ESA astronaut Luca Parmitano prepares for ANALOG-1 experiment operations on the ground in the European Astronaut Center in Cologne, Germany. The investigation will require him to remotely control an Earth-based rover from the space station. Credit: ESA

Astronauts could one day remotely control Moon and Mars rovers from orbit. An upcoming test aboard the International Space Station could help make this a possibility. In November, the ESA (European Space Agency) will conduct an experiment in orbit known as ANALOG-1 to see if station crews, scientists on the ground and new technology can work together to guide a rover on a simulated lunar mission.

This project investigates how effectively an astronaut on the International Space Station can operate a rover on a Moon-like terrain on Earth. The rover is tasked with collecting rock and soil samples, then remotely investigating the samples.

"This is a potential scientific scenario during future missions to the Moon and Mars," said William Carey, ESA scientist and principle investigator for the ANALOG-1 experiment. "Space is such a harsh place for humans and machines. Future exploration of the solar system may involve sending robotic explorers to test the waters on uncharted planets before sending humans."

Remotely Close

ANALOG-1 is the final step in ESA's ongoing METERON (Multi-purpose End To End Robotics Operations Network) project, which is an initiative to develop and test robotics, communications and operations innovations that astronauts could use to explore the solar system.

Historically, rovers exploring other planets have been controlled with preprogrammed software and by scientists sending commands from Earth that take long periods of time to reach the robots. These approaches worked well enough to greatly advance our knowledge of other worlds, but they can make it difficult to work fast, change plans or quickly adapt to unexpected situations.

The ANALOG-1 Interact rover located near the European Space Research and Technology Centre in the Netherlands is controlled by a surrogate astronaut based at the European Astronaut Center in Germany. The cones mark out a route that the rover has to follow to get to the sample site. Credit: ESA

Carey and his ESA team suspect a better method may be placing astronauts in orbit around exploration sites where they could quickly communicate with the rover. With a nearby astronaut at the rover's controls, scientists could more efficiently explore a planned target, take advantage of a surprise opportunity or rapidly manage a problem.

"A number of space agencies have looked at such a scenario for the exploration of planetary bodies—particularly for Mars," said Carey. "The approach could greatly increase the scientific return on those missions, as well as offer a way to avoid potential contamination from humans landing on the surface before we can answer questions about existing or previous life on Mars."

The results of the experiment could be of particular value to NASA as it prepares to explore the Moon from the planned Gateway spaceship as part of the Artemis program, where NASA will be going forward to the Moon and on to Mars.

Within Arm's Reach

During the two-hour experiment, ESA astronaut Luca Parmitano will use a workstation aboard the orbiting laboratory to attempt to command a remotely controllable rover and its arm while it traverses a Moon-like surface near Noordwijk, a town in the Netherlands. Parmitano will drive the robot using a specialized computer system and will be guided by scientists communicating with him on the ground. He will also use a state-of-the-art Sigma 7 "joystick" that will allow the astronaut to sense what the rover's arm encounters.

he rover that will be used as a part of the ESA ANALOG-1 experiment moves cones inside of the sample box which will contain rocks during the experiment. Credits: ESA

"The force feedback enables the operator to feel what the robot feels," said ESA robotics lead engineer Thomas Krueger. "For example, if the robot touches a fragile object, it measures and transmits information back to the user, who then feels its delicateness on the Sigma 7 joystick. They can then operate the arm more carefully than with a normal joystick."

Parmitano will use the joystick to direct the robot's arm to take samples of rock and soil back on Earth. Scientists expect he may face additional difficulty because of how the human body responds to space. Research has shown that microgravity can impair an astronaut's sense of touch or feel, as well as the ability to track moving objects—both of which are critical in this investigation's task.

Evaluating the Task At Hand

When the experiment is done, researchers on the ground will evaluate how well the robotic control systems functioned and examine Parmitano's ability to operate the rover under the effects of microgravity. They will also observe how well Parmitano and the science team back on Earth were able to communicate to make decisions and plans for controlling the .

"Robots have the ability to extend our presence on other worlds and increase our exploration efficiency," said ESA project manager Kjetil Wormnes. "The results of ANALOG-1 will help us determine the most effective way to collaborate with robots in order to prepare for our future exploration of the Moon."

Provided by NASA