The rover Curiosity is the name of a new robot that has been on the scene since the rover landed on Mars in August 2012.
Curiosity is now at a place where it has to learn more about what’s happening on Mars, and what it’s looking at.
So, what’s the most important thing to understand about this robot?
What makes it different?
How can we learn more?
Curiosity is designed to be a real-time science exploration robot, as it’s currently not able to get any data from the surface of Mars.
Instead, the rover is using its onboard cameras to analyze the environment and take photos of the Martian surface.
In addition to taking photos, Curiosity can also detect chemical compounds and other minerals on the surface, as well as track down potential landing sites.
Curiosity’s main goal is to understand how water, soil and other rocks are being deposited on Mars and whether they could be used as sources of future resources.
The rover is equipped with a camera called CuriosityCam that’s the first of its kind in the world, and it uses lasers to detect and collect data about the Martian environment.
It can also use a small laser to spot small deposits on the Martian soil.
This laser can pick up the shape of a small boulder that is the result of an interaction between water and minerals, and the rover can also measure how much water and other materials are present in the soil.
The laser that CuriosityCam uses to detect these tiny rocks and soil depositsThe rover also uses a small camera called a camera to gather data about how the Martian landscape is changing.
CuriosityCam takes photos of rocks and rocks in the area where the rover found the evidence of the rover’s landing, and then uses this information to determine if any features are present.
It also uses the data to determine the type of landscape that has developed over the past few thousand years.
Curve camera, CuriosityCam source The rover’s main purpose is to find out what’s up there, and how the environment is changing over time.
Curiosity also uses radar to get images of the rocks and soils that Curiosity finds.
In a recent paper, scientists from the Jet Propulsion Laboratory (JPL) and the California Institute of Technology (Caltech) described the camera’s capabilities and demonstrated how they could take high-resolution images of Martian rocks.
The JPL and Caltech researchers are also working on a rover that uses radar, which could be similar to the CuriosityCam.
However, radar is more expensive and takes longer to acquire high-quality images, which is why the JPL researchers have also developed a cheaper camera that is smaller and more powerful, called the MagnetoCam.
MagnetoCam, Curiositycam source The magnetoCam is similar to CuriosityCam in many ways.
The JPL-Caltech researchers say that it’s also cheaper and less powerful than CuriosityCam, which means that it could be more efficient for a robotic mission.
However to get the best picture of the landscape on Mars that we can, the magnetoCamera would need to be able to take a lot of images.
For this reason, the JAPL and CalTech researchers have designed the MagnetoSampler, a magnetometer that can measure a lot more than just rock formations.
Magnetic solids and minerals that the magnetosampler detects and measuresThe MagnetoSamppler is a magnetosample, or a sample taken from the Martian atmosphere and deposited on the magnetized surface of the planet.
The magnetosamppler uses an array of lasers that are focused on the sample and then used to take photos.
The camera takes photos in two-dimensional space, so it can take images of different areas on the planet at once.
Magroscope, Magnetosample source This photo shows a magnetoscope that the JAPS researchers made.
The MagnetoSample is a sample that is collected by the magnetometer and deposited in the magnetosphere, which contains the Martian material that makes up the atmosphere.
It is the magnetism that makes the magnetospheres magnetic, which creates the magnetic fields that are in the pictures.
This image shows a sample being deposited into the magnetosequature.
The image shows the magnetization of the magnetosesampler.
The photograph shows the image taken by the laser, which looks like the laser beam reflected off of a surface of sandstone.
The photo shows the results of a magnetospheric scan taken using the Magnetosampling.
The picture shows the photo taken by a laser that has bounced off the magnetopause.
The photo shows two of the three laser pulses that bounced off of the surface.
The third laser pulse, which was not reflected by the surface and was instead reflected by a magnetosphere layer, showed how the laser bounces off the surface to measure the energy in the signal.
The two laser pulses shown in the image have been magnified to show them better.
The magnified image shows that the energy from the laser