UC Berkeley unveils an AI tool that designs shape-shifting “metatruss” robots with minimal control units. . . Sources: https://lnkd.in/gb68eh3u. . . Researchers at UC Berkeley have built an AI-driven framework that optimizes the design of metatruss robots — structures made of hundreds of beams and joints that twist and morph to adapt to different tasks. The system uses a genetic algorithm to find the minimum number of control units needed for a robot to shape-shift, move fast, or grasp objects.rototype designs include a walking quadruped, a shape-changing helmet, and a lobster-like robot — all achieving complex behaviors with fewer actuators. Official Video credit : Berkeley Engineering. . . Join Telegram(link in bio) to get source link 🔗 #MetatrussRobots #ShapeShiftingTech #AIDesignedRobots #MorphingMachines #SmartStructures #FutureRobotics #AdaptiveTech #RobotDesignAI #ControlEfficiency #MorphingFurniture #WearableRobotics #DynamicStructures #RoboticInnovation #NextGenRobots   #TransformTech ----------------------⚠️ Disclaimer:--------------------- All rights belong to the original creators. This video is for educational purposes only.

I am thrilled to share my research on 'AI-Powered Adaptive Robotics for Dynamic Industrial Environments.'" As a Research Scholar, I study how AI-driven adaptive systems can get beyond the inability of traditional industrial robots to function well in unstructured environments. We are investigating solutions that improve real-time flexibility, which will result in safer operations, more efficiency, and less downtime in manufacturing, logistics, and other fields. #Mechatronics #Robotics #AI #AdaptiveRobotics #IndustrialAutomation #Research #Engineering #Innovation

"Columbia University researchers introduce a process that allows machines to “grow” physically by integrating parts from their surroundings or from other robots, demonstrating a step towards self-sustaining robot ecologies." Columbia Engineering Robots that Grow by Consuming Other Robots Paper in comment PRINTED & MUSCULOSKELETAL ROBOTICS Robot metabolism: Toward machines that can grow by consuming other machines. Abstract :" Biological lifeforms can heal, grow, adapt, and reproduce, which are abilities essential for sustained survival anddevelopment. In contrast, robots today are primarily monolithic machines with limited ability to self-repair, phys-ically develop, or incorporate material from their environments. While robot minds rapidly evolve new behaviorsthrough artificial intelligence, their bodies remain closed systems, unable to systematically integrate material togrow or heal. We argue that open-ended physical adaptation is only possible when robots are designed using asmall repertoire of simple modules. This allows machines to mechanically adapt by consuming parts from othermachines or their surroundings and shed broken components. We demonstrate this principle on a truss modularrobot platform. We show how robots can grow bigger, faster, and more capable by consuming materials from theirenvironment and other robots. We suggest that machine metabolic processes like those demonstrated here willbe an essential part of any sustained future robot ecology." https://lnkd.in/eA3Fp2Fr

The future of robots might look less like machines and more like…nature itself. Take this video. What seems like a pile of elephant dung is actually a camera on wheels, sneaking up to elephants without breaking their calm. My daughter thought it was hilarious. I found it fascinating. And this isn’t a one-off trick. We’ve seen bird-like robots flapping indoors. Fish-like robots swimming quietly in water. Each new design made possible by two big shifts: - Hardware that’s smaller, tougher, more versatile. - Intelligent algorithms that make them useful in real-world settings. Nature-inspired robots are only going to multiply. To me, that’s exciting—not just for research but for what it means about how far robotics has come. Video included for educational purposes only. No copyright ownership claimed. Video credits: BBC --- Download this free career guide to learn the top 5 skills needed to land a high-paying robotics job: https://robocareer.crd.co/

Exciting times in the world of robotics are unfolding across the globe! Over the past month, leading companies and research labs have announced a series of breakthroughs that promise to reshape how we interact with intelligent machines. Boston Dynamics revealed a new ESR (Elastic Snake Robot) prototype designed for disaster response, capable of navigating tight, uneven spaces and delivering vital supplies. Meanwhile, a team at MIT demonstrated a swarm of micro‑drones that can coordinate complex search patterns without traditional programming, opening doors to efficient environmental monitoring. In manufacturing, ABB’s Cobots are now equipped with advanced perceptual systems, enabling them to adjust to unexpected object variations in real time. This marks a significant stride toward truly autonomous production lines. The automotive sector is also moving fast: Mobileye has released a perception stack that surpasses current lane‑keeping technologies, integrating LIDAR and camera feeds into a unified neural network. Early trials at test tracks have shown a 30% reduction in steering errors compared to existing solutions. Lastly, the AI community is abuzz with a new reinforcement learning algorithm that lets robots learn navigation tasks from raw video input alone, cutting the training time from months to weeks. Future sports robotics seriously look now—there’s genuine proof that machines can adapt with human-like agility. These stories illustrate that robotics is rapidly transitioning from prototype concepts to everyday applications. I’m thrilled to watch how these technologies will be woven into industries, services, and daily life. If you have insights or thoughts on these developments, drop a comment below—I’d love to hear from fellow enthusiasts and professionals!

ROBOTICS 🤖 Understanding Robotics: The Future of Intelligent Machines Robotics is a multidisciplinary branch of engineering and science that focuses on the design, construction, operation, and application of robots. These machines are capable of carrying out a variety of tasks—either autonomously or under human control—across a wide range of industries. What is a Robot? A robot is a programmable machine that can perform physical tasks. Robots typically consist of three main components: Sensors to perceive the environment, Processors (brains) to make decisions, Actuators (motors or limbs) to perform actions. Some robots are fully autonomous, using artificial intelligence (AI) to make decisions in real-time, while others operate under direct human control (teleoperated). History and Evolution The concept of robotics dates back to ancient civilizations, but the modern era began in the 20th century. The first industrial robot, Unimate, was introduced in the 1960s to automate factory work. Since then, robotics has evolved rapidly, with advancements in AI, machine learning, and materials science fueling its growth. Applications of Robotics Robots are transforming numerous fields: #snsintutitions #snsdesignthikers #snsdesignthinking

These little robots literally walk on water: HydroSpread, a breakthrough fabrication method, lets scientists build ultrathin soft robots directly on water. These tiny, insect-inspired machines could transform robotics, healthcare, and environmental monitoring. #ScienceDaily #Technology

🤖 Roboticists from Drexel University are working to develop touch-sensitive clothing to help their robot distinguish something as nuanced as a tap on the shoulder from something as potentially dangerous as an aggressive push. https://spr.ly/6043A5jDJ #MATLAB #Simulink #robotics

Meet N1, the small, open-source humanoid robot that's making waves in the robotics community! 🤖💻 Recently, Fourier, the Shanghai-based robotics firm, released a demo video showcasing the N1's impressive gymnastic abilities, including a cartwheel and a 360-degree jump. 🤸♀️🔥 The N1's capabilities are a testament to its dynamic control and hardware strength, and its open-source platform makes it an exciting tool for developers and researchers. 📚💡 With its lightweight aluminum alloy and engineering plastics construction, the N1 is designed to be accessible and user-friendly, with an operating time of over two hours on a single charge. 📈 The implications of the N1's technology are significant, with potential applications in fields such as rehabilitation robotics, companionship, and sensory engagement. 🤝💻 As the robotics industry continues to evolve, it's exciting to see companies like Fourier pushing the boundaries of what's possible with humanoid robots. 🚀 Key statistics: 1. 📊 The N1 is approximately 1.3 meters tall and weighs roughly 38 kilograms. 2. 📈 It can reach speeds of up to 3.5 meters per second. 3. 📚 The N1's open-source platform makes it an ideal tool for developers and researchers. What do you think about the future of humanoid robotics? Share your thoughts in the comments! 💬 #Robotics #ArtificialIntelligence #HumanoidRobot #OpenSource #Innovation #Technology #FutureOfWork 🔄 Share 👍 React 🌐 Visit www.aravind-r.com #AravindRaghunathan

Coco Robotics, a Los Angeles-based startup known for its last-mile delivery robots, has launched a physical AI research lab led by UCLA professor Bolei Zhou, who also joins as Chief AI Scientist. read more at https://lnkd.in/gUB-5b3A Follow us for more daily global tech news stories. #LastMileDelivery #AIResearch #Innovation #TechStartup #remoteworknews #breakingnews #news #newsupdate #tech #technews #ict #technewsupdate #techworld #techgeek #geek #computer #computernews #computernewsupdate #modernlife #trends #techtrends #computertrends #icttrends #techmagazinenews #globaltech #globaltechnews #globalnewsupdate