voyager spacecraft 1977

Suggested Searches

• Climate Change
• Expedition 64
• Mars perseverance
• SpaceX Crew-2
• International Space Station
• View All Topics A-Z

Humans in Space

Earth & climate, the solar system, the universe, aeronautics, learning resources, news & events.

NASA Receives 13 Nominations for the 28th Annual Webby Awards

Through Astronaut Eyes, Virtual Reality Propels Gateway Forward  

How NASA Spotted El Niño Changing the Saltiness of Coastal Waters

• Search All NASA Missions
• A to Z List of Missions
• Upcoming Launches and Landings
• Spaceships and Rockets
• Communicating with Missions
• James Webb Space Telescope
• Hubble Space Telescope
• Why Go to Space
• Astronauts Home
• Commercial Space
• Destinations
• Living in Space
• Explore Earth Science
• Earth, Our Planet
• Earth Science in Action
• Earth Multimedia
• Earth Science Researchers
• Pluto & Dwarf Planets
• Asteroids, Comets & Meteors
• The Kuiper Belt
• The Oort Cloud
• Skywatching
• The Search for Life in the Universe
• Black Holes
• The Big Bang
• Dark Energy & Dark Matter
• Earth Science
• Planetary Science
• Astrophysics & Space Science
• The Sun & Heliophysics
• Biological & Physical Sciences
• Lunar Science
• Citizen Science
• Astromaterials
• Aeronautics Research
• Human Space Travel Research
• Science in the Air
• NASA Aircraft
• Flight Innovation
• Supersonic Flight
• Air Traffic Solutions
• Green Aviation Tech
• Drones & You
• Technology Transfer & Spinoffs
• Space Travel Technology
• Technology Living in Space
• Manufacturing and Materials
• Science Instruments
• For Kids and Students
• For Educators
• For Colleges and Universities
• For Professionals
• Science for Everyone
• Requests for Exhibits, Artifacts, or Speakers
• STEM Engagement at NASA
• NASA's Impacts
• Centers and Facilities
• Directorates
• Organizations
• People of NASA
• Internships
• Our History
• Doing Business with NASA
• Get Involved
• Aeronáutica
• Ciencias Terrestres
• Sistema Solar
• All NASA News
• Video Series on NASA+
• Newsletters
• Social Media
• Media Resources
• Upcoming Launches & Landings
• Virtual Events
• Sounds and Ringtones
• Interactives
• STEM Multimedia

NASA Technology Helps Guard Against Lunar Dust

From NASA’s First Astronaut Class to Artemis II: The Importance of Military Jet Pilot Experience

NASA Shares Medical Expertise with New Space Station Partners

Commercial Space Frequently Asked Questions

NASA’s Lola Fatoyinbo Receives Royal Geographical Society Prize

Earth Day Toolkit

More Than 36,000 Volunteers Helped Do NASA Eclipse Science

NASA Names Finalists of the Power to Explore Challenge

NASA’s LRO Finds Photo Op as It Zips Past SKorea’s Danuri Moon Orbiter

NASA’s New Hubble E-Book Spotlights Universe’s Best-Kept Dark Secrets

Hubble Peers at Pair of Closely Interacting Galaxies

SRPD Gamma-ray Astrophysics

Making Ultra-fast Electron Measurements in Multiple Directions to Reveal the Secrets of the Aurora

NASA Langley Team to Study Weather During Eclipse Using Uncrewed Vehicles

NASA Noise Prediction Tool Supports Users in Air Taxi Industry

ARMD Solicitations

Tech Today: Synthetic DNA Diagnoses COVID, Cancer

David Woerner

NASA Partnerships Bring 2024 Total Solar Eclipse to Everyone

Launch Week Event Details

La presentación del X-59 de la NASA personifica la tradición aeronáutica

Voyager, nasa’s longest-lived mission, logs 45 years in space, jet propulsion laboratory, beyond expectations, the long journey, more about the mission.

Launched in 1977, the twin Voyager probes are NASA’s longest-operating mission and the only spacecraft ever to explore interstellar space.

NASA’s twin Voyager probes have become, in some ways, time capsules of their era: They each carry an eight-track tape player for recording data, they have about 3 million times less memory than modern cellphones, and they transmit data about 38,000 times slower than a 5G internet connection.

Yet the Voyagers remain on the cutting edge of space exploration. Managed and operated by NASA’s Jet Propulsion Laboratory in Southern California, they are the only probes to ever explore interstellar space – the galactic ocean that our Sun and its planets travel through.

The Sun and the planets reside in the heliosphere, a protective bubble created by the Sun’s magnetic field and the outward flow of solar wind (charged particles from the Sun). Researchers – some of them younger than the two distant spacecraft – are combining Voyager’s observations with data from newer missions to get a more complete picture of our Sun and how the heliosphere interacts with interstellar space.

“The heliophysics mission fleet provides invaluable insights into our Sun, from understanding the corona or the outermost part of the Sun’s atmosphere, to examining the Sun’s impacts throughout the solar system, including here on Earth, in our atmosphere, and on into interstellar space,” said Nicola Fox, director of the Heliophysics Division at NASA Headquarters in Washington. “Over the last 45 years, the Voyager missions have been integral in providing this knowledge and have helped change our understanding of the Sun and its influence in ways no other spacecraft can.”

NASA’s Solar System Interactive lets users see where the Voyagers are right now relative to the planets, the Sun, and other spacecraft. Eyes on the Solar System . Credit: NASA/JPL-Caltech

The Voyagers are also ambassadors, each carrying a golden record containing images of life on Earth, diagrams of basic scientific principles, and audio that includes sounds from nature, greetings in multiple languages, and music. The gold-coated records serve as a cosmic “message in a bottle” for anyone who might encounter the space probes. At the rate gold decays in space and is eroded by cosmic radiation, the records will last more than a billion years. 

Voyager 2 launched on Aug. 20, 1977, quickly followed by Voyager 1 on Sept. 5. Both probes traveled to Jupiter and Saturn, with Voyager 1 moving faster and reaching them first. Together, the probes unveiled much about the solar system’s two largest planets and their moons. Voyager 2 also became the first and only spacecraft to fly close to Uranus (in 1986) and Neptune (in 1989), offering humanity remarkable views of – and insights into – these distant worlds.

While Voyager 2 was conducting these flybys, Voyager 1 headed toward the boundary of the heliosphere. Upon exiting it in 2012 , Voyager 1 discovered that the heliosphere blocks 70% of cosmic rays, or energetic particles created by exploding stars. Voyager 2, after completing its planetary explorations, continued to the heliosphere boundary, exiting in 2018 . The twin spacecraft’s combined data from this region has challenged previous theories about the exact shape of the heliosphere.

“Today, as both Voyagers explore interstellar space, they are providing humanity with observations of uncharted territory,” said Linda Spilker, Voyager’s deputy project scientist at JPL. “This is the first time we’ve been able to directly study how a star, our Sun, interacts with the particles and magnetic fields outside our heliosphere, helping scientists understand the local neighborhood between the stars, upending some of the theories about this region, and providing key information for future missions.”

Over the years, the Voyager team has grown accustomed to surmounting challenges that come with operating such mature spacecraft, sometimes calling upon retired colleagues for their expertise or digging through documents written decades ago.

Each Voyager is powered by a radioisotope thermoelectric generator containing plutonium, which gives off heat that is converted to electricity. As the plutonium decays, the heat output decreases and the Voyagers lose electricity. To compensate , the team turned off all nonessential systems and some once considered essential, including heaters that protect the still-operating instruments from the frigid temperatures of space. All five of the instruments that have had their heaters turned off since 2019 are still working, despite being well below the lowest temperatures they were ever tested at.

Recently, Voyager 1 began experiencing an issue that caused status information about one of its onboard systems to become garbled. Despite this, the system and spacecraft otherwise continue to operate normally, suggesting the problem is with the production of the status data, not the system itself. The probe is still sending back science observations while the engineering team tries to fix the problem or find a way to work around it.

“The Voyagers have continued to make amazing discoveries, inspiring a new generation of scientists and engineers,” said Suzanne Dodd, project manager for Voyager at JPL. “We don’t know how long the mission will continue, but we can be sure that the spacecraft will provide even more scientific surprises as they travel farther away from the Earth.”

A division of Caltech in Pasadena, JPL built and operates the Voyager spacecraft. The Voyager missions are a part of the NASA Heliophysics System Observatory, sponsored by the Heliophysics Division of the Science Mission Directorate in Washington.

For more information about the Voyager spacecraft, visit:

https://www.nasa.gov/voyager

Calla Cofield Jet Propulsion Laboratory, Pasadena, Calif. 626-808-2469 [email protected]

• April 8, 2024 | What Came First the Chicken or the Egg? Discovery of Ancient Eggshells Rewrites Chicken History
• April 8, 2024 | Revolutionizing AI With the Power of Energy Efficiency
• April 8, 2024 | Motion Camouflage: The Remarkable Hunting Tactics of Trumpetfish
• April 8, 2024 | Researchers Discover Possible Solutions To Reverse the Impact of Alzheimer’s Disease
• April 8, 2024 | Magnetic Awakening: Unusual Radio Pulses Detected From a Previously Dormant Star

Flashback 1977: NASA’s Voyager 1 Lifts Off Toward an Interstellar Journey

By NASA September 5, 2023

NASA’s Voyager 1 spacecraft lifts off atop its Titan/Centaur-6 launch vehicle on September 5, 1977, from Launch Complex 41 at Cape Canaveral Air Force Station, now Cape Canaveral Space Force Station, in Florida. Credit: NASA

On September 5, 1977, NASA ’s Voyager 1 spacecraft lifted off atop its Titan/Centaur-6 launch vehicle from Launch Complex 41 at Cape Canaveral Air Force Station, now Cape Canaveral Space Force Station, in Florida.

Voyager 1 and its twin, Voyager 2, were originally launched to conduct closeup studies of Jupiter and Saturn , Saturn’s rings, and the larger moons of the two planets. After completing these missions and more , Voyager 1 became the first spacecraft to reach interstellar space and is now the farthest human-made object from Earth. Scientists think it will reach the inner edge of the Oort Cloud in 300 years.

Follow along with Voyager’s live mission status .

This artist’s concept shows NASA’s Voyager spacecraft against a field of stars in the darkness of space. The two Voyager spacecraft are traveling farther and farther away from Earth, on a journey to interstellar space, and will eventually circle around the center of the Milky Way galaxy. Credit: NASA/JPL-Caltech

The Voyager missions, launched by NASA in 1977, consist of two spacecraft: Voyager 1 and Voyager 2. These missions were initially intended to study the outer planets of our Solar System, particularly the gas giants Jupiter and Saturn. Both probes provided unprecedented observations and data on these planets, their major moons, and their ring systems.

Voyager 2, in an extended mission, continued on to Uranus and Neptune , becoming the first (and, to date, the only) spacecraft to visit these outer planets. Both Voyager 1 and 2 are equipped with the “Golden Records,” which carry sounds and images selected to portray the diversity of life on Earth for any extraterrestrial beings that might encounter the probes.

Following their planetary missions, both spacecraft have continued to journey outward, sending back data from the far reaches of our Solar System. As of September 5, 2023, Voyager 1, the most distant human-made object from Earth, is 14.97 million miles away, and Voyager 2 is 12.44 million miles away.

The Voyager missions have significantly expanded our understanding of the Solar System and continue to send back data, providing insights into the space environment outside of our planet’s protective bubble.

More on SciTechDaily

NASA’s Longest-Lived Mission: Voyager Probes Log 45 Years in Space

2021 Was an Amazing Year for NASA: Mars Landing, First Flight, Artemis, More [Video]

It’s Official – Voyager 1 Has Entered Interstellar Space

Voyager 2 Illuminates Boundary of Interstellar Space 11 Billion Miles From Earth

Voyager 2 Probe Enters Interstellar Space, Over 18 Billion Kilometers from Earth

Voyager Spacecraft Poised to Make New Discoveries

Hear the Eerie Sounds of Interstellar Space Captured by NASA’s Voyager

What You Need To Know About NASA’s Boeing Starliner Spacecraft Launch + How To Watch It Live

1 comment on "flashback 1977: nasa’s voyager 1 lifts off toward an interstellar journey".

The distances from earth are incorrect. I think the distances are in billions of miles, not millions

Leave a comment Cancel reply

Email address is optional. If provided, your email will not be published or shared.

Save my name, email, and website in this browser for the next time I comment.

The Golden Record

Launched in 1977, both Voyager spacecraft carry a unique 'time capsule' along with them into interstellar space.

A Kind of Time Capsule

Pioneers 10 and 11, which preceded Voyager, both carried small metal plaques identifying their time and place of origin for the benefit of any other spacefarers that might find them in the distant future. With this example before them, NASA placed a more ambitious message aboard Voyager 1 and 2, a kind of time capsule, intended to communicate a story of our world to extraterrestrials. The Voyager message is carried by a phonograph record, a 12-inch gold-plated copper disk containing sounds and images selected to portray the diversity of life and culture on Earth.

The Golden Record Cover

The record's protective cover includes with instructions for playing its contents, finding Earth in the cosmos, and dating how long it has been in space.

What's on the Record?

The record features images and a variety of natural sounds, such thunder, birds, musical selections from different cultures and eras, and spoken greetings in 55 languages.

History and Manufacturing

Many people were instrumental in the design, development and manufacturing of the golden record.

Discover More Topics From NASA

Our Solar System

45 Years Ago: Voyager 2 Begins Its Epic Journey to the Outer Planets and Beyond

The ambitious mission took advantage of a rare alignment of the outer planets before continuing its journey into interstellar space.

Forty-five years ago, the Voyager 2 spacecraft left Earth to begin an epic journey that continues to this day. The first of a pair of spacecraft, Voyager 2 lifted off on Aug. 20, 1977. NASA’s Jet Propulsion Laboratory in Southern California manages the spacecraft on their missions to explore the outer planets and beyond. Taking advantage of a rare planetary alignment to use the gravity of one planet to redirect the spacecraft to the next, the Voyagers initially targeted only Jupiter and Saturn, but Voyager 2 went on to explore Uranus and Neptune as well. The Voyagers carried sophisticated instruments to conduct their in-depth explorations of the outer planets. Both spacecraft continue to return data as they make their way out of our solar system and enter interstellar space.

Proposed trajectories for the Thermoelectric Outer Planet Spacecraft Grand Tour, canceled in 1971.

In the 1960s, mission designers at JPL noted that the next alignment of the outer planets that occurs only every 175 years would happen in the late 1970s. Technology had advanced sufficiently that spacecraft could take advantage of this rare alignment to fly by Jupiter and use its gravity to bend their trajectories to visit Saturn, and repeat the process to also visit Uranus, Neptune, and Pluto. Launching several missions to visit each planet individually would take much longer and cost much more. The original plan to send two pairs of Thermoelectric Outer Planet Spacecraft on these Grand Tours proved too costly, leading to cancellation in 1971. The next year, NASA approved a scaled-down version of the project to launch a pair of Mariner-class spacecraft in 1977 to explore just Jupiter and Saturn. On March 7, 1977, NASA Administrator James C. Fletcher announced the renaming of these Mariner Jupiter/Saturn 1977 spacecraft as Voyager 1 and 2. Scientists held out hope that one of them could ultimately visit Uranus and Neptune, thereby fulfilling most of the original Grand Tour’s objectives. Pluto would have to wait many more years for its first visit.

From left: a 1975 illustration of the Mariner Jupiter/Saturn 1977 mission; a model of the Voyager spacecraft; the Aug. 20, 1977, launch of Voyager 2 at Cape Canaveral in Florida.

Each Voyager carried a suite of 11 instruments to study the planets during each encounter and to learn more about interplanetary space in the outer reaches of the solar system, including:

• An imaging science system consisting of narrow-angle and wide-angle cameras to photograph the planet and its satellites.
• A radio science system to determine the planet’s physical properties.
• An infrared interferometer spectrometer to investigate local and global energy balance and atmospheric composition.
• An ultraviolet spectrometer to measure atmospheric properties.
• A magnetometer to analyze the planet’s magnetic field and interaction with the solar wind.
• A plasma spectrometer to investigate microscopic properties of plasma ions.
• A low energy charged particle device to measure fluxes and distributions of ions.
• A cosmic ray detection system to determine the origin and behavior of cosmic radiation.
• A planetary radio astronomy investigation to study radio emissions from Jupiter.
• A photopolarimeter to measure the planet’s surface composition.
• A plasma wave system to study the planet’s magnetosphere.

From left: a schematic of the Voyager spacecraft showing the science experiments; trajectories of the Voyagers through the solar system.

Voyager 2 left Earth first, lifting off on Aug. 20, 1977, atop a Titan IIIE-Centaur rocket from Launch Complex 41 at Cape Canaveral Air Force Station, now Cape Canaveral Space Force Station, in Florida. Although its twin launched two weeks later, it traveled on a faster trajectory and arrived at Jupiter four months earlier. Voyager 2 successfully crossed the asteroid belt between Dec. 10, 1977, and Oct. 21, 1978. In April 1978, its primary radio receiver failed, and it has been operating on its backup receiver ever since.

Voyager 2 images of Jupiter, left, and Saturn with its rings and several of its moons.

Voyager 2 conducted its observations of Jupiter between April 24 and Aug. 5, 1979, making its closest approach of 350,000 miles above the planet’s cloud tops on July 9. The spacecraft returned 17,000 images of Jupiter, many of its satellites, and confirmed Voyager 1’s discovery of a thin ring encircling the planet. Its other instruments returned information about Jupiter’s atmosphere and magnetic field. Jupiter’s massive gravity field bent the spacecraft’s trajectory, accelerating it toward Saturn.

Voyager 2 began its long-range observations of the ringed planet on June 5, 1981, passed within 26,000 miles of the planet’s cloud tops on Aug. 26, and concluded its studies on Sept. 4. The spacecraft captured 16,000 photographs of the planet, its rings, and many of its known satellites. It discovered several new ones, and its instruments returned data about Saturn’s atmosphere. Saturn’s gravity sent Voyager 2 on to Uranus.

Voyager 2 images of Uranus, left, and Neptune.

Voyager 2 carried out the first close-up observations of Uranus between Nov. 4, 1985, and Feb. 25, 1986, making its closest approach of 50,700 miles above the planet’s cloud tops on Jan. 24, 1986. It returned more than 7,000 photographs of the planet, its rings and moons, discovering two new rings and 11 new moons. The spacecraft’s instruments returned data about the planet’s atmosphere and its unusual magnetic field, tilted by 59 degrees compared to its rotational axis and offset from the planet’s center by about one-third of the planet’s radius.

Voyager 2 took advantage of Uranus’ gravity to send it on to its last planetary destination, Neptune. The spacecraft conducted the first close-up observations of the eighth planet between June 5 and Oct. 2, 1989, making its flyby just 3,408 miles above its north pole on Aug. 25, its closest approach to any planet since leaving Earth in 1977. This trajectory allowed Voyager 2 to observe Neptune’s large moon Triton, the last solid object it explored. During the encounter, it returned more than 9,000 images of the planet, its atmosphere, dark rings, and moons, discovering six new moons. Like Uranus, Voyager 2’s instruments revealed that Neptune has an unusual magnetic field, not only tilted 47 degrees from the planet’s axis but also significantly offset from the planet’s center.

An illustration showing the position of the Voyager 1 and 2 spacecraft outside of the heliosphere, a protective bubble created by the sun that extends well past the orbit of Neptune.

Following its reconnaissance of Neptune, Voyager 2 began its Interstellar Mission extension that continues to this day. Over the years, several of the spacecraft’s instruments have been turned off to conserve power, beginning with the imaging system in 1998, but it continues to return data about cosmic rays and the solar wind. On Nov. 5, 2018, six years after its twin, Voyager 2 crossed the heliopause, the boundary between the heliosphere – the bubble-like region of space created by the Sun – and the interstellar medium. Currently, Voyager 2 continues its mission, more than 12 billion miles from Earth, so distant that a signal from the spacecraft takes 18 hours to reach Earth, and just as long for a return signal to reach the craft. Engineers expect that Voyager 2 will continue to return data until about 2025. And just in case an alien intelligence finds it one day, Voyager 2 like its twin carries a gold-plated record that contains information about its home planet, including recordings of terrestrial sounds, music, and greetings in 55 languages. Engineers at NASA thoughtfully included instructions on how to play the record.

The gold disc carried by each Voyager.

News Media Contact

Calla Cofield

Jet Propulsion Laboratory, Pasadena, Calif.

626-808-2469

[email protected]

Written by John Uri, NASA’s Johnson Space Center

Voyager 1 and 2: The Interstellar Mission

An image of Neptune taken by the Voyager 2 spacecraft. Image credit: NASA

NASA has beautiful photos of every planet in our solar system. We even have images of faraway Neptune , as you can see in the photo above.

Neptune is much too distant for an astronaut to travel there with a camera. So, how do we have pictures from distant locations in our solar system? Our photographers were two spacecraft, called Voyager 1 and Voyager 2!

An artist’s rendering of one of the Voyager spacecraft. Image credit: NASA

The Voyager 1 and 2 spacecraft launched from Earth in 1977. Their mission was to explore Jupiter and Saturn —and beyond to the outer planets of our solar system. This was a big task. No human-made object had ever attempted a journey like that before.

The two spacecraft took tens of thousands of pictures of Jupiter and Saturn and their moons. The pictures from Voyager 1 and 2 allowed us to see lots of things for the first time. For example, they captured detailed photos of Jupiter's clouds and storms, and the structure of Saturn's rings .

Image of storms on Jupiter taken by the Voyager 1 spacecraft. Image credit: NASA

Voyager 1 and 2 also discovered active volcanoes on Jupiter's moon Io , and much more. Voyager 2 also took pictures of Uranus and Neptune. Together, the Voyager missions discovered 22 moons.

Since then, these spacecraft have continued to travel farther away from us. Voyager 1 and 2 are now so far away that they are in interstellar space —the region between the stars. No other spacecraft have ever flown this far away.

Where will Voyager go next?

Watch this video to find out what's beyond our solar system!

Both spacecraft are still sending information back to Earth. This data will help us learn about conditions in the distant solar system and interstellar space.

The Voyagers have enough fuel and power to operate until 2025 and beyond. Sometime after this they will not be able to communicate with Earth anymore. Unless something stops them, they will continue to travel on and on, passing other stars after many thousands of years.

Each Voyager spacecraft also carries a message. Both spacecraft carry a golden record with scenes and sounds from Earth. The records also contain music and greetings in different languages. So, if intelligent life ever find these spacecraft, they may learn something about Earth and us as well!

A photo of the golden record that was sent into space on both Voyager 1 and Voyager 2. Image credit: NASA/JPL-Caltech

More about our universe!

Where does interstellar space begin?

Searching for other planets like ours

Play Galactic Explorer!

If you liked this, you may like:

• Mobile Site
• Staff Directory
• Advertise with Ars

Filter by topic

• Biz & IT
• Gaming & Culture

Front page layout

Hope returns —

Nasa knows what knocked voyager 1 offline, but it will take a while to fix, "engineers are optimistic they can find a way for the fds to operate normally.".

Stephen Clark - Apr 6, 2024 12:28 am UTC

Engineers have determined why NASA's Voyager 1 probe has been transmitting gibberish for nearly five months, raising hopes of recovering humanity's most distant spacecraft.

Voyager 1, traveling outbound some 15 billion miles (24 billion km) from Earth, started beaming unreadable data down to ground controllers on November 14. For nearly four months, NASA knew Voyager 1 was still alive—it continued to broadcast a steady signal—but could not decipher anything it was saying.

Confirming their hypothesis, engineers at NASA's Jet Propulsion Laboratory (JPL) in California confirmed a small portion of corrupted memory caused the problem. The faulty memory bank is located in Voyager 1's Flight Data System (FDS), one of three computers on the spacecraft. The FDS operates alongside a command-and-control central computer and another device overseeing attitude control and pointing.

The FDS duties include packaging Voyager 1's science and engineering data for relay to Earth through the craft's Telemetry Modulation Unit and radio transmitter. According to NASA, about 3 percent of the FDS memory has been corrupted, preventing the computer from carrying out normal operations.

Optimism growing

Suzanne Dodd, NASA's project manager for the twin Voyager probes, told Ars in February that this was one of the most serious problems the mission has ever faced. That is saying something because Voyager 1 and 2 are NASA's longest-lived spacecraft. They launched 16 days apart in 1977, and after flying by Jupiter and Saturn, Voyager 1 is flying farther from Earth than any spacecraft in history. Voyager 2 is trailing Voyager 1 by about 2.5 billion miles, although the probes are heading out of the Solar System in different directions.

Normally, engineers would try to diagnose a spacecraft malfunction by analyzing data it sent back to Earth. They couldn't do that in this case because Voyager 1 has been transmitting data packages manifesting a repeating pattern of ones and zeros. Still, Voyager 1's ground team identified the FDS as the likely source of the problem.

The Flight Data Subsystem was an innovation in computing when it was developed five decades ago. It was the first computer on a spacecraft to use volatile memory. Most of NASA's missions operate with redundancy, so each Voyager spacecraft launched with two FDS computers. But the backup FDS on Voyager 1 failed in 1982.

Due to the Voyagers' age, engineers had to reference paper documents, memos, and blueprints to help understand the spacecraft's design details. After months of brainstorming and planning, teams at JPL uplinked a command in early March to prompt the spacecraft to send back a readout of the FDS memory.

The command worked, and Voyager1 responded with a signal different from the code it had been transmitting since November. After several weeks of meticulous examination of the new code, engineers pinpointed the location of the bad memory.

"The team suspects that a single chip responsible for storing part of the affected portion of the FDS memory isn’t working," NASA said in an update posted Thursday. "Engineers can’t determine with certainty what caused the issue. Two possibilities are that the chip could have been hit by an energetic particle from space or that it simply may have worn out after 46 years."

Voyager 1's distance from Earth complicates the troubleshooting effort. The one-way travel time for a radio signal to reach Voyager 1 from Earth is about 22.5 hours, meaning it takes roughly 45 hours for engineers on the ground to learn how the spacecraft responded to their commands.

NASA also must use its largest communications antennas to contact Voyager 1. These 230-foot-diameter (70-meter) antennas are in high demand by many other NASA spacecraft , so the Voyager team has to compete with other missions to secure time for troubleshooting. This means it will take time to get Voyager 1 back to normal operations.

"Although it may take weeks or months, engineers are optimistic they can find a way for the FDS to operate normally without the unusable memory hardware, which would enable Voyager 1 to begin returning science and engineering data again," NASA said.

reader comments

Channel ars technica.

We finally know why NASA's Voyager 1 spacecraft stopped communicating — scientists are working on a fix

The first spacecraft to explore beyond the solar system started spouting gibberish late last year. Now, NASA knows why.

NASA engineers have discovered the cause of a communications breakdown between Earth and the interstellar explorer Voyager 1. It would appear that a small portion of corrupted memory exists in one of the spacecraft's computers. 

The glitch caused Voyager 1 to send unreadable data back to Earth, and is found in the NASA spacecraft's flight data subsystem (FDS). That's the system responsible for packaging the probe's science and engineering data before the telemetry modulation unit (TMU) and radio transmitter send it back to mission control. 

The source of the issue began to reveal itself when Voyager 1 operators sent the spacecraft a "poke" on March 3, 2024. This was intended to prompt FDS to send a full memory readout back to Earth.

The readout confirmed to the NASA team that about 3% of the FDS memory had been corrupted, and that this was preventing the computer from carrying out its normal operations.

Related: NASA finds clue while solving Voyager 1's communication breakdown case

Launched in 1977, Voyager 1 became the first human-made object to leave the solar system and enter interstellar space in 2012. Voyager 2 followed its spacecraft sibling out of the solar system in 2018, and is still operational and communicating well with  Earth.

After 11 years of interstellar exploration, in Nov. 2023, Voyager 1's binary code — the computer language it uses to communicate with Earth — stopped making sense. Its 0's and 1's didn't mean anything anymore.

Get the Space.com Newsletter

Breaking space news, the latest updates on rocket launches, skywatching events and more!

"Effectively, the call between the spacecraft and the Earth was still connected, but Voyager's 'voice' was replaced with a monotonous dial tone," Voyager 1's engineering team previously  told Space.com .

The team strongly suspects this glitch is the result of a single chip that's responsible for storing part of the affected portion of the FDS memory ceasing to work.

Currently, however, NASA can’t say for sure what exactly caused that particular issue. The chip could have been struck by a high-speed energetic particle from space or, after 46 years serving Voyager 1, it may simply have worn out.

—  Voyager 2: An iconic spacecraft that's still exploring 45 years on

—  NASA's interstellar Voyager probes get software updates beamed from 12 billion miles away

—  NASA Voyager 2 spacecraft extends its interstellar science mission for 3 more years

Voyager 1 currently sits around 15 billion miles (24 billion kilometers) from Earth, which means it takes 22.5 hours to receive a radio signal from it — and another 22.5 hours for the spacecraft to receive a response via the Deep Space Network's antennas. Solving this communication issue is thus no mean feat.

Yet, NASA scientists and engineers are optimistic they can find a way to help FDS operate normally, even without the unusable memory hardware.

Solving this issue could take weeks or even months, according to NASA — but if it is resolved, Voyager 1 should be able to resume returning science data about what lies outside the solar system.

Join our Space Forums to keep talking space on the latest missions, night sky and more! And if you have a news tip, correction or comment, let us know at: [email protected].

Robert Lea is a science journalist in the U.K. whose articles have been published in Physics World, New Scientist, Astronomy Magazine, All About Space, Newsweek and ZME Science. He also writes about science communication for Elsevier and the European Journal of Physics. Rob holds a bachelor of science degree in physics and astronomy from the U.K.’s Open University. Follow him on Twitter @sciencef1rst.

SpaceX launches 23 Starlink satellites in nighttime liftoff (photos, video)

'Heavy' history: ULA launches final Delta rocket after 64 years (video, photos)

Why Peter Higgs leaves a massive legacy in the field of physics

Most Popular

By Harry Baker April 10, 2024

By Robert Lea April 10, 2024

By Daisy Dobrijevic April 10, 2024

By Mike Wall April 10, 2024

By Elizabeth Howell April 09, 2024

By Daisy Dobrijevic April 09, 2024

By Robert Lea April 09, 2024

By Josh Dinner April 09, 2024

By Robert Z. Pearlman April 09, 2024

By Mike Wall April 09, 2024

By Keumars Afifi-Sabet April 09, 2024

• 2 See Jupiter close to a crescent moon (Mars near Saturn, too) in the 'View a Planet Day' night sky
• 3 What happened when the moon 'turned itself inside out' billions of years ago?
• 4 Could these big expandable habitats help humanity settle the moon and Mars?
• 5 US needs new space tech or it 'will lose,' Space Force chief says

NASA engineers discover why Voyager 1 is sending a stream of gibberish from outside our solar system

Voyager 1 has been sending a stream of garbled nonsense since November. Now NASA engineers have identified the fault and found a potential workaround.

For the past five months, the Voyager 1 spacecraft has been sending a steady stream of unreadable gibberish back to Earth. Now, NASA engineers finally know why.

The 46-year-old spacecraft sends regular radio signals as it drifts further from our solar system . But in November 2023, the signals suddenly became garbled, meaning  scientists were unable to read any of its data, and they were left mystified about the fault's origins. 

In March, NASA engineers sent a command prompt, or "poke," to the craft to get a readout from its flight data subsystem (FDS) — which packages Voyager 1's science and engineering data before beaming it back to Earth. 

After decoding the spacecraft's response, the engineers have found the source of the problem: The FDS's memory has been corrupted.

Related: NASA's Voyager 1 sends readable message to Earth after 4 nail-biting months of gibberish

"The team suspects that a single chip responsible for storing part of the affected portion of the FDS memory isn't working," NASA said in a blog post Wednesday (March 13) . "Engineers can't determine with certainty what caused the issue. Two possibilities are that the chip could have been hit by an energetic particle from space or that it simply may have worn out after 46 years."

— NASA hears 'heartbeat' signal from Voyager 2 probe a week after losing contact

— Historic space photo of the week: Voyager 2 spies a storm on Saturn 42 years ago

— NASA reestablishes full contact with Voyager 2 probe after nail-biting 2-week blackout

Although it may take several months, the engineers say they can find a workaround to run the FDS without the fried chip — restoring the spacecraft's messaging output and enabling it to continue to send readable information from outside our solar system.

Sign up for the Live Science daily newsletter now

Get the world’s most fascinating discoveries delivered straight to your inbox.

Launched in 1977, Voyager 1 zipped past Saturn and Jupiter in 1979 and 1980 before flying out into interstellar space in 2012. It is now recording the conditions outside of the sun's protective magnetic field , or heliosphere, which blankets our solar system.

Voyager 1 is currently more than 15 billion miles (24 billion kilometers) from Earth, and it takes 22.5 hours for any radio signal to travel from the craft to our planet.

Ben Turner is a U.K. based staff writer at Live Science. He covers physics and astronomy, among other topics like tech and climate change. He graduated from University College London with a degree in particle physics before training as a journalist. When he's not writing, Ben enjoys reading literature, playing the guitar and embarrassing himself with chess.

NASA spacecraft snaps mysterious 'surfboard' orbiting the moon. What is it?

The moon is getting its own time zone, White House memo to NASA reveals

Why I watched the solar eclipse with my kids, a goose and 2,000 trees

• TorbjornLarsson Bon voyage, Voyager! Reply
• Jay McHue What if aliens are doing it to try to communicate with us? 🤪 Reply

Jay McHue said: What if aliens are doing it to try to communicate with us? 🤪

admin said: Voyager 1 has been sending a stream of garbled nonsense since November. Now NASA engineers have identified the fault and found a potential workaround. NASA engineers discover why Voyager 1 is sending a stream of gibberish from outside our solar system : Read more

sourloaf said: What does FSB mean?

Rusty Lugnuts said: Where are you seeing "FSB"? The closest thing I can see in the article is "FDS". In modern computers, FSB would most likely refer to the Fr0nt S1ide Bu5, though I have no idea if a system as old as Voyagers, let alone engineered so specifically, would have an FSB. (apparently I can't spell out "Fr0nt S1ide Bu5" or my post gets flagged as spam or inappropriate??)

• SkidWard Just cut the % of ram needed... skip the bad sectors Reply
• kloudykat FDS = fl1ght da1a sub5ystem5 Reply
• 5ft24dave This is pretty old news, like 6 months old. Are you guys just now discovering this? Reply

Commodore Browncoat said: That's about as sane a theory as many of the others that have become ridiculously popular in the past several years, so sure - why not? What reply do you think we should send?

• View All 11 Comments

Most Popular

By Peter Ray Allison April 10, 2024

By Tom Metcalfe April 09, 2024

By Rebecca Sohn April 09, 2024

By Stephanie Pappas April 09, 2024

By Samantha Mathewson April 09, 2024

By Nicoletta Lanese April 09, 2024

By Sascha Pare April 09, 2024

By Emily Cooke April 09, 2024

By Harry Baker April 09, 2024

• 2 Here are the best photos of the April 8 total solar eclipse over North America
• 3 Part of the San Andreas fault may be gearing up for an earthquake
• 4 Pet fox with 'deep relationship with the hunter-gatherer society' buried 1,500 years ago in Argentina
• 5 NASA engineers discover why Voyager 1 is sending a stream of gibberish from outside our solar system
• 2 Pet fox with 'deep relationship with the hunter-gatherer society' buried 1,500 years ago in Argentina
• 3 No, you didn't see a solar flare during the total eclipse — but you may have seen something just as special
• 4 Neolithic women in Europe were tied up and buried alive in ritual sacrifices, study suggests
• 5 Superfast drone fitted with new 'rotating detonation rocket engine' approaches the speed of sound

• The Contents
• The Making of
• Where Are They Now
• Frequently Asked Questions
• Q & A with Ed Stone

golden record

Where are they now.

• frequently asked questions
• Q&A with Ed Stone

The Golden Record

Pioneers 10 and 11, which preceded Voyager, both carried small metal plaques identifying their time and place of origin for the benefit of any other spacefarers that might find them in the distant future. With this example before them, NASA placed a more ambitious message aboard Voyager 1 and 2, a kind of time capsule, intended to communicate a story of our world to extraterrestrials. The Voyager message is carried by a phonograph record, a 12-inch gold-plated copper disk containing sounds and images selected to portray the diversity of life and culture on Earth.

Engineers Pinpoint Cause of Voyager 1 Issue, Are Working on Solution

Engineers have confirmed that a small portion of corrupted memory in one of the computers aboard NASA’s Voyager 1 has been causing the spacecraft to send unreadable science and engineering data to Earth since last November. Called the flight data subsystem (FDS), the computer is responsible for packaging the probe’s science and engineering data before the telemetry modulation unit (TMU) and radio transmitter send the data to Earth.

In early March , the team issued a “poke” command to prompt the spacecraft to send back a readout of the FDS memory, which includes the computer’s software code as well as variables (values used in the code that can change based on commands or the spacecraft’s status). Using the readout, the team has confirmed that about 3% of the FDS memory has been corrupted, preventing the computer from carrying out normal operations.

The team suspects that a single chip responsible for storing part of the affected portion of the FDS memory isn’t working. Engineers can’t determine with certainty what caused the issue. Two possibilities are that the chip could have been hit by an energetic particle from space or that it simply may have worn out after 46 years.

Although it may take weeks or months, engineers are optimistic they can find a way for the FDS to operate normally without the unusable memory hardware, which would enable Voyager 1 to begin returning science and engineering data again.

Launched in 1977 , the twin Voyager spacecraft flew by Saturn and Jupiter, and Voyager 2 flew by Uranus and Neptune. They are both exploring interstellar space, outside the bubble of particles and magnetic fields created by the Sun, called the heliosphere. Voyager 2 continues to operate normally.

News Media Contact Calla Cofield Jet Propulsion Laboratory, Pasadena, Calif. 626-808-2469 [email protected]

More From Forbes

Nasa discovers source of voyager 1 glitch in interstellar space.

• Share to Facebook
• Share to Twitter
• Share to Linkedin

A NASA image of one of the Voyager space probes. Voyager 1 and its identical sister craft Voyager 2 ... [+] were launched in 1977 to study the outer Solar System and eventually interstellar space. (Photo by NASA/Hulton Archive/Getty Images)

NASA’s pioneering Voyager 1 spacecraft has a memory problem. The space agency has been troubleshooting the elderly machine since it began sending back gibberish communications in November. NASA hasn’t fixed Voyager 1 yet, but engineers now know what’s vexing the spacecraft.

The glitch paused Voyager 1’s science work and kicked off a long-distance diagnosis process. The team traced the issue to the flight data subsystem, a computer that talks to the spacecraft’s telemetry modulation unit to send science and engineering data to Earth. The data came back unintelligible. The culprit appears to be a single chip that’s part of the FDS.

The breakthrough came thanks to a “poke” NASA sent in March that prompted Voyager 1 to send back a readout of its FDS memory. “Using the readout, the team has confirmed that about 3% of the FDS memory has been corrupted, preventing the computer from carrying out normal operations,” NASA said in a statement on April 4.

Voyager 1’s position so far away from home creates a lot of challenges when it comes to fixing problems. NASA talks to the spacecraft over a distance of over 15 billion miles. It takes 22.5 hours for a radio signal to reach Voyager 1 and it takes an equally long time to receive a response. It’s troubleshooting in slow motion. It also means figuring out the exact cause of the glitch is mostly educated guesswork. It could be damage or it could be a matter of age. “Engineers can’t determine with certainty what caused the issue,” said NASA. “Two possibilities are that the chip could have been hit by an energetic particle from space or that it simply may have worn out after 46 years.”

There’s reason for optimism, though Voyager 1 won’t make a quick recovery. “Although it may take weeks or months, engineers are optimistic they can find a way for the FDS to operate normally without the unusable memory hardware, which would enable Voyager 1 to begin returning science and engineering data again,” NASA said.

Best High-Yield Savings Accounts Of 2024

Best 5% interest savings accounts of 2024.

Voyager 1 has made an unprecedented journey across space. It launched in 1977 on an initial mission to study our solar system and visit Jupiter and Saturn. That was just the beginning. The resilient spacecraft kept on going and eventually entered interstellar space in 2012. It was the first human-made object to venture into the unexplored territory outside our solar system. Voyager 1’s twin Voyager 2 crossed over into interstellar space in 2018.

NASA turned off some of Voyager 1’s science instruments as the spacecraft aged, but the probe has still been returning valuable data on interstellar space. If a fix works, Voyager 1 will get back into the swing of science and write yet another chapter in an epic story of exploration.

• Editorial Standards
• Reprints & Permissions

NASA Figured Out Why Its Voyager 1 Probe Has Been Glitching for Months

An artist’s concept of the Voyager 1 spacecraft in interstellar space.

After months of sending unusable data to mission control, there’s finally hope for the Voyager 1 spacecraft. NASA engineers pinpointed the cause behind the mission’s odd anomaly, and think they can help the interstellar probe make sense again.

Engineers at NASA’s Jet Propulsion Laboratory believe the Voyager 1 spacecraft has been sending nonsensical data due to corrupted memory hardware in the spacecraft’s flight data system (FDS). “The team suspects that a single chip responsible for storing part of the affected portion of the FDS memory isn’t working,” NASA wrote in an update.

FDS collects data from Voyager’s science instruments, as well as engineering data about the health of the spacecraft, and combines them into a single package that’s transmitted to Earth through one of the probe’s subsystems, the telemetry modulation unit (TMU), in binary code.

FDS and TMU have been having trouble communicating with one another. As a result, TMU has been sending data to mission control in a repeating pattern of ones and zeroes. NASA’s engineers aren’t quite sure what corrupted the FDS memory hardware; they think that either the chip was hit by an energetic particle from space or that it’s just worn out after operating for 46 years.

Voyager 1 launched in 1977, less than a month after its twin probe, Voyager 2, began its own journey to space. The probe ventured into interstellar space in August 2012, becoming the first spacecraft to leave the heliosphere.

The problem first began in May 2022, when the probe suddenly started sending nonsensical attitude articulation and control (AACS) data . Engineers resolved the issue by sending the telemetry data through one of the spacecraft’s other computers. In December 2023, Voyager 1 started speaking gibberish again .

On March 1, the team sent a “poke” to the spacecraft’s data system, a command that gently prompts FDS to try different sequences in its software package in an effort to pinpoint the corrupted section. Two days later, Voyager 1 sent a signal that contained a readout of the entire FDS memory , which helped the team pinpoint the source of the glitch by comparing this memory readout with a previous one to look for discrepancies in the code.

“Using the readout, the team has confirmed that about 3% of the FDS memory has been corrupted, preventing the computer from carrying out normal operations,” NASA wrote in its update.

The engineers are hoping to resolve the issue by finding a way for FDS to operate normally without the corrupted memory hardware, enabling Voyager 1 to begin transmitting data about the cosmos and continue its journey through deep space.

For more spaceflight in your life, follow us on X and bookmark Gizmodo’s dedicated Spaceflight page .

For the latest news, Facebook , Twitter and Instagram .