ELaNa) 43 mission as part of the agency’s CubeSat Launch Initiative and Firefly’s Venture-Class Launch Services Demonstration 2 contract. Photo credit: NASA
NASA and Firefly Aerospace are targeting no earlier than Wednesday, June 26, for the launch of eight CubeSats as part of NASA’s CubeSat Launch Initiative’s (CSLI) ELaNa (Educational Launch of Nanosatellites) 43. The 30-minute launch window will open at 9 p.m. PDT on June 26 (12 a.m. EDT on June 27).
Firefly Aerospace’s “Noise of Summer” will launch on an Alpha rocket from Space Launch Complex 2 at Vandenberg Space Force Base in California.
The CubeSats flying on ELaNa 43 are:
CatSat – University of Arizona, Tucson, Arizona
KUbe-Sat-1 – University of Kansas, Lawrence, Kansas
MESAT1 – University of Maine, Orono, Maine
R5-S4 – NASA’s Johnson Space Center, Houston, Texas
R5-S2-2.0 – NASA’s Johnson Space Center, Houston, Texas
SOC-i – University of Washington, Seattle, Washington
TechEdSat-11 – NASA Ames Research Center
Serenity – Teachers in Space
Firefly Aerospace is one of three companies selected under NASA’s Launch Services Program Venture-Class Launch Services Demonstration 2 (VCLS Demo 2) contract awarded in December 2020. The venture-class contracts illustrate how NASA offers opportunities for new launch providers to grow the commercial industry at all levels, which will result in cost-effective competition for NASA missions in the future.
Seen here with its solar arrays deployed, the Low-Latitude Ionosphere/Thermosphere Enhancements in Density (LLITED) mission will measure and study two features of the upper atmosphere: the equatorial temperature and wind anomaly (ETWA) that occurs in the neutral atmosphere, and the equatorial ionization anomaly (EIA) that occurs in the region containing charged particles. Photo credit: Courtesy of The Aerospace Corporation
Editor’s note: This article was updated on April 4 to provide the latest target launch date information.
NASA is announcing two small CubeSats missions to launch on a commercial dedicated rideshare flight as part of the agency’s Educational Launch of Nanosatellites (ELaNa) initiative, which helps advance scientific and human exploration, as well as reduce the cost of new space missions, and expand access to space.
The CubeSat missions, which will study parts of Earth’s atmosphere and its radiation belt dynamics, are targeted for launch no earlier than April 2023 on a SpaceX Falcon 9 rocket from Vandenberg Space Force Base in California.
The Colorado Inner Radiation Belt Experiment (CIRBE) and Low-Latitude Ionosphere/Thermosphere Enhancements in Density (LLITED) are ELaNa missions 47 and 40, respectively.
CIRBE is a 3U CubeSat (1U, or unit = 10cm x 10cm x 10cm) from the University of Colorado Boulder, designed to provide state-of-the-art measurements within Earth’s radiation belt in a highly inclined low-Earth orbit. CIRBE aims for a better understanding of radiation belt dynamics, consequently improving the forecast capability of the energetic particles known to pose a threat to orbiting satellites as well as astronauts during spacewalks.
Engineers from University of Colorado’s Laboratory for Atmospheric and Space Physics integrate CIRBE into a dispenser at Maverick Space Systems in California ahead of launch at Vandenberg Space Force Base. Photo credit: Courtesy of University of Colorado Boulder, Laboratory for Atmospheric and Space Physics
“Despite being the first scientific discovery of the space age, there are still many unsolved puzzles regarding the dynamics of these energetic particles,” said Dr. Xinlin Li, CIRBE principal investigator and professor at the university’s Laboratory for Atmospheric and Space Physics.
CIRBE’s sole instrument, Relativistic Electron Proton Telescope integrated little experiment-2 (REPTile-2), is an advanced version of an instrument previously in space from 2012 to 2014. The original REPTile could detect three energy channels, whereas REPTile-2 can distinguish 50 distinct channels, providing far greater measurement of elusive high energy particles with potential to damage satellites and penetrate spacesuits. REPTile-2 will measure the energies of incident electrons and protons, with its data downlinked to the ground via S-band radio. At mission’s end, the spacecraft’s orbit will begin degrading, eventually re-entering the atmosphere and burning up.
NASA’s LLITED consists of two 1.5U CubeSats developed by The Aerospace Corporation, Embry-Riddle Aeronautical University in Florida, and the University of New Hampshire (UNH). LLITED will study two late-day features of Earth’s atmosphere between 217 to 310 miles, with the aim of gaining a greater understanding of the interactions between the neutral and electrically charged parts of the atmosphere, consequently improving upper-atmosphere modeling capabilities and predictions for orbital proximity and re-entry.
“For the first time, we will be able to make simultaneous and co-located measurements of two phenomena in lower thermosphere/ionosphere – Equatorial Ionization Anomaly (EIA) and Equatorial Temperature Wind Anomaly (ETWA) – from a CubeSat platform,” said Dr. Rebecca Bishop, principal investigator for LLITED. “The two LLITED CubeSats will be able to observe changes in time and space of the two features.”
Both LLITED CubeSats carry three science instruments – a GPS radio-occultation sensor provided by Aerospace, an ionization gauge from UNH, and a planar ion probe provided by Embry-Riddle. Working together, the instruments will show how these atmospheric regions of enhanced density form, evolve, and then interact with each other after sunset.
“Because CubeSats can weigh 100 times less than larger satellites, missions such as LLITED demonstrate the potential of these small and cost-effective spacecraft to perform cutting-edge, comprehensive science experiments that previously were not feasible within traditional program resources,” said Bishop.
NASA’s CubeSat Launch Initiative (CSLI) supporting the agency’s Launch Services Program at Kennedy Space Center in Florida provides launch opportunities for small satellite payloads built by U.S. universities, high schools, NASA Centers, and non-profit organizations. To date, NASA has selected more than 225 CubeSat missions, representing participants from 42 states, the District of Columbia, Puerto Rico, and over 115 unique organizations.
LightCube team members inspect the CubeSat prior to integration into the deployer. From left to right: David Ordaz Perez, Chandler Hutchens, Sam Cherian, Christopher McCormick, Ashley Lepham, Raymond Barakat. Photo credit: Jaime Sanchez de la Vega
On NASA’s next Educational Launch of Nanosatellites (ELaNa) mission, a pair of small satellites, called CubeSats, will hitch a ride on SpaceX’s 27th commercial resupply services mission to the International Space Station for NASA.
The ELaNa 50 complement of CubeSats will launch aboard the SpaceX Falcon 9 and Dragon spacecraft this March, from Launch Complex 39A at NASA’s Kennedy Space Center in Florida, along with additional supplies, equipment, and science investigations to be delivered to the crew aboard the station.
The university-built CubeSats are going to space as part of NASA’s CubeSat Launch Initiative (CSLI). Once deployed, the CubeSats will demonstrate technologies to conduct atmospheric experiments and reduce space debris, as well as provide people on Earth the opportunity for an immediate and powerful connection with an object in space.
First Launch for The Natural State
The CSLI program will launch its first CubeSat from Arkansas. Developed at the University of Arkansas, Fayetteville, ARKSAT-1, is a CubeSat measuring 1U, or unit, (about 4 inches cubed). It will illuminate an LED from orbit and use a ground spectrometer to track and perform atmospheric measurements.
ARKSAT-1 team members Samuel Cano (left) and Charles Smith perform final checkout tests on the ARKSAT-1 flight model, with its electronics stack engineering model also shown. Photo credit: University of Arkansas
“It might be the first time this instrument technology is purposefully designed to be done with a CubeSat,” said Adam Huang, principal investigator. “It could be developed into future satellite-based systems using cooperative formations of CubeSats.”
ARKSAT-1’s secondary objective sets out to demonstrate a way to help alleviate the problem of space debris with a lightweight Solid State Inflatable Balloon (SSIB) that can be used to deorbit small satellites after a mission ends. When the balloon on ARKSAT-1 inflates, it will greatly increase the ARKSAT-1’s aerodynamic drag, thereby helping the satellite re-enter and disintegrate safely in Earth’s atmosphere. If successful, the SSIB technology could help reduce the amount of time a small satellite remains “space junk” in low-Earth orbit after its mission has ended.
Helping Others See the Light
LightCube, a 1U CubeSat developed by Arizona State University, Tempe, in collaboration with Vega Space Systems and Mexico’s CETYS Universidad, features a flash bulb that can be controlled remotely by amateur radio operators on Earth who will be able to activate the satellite to produce a brief flash visible from the ground.
The LightCube CubeSat is loaded into the Nanoracks CubeSat Deployer. Photo credit: Nanoracks
“LightCube provides potential users worldwide with the opportunity to telecommand a spacecraft and observe a tangible and immediate response in the night sky,” said Jaime Sanchez de la Vega, principal investigator. “The team hopes that this process inspires users to learn about space, satellites, and related concepts.”
The flash will appear at a brightness similar to the International Space Station, and several commonly available smartphone and computer apps will show when LightCube is overhead and where to look in the sky to see its flash.
Considering the observational environment, the LightCube team conducted an in-depth assessment to confirm that the brief flashes generated will not have a significant impact on astronomy.
In selecting the CubeSats for ELaNa 50, CSLI continues furthering its goal of providing U.S. educational institutions, nonprofits with an education/outreach component, informal educational institutions (museums and science centers), and NASA centers with access to space at a low cost. Through CSLI, NASA’s Launch Services Program pairs selected CubeSats with launches best suited for each CubeSat’s mission and ready date, taking into consideration the planned orbit and any special constraints the CubeSat’s mission may have.
A group of students at Thomas Jefferson High School for Science and Technology work on their CubeSat, TJREVERB (Thomas Jefferson Research and Education Vehicle for Evaluating Radio Broadcasts). Photo credit: Thomas Jefferson High School
Four small, shoebox-sized satellites are being prepared to launch to the International Space Station as part of NASA’s Educational Launch of Nanosatellites (ELaNa) 49 mission. The small satellites, called CubeSats, will study a range of topics – from satellite communication methods to space weather to testing technology for robotic assembly of large telescopes.
The CubeSats will hitch a ride on the SpaceX Falcon 9 rocket and Dragon spacecraft set to deliver additional science, crew supplies, and hardware to the station during the company’s 26th commercial resupply services mission for NASA. Launch is targeted at 4:19 p.m. EST from Launch Complex 39A at the agency’s Kennedy Space Center in Florida.
Satellite Communications
Seen here is an up-close view of the University of Michigan’s Measurement of Actuator Response In Orbit (MARIO) CubeSat. Photo credit: University of Michigan
The first U.S. high school to send a CubeSat to space back in 2013, Thomas Jefferson High School for Science and Technology’s Research and Education Vehicle for Evaluating Radio Broadcasts satellite aims to study the use of iridium as a primary radio communication method. Additionally, the satellite will demonstrate using a passive magnet onboard and the Earth’s magnetic field for stabilization rather than using an attitude determination and control system for pointing accuracy and stabilization for iridium. What makes this satellite even more notable is that it was a system’s engineering project. The students selected space-grade parts, wired the electronics for the satellite, wrote the drivers to control the different systems, and coded the flight software.
“What’s special about TJREVERB isn’t necessarily the mission, it’s what we did. These kids literally built a satellite the way the industry would build a satellite; we selected parts from vendors and got those parts to work together,” said Kristen Kucko, robotics lab director and the school’s space faculty advisor. “This is an engineering feat.”
Structure Testing
The University of Michigan’s Measurement of Actuator Response In Orbit (MARIO) is a technology demonstration that will show how test structures made of a piezoelectric material – a type of material that bends when electricity is applied and can also generate electricity when bent – perform in low-Earth orbit. This will allow the spacecraft to bend or move without any rotating parts and could one day be used to point and adjust telescope mirrors more accurately.
Space Weather
Seen here is an up-close view of NASA Marshall Space Flight Center’s Scintillation Prediction Observations Research Task (SPORT) CubeSat. Photo credit: NASA
NASA Goddard Space Flight Center’s Plasma Enhancement in The Ionosphere-Thermosphere Satellite (petitSat) will study density irregularities in the Earth’s ionosphere – a tiny fraction of the atmosphere made of plasma, or ionized gas. During long distance radio communication, the ionosphere reflects radio waves back to Earth. Disturbances in the upper atmosphere can change the shape of the ionosphere, creating a funhouse mirror effect and distorting these radio waves. The mission will use two instruments to measure the structure and motion of plasma in the ionosphere resulting from these changes in the upper atmosphere to better understand how these affect satellite communications.
NASA Marshall Space Flight Center’s Scintillation Prediction Observations Research Task (SPORT) will also look to the ionosphere to study space weather. The joint mission between the U.S. and Brazil will examine the formation of plasma bubbles, which sometimes scatter radio signals. Understanding how these bubbles are formed and how their evolution impacts communication signals can help scientists improve the reliability of communication and navigation systems.
“The more we learn about space weather – and how to predict it – the better we can protect our astronauts, spacecraft, and technology,” said Shelia Nash-Stevenson, SPORT project manager.
All of these were selected through NASA’s CubeSat Launch Initiative (CSLI), which provides U.S. educational institutions, nonprofits with an education/outreach component, informal educational institutions (museums and science centers), and NASA centers with access to space at a low cost. Once the CubeSat selections are made, NASA’s Launch Services Program works to pair them with a launch that is best suited to carry them as auxiliary payloads, taking into account the planned orbit and any constraints the CubeSat missions may have.
Virgin Orbit’s LauncherOne rocket is attached to the underside of the company’s Cosmic Girl – a Boeing 747-400 carrier aircraft – at the Mojave Air and Space Port in California. LauncherOne is carrying two small satellites, or CubeSats, for NASA’s ELaNa 39 mission. Photo credit: Virgin Orbit
Two small NASA-sponsored research satellites, or CubeSats, are preparing to launch on Virgin Orbit’s LauncherOne rocket as part of the agency’s Educational Launch of Nanosatellites (ELaNa) 39 mission. The rocket, attached to the underside of the company’s Cosmic Girl aircraft, will be air launched when the 747-aircraft reaches its specified altitude over the Pacific Ocean. Takeoff is currently scheduled for June 29, 2022, from the Mojave Air and Space Port in California.
Seen here is an up-close view of Virgin Orbit’s LauncherOne rocket attached to the underside of the company’s Cosmic Girl aircraft at the Mojave Air and Space Port in California. Photo credit: Virgin Orbit
Once LauncherOne is released from Cosmic Girl, the rocket’s NewtonThree first stage engine will ignite to start the launch sequence that will send the CubeSats into low-Earth orbit.
The two satellites comprising ELaNa 39 are NASA Langley Research Center’s GPX2 and the University of Colorado at Boulder’s Compact Total Irradiance Monitor-Flight Demonstration, or CTIM-FD. They were selected through NASA’s CubeSat Launch Initiative (CSLI) – a NASA effort to provide U.S. educational institutions, informal educational institutions such as museums and science centers, nonprofits with an education/outreach component, and NASA centers with low-cost access to space.
Langley’s GPX2 will use commercial-off-the-shelf differential global positioning systems to demonstrate autonomous, close-proximity operations for small satellites in orbit, such as flying in formation or docking. If successful, this could help reduce costs and greatly simplify in-orbit operations.
CTIM-FD will spend one year in orbit, measuring total solar irradiance (TSI) – data that describes the amount of incident solar radiation that reaches the Earth from the Sun. These levels impact local weather conditions as well as global climate change. The flight demonstration will show whether small satellites are as effective at measuring TSI as the larger, space-based remote sensors in use currently.
Middle schoolers are sending their science fair project to space, one of five CubeSats on a ride-share on the 25th Commercial Resupply Services, CRS-25. The CapSat-1 team are three 7th-grade students from the Weiss School in Palm Beach Gardens, Florida. Photo credit: Weiss School
NASA’s Launch Services Program is preparing to send five CubeSats to the International Space Station as part of the ELaNa 45 (Educational Launch of Nanosatellites) mission aboard SpaceX’s 25th Commercial Resupply Services (CRS-25) mission for NASA. Liftoff is scheduled for June 7 from Launch Complex 39A at the agency’s Kennedy Space Center in Florida.
The small satellites were selected through NASA’s CubeSat Launch Initiative, which provides low-cost access to space for U.S. educational institutions, NASA centers, and others to develop and demonstrate novel technologies in space and to inspire and grow the next generation of scientists, engineers, and technologists.
The CubeSats were developed by the Massachusetts Institute of Technology; The Weiss School in Palm Beach Gardens, Florida; NASA’s Ames Research Center in Silicon Valley, California; Embry-Riddle Aeronautical University in Daytona Beach, Florida; and the University of South Alabama in Mobile. The CubeSats will be deployed from the space station.
NASA has selected over 200 CubeSat missions from more than 100 unique organizations representing 42 states, the District of Columbia, and Puerto Rico through the CubeSat Launch Initiative since 2010. To date, 134 CubeSat missions have launched into space through ELaNa rideshare opportunities.
