fotos de voyager 1

Early Voyager 1 Images of Jupiter

Each of the pictures was produced from blue, green, and orange originals in JPL's Image Processing Laboratory.

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Voyager: 15 incredible images of our solar system captured by the twin probes (gallery)

The twin probes have captured some remarkable images of our cosmic neighborhood.

NASA's twin probes Voyager 1 and Voyager 2 have captured some truly remarkable images of our solar system and are currently roaming through interstellar space. 

Despite its name Voyager 2 launched before Voyager 1 , when it lifted off from Cape Canaveral Space Launch Complex 41 aboard a Titan IIIE-Centaur on Aug. 20, 1977. Voyager 1 followed suit about two weeks later on Sept. 5. 

While Voyager 1 primarily focused on Jupiter and Saturn , Voyager 2 visited both gas giants and then ventured on to Uranus and Neptune . But the duo didn't stop there. Voyager 1 officially entered interstellar space on Aug. 25, 2012, while Voyager 2 entered on Nov. 5, 2018. The pair continue to journey through the cosmos and have enough power and fuel to keep scientific instruments running until at least 2025, according to NASA . 

Here we celebrate the achievements of both Voyager 1 and Voyager 2 with some incredible images captured by the pair. 

This image was taken when NASA's Voyager 1 spacecraft zoomed toward Jupiter in January and February 1979, capturing hundreds of images during its approach, including this close-up of swirling clouds around Jupiter's Great Red Spot . 

This image of the Earth and moon are in a single frame. Voyager was the first spacecraft to achieve this and captured the iconic image on Sept. 18, 1977, by Voyager 1 when it was 7.25 million miles from Earth. The moon is at the top of the picture and beyond the Earth as viewed by Voyager. 

Color composite by Voyager 2 showing Jupiter's faint ring system. Images captured in July 1979. 

A Voyager 1 image of Jupiter's moon Io showing the active plume of the volcano Loki. The heart-shaped feature southeast of Loki consists of fallout deposits from the active plume Pele. The images that make up this mosaic were taken from an average distance of approximately 340,000 miles (490,000 kilometers) from the moon. 

Layers of haze covering Saturn's moon Titan are seen in this image taken by Voyager 1 on Nov. 12, 1980, at a range of 13,700 miles (22,000 km). This false-color image shows the details of the haze that covers Titan. The upper level of the thick aerosol above the moon's limb appears orange. 

This view of Uranus was recorded by Voyager 2 on Jan. 25, 1986, as the spacecraft left the planet behind and set forth on the cruise to Neptune. Even at this extreme angle, Uranus retains the pale blue-green color seen by ground-based astronomers and recorded by Voyager during the historic encounter. 

This Voyager 2 high-resolution color image provides obvious evidence of vertical relief in Neptune's bright cloud streaks. These clouds were observed at a latitude of 29 degrees north near Neptune's east terminator, the "line" on a planet where daylight meets darkness. 

Global color mosaic of Triton , taken in 1989 by Voyager 2 during its flyby of the Neptune system. The color was synthesized by combining high-resolution images taken through orange, violet and ultraviolet filters; these images were displayed as red, green and blue images and combined to create this color version. 

Saturn and three of its moons, Tethys, Dione and Rhea, seen by a Voyager spacecraft on Aug. 4, 1982, from a distance of 13 million miles (21 million km). 

This narrow-angle color image of the Earth, dubbed the "Pale Blue Dot," is a part of the first ever 'portrait' of the solar system taken by Voyager 1. The spacecraft acquired a total of 60 frames for a mosaic of the solar system from a distance of more than 4 billion miles (6 billion km) from Earth and about 32 degrees above the ecliptic, which is the plane that contains most of the planets of the solar system. 

Voyager 1 took photos of Jupiter and two of its satellites (Io, left, and Europa ).

Enhanced color view of Saturn's ring system captured by Voyager 2 on Aug. 17, 1981, at a distance of 5.5 million miles (8.9 million km). The color variations between the rings possibly indicate variations in chemical composition from one part of Saturn's ring system to another.  

Close-up of the surface of Jupiter's moon Europa captured by Voyager 2 at a distance of 152,000 miles (246,000 km). 

Voyager 2 captured this image of Neptune's rings on Aug. 26, 1989, from a distance of 175,000 miles (280,000 km).  

A false-color image of Callisto captured on July 7, 1979, by Voyager 2 at a distance of about 677,000 miles (1.09 million km). Callisto is the second largest moon of Jupiter and is the most heavily cratered of the Galilean satellites. 

Daisy Dobrijevic joined Space.com in February 2022 having previously worked for our sister publication All About Space magazine as a staff writer. Before joining us, Daisy completed an editorial internship with the BBC Sky at Night Magazine and worked at the National Space Centre in Leicester, U.K., where she enjoyed communicating space science to the public. In 2021, Daisy completed a PhD in plant physiology and also holds a Master's in Environmental Science, she is currently based in Nottingham, U.K. Daisy is passionate about all things space, with a penchant for solar activity and space weather. She has a strong interest in astrotourism and loves nothing more than a good northern lights chase! 

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Voyager 1 y 2: La Misión Interestelar

Imagen de Neptuno tomada por la nave espacial Voyager 2. Imagen crédito: NASA

NASA tiene hermosas fotos de cada planeta de nuestro sistema solar. Incluso tenemos imágenes del lejano Neptuno , como podemos apreciar en la foto de arriba.

Neptuno está demasiado lejos para que un astronauta viaje hasta allí con una cámara. Entonces, ¿cómo tenemos imágenes de lugares tan lejanos de nuestro sistema solar? Nuestros fotógrafos fueron dos naves espaciales llamadas ¡Voyager 1 y Voyager 2!

Representación artística de una de las naves espaciales Voyager. Imagen crédito: NASA

Las naves espaciales Voyager 1 y Voyager 2 fueron lanzadas desde la Tierra en 1977. Su misión fue explorar Júpiter y Saturno --y planetas que se encuentran más allá de nuestro sistema solar. Esta fue una gran hazaña. Ningún objeto hecho en el pasado por el ser humano, había intentado un viaje como éste.

Las dos naves espaciales tomaron decenas de miles de imágenes de Júpiter y Saturno. Las imágenes del Voyager 1 y 2 nos permitieron ver muchas cosas por primera vez. Por ejemplo, ellos capturaron fotos a detalle de las nubes y tormentas de Júpiter, y la estructura de los anillos de Saturno .

Imagen de las tormentas en Júpiter tomadas por la nave espacial Voyager 1. Crédito: NASA

Voyager 1 y 2 también descubrieron volcanes activos en Io, una de las lunas de Júpiter , y mucho más. Voyager 2 también tomó imágenes de Urano y Neptuno. En conjunto, la misión Voyager descubrió 22 lunas.

Desde entonces, estas astronaves continúan su viaje alejándose de nosotros. Voyager 1 y 2 están ahora tan lejos que han llegado al espacio interestelar --la región entre las estrellas. Ninguna otra nave espacial ha viajado tan lejos.

¿A dónde irá Voyager después?

¡Mira éste video para descubrir qué hay más allá de nuestro sistema solar!

Ambas naves espaciales continúan enviando información de regreso a la Tierra. Estos datos nos ayudarán a entender acerca de las condiciones en el distante sistema solar y el espacio interestelar.

Los Voyager tienen suficiente combustible y energía para operar hasta el 2025 y más allá. Después de algún tiempo de esto, ya no podrán comunicarse con la Tierra. A menos que algo los detenga, continuarán pasando por nuevas estrellas una y otra vez por muchos miles de años.

Cada nave espacial Voyager contiene un mensaje. Ambas lleva consigo un disco de oro con escenas y sonidos de la Tierra. Los discos también contienen música y saludos en diferentes idiomas. Por lo cual, si vida inteligente encuentra alguna vez estas naves espaciales, ¡podrán saber acerca de la Tierra y de nosotros!

Foto del disco de oro que se envió al espacio en ambos Voyagers 1 y 2. Imagen crédito: NASA/JPL-Caltech

¡Más sobre nuestro universo!

¿Dónde comienza el espacio interestelar?

Buscando otros planetas como el nuestro.

¡Juega al Explorador Galáctico!

More about our universe!

Where does interstellar space begin?

Searching for other planets like ours

Play Galactic Explorer!

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Rae Paoletta • Mar 03, 2022

The best space pictures from the Voyager 1 and 2 missions

Launched in 1977, NASA’s Voyager 1 and 2 missions provided an unprecedented glimpse into the outer solar system — a liminal space once left largely to the imagination. The spacecraft provided views of worlds we’d never seen before, and in some cases, haven’t seen much of since.

The Voyager probes were launched about two weeks apart and had different trajectories, like two tour guides at the same museum. Only Voyager 2 visited the ice giants — Uranus and Neptune — for example.

The Voyagers hold a unique position in the pantheon of space history because they’re still making it; even right now, Voyagers 1 and 2 are the only functioning spacecraft in interstellar space. Both hold a Golden Record that contains sights and sounds of Earth in case alien life were to find one of the spacecraft.

As the Voyager missions voyage on, it’s good to look back at how they captured our solar system before leaving it.

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Voyager 1 image of saturn.

Voyager 1 looked back at Saturn on Nov. 16, 1980, four days after the spacecraft flew past the planet, to observe the appearance of Saturn and its rings from this unique perspective. A few of the spokelike ring features discovered by Voyager appear in the rings as bright patches in this image, taken at a distance of 5.3 million kilometers (3.3 million miles) from the planet. Saturn’s shadow falls upon the rings, and the bright Saturn crescent is seen through all but the densest portion of the rings. From Saturn, Voyager 1 is on a trajectory taking the spacecraft out of the ecliptic plane, away from the Sun and eventually out of the solar system (by about 1990). Although its mission to Jupiter and Saturn is nearly over (the Saturn encounter ends Dec. 18, 1980), Voyager 1 will be tracked by the Deep Space Network as far as possible in an effort to determine where the influence of the Sun ends and interstellar space begins. Voyager 1’s flight path through interstellar space is in the direction of the constellation Ophiuchus. Voyager 2 will reach Saturn on August 25, 1981, and is targeted to encounter Uranus in 1986 and possibly Neptune in 1989. The Voyager project is managed for NASA by the Jet Propulsion Laboratory, Pasadena, California.

Image Credt: NASA/JPL

The most distant human-made object

No spacecraft has gone farther than NASA's Voyager 1. Launched in 1977 to fly by Jupiter and Saturn, Voyager 1 crossed into interstellar space in August 2012 and continues to collect data.

Mission Type

What is Voyager 1?

Voyager 1 has been exploring our solar system since 1977. The probe is now in interstellar space, the region outside the heliopause, or the bubble of energetic particles and magnetic fields from the Sun. Voyager 1 was launched after Voyager 2, but because of a faster route, it exited the asteroid belt earlier than its twin, and it overtook Voyager 2 on Dec. 15, 1977.

• Voyager 1 was the first spacecraft to cross the heliosphere, the boundary where the influences outside our solar system are stronger than those from our Sun.
• Voyager 1 is the first human-made object to venture into interstellar space.
• Voyager 1 discovered a thin ring around Jupiter and two new Jovian moons: Thebe and Metis.
• At Saturn, Voyager 1 found five new moons and a new ring called the G-ring.

In Depth: Voyager 1

Voyager 1 at jupiter.

Voyager 1 began its Jovian imaging mission in April 1978 at a range of 165 million miles (265 million km) from the planet. Images sent back by January the following year indicated that Jupiter’s atmosphere was more turbulent than during the Pioneer flybys in 1973–1974.

Beginning on January 30, Voyager 1 took a picture every 96 seconds for a span of 100 hours to generate a color timelapse movie to depict 10 rotations of Jupiter. On Feb. 10, 1979, the spacecraft crossed into the Jovian moon system and by early March, it had already discovered a thin (less than 30 kilometers thick) ring circling Jupiter.

Voyager 1’s closest encounter with Jupiter was at 12:05 UT on March 5, 1979 at a range of about 174,000 miles (280,000 km). It encountered several of Jupiter’s Moons, including Amalthea, Io, Europa, Ganymede, and Callisto, returning spectacular photos of their terrain, opening up completely new worlds for planetary scientists.

The most interesting find was on Io, where images showed a bizarre yellow, orange, and brown world with at least eight active volcanoes spewing material into space, making it one of the most (if not the most) geologically active planetary body in the solar system. The presence of active volcanoes suggested that the sulfur and oxygen in Jovian space may be a result of the volcanic plumes from Io which are rich in sulfur dioxide. The spacecraft also discovered two new moons, Thebe and Metis.

Voyager 1 at Saturn

Following the Jupiter encounter, Voyager 1 completed an initial course correction on April 9, 1979 in preparation for its meeting with Saturn. A second correction on Oct. 10, 1979 ensured that the spacecraft would not hit Saturn’s moon Titan.

Its flyby of the Saturn system in November 1979 was as spectacular as its previous encounter. Voyager 1 found five new moons, a ring system consisting of thousands of bands, wedge-shaped transient clouds of tiny particles in the B ring that scientists called “spokes,” a new ring (the “G-ring”), and “shepherding” satellites on either side of the F-ring—satellites that keep the rings well-defined.

During its flyby, the spacecraft photographed Saturn’s moons Titan, Mimas, Enceladus, Tethys, Dione, and Rhea. Based on incoming data, all the moons appeared to be composed largely of water ice. Perhaps the most interesting target was Titan, which Voyager 1 passed at 05:41 UT on November 12 at a range of 2,500 miles (4,000 km). Images showed a thick atmosphere that completely hid the surface. The spacecraft found that the moon’s atmosphere was composed of 90% nitrogen. Pressure ad temperature at the surface was 1.6 atmospheres and 356 °F (–180°C), respectively.

Atmospheric data suggested that Titan might be the first body in the solar system (apart from Earth) where liquid might exist on the surface. In addition, the presence of nitrogen, methane, and more complex hydrocarbons indicated that prebiotic chemical reactions might be possible on Titan.

Voyager 1’s closest approach to Saturn was at 23:46 UT on 12 Nov. 12, 1980 at a range of 78,000 miles(126,000 km).

Voyager 1’s ‘Family Portrait’ Image

Following the encounter with Saturn, Voyager 1 headed on a trajectory escaping the solar system at a speed of about 3.5 AU per year, 35° out of the ecliptic plane to the north, in the general direction of the Sun’s motion relative to nearby stars. Because of the specific requirements for the Titan flyby, the spacecraft was not directed to Uranus and Neptune.

The final images taken by the Voyagers comprised a mosaic of 64 images taken by Voyager 1 on Feb. 14, 1990 at a distance of 40 AU of the Sun and all the planets of the solar system (although Mercury and Mars did not appear, the former because it was too close to the Sun and the latter because Mars was on the same side of the Sun as Voyager 1 so only its dark side faced the cameras).

This was the so-called “pale blue dot” image made famous by Cornell University professor and Voyager science team member Carl Sagan (1934-1996). These were the last of a total of 67,000 images taken by the two spacecraft.

Voyager 1’s Interstellar Mission

All the planetary encounters finally over in 1989, the missions of Voyager 1 and 2 were declared part of the Voyager Interstellar Mission (VIM), which officially began on Jan. 1, 1990.

The goal was to extend NASA’s exploration of the solar system beyond the neighborhood of the outer planets to the outer limits of the Sun’s sphere of influence, and “possibly beyond.” Specific goals include collecting data on the transition between the heliosphere, the region of space dominated by the Sun’s magnetic field and solar field, and the interstellar medium.

On Feb. 17, 1998, Voyager 1 became the most distant human-made object in existence when, at a distance of 69.4 AU from the Sun when it “overtook” Pioneer 10.

On Dec. 16, 2004, Voyager scientists announced that Voyager 1 had reported high values for the intensity for the magnetic field at a distance of 94 AU, indicating that it had reached the termination shock and had now entered the heliosheath.

The spacecraft finally exited the heliosphere and began measuring the interstellar environment on Aug. 25, 2012, the first spacecraft to do so.

On Sept. 5, 2017, NASA marked the 40th anniversary of its launch, as it continues to communicate with NASA’s Deep Space Network and send data back from four still-functioning instruments—the cosmic ray telescope, the low-energy charged particles experiment, the magnetometer, and the plasma waves experiment.

The Golden Record

Each of the Voyagers contain a “message,” prepared by a team headed by Carl Sagan, in the form of a 12-inch (30 cm) diameter gold-plated copper disc for potential extraterrestrials who might find the spacecraft. Like the plaques on Pioneers 10 and 11, the record has inscribed symbols to show the location of Earth relative to several pulsars.

The records also contain instructions to play them using a cartridge and a needle, much like a vinyl record player. The audio on the disc includes greetings in 55 languages, 35 sounds from life on Earth (such as whale songs, laughter, etc.), 90 minutes of generally Western music including everything from Mozart and Bach to Chuck Berry and Blind Willie Johnson. It also includes 115 images of life on Earth and recorded greetings from then U.S. President Jimmy Carter (1924– ) and then-UN Secretary-General Kurt Waldheim (1918–2007).

By January 2024, Voyager 1 was about 136 AU (15 billion miles, or 20 billion kilometers) from Earth, the farthest object created by humans, and moving at a velocity of about 38,000 mph (17.0 kilometers/second) relative to the Sun.

National Space Science Data Center: Voyager 1

A library of technical details and historic perspective.

Beyond Earth: A Chronicle of Deep Space Exploration

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News | February 12, 1990

Voyager 1 to take pictures of solar system planets.

NASA's Voyager 1 spacecraft, having completed its mission along with Voyager 2 to explore the outer planets, will use its cameras February 13-14 to take an unprecedented family portrait of most of the planets in our solar system.

The collection of images will be from a unique point-of-view -- looking down on the solar system from a position 32 degrees above the ecliptic plane in which the planets orbit the Sun. No other spacecraft has ever been in a position to attempt a similar series of photos of most of the planets.

Voyager 1, launched in 1977, is now about 6 billion kilometers (3.7 billion miles) from Earth. The Voyager spacecraft are controlled by and their data received at the Jet Propulsion Laboratory, Pasadena, Calif.

"This is not just the first time, but perhaps the only time for decades that we'll be able to take a picture of the planets from outside the solar system," said Voyager Project Scientist Dr. Edward C. Stone of Caltech. No future space missions are planned that would fly a spacecraft so high above the ecliptic plane of the solar system, he said.

Starting shortly after 5 p.m. (PST) on Feb. 13 and continuing over the course of four hours, Voyager 1 will point its wide- and narrow-angle cameras at Neptune, Uranus, Saturn, Jupiter, Mars, Earth and Venus. Mercury is too close to the Sun to be photographed by Voyager's cameras, and Pluto is too far away and too small to show up in images taken by the spacecraft. Beginning with the dimmest of the targets - Neptune -- and working toward the Sun, Voyager 1 will shutter about 64 images of the planets and the space between them.

The constellation Eridanus (The River), stretching behind the planets from Voyager 1's perspective, will provide the backdrop for the images.

Due to the schedules of several spacecraft being tracked by NASA's Deep Space Network (DSN), the images will be recorded on board Voyager 1 and played back to DSN receivers on Earth in late March. The Voyager imaging team estimates that processing the images to reveal as much detail as possible will take several weeks. Most of the planets will appear as relatively small dots (about one to four pixels, or picture elements, in the 800-by-800 pixel frame of one Voyager image).

The enormous scale of the subject matter makes it unlikely that the entire set of images can be mosaicked to produce for publication a single photograph showing all the planets. Even an image covering the planets out to Jupiter would easily fill a poster-sized photographic print. At the least, imaging team hopes to assemble a mosaicked image composed of the frames showing Earth, Venus and perhaps Mars together.

Voyager 1, rather than Voyager 2, received the solar system photo assignment largely because of Voyager 1's improved viewpoint of the planets.

Voyager 1 completed flybys of Jupiter and Saturn in 1979 and 1980, respectively. Voyager 2 flew past Jupiter in 1979, Saturn in 1981, Uranus in 1986 and Neptune last August. Both are now on missions that will take the spacecraft to the boundary of our solar system and into interstellar space.

According to Voyager engineers and scientists, the only potential damage from pointing the cameras toward the Sun is that the shutter blades of the wide-angle camera might warp. There are no plans, however, to use Voyager 1's cameras after the solar system photo series is completed.

The Voyager mission is conducted by Caltech's JPL for NASA's Office of Space Science and Applications.