NASA's Ingenuity helicopter captured this photo as it hovered over the Martian surface on April 19 during
the first instance of powered, controlled flight on another planet. It used its navigation camera, which autonomously tracks the ground during flight. Photo courtesy of NASA |
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NASA's Perseverance Mars rover took a selfie with the Ingenuity helicopter on April 6, using the WATSON (Wide Angle Topographic Sensor for Operations and eNgineering) camera located at the end of the rover's long robotic arm. The image was constructed of 62 individual images, taken in sequence while the rover was looking at the helicopter, then again while looking at the WATSON camera, stitched together once they are sent back to Earth. The Curiosity rover takes similar selfies using a camera on its robotic arm. Photo courtesy of NASA | License Photo
Perseverance acquired this image of the Ingenuity Mars Helicopter using its onboard Rear Left Hazard Avoidance Camera on April 4. The helicopter will soon make its first attempt at a powered, controlled flight of an aircraft on another planet. Photo courtesy of NASA | License Photo
Perseverance acquired this image of the Ingenuity Mars Helicopter on March 29 using its SHERLOC WATSON camera, located on the turret at the end of the rover's robotic arm. Photo courtesy of NASA | License Photo
The debris shield, a protective covering on the bottom of Perseverance, was released to allow the Ingenuity helicopter to fold out of the rover on March 21. The debris shield protects the helicopter during landing; releasing it allows the helicopter to rotate down out of the rover's belly. Photo courtesy of NASA | License Photo
Perseverance acquired this image of its "ejectable belly pan" laying on the surface of Mars on March 14 using its onboard Left Navigation Camera. Photo courtesy of NASA | License Photo
Perseverance acquired this image of its "ejectable belly pan" laying on the surface of Mars using its SHERLOC WATSON camera, located on the turret at the end of the rover's robotic arm. Photo courtesy of NASA | License Photo
A key objective for Perseverance's mission on Mars is astrobiology, including the search for signs of ancient microbial life. In cooperation with the European Space Agency, subsequent NASA missions would send spacecraft to Mars to collect these sealed samples from the surface and return them to Earth for in-depth analysis. Photo courtesy of NASA | License Photo
Perseverance acquired this image on March 6, of the area in front of it using its onboard Front Right Hazard Avoidance Camera A. Photo courtesy of NASA | License Photo
Perseverance took this photo on March 4 of a rocky mound in Jezero Crater, which NASA scientists said is likely a remnant of an ancient river delta. Photo courtesy of NASA
Perseverance acquired this image of the area in back of it using its onboard Rear Left Hazard Avoidance Camera. Photo courtesy of NASA | License Photo
Perseverance acquired this image using its onboard Left Navigation Camera on March 3. The camera is located high on the rover's mast and aids in driving. Photo courtesy of NASA | License Photo
The rover can be seen in this enhanced HiRISE color image at its landing site six days after touchdown on February 24. Photo courtesy of NASA | License Photo
Perseverance rover acquired this image using its left Mastcam-Z camera. Mastcam-Z is a pair of cameras located high on the rover's mast. Photo courtesy of NASA | License Photo
Perseverance documents the Martian surface. Photo courtesy of NASA | License Photo
The Martian surface is documented is detail from Perseverance. Photo courtesy of NASA | License Photo
The navigation cameras aboard the Mars rover captured this view of the rover’s deck on Monday. This view provides a look at PIXL (the Planetary Instrument for X-ray Lithochemistry), one of the instruments on the rover’s stowed arm. Photo courtesy of NASA/JPL-Caltech
This panorama, made by the navigation cameras aboard Perseverance, was stitched together from six individual images after they were sent back to Earth. Subsequent missions, currently under consideration by NASA in cooperation with the European Space Agency, would send spacecraft to Mars to collect these cached samples from the surface and return them to Earth for in-depth analysis. Photo courtesy of NASA/JPL-Caltech
This is the first high-resolution, color image to be sent back by the Hazard Cameras (Hazcams) on the underside of NASA's Perseverance Mars rover after its landing on February 18. Photo courtesy of NASA | License Photo
This high-resolution still image, from the camera aboard the descent stage, is part of a video taken by several cameras as NASA's Perseverance rover touched down on Mars. Photo courtesy of NASA | License Photo
Perseverance can be seen falling through the Martian atmosphere in the descent stage, its parachute trailing behind, in this image taken on Thursday by the High-Resolution Imaging Experiment camera aboard the Mars Reconnaissance Orbiter. The ancient river delta, which is the Perseverance mission's target, can be seen entering Jezero Crater from the left. Photo courtesy of NASA | License Photo
An illustration depicts the rover driving in the foreground across the plain of Jezero Crater, where the robotic explorer landed safely. Image courtesy of NASA
An image showing where Perseverance Mars rover landed is shown during a NASA Perseverance rover mission post-landing update, on February 18, at NASA's Jet Propulsion Laboratory in Pasadena, Calif. Photo by Bill Ingalls/NASA | License Photo
Members of NASA's Perseverance Mars rover team watch in mission control as the first images arrive moments after the spacecraft successfully touched down on Mars. Photo by Bill Ingalls/NASA | License Photo
The first photos taken by NASA's Perseverance Mars rover after landing on the Martian surface. A key objective for Perseverance's mission on Mars is astrobiology, including the search for signs of ancient microbial life. Photo courtesy of NASA | License Photo
These computer simulations show Perseverance landing on the Martian surface. The rover will characterize the planet's geology and past climate, paving the way for human exploration of the Red Planet and be the first mission to collect and cache Martian rock and regolith. Image courtesy of NASA | License Photo
In this illustration of its descent to Mars, the spacecraft carrying NASA's Perseverance rover slows down using the drag generated by its motion in the Martian atmosphere. Hundreds of critical events must execute precisely on time for the rover to land on Mars safely. Entry, descent, and landing, or "EDL," begins when the spacecraft reaches the top of the Martian atmosphere, traveling nearly 12,500 mph. The cruise stage separates about 10 minutes before entering into the atmosphere, leaving the aeroshell, which encloses the rover and descent stage, to make the trip to the surface. Image courtesy of NASA | License Photo
An illustration of Perseverance on Mars, launched from Earth in July. It is the fifth rover to successfully reach Mars, and is the first of three that may return rocks samples to Earth. Image courtesy of NASA | License Photo