NASA’s Mariner 4 captured the first-ever close-up
image of Mars on July 14, 1965. While waiting for the data to be processed into
the image (inset at right), team members hand-colored strips of paper that the
data was printed on, assigning hues to value ranges. The result is on display
at JPL.
NASA/JPL-Caltech
Sixty years ago, NASA’s Mariner 4 captured groundbreaking views of the
Red Planet, leading to a steady stream of advances in the cameras used to study
other worlds.
In 1965, NASA’s Mariner 4 mission
brought Mars into American living rooms, where TV sets showed fuzzy
black-and-white images of a cratered landscape. The spacecraft took 21 complete
pictures — the first ever captured of another planet — as it flew by as close
as 6,118 miles (9,846 kilometers) above the surface.
The mission team couldn’t wait to
see what the camera aboard the spacecraft would return. When the actual images
were delayed, they went so far as to create
a color-by-numbers image, assigning hues to specific values in the data.
Their handiwork wasn’t far off, and
the barren landscape Mariner 4 captured ignited the imaginations of future
scientists and engineers who would go on to work on a succession of missions,
each revealing Mars in a way it had never been seen before.
Millions of Mars images have been
taken since then, many of which are captivating in their own way. The images
that follow highlight some of the “firsts” in the way the agency has used
imaging to help unlock the secrets of Mars.
Viking 1 Sets
Foot on Mars
July 20, 1976
This historic image — the first from the surface of
Mars — confirmed that NASA’s Viking 1 lander had become the first spacecraft to
touch down on the Red Planet on July 20, 1976.
NASA/JPL-Caltech
Viking 1 became the first spacecraft to touch down on
Mars on July 20, 1976. The first high-resolution image it sent to Earth
captured a dry, rocky landscape that dashed any hope among scientists of
discovering life on the surface. But the crisp images that followed from the lander’s 360-degree cylindrical scan camera
underscored the scientific value of seeing Mars from the ground and generated
excitement for a more ambitious visit: a robotic spacecraft that could drive
across this alien world.
Portrait of
Mars by Viking 1 Orbiter
1980
NASA’s twin Viking landers didn’t travel alone. Two
accompanying orbiters circled Mars to study it from above. The Viking 1 orbiter
captured many images in 1980 that were combined to produce this view of Valles
Marineris, the “Grand Canyon of Mars.”
NASA/JPL-Caltech/USGS
When the twin Viking landers arrived at Mars, each descended from an
orbiter that used cameras to map Mars in a way Earth-based telescopes couldn’t.
They began capturing images before the landers even touched down, continuing
until 1980. That year, the Viking 1 orbiter captured images that were later
stitched into a defining portrait of Valles Marineris — the “Grand Canyon of
Mars.”
Sojourner
Starts to Explore
July 5, 1997
The size of a microwave oven, NASA’s Sojourner rover
was the first spacecraft to drive on Mars, as seen in this image taken by
NASA’s Pathfinder lander on July 5, 1997. The rover explored the Martian
surface for 83 days, well beyond its planned seven-day mission.
NASA/JPL-Caltech
By the time NASA returned to the Martian surface in 1997 with the Pathfinder lander and its microwave-oven-size Sojourner rover, much had changed
on Earth since Mariner 4’s images beamed to TV viewers: Now, the internet was
bringing around-the-clock news to personal computers, allowing a young
generation of space fans to witness the tentative first steps of a new form of
planetary exploration. The panoramic images from the ground were the first
since Viking and, as part of NASA’s “faster, better, cheaper” initiative,
offered more detail and a comparatively lower cost.
Opportunity
Spots Passing Dust Devil
March 31, 2016
NASA’s Spirit and Opportunity rovers crossed many
miles of Martian terrain, capturing stunning vistas and passing dust devils
along the way. The twins far outlasted their planned mission of 90 days: Spirit
traveled the Red Planet for more than six years, while Opportunity journeyed
for almost 15.
NASA/JPL-Caltech
In 2004, NASA’s golf-cart-size twin rovers Spirit and Opportunity set down on the Red Planet, beginning a new
phase of Martian exploration. Equipped with both mast-mounted panoramic and
arm-mounted microscopic imagers, the roving spacecraft let scientists,
engineers, and the world discover new terrain each day. They captured colorful
views of Martian
vistas and
revealed details of pebble-size
“blueberries.” Mars was beginning to feel less like an unfamiliar world than a place
with recognizable landmarks.
MRO’s HiRISE
Views Victoria Crater
July 18, 2009
More advanced orbiters have brought a different
perspective of the Red Planet — especially NASA’s Mars Reconnaissance Orbiter,
which uses its HiRISE camera to see surface features that appeared blurry in
earlier images. Here, HiRISE views Victoria Crater.
NASA/JPL-Caltech/University of Arizona
Since Viking, a series of increasingly advanced orbiters have arrived at
Mars with new science tools and cameras. Using increasingly sophisticated
imagers, they have mapped the planet’s hills and valleys, identified
significant minerals, and found buried glaciers. A camera that has been in
operation aboard NASA’s Mars Reconnaissance Orbiter since 2006, the High-Resolution Imaging Science
Experiment (HiRISE) frequently captures individual dunes, boulders, and
craters, as with this picture of Victoria Crater, revealing features that had
been blurry in previous images. The camera has also identified landing sites
and places where future rovers (perhaps even astronauts) could explore.
Curiosity,
Perseverance Bring More Cameras and Color
Aug. 5, 2012
and Feb. 18, 2021
Image Details
NASA’s Curiosity and
Perseverance rovers each brought more cameras — and more color — to the Martian
surface. One example are the hazard-avoidance cameras, which are
black-and-white on Curiosity, left, and higher-resolution color on
Perseverance. NASA/JPL-Caltech
Both Curiosity and Perseverance arrived at Mars (in 2012 and 2021, respectively) loaded with cameras
that pack millions of pixels into their images and peer farther into the
distance than Spirit or Opportunity ever could. They also feature upgraded
arm-mounted cameras for studying fine details like sand
particles and rock
textures. Perseverance
took a step beyond Curiosity in several ways, including with high-speed
cameras that
showed its parachute deploying and its rocket-powered jetpack flying away
during entry, descent, and landing on Mars. Another advance can be seen in each
vehicle’s hazard-avoidance cameras, which help rover drivers spot rocks they
might bump into. As seen in the first images each rover sent back, Curiosity’s
black-and-white cameras were upgraded to color and higher resolution for
Perseverance, providing clearer views of the surface.
Ingenuity
Spots Perseverance at Belva Crater
Aug. 22, 2023
NASA’s Perseverance landed along with the Ingenuity
helicopter, which proved flight in Mars’ thin atmosphere was possible. This
view from Ingenuity — taken from an altitude of about 40 feet (12 meters)
during its 51st flight — includes the rover, visible as a whitish speck at
upper left.
NASA/JPL-Caltech
Just as Pathfinder brought the tiny Sojourner rover to Mars, NASA’s
next-generation Perseverance rover carried the Ingenuity helicopter. Along with proving flight in Mars’ thin air was possible,
Ingenuity used a commercial, off-the-shelf color camera to take aerial views
over the course of 72 flights. During one of those flights, Ingenuity even spotted Perseverance in the
distance — another first on the Red Planet. Future Mars helicopters might be
able to scout paths ahead and find scientifically interesting sites for robots
and astronauts alike.
More About
These Missions
NASA JPL, which is managed for the
agency by Caltech in Pasadena, California, built Mariner 4, the Viking 1 and 2
orbiters, Pathfinder, Sojourner, Spirit and Opportunity, Curiosity,
Perseverance, and Ingenuity. It continues to operate Curiosity and Perseverance.
Lockheed Martin Space in Denver
built MRO and supports its operations, while JPL manages the mission. The
University of Arizona, in Tucson, operates HiRISE, which was built by BAE
Systems, in Boulder, Colorado.
The Viking 1 and 2 landers were
built by Martin Marietta; the Viking program was managed by NASA’s Langley
Research Center in Hampton, Virginia. JPL led operations for the Viking landers
and orbiters.
Mariner 4
Mars Flyby 60th Anniversary Media Reel
Source: Advances in NASA Imaging Changed How World Sees Mars - NASA
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