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How to reach a tumbling target in space

Experiments aboard International Space Station demonstrate a potential solution for cleaning up orbital debris and repairing damaged satellites.
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Photo of the interior of International Space Station with two cube-shaped robots floating in the middle
Caption:
Astrobee is a team of free-flying cube-shaped robots that help astronauts perform routine tasks either autonomously or by remote control. An international research collaboration between researchers at MIT and the German Space Agency used this platform to test a set of algorithms to enable a rendezvous with a tumbling target.
Credits:
Photo courtesy of the researchers
Simple illustration of 3D cubes and arrows showing the movement of Astrobee robots during maneuver
Caption:
To test the set of algorithms selected by the TumbleDock/ROAM team, first the “Chaser” Astrobee robot (yellow) observes the movement of a tumbling “Target” robot (blue) using its time-of-flight camera. Using data gathered from its cameras, lidar sensors, and onboard inertial measurement unit, the Chaser develops a model of the Target’s state. From there, the Chaser will create a trajectory to follow, correcting reference errors using robust control. Once the trajectory is completed, the Chaser robot reaches a “mating point” with the Target robot. The result: a successful rendezvous.
Credits:
Background image courtesy of NASA. Illustration by MIT AeroAstro.
Series of images show the maneuver of Astrobee robots in real time and in simulation.
Caption:
In microgravity experiments conducted aboard the International Space Station using NASA’s Astrobee robot system, a research team from MIT and DLR tested a set of algorithms to enable a successful autonomous rendezvous of a "Chaser" Astrobee robot with a tumbling "Target" Astrobee. The time-lapse on top shows a successful rendezvous in real time, while the time-lapse below shows a trajectory in simulation.
Credits:
Image courtesy of the researchers
Simulated image of cube-shaped Astrobee robots traveling through a tunnel-like passage way on the ISS.
Caption:
Before the TumbleDock/ROAM team commanded their experiment aboard the ISS from Earth, they ran through rendezvous maneuvers in simulation.
Credits:
Image courtesy of the researchers
Photo of a masked student looking at computer in front of wall of screens with analog clocks from three time zones
Caption:
Graduate student Charles Oestreich SM ’21 commands the Astrobee robots aboard the International Space Station from MIT’s campus during the TumbleDock/ROAM experiments
Credits:
Photo courtesy of the researchers

In 2002, the European Space Agency launched Envisat, the largest civilian satellite (at the time) to go to low Earth orbit (LEO). For a decade, it observed our planet and sent back valuable data on Earth's climate, tracking the decline of Arctic sea ice and more, until it went dark in 2012. One of the prevailing theories for its demise is that it simply ran out of fuel. As LEO becomes more crowded, Envisat is a school bus-sized example of a growing area of concern in the space domain: orbital debris and the ever-increasing risk of disrupting active satellite missions that would yield outcomes ranging from inconvenient to catastrophic for modern society.

But how do you catch up to an uncooperative object tumbling through space faster than a speeding bullet? An international research collaboration between MIT and the German Space Agency (DLR) completed a series of experiments aboard the International Space Station (ISS) that illuminated a possible path forward to help address this question.

"If we could refuel or repair these tumbling bodies that are otherwise functional, it would be really useful for orbital debris reduction, as long as we can catch up to it. But a close-proximity rendezvous is hard to do if you don't know exactly how your target is moving," says Keenan Albee SM '19, a PhD candidate in aeronautics and astronautics who helped lead the project. "We've assembled a set of algorithms that figures out how the target is tumbling, and then along with other tools that allow us to account for uncertainty, we can produce a plan to get us to the target, despite the tumble."

To test their algorithms in microgravity, the team used NASA's Astrobee robots aboard the ISS as their test bed. Astrobee is a team of three cube-shaped robots that help astronauts perform routine tasks either autonomously or by remote control, such as taking inventory, documenting experiments, or moving cargo, using their electric fan propulsion system as well as their built-in cameras and sensors to move about the station and perform their tasks. The first round of microgravity experiments aboard the ISS in June 2021 tested this set of algorithms both individually and together to enable a successful autonomous rendezvous of a "Chaser" Astrobee robot with a tumbling "Target" Astrobee, which were improved upon and tested again in a successful second session in February 2022.

The MIT project team comprises researchers from the Space Systems Laboratory (SSL) and the Astrodynamics, space Robotics, and Controls Laboratory (ARCLab), including Albee, Charles Oestreich SM '21, and principal investigator Richard Linares, the Boeing Career Development Professor in Aeronautics and Astronautics. The DLR team includes principal investigator Roberto Lampariello, graduate student Caroline Specht, and graduate student Hrishik Mishra.

The TumbleDock/ROAM project

First, the MIT and DLR research teams identified a series of algorithms, including simultaneous localization and mapping (SLAM), system identification, online motion planning, and model predictive control to test on Astrobee's autonomous robots and software platform to enable autonomous rendezvous. Then, they worked to develop the software and hardware required to experiment on the Astrobee platform. Astrobee’s open-source flight software, developed by NASA Ames, was augmented with MIT’s testing interface, the Astrobee Science Application Package, to enable low-level autonomy experiments. The TumbleDock/ROAM project was the first of a series of research collaborations out of the SSL/ARCLab to use this interface for algorithm testing on-orbit.

Working in a control room from MIT's campus, the team commanded the first round of microgravity testing with Astrobee. One Astrobee served as the "Chaser," with the goal of performing an autonomous rendezvous with another Astrobee acting as the tumbling "Target." Using data from Astrobee's cameras, lidar sensors, and onboard inertial measurement unit, the observing Chaser developed a model of the tumbling Target's motion and inertial properties, which then informed a nonlinear programming-based trajectory optimization to reach a "mating point," fixed in the rotating Target's frame. This trajectory was then tracked using robust model predictive control. The result: a successful rendezvous.

After the first round of testing, the team continued to refine their software based on lessons learned from seeing their work operate on an actual test bed. According to the students, seeing their experiment operate in an actual test bed rather than a simulation is a game-changer.

"I think it's so important for young roboticists and engineers to actually get their hands dirty on a physical system because you see the actual interactions between bodies in the field and gain a new understanding on parameters you may not have thought were important, but require copious amounts of tuning," says Specht. "Working out the math and simulating it is one thing, but actually putting it on a real system and seeing how that works in the real world is a completely different experience, and it opens your mind to so many different possibilities."

After the first test session, the TumbleDock/ROAM team worked closely with both NASA and DLR to make further improvements to their system. DLR developed enhancements to Astrobee’s default localization system that complemented additional upgrades created by the team at NASA Ames, with MIT continuing work on system integration and other algorithm overhauls. The final test session in February 2022 put these improvements in estimating the Target's orientation, safely tracking the motion plan to the Target with robustness guarantees, and working with Astrobee’s maturing localization system to the test, yielding a number of successful rendezvous maneuvers with differing motion plans.

Animated gif shows simulation of two robots and their virtual appendages
During motion planning the Chaser robot “sees” virtual appendages on the Target robot when predicting its trajectory.
Image courtesy of the researchers

"Because Astrobee is such a new system, we've had a lot more opportunity to collaborate more closely with the engineers from NASA Ames throughout the entire process than we would have otherwise," says Oestreich. "We've had some unique use cases for their system, so it's been an interesting challenge to work through together and get everyone in the same loop."

Working closely together on this project has also yielded benefits for the agency. NASA used portions of data from their project to improve the Astrobee base localization system and have also incorporated changes into the flight code software, providing crucial inputs to the autonomous rendezvous pipeline that will continue to benefit all future Astrobee users. 

Passing the torch 

NASA's Astrobee robot system is preceded by SPHERES (Synchronized Position Hold, Engage, Reorient Experimental Satellites), small programmable probes first conceived of by MIT undergraduates and further developed by MIT SSL. The SPHERES satellites launched in 2006 and were operated by SSL and NASA under professors David Miller and Alvar Saenz-Otero until Dec. 31, 2019, when Astrobee took over as the sole microgravity robotics test bed aboard the ISS. ROAM, or Relative Operations for Autonomous Maneuvers, became the umbrella for SSL research projects that focused on developing systems to support satellite proximity operations and is part of the namesake of the TumbleDock/ROAM project team.

"Our project achieved multiple on-orbit firsts both for MIT and for Astrobee, which is really exciting," says Albee. "We were the first Astrobee payload to perform simultaneous complex control of multiple robots and the first to perform low-level planning and control autonomy research using the Astrobee system. It was also the first time the SSL commanded an ISS payload directly and in real time from MIT's campus."

In addition to building the systems, the research teams at MIT and DLR collaborated on operations, experiments, and testing, leveraging the work done previously in SPHERES to enable this new application with Astrobee. When Lampariello first met David Miller, the Jerome C. Hunsaker Professor and former director of the SSL at MIT, he proposed a research project to test his motion planning software for tumbling targets on the SPHERES system. This initial collaboration eventually led to the TumbleDock/ROAM project on Astrobee.

"This project brings together the work my lab has done in motion planning and the work in perception that MIT has developed. Together, we all worked to develop the controls required to test the hardware," says Lampariello. "By the time we ran the tests aboard the ISS, we had a whole pipeline of functionalities — perception, motion prediction, planning, and control — to demonstrate on the Astrobee platform."

According to Oestreich, the TumbleDock/ROAM project not only builds on a foundation of knowledge and collaboration from SPHERES, but also on a legacy of generations of graduate work in SSL that came before them.

"The SLAM and target estimation algorithms, which help with the initial stage of finding out how the target is tumbling, were developed by graduate students in SSL and have been handed down through generations of us now," says Oestreich. "It's been interesting to see how it has evolved over the past eight years from thesis to thesis as each person worked to advance its capabilities further, and it has been cool to be able to implement it on new hardware like Astrobee."

In the process of building and refining their Astrobee experiment, they found the interface they developed could be adapted and repurposed for other investigations. Looking ahead, the TumbleDock/ROAM team hopes to make Astrobee as useful for other researchers as SPHERES was for them. The team has already run another set of experiments, RElative Satellite sWArming and Robotic Maneuvering (ReSWARM), in collaboration with KTH Space Center in Sweden and IST at the University of Lisbon in Portugal. The ReSWARM experiments successfully demonstrated a variety of algorithms related to on-orbit assembly and servicing, including information-aware motion planning and distributed model predictive control of microgravity robot teams. While MIT is currently one of the most prolific users of the Astrobee platform, the project team plans to continue refining their work with the goal to make testing resources open source for other researchers at MIT and beyond.

TumbleDock/ROAM was funded by The Aerospace Corporation’s University Partnership Program, the NASA Space Technology Research Fellowship grant 80NSSC17K0077, The Draper Fellow Program, and DLR research agreement 67272241, with the support of ISS National Lab.

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