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  • ✇IEEE Spectrum
  • Pogo Stick Microcopter Bounces off Floors and WallsEvan Ackerman
    We tend to think about hopping robots from the ground up. That is, they start on the ground, and then, by hopping, incorporate a aerial phase into their locomotion. But there’s no reason why aerial robots can’t approach hopping from the other direction, by adding a hopping ground phase to flight. Hopcopter is the first robot that I’ve ever seen give this a try, and it’s remarkably effective, combining a tiny quadrotor with a springy leg to hop hop hop all over the place. Songnan Bai, Runze D
     

Pogo Stick Microcopter Bounces off Floors and Walls

12. Duben 2024 v 15:30


We tend to think about hopping robots from the ground up. That is, they start on the ground, and then, by hopping, incorporate a aerial phase into their locomotion. But there’s no reason why aerial robots can’t approach hopping from the other direction, by adding a hopping ground phase to flight. Hopcopter is the first robot that I’ve ever seen give this a try, and it’s remarkably effective, combining a tiny quadrotor with a springy leg to hop hop hop all over the place.


Songnan Bai, Runze Ding, Song Li, and Bingxuan Pu

So why in the air is it worth adding a pogo stick to an otherwise perfectly functional quadrotor? Well, flying is certainly a valuable ability to have, but does take a lot of energy. If you pay close attention to birds (acknowledged experts in the space), they tend to spend a substantial amount of time doing their level best not to fly, often by walking on the ground or jumping around in trees. Not flying most of the time is arguably one of the things that makes birds so successful—it’s that multimodal locomotion capability that has helped them to adapt to so many different environments and situations.

Hopcopter is multimodal as well, although in a slightly more restrictive sense: Its two modes are flying and intermittent flying. But the intermittent flying is very important, because cutting down on that flight phase gives Hopcopter some of the same efficiency benefits that birds experience. By itself, a quadrotor of hopcopter’s size can stay airborne for about 400 seconds, while Hopcopter can hop continuously for more than 20 minutes. If your objective is to cover as much distance as possible, Hopcopter might not be as effective as a legless quadrotor. But if your objective is instead something like inspection or search and rescue, where you need to spend a fair amount of time not moving very much, hopping could be significantly more effective.

A diagram of the Hopcopter system, and a closeup of the Hopcopter leg. Hopcopter is a small quadcopter (specifically a Crazyflie) attached to a springy pogo-stick leg.Songnan Bai, Runze Ding, Song Li, and Bingxuan Pu

Hopcopter can reposition itself on the fly to hop off of different surfaces.Songnan Bai, Runze Ding, Song Li, and Bingxuan Pu

The actual hopping is mostly passive. Hopcopter’s leg is two rigid pieces connected by rubber bands, with a Crazyflie microcopter stapled to the top. During a hop, the Crazyflie can add directional thrust to keep the hops hopping and alter its direction as well as its height, from 0.6 meters to 1.6 meters. There isn’t a lot of room for extra sensors on Hopcopter, but the addition of some stabilizing fins allow for continuous hopping without any positional feedback.

Besides vertical hopping, Hopcopter can also position itself in midair to hop off of surfaces at other orientations, allowing it to almost instantaneously change direction, which is a neat trick.

And it can even do mid air somersaults, because why not?

Hopcopter’s repertoire of tricks includes somersaults.Songnan Bai, Runze Ding, Song Li, and Bingxuan Pu

The researchers, based at the City University of Hong Kong, say that the Hopcopter technology (namely, the elastic leg) could be easily applied to most other quadcopter platforms, turning them into Hopcopters as well. And if you’re more interested in extra payload rather than extra endurance, it’s possible to use hopping in situations where a payload would be too heavy for continuous flight.

The researchers published their work 10 April in Science Robotics.

  • ✇IEEE Spectrum
  • Video Friday: Monocycle Robot With LegsEvan Ackerman
    Video Friday is your weekly selection of awesome robotics videos, collected by your friends at IEEE Spectrum robotics. We also post a weekly calendar of upcoming robotics events for the next few months. Please send us your events for inclusion.Cybathlon Challenges: 02 February 2024, ZURICHHRI 2024: 11–15 March 2024, BOULDER, COLO.Eurobot Open 2024: 8–11 May 2024, LA ROCHE-SUR-YON, FRANCEICRA 2024: 13–17 May 2024, YOKOHAMA, JAPANEnjoy today’s videos! In this video, we present Ringbot, a novel leg
     

Video Friday: Monocycle Robot With Legs

9. Únor 2024 v 18:41


Video Friday is your weekly selection of awesome robotics videos, collected by your friends at IEEE Spectrum robotics. We also post a weekly calendar of upcoming robotics events for the next few months. Please send us your events for inclusion.

Cybathlon Challenges: 02 February 2024, ZURICH
HRI 2024: 11–15 March 2024, BOULDER, COLO.
Eurobot Open 2024: 8–11 May 2024, LA ROCHE-SUR-YON, FRANCE
ICRA 2024: 13–17 May 2024, YOKOHAMA, JAPAN

Enjoy today’s videos!

In this video, we present Ringbot, a novel leg-wheel transformer robot incorporating a monocycle mechanism with legs. Ringbot aims to provide versatile mobility by replacing the driver and driving components of a conventional monocycle vehicle with legs mounted on compact driving modules inside the wheel.

[ Paper ] via [ KIMLAB ]

Making money with robots has always been a struggle, but I think ALOHA 2 has figured it out.

Seriously, though, that is some impressive manipulation capability. I don’t know what that freakish panda thing is, but getting a contact lens from the package onto its bizarre eyeball was some wild dexterity.

[ ALOHA 2 ]

Highlights from testing our new arms built by Boardwalk Robotics. Installed in October of 2023, these new arms are not just for boxing and provide much greater speed and power. This matches the mobility and manipulation goals we have for Nadia!

The least dramatic but possibly most important bit of that video is when Nadia uses her arms to help her balance against a wall, which is one of those things that humans do all the time without thinking about it. And we always appreciate being shown things that don’t go perfectly alongside things that do. The bit at the end there was Nadia not quite managing to do lateral arm raises. I can relate; that’s my reaction when I lift weights, too.

[ IHMC ]

Thanks, Robert!

The recent progress in commercial humanoids is just exhausting.

[ Unitree ]

We present an avatar system designed to facilitate the embodiment of humanoid robots by human operators, validated through iCub3, a humanoid developed at the Istituto Italiano di Tecnologia.

[ Science Robotics ]

Have you ever seen a robot skiing?! Ascento robot enjoying a day in the ski slopes of Davos.

[ Ascento ]

Can’t trip Atlas up! Our humanoid robot gets ready for real work combining strength, perception, and mobility.

Notable that Boston Dynamics is now saying that Atlas “gets ready for real work.” Wonder how much to read into that?

[ Boston Dynamics ]

You deserve to be free from endless chores! YOU! DESERVE! CHORE! FREEDOM!

Pretty sure this is teleoperated, so someone is still doing the chores, sadly.

[ MagicLab ]

Multimodal UAVs (unmanned aerial vehicles) are rarely capable of more than two modalities—that is, flying and walking or flying and perching. However, being able to fly, perch, and walk could further improve their usefulness by expanding their operating envelope. For instance, an aerial robot could fly a long distance, perch in a high place to survey the surroundings, then walk to avoid obstacles that could potentially inhibit flight. Birds are capable of these three tasks, and so offer a practical example of how a robot might be developed to do the same.

[ Paper ] via [ EPFL LIS ]

Nissan announces the concept model of “Iruyo,” a robot that supports babysitting while driving. Ilyo relieves the anxiety of the mother, father, and baby in the driver’s seat. We support safe and secure driving for parents and children. Nissan and Akachan Honpo are working on a project to make life better with cars and babies. Iruyo was born out of the voices of mothers and fathers who said, “I can’t hold my baby while driving alone.”

[ Nissan ]

Building 937 houses the coolest robots at CERN. This is where the action happens to build and program robots that can tackle the unconventional challenges presented by the laboratory’s unique facilities. Recently, a new type of robot called CERNquadbot has entered CERN’s robot pool and successfully completed its first radiation protection test in the North Area.

[ CERN ]

Congrats to Starship, the OG robotic delivery service, on their US $90 million raise.

[ Starship ]

By blending 2D images with foundation models to build 3D feature fields, a new MIT method helps robots understand and manipulate nearby objects with open-ended language prompts.

[ GitHub ] via [ MIT ]

This is one of those things that’s far more difficult than it might look.

[ ROAM Lab ]

Our current care system does not scale, and our populations are aging fast. Robodies are multipliers for care staff, allowing them to work together with local helpers to provide protection and assistance around the clock while maintaining personal contact with people in the community.

[ DEVANTHRO ]

It’s the world’s smallest humanoid robot, until someone comes out with slightly smaller servos!

[ Guinness ]

Deep Robotics wishes you a happy year of the dragon!

[ Deep Robotics ]

SEAS researchers are helping develop resilient and autonomous deep-space and extraterrestrial habitations by developing technologies to let autonomous robots repair or replace damaged components in a habitat. The research is part of the Resilient ExtraTerrestrial Habitats institute (RETHi), led by Purdue University in partnership with SEAS, the University of Connecticut, and the University of Texas at San Antonio. Its goal is to “design and operate resilient deep-space habitats that can adapt, absorb, and rapidly recover from expected and unexpected disruptions.”

[ Harvard ]

Find out how a bold vision became a success story! The DLR Institute of Robotics and Mechatronics has been researching robotic arms since the 1990s, originally for use in space. It was a long and ambitious journey before these lightweight robotic arms could be used on Earth and finally in operating theaters, a journey that required concentrated robotics expertise, interdisciplinary cooperation, and ultimately a successful technology transfer.

[ DLR MIRO ]

Robotics is changing the world, driven by focused teams of diverse experts. Willow Garage operated with the mantra “Impact first, return on capital second” and through ROS and the PR2 had enormous impact. Autonomous mobile robots are finally being accepted in the service industry, and Savioke (now Relay Robotics) was created to drive that impact. This talk will trace the evolution of Relay robots and their deployment in hotels, hospitals, and other service industries, starting with roots at Willow Garage. As robotics technology is poised for the next round of advances, how do we create and maintain the organizations that continue to drive progress?

[ Northwestern ]

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