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.
London Humanoids Summit: 29–30 May 2025, LONDON
IEEE RCAR 2025: 1–6 June 2025, TOYAMA, JAPAN
2025 Energy Drone & Robotics Summit: 16–18 June 2025, HOUSTON, TX
RSS 2025: 21–25 June 2025, LOS ANGELES
ETH Robotics Summer School: 21–27 June 2025, GENEVA
IAS 2025: 30 June–4 July 2025, GENOA, ITALY
ICRES 2025: 3–4 July 2025, PORTO, PORTUGAL
IEEE World Haptics: 8–11 July 2025, SUWON, KOREA
IFAC Symposium on Robotics: 15–18 July 2025, PARIS
RoboCup 2025: 15–21 July 2025, BAHIA, BRAZIL
RO-MAN 2025: 25–29 August 2025, EINDHOVEN, THE NETHERLANDS
CLAWAR 2025: 5–7 September 2025, SHENZHEN
CoRL 2025: 27–30 September 2025, SEOUL
IEEE Humanoids: 30 September–2 October 2025, SEOUL
World Robot Summit: 10–12 October 2025, OSAKA, JAPAN
IROS 2025: 19–25 October 2025, HANGZHOU, CHINA
Enjoy today’s videos!
This is our latest work about a hybrid aerial-terrestrial quadruped robot called SPIDAR, which shows a unique grasping style in midair. This work has been presented in the 2025 IEEE International Conference on Robotics & Automation (ICRA).
Thanks, Moju!
These wormlike soft robots can intertwine into physically entangled “blobs,†like living California blackworms. Both the robots and the living worms can operate individually as well as collectively as a blob, carrying out functions like directed movement and transporting objects.
At only 3 centimeters tall, Zippy, the world’s smallest bipedal robot, is also self-contained--all the controls, power, and motor are on board so that it operates autonomously. Moving at 10 leg lengths per second, it is also the fastest bipedal robot [relative to its size].
[CMU]
Spot is getting some AI upgrades to help it with industrial inspection.
A 3D-printed sphere that can morph from smooth to dimpled on demand could help researchers improve how underwater vehicles and aircraft maneuver. Inspired by a golf ball aerodynamics problem, Assistant Professor of Naval Architecture and Marine Engineering and Mechanical Engineering Anchal Sareen and her team applied soft robotic techniques with fluid dynamics principles to study how different dimple depths at different flow velocities could reduce an underwater vehicle’s drag, as well as allow it to maneuver without fins and rudders.
[UMich]
Tool use is critical for enabling robots to perform complex real-world tasks, and leveraging human tool-use data can be instrumental for teaching robots. However, existing data-collection methods like teleoperation are slow, prone to control delays, and unsuitable for dynamic tasks. In contrast, human play—where humans directly perform tasks with tools—offers natural, unstructured interactions that are both efficient and easy to collect. Building on the insight that humans and robots can share the same tools, we propose a framework to transfer tool-use knowledge from human play to robots.
Thanks, Haonan!
UR15 is our new high-performance collaborative robot. UR15 is engineered for ultimate versatility, combining a lightweight design with a compact footprint to deliver unmatched flexibility—even in the most space-restricted environments. It reaches an impressive maximum speed of 5 meters per second, which ultimately enables reduced cycle times and increased productivity, and is designed to perform heavy-duty tasks while delivering speed and precision wherever you need it.
Debuting at the 2025 IEEE International Conference on Robotics & Automation (May 19–23, Atlanta, USA), this interactive art installation features buoyant bipedal robots—composed of helium balloons and articulated legs—moving freely within a shared playground in the exhibition space. Visitors are invited to engage with the robots via touch, gamepads, or directed airflow, influencing their motion, color-changing lights, and expressive behavior.
[RoMeLa]
We gave TRON 1 an arm. Now, it’s faster, stronger, and ready for whatever the terrain throws at it.
Humanoid robots can support human workers in physically demanding environments by performing tasks that require whole-body coordination, such as lifting and transporting heavy objects. These tasks, which we refer to as Dynamic Mobile Manipulation (DMM), require the simultaneous control of locomotion, manipulation, and posture under dynamic interaction forces. This paper presents a teleoperation framework for DMM on a height-adjustable wheeled humanoid robot for carrying heavy payloads.
Yoshua Bengio—the world’s most-cited computer scientist and a “godfather†of artificial intelligence—is deadly concerned about the current trajectory of the technology. As AI models race toward full-blown agency, Bengio warns that they’ve already learned to deceive, cheat, self-preserve, and slip out of our control. Drawing on his groundbreaking research, he reveals a bold plan to keep AI safe and ensure that human flourishing, not machines with unchecked power and autonomy, defines our future.
[TED]
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Evan Ackerman
Evan Ackerman is a senior editor at IEEE Spectrum. Since 2007, he has written over 6,000 articles on robotics and technology. He has a degree in Martian geology and is excellent at playing bagpipes.
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