Tag Archives: robots
#439271 Video Friday: NASA Sending Robots to ...
Video Friday is your weekly selection of awesome robotics videos, collected by your Automaton bloggers.
It’s ICRA this week, but since the full proceedings are not yet available, we’re going to wait until we can access everything to cover the conference properly. Or, as properly as we can not being in Xi’an right now.
We’ll also be posting a weekly calendar of upcoming robotics events for the next few months; here's what we have so far (send us your events!):
RoboCup 2021 – June 22-28, 2021 – [Online Event]
RSS 2021 – July 12-16, 2021 – [Online Event]
Humanoids 2020 – July 19-21, 2021 – [Online Event]
DARPA SubT Finals – September 21-23, 2021 – Louisville, KY, USA
WeRobot 2021 – September 23-25, 2021 – Coral Gables, FL, USA
IROS 2021 – September 27-1, 2021 – [Online Event]
ROSCon 2021 – October 21-23, 2021 – New Orleans, LA, USA
Let us know if you have suggestions for next week, and enjoy today's videos.
NASA has selected the DAVINCI+ (Deep Atmosphere Venus Investigation of Noble-gases, Chemistry and Imaging +) mission as part of its Discovery program, and it will be the first spacecraft to enter the Venus atmosphere since NASA’s Pioneer Venus in 1978 and USSR’s Vega in 1985.
The mission, Deep Atmosphere Venus Investigation of Noble gases, Chemistry, and Imaging Plus, will consist of a spacecraft and a probe. The spacecraft will track motions of the clouds and map surface composition by measuring heat emission from Venus’ surface that escapes to space through the massive atmosphere. The probe will descend through the atmosphere, sampling its chemistry as well as the temperature, pressure, and winds. The probe will also take the first high-resolution images of Alpha Regio, an ancient highland twice the size of Texas with rugged mountains, looking for evidence that past crustal water influenced surface materials.
Launch is targeted for FY2030.
[ NASA ]
Skydio has officially launched their 3D Scan software, turning our favorite fully autonomous drone into a reality capture system.
Skydio held a launch event at the U.S. Space & Rocket Center and the keynote is online; it's actually a fairly interesting 20 minutes with some cool rockets thrown in for good measure.
[ Skydio ]
Space robotics is a key technology for space exploration and an enabling factor for future missions, both scientific and commercial. Underwater tests are a valuable tool for validating robotic technologies for space. In DFKI’s test basin, even large robots can be tested in simulated micro-gravity with mostly unrestricted range of motion.
[ DFKI ]
The Harvard Microrobotics Lab has developed a soft robotic hand with dexterous soft fingers capable of some impressive in-hand manipulation, starting (obviously) with a head of broccoli.
Training soft robots in simulation has been a bit of a challenge, but the researchers developed their own simulation framework that matches the real world pretty closely:
The simulation framework is avilable to download and use, and you can do some nutty things with it, like simulating tentacle basketball:
I’d pay to watch that IRL.
[ Paper ] via [ Harvard ]
Using the navigation cameras on its mast, NASA’s Curiosity Mars rover this movie of clouds just after sunset on March 28, 2021, the 3,072nd so, or Martian day, of the mission. These noctilucent, or twilight clouds, are made of water ice; ice crystals reflect the setting sun, allowing the detail in each cloud to be seen more easily.
[ JPL ]
Genesis Robotics is working on something, and that's all we know.
[ Genesis Robotics ]
To further improve the autonomous capabilities of future space robots and to advance European efforts in this field, the European Union funded the ADE project, which was completed recently in Wulsbüttel near Bremen. There, the rover “SherpaTT” of the German Research Center for Artificial Intelligence (DFKI) managed to autonomously cover a distance of 500 meters in less than three hours thanks to the successful collaboration of 14 European partners.
[ DFKI ]
For $6.50, a NEXTAGE robot will make an optimized coffee for you. In Japan, of course.
[ Impress ]
Things I’m glad a robot is doing so that I don’t have to: dross skimming.
[ Fanuc ]
Today, anyone can hail a ride to experience the Waymo Driver with our fully autonomous ride-hailing service, Waymo One. Riders Ben and Ida share their experience on one of their recent multi-stop rides. Watch as they take us along for a ride.
[ Waymo ]
The IEEE Robotics and Automation Society Town Hall 2021 featured discussion around Diversity & Inclusion, RAS CARES committee & Code of Conduct, Gender Diversity, and the Developing Country Faculty Engagement Program.
[ IEEE RAS ] Continue reading
#439252 The Cheetah’s Fluffy Tail Points ...
Almost but not quite a decade ago, researchers from UC Berkeley equipped a little robotic car with an actuated metal rod with a weight on the end and used it to show how lizards use their tails to stabilize themselves while jumping through the air. That research inspired a whole bunch of other tailed mobile robots, including a couple of nifty ones from Amir Patel at the University of Cape Town.
The robotic tails that we’ve seen are generally actuated inertial tails: a moving mass that goes one way causes the robot that it’s attached to to go the other way. This is how lizard tails work, and it’s a totally fine way to do things. In fact, people generally figured that many if not most other animals that use their tails to improve their agility leverage this inertial principle, including (most famously) the cheetah. But at least as far as the cheetah was concerned, nobody had actually bothered to check, until Patel took the tails from a collection of ex-cheetahs and showed that in fact cheetah tails are almost entirely fluff. So if it’s not the mass of its tail that helps a cheetah chase down prey, then it must be the aerodynamics.
The internet is full of wisdom on cheetah tails, and most of it describes “heavy” tails that “act as a counterbalance” to the rest of the cheetah’s body. This makes intuitive sense, but it’s also quite wrong, as Amir Patel figured out:
The aerodynamics of cheetah tails are super important, and actually something I discovered by accident! Towards the end of my PhD I was invited to a cheetah autopsy at the National Zoological Gardens here in South Africa. The idea was to weigh and measure the inertia of the cheetah tail because no such data existed. Based on what I’d seen in wildlife documentaries (and speaking to any game ranger in South Africa), the cheetah tail is often considered to be heavy, and used as a counterweight.
However, once we removed the fur and skin from the tail during the autopsy, it was surprisingly skinny! We measured it (and the tails of another 6 cheetahs) as being only about 2 percent of the body mass—much lower than my own robotic tails. But the fur made up a significant volume of the tail. So, I figured that there must be something to it: maybe the fur was making the tail appear like a larger object aerodynamically, without the weight penalty of an inertial tail.
A few years ago, Patel started to characterize tail aerodynamics in partnership with Aaron Johnson’s lab at CMU, and that work has lead to a recent paper published in IEEE Transactions on Robotics, exploring how aerodynamic drag on a lightweight tail can help robots perform dynamic behaviors more successfully.
The specific tail design that Minitaur is sporting in the video above doesn’t look particularly cheetah-like, being made out of carbon fiber and polyethylene film rather than floof, and only sporting an aerodynamic component at the end of the tail rather than tip to butt. This is explained by cheetahs in the wild not having easy access to either carbon fiber or polyethylene, and by a design that the researchers optimized to maximize drag while minimizing mass rather than for biomimicry. “We experimented with a whole array of furry tails to mimic cheetah fur, but found that the half cylinder shape had by far the most drag,” first author Joseph Norby told us in an email. “And the reduction of the drag component to just the end of the tail was a balance of effectiveness and rigidity—we could have made the drag component cover the entire length, but really the section near the tip produces most of the drag, and reducing the length of the drag component helps maintain the shape of the tail.”
Aerodynamic tails are potentially appealing because unlike inertial tails, the amount of torque that they can produce doesn't depend on how much they weigh, but rather with the velocity at which the robot is moving: the faster the robot goes, the more torque an aerodynamic tail can produce. We see this in animals, too, with fluffy tails commonly found on fast movers and jumpers like jerboas and flying squirrels. This offers some suggestion about what kind of robots could benefit most from tails like these, although as Norby points out, the greatest limitation of these tails is the large workspace required for the tail to move around safely.
Image: Norby et al
A variety of animals (and one robot) with aerodynamic drag tails, including a jerboa and giant Indian squirrel.
While this paper is focused on quantifying the effects of aerodynamic drag on robotic tails, it seems like there’s a lot of potential for some really creative designs—we were wondering about tails with adjustable floofitude, for example, and we asked Norby about some ways in which this research might be extended.
I think a foldable or retractable tail would greatly improve practicality by reducing the workspace when the tail is not needed. Essentially all of the animals we studied had some sort of flexibility to their tails, which I believe is a crucial property for improving both practicality and durability. In a similar vein, we've also thought about employing active or passive designs that could quickly modify the drag coefficient, whether by furling and unfurling, or simply rotating an asymmetric tail like our half cylinder. This could perhaps allow new forms of control similar to paddling and feathering a canoe: increasing drag when moving in one direction and reducing drag in the other could allow for more net control authority. This would be completely impossible with an inertial tail, which cannot do work on the environment.
Photo: Evan Ackerman/IEEE Spectrum
Gratuitous cheetah picture.
Even though animals had the idea for lightweight aerodynamic drag tails first, there’s no reason why we need to restrict ourselves to animal-like form factors when leveraging the advantages that tails like these offer, or indeed with the designs of the tails themselves. Without a mass penalty to worry about, why not put tails on any robot that has trouble keeping its balance, like pretty much every bipedal robot, right? Of course there are plenty of reasons not to do this, but still, it’s exciting to see this whole design space of aerodynamic drag tails potentially open up for any robot platform that needs a little bit of help with dynamic motion.
Enabling Dynamic Behaviors With Aerodynamic Drag in Lightweight Tails, by Joseph Norby, Jun Yang Li, Cameron Selby, Amir Patel, and Aaron M. Johnson from CMU and the University of Cape Town is published in IEEE Transactions on Robotics. Continue reading
#439224 Mobile dexterous robots: a key element ...
Kinova robotic arms, from left to right: Gen2, Gen3 lite, Gen3
Multiple companies turned to Kinova® robotic arms to create mobile platforms with manipulation capabilities to tackle many aspects of the sanitary crisis. The addition of a dexterous manipulator to mobile platforms opens the door to applications such as patient care disinfection and cleaning — critical to the fight against the virus.
Ever since the pandemic hit at the beginning of 2020, it became clear that the human resources available to address all the different fronts in the fight against the virus would be thinly stretched — especially considering the fact that these people are subject to falling ill. Mobile robots with manipulation capabilities were quickly identified as a solution to alleviate this problem by freeing skilled people from menial tasks and by allowing remote or automated work which keeps exposure to the virus to a minimum.
Multiple companies turned to Kinova robotic arms for an off-the-shelf manipulation solution suitable for mobile platforms. The history Kinova has with the assistive market is now at the core of the technology — assistive products such as motorized wheelchair-mounted robots like Jaco® were designed from the beginning to be extremely safe, user-friendly, ultra-lightweight, and power-efficient. This experience has transpired into more recent products as well. All these features do not come at the expense of performance, in fact, Kinova robots boast some of the highest payload-to-weight ratios in the industry. It does make sense that robots like these are ideal for applications involving mobile platforms and integration into products that are meant to be interacted with in non-industrial settings.
One of the companies that successfully made such an integration is Diligent, who developed a patient care robot called Moxi by integrating a Kinova Gen2 robot to a mobile platform powered by cloud-based software and artificial intelligence. Moxi is designed to help clinical staff with menial tasks that do not involve the patients, like fetching supplies, delivering samples, and distributing equipment, thus freeing skilled staff like nurses to perform more value-added tasks. Its rounded design and friendly face make interactions with it feel more natural for both the public and the hospital staff who otherwise may not be used to interacting with robots. In the current pandemic, one can easily understand how a robot such as Moxi can find its uses to alleviate the workload of healthcare workers and prove to quickly provide a return on investment for healthcare institutions.
Another type of menial task that became surprisingly important in the context of the sanitary crisis is that of cleaning. Prior to the crisis, Peanut Robotics, a startup from California that raised $2 million in 2019 was already developing a mobile platform carrying a Kinova Gen3 for cleaning commercial spaces such as restaurants, offices, hotels, and even airports. By coupling the 7 degrees of freedom robot to a vertical rail, their system can reach even the most inconvenient places. Rather than using specialized robot end-effectors to work, they take advantage of the flexibility of the robot gripper to grab tools similar to what a human would use, thus making it possible to clean an entire room with a single system, including spraying disinfectant, scrubbing, and wiping — and all that autonomously! With the current context where more surfaces need more frequent cleaning and where being in contact with objects comes with a higher risk of infection, surely we will see this kind of robot increasingly frequently.
However, not all environments are suitable for such a deep cleaning. Common areas in malls or airports for example are simply too large and possibly too crowded for such operations. It is these kinds of cases that A&K Robotics are tackling with their Autonomous Mobile Robotic UV Disinfector (Amrud) — a project selected for funding by Canada’s Advanced Manufacturing Supercluster. They combined their expertise in navigation and mobile platforms with the capabilities of a Kinova Gen3 lite robot. The compact and extremely light (less than 6 kg) robot is carried around wielding a UV light source to disinfect surfaces. Its 6 degrees of freedom allow for more than enough flexibility to waive the light source around even the most complex surfaces. A&K already made the news a few times in 2020 by deploying their solution to assist in the disinfection of floors and high-touch surfaces. Whereas when they started the project back in 2017 they did not get much traction, it is clear that the recent needs got them much deserved attention.
As the pandemic settles, an always-increasing number of applications for robots are found. Be it traditionally non-industrialized industries looking to be more resilient to staff shortages or due to the democratization of working from home, robots are becoming more commonplace than ever. Kinova, with its wide range of robot type offers, is there to assist developers and integrators accomplish their tasks and contribute to the growth of the collaboration of robots in our daily lives.
To learn more about Kinova click here. Continue reading
#439222 MOBLOT: A theoretical model that ...
Research focusing on swarm robotics typically uses theoretical approaches to describe robotic systems in an abstract way. A theoretical model that is often used in robotics studies is OBLOT, an approach that represents robots as simple systems, all identical, without a memory and unable to communicate with each other. Continue reading
#438882 Robotics in the entertainment industry
Mesmer Entertainment Robotics demonstrate some of their humanoid animatronics, as well as their humanoid robot, Owen.