So far, scientists have found around 34,000 near-Earth asteroids (NEAs) that could serve as humanity's stepping stone to the stars. These balls of rock and ice hold valuable resources as we expand throughout the solar system, making them valuable real estate in any future space economy. But the 34,000 we know of only make up a small percentage of the total number of asteroids in our vicinity—some estimates theorize that up to 1 billion asteroids larger than a modern car exist near Earth.

A project from the Trans Astronautics Corp (TransAstra), an asteroid-hunting start-up based in California, hopes to find the missing billion: the Sutter Ultra project. Before we get into what Sutter Ultra is, it's best to understand why we have such a hard time finding the hundreds of millions of small asteroids in our vicinity.

To put it bluntly, the problem is two-fold—brightness and speed.

Fine motor tasks under space conditions are particularly challenging and must first be trained on Earth. Scientists from the German Research Center for Artificial Intelligence (DFKI) and the University of Duisburg-Essen (UDE) are investigating whether a robotic exoskeleton that can simulate weightlessness is suitable for astronautical training.

The team had the opportunity to participate in the 42nd DLR Parabolic Flight Campaign in Bordeaux, France, to compare the effects of simulated weightlessness with those of real weightlessness.

During space missions, astronauts are often faced with fine motor tasks, such as performing repairs or experiments, that are made more difficult by the weightlessness of space. Targeted training of these skills is particularly important, not only to increase the efficiency of the missions, but also to ensure the safety of the astronauts. Until now, such missions could only be practiced on Earth during parabolic flights or in spacesuits underwater.

Innovative space training with exoskeleton

Scientists at the DFKI Robotics Innovation Center Bremen and the Department of Medical Engineering Systems at the University of Duisburg-Essen (UDE) are working on an alternative and more cost-effective training method.

Production of Galileo Second Generation satellites advances at full speed after two independent Satellite Critical Design Review boards have confirmed that the satellite designs of the respective industries meet all mission and performance requirements. This achievement is another crucial milestone hit on time in the ambitious schedule to develop the first 12 satellites of the Galileo Second Generation fleet.

The European Galileo navigation system, the most precise worldwide, is gearing up for the Second Generation (G2). G2 will bring unprecedented positioning, navigation and timing capabilities to support a wide array of user needs and services.