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By NASA
5 min read
Preparations for Next Moonwalk Simulations Underway (and Underwater)
An artist’s concept depicts one of NASA’s Voyager probes. The twin spacecraft launched in 1977.NASA/JPL-Caltech The farthest-flung human-made objects will be able to take their science-gathering even farther, thanks to these energy-conserving measures.
Mission engineers at NASA’s Jet Propulsion Laboratory in Southern California turned off the cosmic ray subsystem experiment aboard Voyager 1 on Feb. 25 and will shut off Voyager 2’s low-energy charged particle instrument on March 24. Three science instruments will continue to operate on each spacecraft. The moves are part of an ongoing effort to manage the gradually diminishing power supply of the twin probes.
Launched in 1977, Voyagers 1 and 2 rely on a radioisotope power system that generates electricity from the heat of decaying plutonium. Both lose about 4 watts of power each year.
“The Voyagers have been deep space rock stars since launch, and we want to keep it that way as long as possible,” said Suzanne Dodd, Voyager project manager at JPL. “But electrical power is running low. If we don’t turn off an instrument on each Voyager now, they would probably have only a few more months of power before we would need to declare end of mission.”
The two spacecraft carry identical sets of 10 science instruments. Some of the instruments, geared toward collecting data during planetary flybys, were turned off after both spacecraft completed their exploration of the solar system’s gas giants.
The instruments that remained powered on well beyond the last planetary flyby were those the science team considered important for studying the solar system’s heliosphere, a protective bubble of solar wind and magnetic fields created by the Sun, and interstellar space, the region outside the heliosphere. Voyager 1 reached the edge of the heliosphere and the beginning of interstellar space in 2012; Voyager 2 reached the boundary in 2018. No other human-made spacecraft has operated in interstellar space.
Last October, to conserve energy, the project turned off Voyager 2’s plasma science instrument, which measures the amount of plasma — electrically charged atoms — and the direction it is flowing. The instrument had collected only limited data in recent years due to its orientation relative to the direction that plasma flows in interstellar space. Voyager 1’s plasma science instrument had been turned off years ago because of degraded performance.
Interstellar Science Legacy
The cosmic ray subsystem that was shut down on Voyager 1 last week is a suite of three telescopes designed to study cosmic rays, including protons from the galaxy and the Sun, by measuring their energy and flux. Data from those telescopes helped the Voyager science team determine when and where Voyager 1 exited the heliosphere.
Scheduled for deactivation later this month, Voyager 2’s low-energy charged particle instrument measures the various ions, electrons, and cosmic rays originating from our solar system and galaxy. The instrument consists of two subsystems: the low-energy particle telescope for broader energy measurements, and the low-energy magnetospheric particle analyzer for more focused magnetospheric studies.
Both systems use a rotating platform so that the field of view is 360 degrees, and the platform is powered by a stepper motor that provides a 15.7-watt pulse every 192 seconds. The motor was tested to 500,000 steps — enough to guarantee continuous operation through the mission’s encounters with Saturn, which occurred in August 1980 for Voyager 2. By the time it is deactivated on Voyager 2, the motor will have completed more than 8.5 million steps.
“The Voyager spacecraft have far surpassed their original mission to study the outer planets,” said Patrick Koehn, Voyager program scientist at NASA Headquarters in Washington. “Every bit of additional data we have gathered since then is not only valuable bonus science for heliophysics, but also a testament to the exemplary engineering that has gone into the Voyagers — starting nearly 50 years ago and continuing to this day.”
Addition Through Subtraction
Mission engineers have taken steps to avoid turning off science instruments for as long as possible because the science data collected by the twin Voyager probes is unique. With these two instruments turned off, the Voyagers should have enough power to operate for about a year before the team needs to shut off another instrument on both spacecraft.
In the meantime, Voyager 1 will continue to operate its magnetometer and plasma wave subsystem. The spacecraft’s low-energy charged particle instrument will operate through the remainder of 2025 but will be shut off next year.
Voyager 2 will continue to operate its magnetic field and plasma wave instruments for the foreseeable future. Its cosmic ray subsystem is scheduled to be shut off in 2026.
With the implementation of this power conservation plan, engineers believe the two probes could have enough electricity to continue operating with at least one science instrument into the 2030s. But they are also mindful that the Voyagers have been weathering deep space for 47 years and that unforeseen challenges could shorten that timeline.
Long Distance
Voyager 1 and Voyager 2 remain the most distant human-made objects ever built. Voyager 1 is more than 15 billion miles (25 billion kilometers) away. Voyager 2 is over 13 billion miles (21 billion kilometers) from Earth.
In fact, due to this distance, it takes over 23 hours to get a radio signal from Earth to Voyager 1, and 19½ hours to Voyager 2.
“Every minute of every day, the Voyagers explore a region where no spacecraft has gone before,” said Linda Spilker, Voyager project scientist at JPL. “That also means every day could be our last. But that day could also bring another interstellar revelation. So, we’re pulling out all the stops, doing what we can to make sure Voyagers 1 and 2 continue their trailblazing for the maximum time possible.”
For more information about NASA’s Voyager missions, visit:
https://science.nasa.gov/mission/voyager
News Media Contacts
DC Agle / Calla Cofield
Jet Propulsion Laboratory, Pasadena, Calif.
818-653-6297 / 626-808-2469
agle@jpl.nasa.gov / calla.e.cofield@jpl.nasa.gov
2025-032
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Last Updated Mar 05, 2025 Related Terms
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By NASA
Pictured from left: Roscosmos cosmonaut Kirill Peskov, NASA astronauts Nichole Ayers and Anne McClain, and JAXA (Japan Aerospace Exploration Agency) astronaut mission specialist Takuya Onishi train at SpaceX facilities in Hawthorne, California (Credit: SpaceX). During NASA’s SpaceX Crew-10 mission to the International Space Station, which is scheduled to launch in March, select members of the four-person crew will participate in exercise and medical research aimed at keeping astronauts fit on future long-duration missions.
Crew members living and working aboard the space station have access to a designated training area outfitted with a weight-lifting system, a stationary bike, and a specialized treadmill called T2. The space station is expansive enough for bulky exercise equipment that helps preserve the health and performance of astronauts in space and when they return to Earth.
However, as NASA looks to explore beyond low Earth orbit, the agency anticipates future spacecraft will not have room for large exercise equipment, like treadmills. Since walking and running are essential parts of workouts aboard the space station, NASA does not fully understand how long-duration spaceflights without a treadmill will impact crews’ health and motor functions. Consequently, NASA researchers are adjusting astronauts’ training regimens, including eliminating the use of the treadmill in some cases, to study ways that maintain crews’ strength, fitness, bone health, and balance.
In an ongoing study called Zero T2, expedition crews are divided into three groups with different workout regimens. One group continues exercising normally, using all the available equipment aboard the orbiting complex. A second group forgoes using the treadmill, relying solely on the other available equipment. While a third group will only exercise using a new, experimental, less bulky workout machine. NASA compares the groups’ health data collected before, during, and after flight to determine if the lack of treadmill use negatively impacts the crews’ fitness, muscle performance, and recovery after return to Earth.
“A treadmill takes up a lot of mass, space, and energy. This is not great for missions to Mars where every kilogram counts,” explained NASA astronaut Matthew Dominick, who participated in the same study while serving as commander of NASA’s SpaceX Crew-8 mission in 2024. “The Zero T2 experiment is helping us figure out if we can go without a treadmill and still be healthy.”
Results of the Zero T2 study will help researchers determine how treadmill-free workouts may affect crew health, which will, in turn, help NASA build realistic exercise protocols for future deep space missions. Additionally, this investigation could support design improvements for exercise devices used to prevent or treat bone, muscle, and cardiovascular health on Earth.
Beyond the Zero T2 study, select NASA crew members will perform additional studies supported by the agency’s Human Research Program during their mission. Participating crew will conduct medical exams, provide biological samples, and document spaceflight-related injuries, among other tasks.
“Astronauts choose which studies to participate in based on their interests,” explained Cherie Oubre, a NASA scientist at the agency’s Johnson Space Center in Houston, who helps oversee human research studies carried out aboard the space station. “The experiments address important risks and gaps associated with human spaceflight.”
One set of experiments, called CIPHER (Complement of Integrated Protocols for Human Exploration Research), will help researchers understand how multiple systems within the human body adjust to varying mission durations. CIPHER study members will complete vision assessments, cognitive tests, and MRI scans to help provide a clearer picture of how the entire body is affected by space.
“The CIPHER experiment tracks changes in the eyes, bones, heart, muscles, immune system, and more,” Oubre said. “The investigation provides the most comprehensive overview of how long-duration spaceflight affects the entire human body ever conducted, helping us advance human expeditions to the Moon, Mars, and elsewhere.”
Some crew members also will contribute to a core set of measurements called Spaceflight Standard Measures. The measurements represent how the human body and mind adapt to space travel over time and serve as a basis for other spaceflight studies like CIPHER. Additionally, crew members may provide biological samples for Omics Archive, a separate study analyzing how the body reacts to long-duration spaceflight at the molecular level.
In another study, select crew members will test a potential treatment for spaceflight-associated neuro-ocular syndrome, a condition associated with brain changes and swelling of the back of the eye. Researchers are unsure what causes the syndrome or why only certain astronauts develop it, but the shift of bodily fluids toward the head in weightlessness may play a role. Some scientists believe genetics related to how the body processes B vitamins may affect how astronauts respond to those fluid shifts. Participating crew will test whether a daily B vitamin supplement can ease or prevent the development of symptoms. They also will investigate if cuffs worn on astronauts’ thighs to keep fluids in the legs could be an effective intervention.
Upon return, the select crew members will complete surveys that record any discomfort or injuries associated with landing, such as scrapes and bruises. Results of the surveys ̶ when combined with data retrieved by sensors in the vehicle ̶ will help researchers catalog these injuries and improve the design of spacecraft.
Crew members began participating in the studies about a year before their mission, learning about the work and offering baseline health data. They will continue to provide data for the experiments for up to two years after returning home.
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NASA’s Human Research Program pursues the best methods and technologies to support safe, productive human space travel. Through science conducted in laboratories, ground-based analogs, commercial missions, and the International Space Station, the program scrutinizes how spaceflight affects human bodies and behaviors. Such research drives NASA’s quest to innovate ways that keep astronauts healthy and mission-ready as human space exploration expands to the Moon, Mars, and beyond.
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By NASA
Credit: NASA NASA has selected Firefly Aerospace Inc. of Cedar Park, Texas, to provide the launch service for the agency’s Investigation of Convective Updrafts (INCUS) mission, which aims to understand why, when, and where tropical convective storms form, and why some storms produce extreme weather. The mission will launch on the company’s Alpha rocket from NASA’s Wallops Flight Facility in Virginia.
The selection is part of NASA’s Venture-Class Acquisition of Dedicated and Rideshare (VADR) launch services contract. This contract allows the agency to make fixed-price indefinite-delivery/indefinite-quantity awards during VADR’s five-year ordering period, with a maximum total value of $300 million across all contracts.
The INCUS mission, comprised of three SmallSats flying in tight coordination, will investigate the evolution of the vertical transport of air and water by convective storms. These storms form when rapidly rising water vapor and air create towering clouds capable of producing rain, hail, and lightning. The more air and water that rise, the greater the risk of extreme weather. Convective storms are a primary source of precipitation and cause of the most severe weather on Earth.
Each satellite will have a high frequency precipitation radar that observes rapid changes in convective cloud depth and intensities. One of the three satellites also will carry a microwave radiometer to provide the spatial content of the larger scale weather observed by the radars. By flying so closely together, the satellites will use the slight differences in when they make observations to apply a novel time-differencing approach to estimate the vertical transport of convective mass.
NASA selected the INCUS mission through the agency’s Earth Venture Mission-3 solicitation and Earth System Science Pathfinder program. The principal investigator for INCUS is Susan van den Heever at Colorado State University in Fort Collins. Several NASA centers support the mission, including Langley Research Center in Hampton, Virginia, the Jet Propulsion Laboratory in Southern California, Goddard Space Flight Center in Greenbelt, Maryland, and Marshall Space Flight Center in Huntsville, Alabama. Key satellite system components will be provided by Blue Canyon Technologies and Tendeg LLC, both in Colorado. NASA’s Launch Services Program, based at the agency’s Kennedy Space Center in Florida, manages the VADR contract.
To learn more about NASA’s INCUS mission, visit:
https://science.nasa.gov/mission/incus
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Tiernan Doyle
Headquarters, Washington
202-358-1600
tiernan.doyle@nasa.gov
Patti Bielling
Kennedy Space Center, Florida
321-501-7575
patricia.a.bielling@nasa.gov
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Last Updated Mar 04, 2025 LocationNASA Headquarters Related Terms
Investigation of Convective Updrafts (INCUS) Earth Science Planetary Science Division Science & Research Science Mission Directorate SmallSats Program Wallops Flight Facility View the full article
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