Throwable Robot Ball Unfolds Legs to Walk

QRoSS can bounce around and then extend four legs to walk over rough terrain

2 min read
Throwable Robot Ball Unfolds Legs to Walk

Anyone who has much in the way of experience with robots is painfully aware of their fragility. Robots like Flyability’s Gimball deal with this through the creative use of roll cages, which have a useful side effect of allowing the robot to dynamically navigate through direct surface contact. Roll cages can protect ground robots too, although it’s a bit more problematic because using a full roll cage makes it difficult for the robot to do anything but roll. At IROS, Japanese researchers presented a design for a robot that can be tossed, roll along the ground, and then pop out four legs when it needs to scramble around.

The researchers cite three inspirations for their design. We’re already familiar with the first one, MorpHex:

And then there’s this little guy called Haro, from Gundam:

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Lastly, from Star Wars, the Droidekas (which is what I thought of when I first saw QRoSS):

As far as real robots go, the primary difference between QRoSS and MorpHex is that QRoSS uses a walking system that’s completely independent from the outer shell. The big advantage of this is that the shell acts as a passive shock absorber, allowing the robot to the rolled (or, hypothetically, thrown) without damaging it. In a disaster area, for example, a human could chuck the robot like a baseball into a dangerous area from a safe one, and after bouncing a few times, QRoSS simply sprouts legs and starts walking around. Legs are excellent at dealing with very rough terrain, and the design of QRoSS allows you to use legs when necessary without having to always worry about how fragile they are, since any slip and fall just turns into a bouncy roll.

The other advantage of a more or less spherical robot is that it can use rolling as a faster and more efficient method of locomotion, as long as the terrain is favorable. QRoSS has a walking speed that tops out at about 0.1 m/s, while its rolling speed is nearly 0.6 m/s.

QRoSS II (the current version) weighs almost 2.5 kilograms, with a 30-centimeter diameter shell, so it’s not yet optimized for throwing. Researchers are still studying its mobility techniques and characteristics, so they haven’t really been focusing on size, weight, or cost. However, the design seems like it should be scalable, and there’s no reason to think that there’d be a very high manufacturing cost: there are twelve servos (three per leg), some electronics, and legs made of a combination of titanium and shape-memory alloy with polyurethane foam shock absorbers. We’re hoping that future iterations might be smaller (on the order of palm sized), and affordable enough to be disposably tossed wherever they might be needed.

“Development of Quadruped Walking Robot With Spherical ShellMechanical Design for Rotational Locomotion,” by Takeshi Aoki, Satoshi Ito, and Yosuke Sei from the Chiba Institute of Technology in Japan, was presented this month at IROS 2015 in Hamburg, Germany.

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Robot with threads near a fallen branch

RoMan, the Army Research Laboratory's robotic manipulator, considers the best way to grasp and move a tree branch at the Adelphi Laboratory Center, in Maryland.

Evan Ackerman
LightGreen

This article is part of our special report on AI, “The Great AI Reckoning.

"I should probably not be standing this close," I think to myself, as the robot slowly approaches a large tree branch on the floor in front of me. It's not the size of the branch that makes me nervous—it's that the robot is operating autonomously, and that while I know what it's supposed to do, I'm not entirely sure what it will do. If everything works the way the roboticists at the U.S. Army Research Laboratory (ARL) in Adelphi, Md., expect, the robot will identify the branch, grasp it, and drag it out of the way. These folks know what they're doing, but I've spent enough time around robots that I take a small step backwards anyway.

The robot, named RoMan, for Robotic Manipulator, is about the size of a large lawn mower, with a tracked base that helps it handle most kinds of terrain. At the front, it has a squat torso equipped with cameras and depth sensors, as well as a pair of arms that were harvested from a prototype disaster-response robot originally developed at NASA's Jet Propulsion Laboratory for a DARPA robotics competition. RoMan's job today is roadway clearing, a multistep task that ARL wants the robot to complete as autonomously as possible. Instead of instructing the robot to grasp specific objects in specific ways and move them to specific places, the operators tell RoMan to "go clear a path." It's then up to the robot to make all the decisions necessary to achieve that objective.

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