Björn JónssonAug 30, 2017

Voyager 40th anniversary: Revisiting the Voyagers' planetary views

I would argue that the Voyager mission is the most successful planetary mission of all time. Even now, 40 years after Voyager 1 and 2 were launched, a lot of the data they returned is still of high interest. In some cases it is obvious why: After all these years Voyager 2 is still the only spacecraft that has visited Uranus and Neptune.

The Voyager Jupiter data is also still very interesting, even though other spacecraft have followed in Voyager's footsteps. This is because the Voyager data, from 1979, allows us to monitor the long-term behavior of Jupiter and Io, and also because the Galileo mission that followed the Voyagers and orbited Jupiter in 1995-2003 was only partially successful due to the failure of its high gain antenna. Cassini flew by Jupiter en route to Saturn in 2000, but came no closer to Jupiter than about 10 million kilometers. Recently the Juno spacecraft has been orbiting Jupiter, but its scientific goals are different from Voyager and Galileo and in many ways complementary to them.

Voyager's Saturn data is perhaps the least interesting data set (surpassed by data from the spectacularly successful and long-lived Cassini mission), but still of interest for monitoring long-term changes in Saturn's and Titan's atmospheres and for studying Saturn's magnetosphere.

So processing (and reprocessing) the Voyager imaging data is still highly rewarding. Amateur space image processors and citizen scientists have produced many spectacular images from the raw Voyager image data set. Below is a selection of Voyager images from all four planets the Voyagers flew by. I did not always select the most spectacular or beautiful images. Instead I selected images to show various features and examples of the Voyager imaging coverage.

Voyager 1 and 2 flew by Jupiter in 1979 in March and July, respectively, obtaining lots of images of Jupiter and its satellites. Thousands of global images were obtained during approach. Below is an example. This is one of the most spectacular global Voyager Jupiter images available since it shows a double satellite transit. This also happens to be the highest-resolution Voyager global mosaic that can be assembled that includes a satellite transit (and luckily it's a double transit).

High-resolution Voyager 1 view of Jupiter with Io and Europa
High-resolution Voyager 1 view of Jupiter with Io and Europa A double transit of Jupiter by moons Io and Europa, as observed by Voyager 1 on its approach on February 27, 1979. This is a 14-frame mosaic. Most of the data was captured in a 3-by-3 mosaic at around 11:00 on February 27, 1979, but gaps were filled with data taken an hour before and an hour later.Image: NASA / JPL / Bjorn Jonsson

At closer range, Voyager obtained higher-resolution images of specific features. This includes a significant amount of time-lapse coverage. In particular the Great Red Spot (GRS) was extensively observed. The Voyager data set has lots of GRS images that are highly rewarding to process. Below is a Great Red Spot time-lapse sequence assembled from the four highest-resolution Voyager 1 Great Red Spot mosaics that completely cover the Great Red Spot. Lower-resolution wide-angle images were used to fill some of the areas around the spot. This is a grayscale movie based on orange and green filtered images. A color movie was not possible because insufficient blue or violet filtered images were available for one of the mosaics. The movie covers a period of about 30 hours.

The movie has been 'tweened' by adding interpolated, synthetic frames to make the motion smoother. The large-scale motions in this tweened movie are fairly accurate but the motion and behavior of some of the small-scale features may be inaccurate. Below is a gif-compressed version, but I encourage you to download the full-resolution video, which has significantly higher resolution and more temporal detail (6MB, AVI format).

Atmospheric flow around the Great Red Spot from Voyager 1
Atmospheric flow around the Great Red Spot from Voyager 1 This time-lapse sequence of atmospheric motion around the Great Red Spot was assembled from the four highest-resolution Voyager 1 Great Red Spot mosaics, captured through orange or green filters on March 5, 1979. Lower-resolution wide-angle images were used to fill some of the areas around the spot. The movie has been 'tweened' by adding interpolated, synthetic frames to make the motion smoother. The large-scale motions in this tweened movie are fairly accurate but the motion and behavior of some of the small-scale features may be inaccurate. The gif-compressed version embedded in this web page is significantly lower-resolution than the full product; to appreciate the rich details of Jupiter's atmospheric flow, download the original in AVI format here (6 MB).Image: NASA / JPL-Caltech / Björn Jónsson

Recently, the Juno mission has obtained images of Jupiter at resolutions that exceed the best Voyager resolution. These images have revealed new details, including cloud shadows and differences in cloud elevations. It has become apparent that small, bright, high-altitude clouds (in some cases clusters of these clouds) casting shadows on clouds farther down are fairly common. However, close inspection reveals that some of these small-scale details observed by Juno are also visible in the highest-resolution Voyager images.

Below is the highest-resolution observation of the Great Red Spot by either of the Voyagers. This is also the highest-resolution Voyager color observation of Jupiter. Close inspection reveals clusters of small, high-altitude clouds, especially near the GRS' center and east and northeast of the center. Clouds casting shadows are also visible in the GRS' northeast periphery.

Highest resolution Voyager 1 color view of the Great Red Spot
Highest resolution Voyager 1 color view of the Great Red Spot Less than 8 hours before closest approach, Voyager 1 obtained a green and violet filter mosaic with its narrow angle camera (NAC) covering most of the Great Red Spot (GRS)—a total of 28 images. Here the effects of the varying illumination across the mosaic have been removed. At ~6 km/pixel, this is the highest resolution pre-Juno color data for Jupiter (all of the higher resolution Voyager images are clear filter images). Lower resolution orange, green and violet images from Voyager 1's wide angle camera (WAC) are also used to show the GRS periphery and surrounding areas. Color, contrast, and sharpness have been enhanced to better show various details.Image: NASA / JPL-Caltech / Björn Jónsson

Many of the Voyager Jupiter images are not only interesting but they also look spectacular. Here are two examples:

Jupiter's limb
Jupiter's limb An approximately true color Voyager 1 mosaic showing Jupiter‘s limb. The resolution of the original imaging data is roughly 8 km/pixel. Jupiter‘s blue sky is visible at the limb.Image: NASA / JPL / Björn Jónsson
Jupiter's North Equatorial Belt and North Tropical Zone
Jupiter's North Equatorial Belt and North Tropical Zone This is a nine frame Voyager 1 mosaic focusing primarily on Jupiter's North Equatorial Belt (NEB), the North Tropical Zone (NTrZ) and their turbulent boundary. A jet stream is visible in central NTrZ, and examples of the NEB plumes are also visible. Gravity waves can be seen below and to the right of center. The images in this mosaic were acquired from a range of ~2.4 million kilometers from Jupiter's center at a resolution of ~24 km/pixel. Color, contrast, and sharpness have been enhanced to better show various details.Image: NASA / JPL-Caltech / Björn Jónsson

The Voyagers made extensive observations of the Galilean satellites. Below is an example, a Voyager 2 mosaic of Ganymede. This still represents the best overall imaging coverage of this area even though Galileo later imaged small parts of this terrain at much higher resolution.

Voyager 2 mosaic of Ganymede
Voyager 2 mosaic of Ganymede This is a grayscale mosaic at a resolution of ~1 km/pixel that has been colorized from lower resolution (3 km/pixel) color images. The prominent bright feature near center is the crater Osiris. Its diameter is 107 km.Image: NASA / JPL / Björn Jónsson

Saturn

Voyager 1 flew by Saturn in November 1980 followed by Voyager 2 in August 1981. Many beautiful images of Saturn, its rings and satellites were obtained. However, unlike the situation at Jupiter (where the Galileo mission was only a partial success), the Cassini mission has been a spectacular success. Because of this some of the Voyager Saturn images are now outdated and are mainly of historical interest. This is especially true for images of Saturn's satellites. However, some of the images of Saturn and Titan are of interest for monitoring long term changes.

An example of how Saturn has changed can be seen in the image below. It is a mosaic of 8 narrow angle green filtered images obtained by Voyager 2 on August 21, 1981 at a range of 4.9 million km. The resolution of the original data is about 50 km/pixel (slightly oversampled here). The image has been colorized from a lower resolution orange/green/blue color composite obtained at a similar time with the wide angle camera. Compared to Cassini images obtained at a similar time in Saturn's seasonal cycle, significant differences can be seen. For example the 'ribbon' and nearby cloud belts look considerably different in the Cassini images.

Saturn's northern hemisphere from Voyager
Saturn's northern hemisphere from Voyager A mosaic of 8 green filtered Voyager 2 narrow angle images obtained on August 21, 1981 when Voyager 2 was 4.9 million km from Saturn. The mosaic has been colorized from a lower resolutiom orange/green/blue color composite obtained at roughly the same time. The color should be fairly close to Saturn‘s true color.Image: NASA / JPL / Björn Jónsson
Voyager 2 Saturn mosaic
Voyager 2 Saturn mosaic A mosaic of 8 green-filtered Voyager 2 narrow angle images obtained on August 21, 1981 when Voyager 2 was 4.9 million km from Saturn. The mosaic has been colorized from a lower resolution orange/green/blue color composite obtained at roughly the same time. The color should be fairly close to Saturn‘s true color. In this version the image has been sharpened to better reveal various small-scale details.Image: NASA / JPL-Caltech / Björn Jónsson

The Voyager Saturn satellite imaging coverage is poor by today's standards but it must be kept in mind that the Voyagers were quick flyby missions. It is impossible to fly very close to many satellites during just two flybys of Saturn and also it is not possible to observe many satellites simultaneously. The best images are of Rhea. These are also the only Saturn icy satellite images that can be processed into 'Cassini-like' mosaics. Below is a mosaic of 10 clear filter images showing Rhea‘s northern hemisphere. The resolution is about 800 m/pixel. A version with a latitude/longitude grid is also included.

Voyager 1 mosaic of Rhea
Voyager 1 mosaic of Rhea Voyager 1 obtained Cassini-like coverage of the northern hemisphere of Saturn's moon Rhea.Image: NASA / JPL / Björn Jónsson
Voyager 1 mosaic of Rhea with superimposed coordinate grid
Voyager 1 mosaic of Rhea with superimposed coordinate grid Image: NASA / JPL-Caltech / Björn Jónsson

Uranus

In January 1986 Voyager 2 flew by Uranus. Compared to Jupiter and Saturn, visually the Voyager 2 images were disappointing. Uranus turned out to be a bland and extremely low contrast body. Here is an approximately true color and contrast Voyager 2 color composite:

Color global view of Uranus from Voyager 2
Color global view of Uranus from Voyager 2 The images for this color composite of Uranus were obtained by Voyager 2 through orange, green, and blue filters on January 14, 1986 from a range of 12.6 million kilometers. The color has been adjusted to approximate what a human eye would see, although the human eye is sensitive to longer wavelengths of light than the Voyager cameras were.Image: NASA / JPL / Björn Jónsson

Uranus has an axial tilt of roughly 90 degrees. At the time of the Voyager 2 flyby it was summer at Uranus' south pole; here the pole is close to the center of the image.

However, the fact that a planetary body appears bland doesn't make it uninteresting (Titan is a great example of this). It's just more difficult to explore. And indeed it turns out that some details are hidden in these images. Here is an image produced by stacking and derotating (to correct for Uranus' zonal winds that vary with latitude) images obtained over a period of about 10 hours. This reveals a significant amount of details.

Uranus (contrast stretched)
Uranus (contrast stretched) An image of Uranus produced by stacking and derotating orange and green filtered images of Uranus obtained over a period of about 10 hours. The contrast of the resulting image was then greatly exaggerated. This reveals various details. The weird appearance of Uranus' limb is a processing artifact.Image: NASA / JPL-Caltech / Björn Jónsson

I have sometimes wondered what the Voyager 2 images would have been like if Voyager 2 had been able to image Uranus at near infrared wavelengths. This would probably have revealed a lot of interesting atmospheric features that are either invisible at visual wavelengths or look extremely subtle. However, the longest wavelength of light that the Voyager cameras could 'see' was orange. But unfortunately, spacecraft CCD cameras that could obtain good images at near infrared wavelengths were still a few years in the future when the Voyagers were launched 40 years ago.

After the Voyager 2 flyby, activity appears to have greatly increased in Uranus' atmosphere, probably due to changing seasons. Lots of atmospheric features have been observed with large Earth based telescopes using adaptive optics. A new spacecraft visit to observe these features at high resolution with modern instruments would be extremely interesting.

All of Uranus' major satellites were imaged by Voyager 2 but by today's standards the imaging coverage is poor, much worse than at e.g. Saturn and Pluto. It is roughly comparable to the coverage of Saturn's satellites before Cassini. This is unfortunate because Uranus' satellites are interesting. In a way they represent a transition from icy bodies like Saturn's satellites to something even more exotic like Pluto/Charon. The need for better data is obvious. As an example, below is a reprocessed version of Voyager 2's best observations of Oberon. The resolution of the original data is only about 6.5 km/pixel. If Cassini-like imaging coverage was available, images at 100 times better resolution would be available.

Global view of Oberon from Voyager 2
Global view of Oberon from Voyager 2 Image: NASA / JPL / Björn Jónsson

Neptune

Voyager 2 flew by Neptune in August 1989. Neptune turned out to be far more photogenic than Uranus and the images did not disappoint. Cloud belts, big ovals, bright clouds and various atmospheric features are visible in the Voyager images. One of the features, the Great Dark Spot, was as big relative to Neptune as Jupiter's Great Red Spot was to Jupiter. However, this spot wasn't very long lived unlike the Great Red Spot. A few years after the Voyager 2 flyby it had disappeared. Neptune's big satellite Triton was also well imaged by Voyager 2.

Below are two high resolution mosaics that show the appearance of Neptune at the time of the Voyager 2 flyby.

High-resolution global Neptune mosaic with Great Dark Spot
High-resolution global Neptune mosaic with Great Dark Spot This mosaic is composed of approximately 20 images taken through green or clear filters about 2 to 3 days prior to Voyager 2's closest approach. It has been colorized with lower-resolution data taken from farther away.Image: NASA / JPL / Björn Jónsson
High-resolution global Neptune mosaic with small storms
High-resolution global Neptune mosaic with small storms This mosaic is composed of approximately 20 images taken through green or clear filters about 2 to 3 days prior to Voyager 2's closest approach. It has been colorized with lower-resolution data taken from farther away.Image: NASA / JPL / Björn Jónsson

The Voyager mission did not end with the Voyager 2 Neptune flyby. Both spacecraft are still active and conducting valuable observations. They have been searching for the heliopause, a boundary where the solar wind becomes too weak to push back the interstellar medium. On August 25, 2012 Voyager 1 crossed the heliopause. So this highly successful mission has not ended yet.

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