Crawling, gripping and floating above ESA’s flat floor

Europe’s flattest floor

For their experiments, the student teams made use of ESA’s ORBIT facility – a part of the Orbital Robotic Laboratory (ORL) located at ESTEC, the agency’s technical heart in the Netherlands. ORBIT consists of a 43 m² ultra-flat floor – the height difference between its lowest and highest points is less than a millimetre.

The facility operates similarly to an air hockey table. Its testing platforms are equipped with air bearings, which create a stable air gap between the platforms and the floor.

This air gap, thinner than a strand of hair and so hardly visible to the human eye, allows the platforms to move across the floor without any friction. This reproduces the state of weightless free-floating in two dimensions for any instruments mounted on the platform.

Skywalker: teaching a robotic arm to crawl across structures

The Skywalker team from Aalborg University, Denmark, used the simulated two-dimensional microgravity environment to test the reinforcement learning algorithms they have developed for their robotic arm. Their project aims to demonstrate the concept of autonomous crawling in microgravity.

“Our first algorithm allows the arm to find an anchor point and to anchor itself to it, all this while attached to the top of a floating platform,” explains Rasmus Kristiansen from the Skywalker team.

“The second algorithm then drags the floating base by moving the arm while anchored. This one gave us a little bit of trouble, producing results that differed from our earlier simulations. Luckily, we were able to identify the issue, and the rest of the testing went smoothly.”

“The goal of our project was to teach a robot to crawl across structures,” comments Skywalker team member Daði Hrannar Davíðsson.

“At the moment, robots moving around structures in space using the crawling motion have to be pre-programmed. Our project is a proof-of-concept, with the objective to enhance robotic capabilities for assembling and maintaining large structures in space.”

V-STARS: tricking the human body’s balance system

In the very first ORBIT facility experiment involving human participants, the V-STARS team from Birkbeck, University of London, and the University of Kent, UK, investigated the relationship between the human vestibular system (region of the inner ear responsible for body balance) and the perception of verticality in a microgravity environment.

Milena da Silva Baiao, V-STARS team member, explains: “Our experiment, involving 22 participants in total, focused on the use of vestibular stochastic resonance – a phenomenon in which controlled noise enhances the sensitivity of a sensory system – to improve perception and potentially accelerate adaptation to microgravity.”

V-STARS team member Maryam Haq describes the experiment: “While sitting on a chair attached to a floating platform, a participant is wearing VR goggles and has small electrodes placed behind their ear. They are slowly pushed around the flat floor in random directions.

“The electrodes are sending gentle signals to stimulate the participant’s vestibular system, while we present an image of a simple line to them in the goggles. We then check the participant’s verticality perception by asking them whether they see the line as vertical or slightly tilted.”

Milena adds: “Performing a neuroscience experiment with human participants was new both for us and for the ORL team. Navigating a new environment while integrating our experiment was a challenge, but an incredibly valuable learning experience.”

GRASP: grasping objects with a gecko-inspired arm

The GRASP team from Sapienza University of Rome, Italy, explored an innovative approach to performing manoeuvres with non-cooperative objects in space. The robotic arm they have developed themselves is sporting an adhesive gripper inspired by nature.

“Our experiment simulates a small spacecraft approaching and capturing an object in space by using a tentacle-like gripper with adhesive pads inspired by geckos,” explains GRASP team member Stefano De Gasperin.

“These remarkable creatures can easily stick to surfaces thanks to microscopic hairs on their feet. This form of adhesion doesn’t need glue or suction, leaves no residue, and can be activated and released repeatedly – making it perfectly suited for the vacuum of space.”

Team member Lorenzo Di Filippo adds: “Our robotic arm was mounted to one floating platform, and its target – a bright yellow object – to another. First, we instructed the arm to find the target and move towards it autonomously using on-board sensors. The two tentacle-like grippers then wrapped around the target and pulled it closer, simulating the initial phase of an in-orbit capture.

“Although the ORBIT facility features the flattest floor in Europe, identifying the flattest area was still relevant to our experiment. This was challenging but ultimately allowed us to collect scientific data of very good quality.”

Where creative ideas turn into reality

“At the Orbital Robotics Laboratory, we see students arrive with bold concepts and leave having accomplished something ambitious and unique on their own,” comments Marti Vilella, manager of the Orbital Robotics Laboratory. “The projects they test here are not just about the technology pushing forward, but also about elevating the students’ professional careers to exciting paths.”

Laura Borella, coordinator of the ESA Academy Experiments Programme, concludes: “The ESA Academy Experiments Programme supports university student teams from concept and design to testing and execution in advanced gravity-related facilities. It emphasizes professional engineering practices, project management, risk mitigation, and funding strategies, with continuous mentorship from ESA experts.

“The programme is open to students from all academic backgrounds, not only STEM fields. Students in areas such as design, psychology, communication, or business often bring valuable perspectives that enhance the quality, usability, and outreach of the experiments, reflecting the interdisciplinary nature of real space projects.

“This hands-on experience gives students unique insights into how space missions are developed and managed, complementing their academic studies with real-world application.”

More information

ESA Academy

ESA Academy Experiments

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