Top News

Industry Briefing

A single destination for timely, editor-curated robotics news from around the world.

Flexiv to offer exclusive preview of next-generation robots at ICRA

Flexiv to offer exclusive preview of next-generation robots at ICRA

Flexiv, a leading provider of general-purpose robotics, is set to showcase its next-generation robotics portfolio at the International Conference on Robotics and Automation (ICRA) from June 1 to June 5 in Vienna, Austria. Attendees will have the opportunity to visit Hall B, Booth 130, for an exclusive preview of two innovative robotic platforms that promise to advance the field of robotics. This event aims to highlight Flexiv's commitment to pushing the boundaries of robotic technology and engaging with industry professionals ahead of the platforms' international launch.

Industrial robots News 7-DOF robotic arm advanced robotics ai robotics automation news
Beyond Dexterity: Why Contact May Define the Next Era of Robotics

Beyond Dexterity: Why Contact May Define the Next Era of Robotics

At the 2026 IEEE International Conference on Robotics (ICRA) in Vienna, AGILINK showcased a captivating demonstration of robotic dexterity by creating a balloon dog, which drew significant attention from attendees. This seemingly playful task is recognized in the robotics community as a complex manipulation challenge due to the balloon's lightweight and highly deformable nature. The demonstration highlighted the intricate balance between motion and contact intelligence, essential for successful robotic manipulation. AGILINK's approach involved mapping the actions of professional balloon artists to robotic hands, allowing the robot to learn both successful manipulation sequences and recovery strategies during failures. This dual focus on motion and contact intelligence is crucial, as maintaining stable interaction with the balloon is as important as executing the correct sequence of actions. In conjunction with the balloon dog demonstration, AGILINK introduced the OmniHand 3 Ultra-M, a dexterous robotic hand designed to enhance contact intelligence through advanced sensing and faster response capabilities. The hand features 20 active degrees of freedom and a direct-drive architecture, enabling precise force regulation and tactile sensing across its surface. The significance of these advancements extends beyond balloon animals, addressing broader challenges in robotics related to unstable and deformable interactions, such as delicate assembly and household tasks. As robotics research increasingly prioritizes interaction dynamics, AGILINK's innovations may pave the way for more effective manipulation in unpredictable real-world environments.

Humanoid-robots Physical-ai Dexterous-hands Direct-drive-actuation Robotic-manipulation Reinforcement-learning
Breakthrough in Mobile Electrostatic Grippers: Soft on Contact, Rigid During Transport

Breakthrough in Mobile Electrostatic Grippers: Soft on Contact, Rigid During Transport

Researchers at Harbin Institute of Technology have unveiled a groundbreaking electrostatic gripper capable of adjusting its stiffness on demand. This innovative device remains soft when in contact with objects, allowing for improved adherence, and transitions to a rigid state during transport to mitigate the risk of drop-offs caused by inertia. The development aims to enhance the stable handling of diverse surfaces and has been integrated into mobile robots, significantly boosting their operational performance. This advancement represents a significant step forward in robotic manipulation technology, promising to improve efficiency in various applications.

Electrostatic Grippers Robotics Mobile Manipulation Variable Stiffness Technology
ETH Zurich's Proprioceptive Transformer Enhances Robotic Dexterity Without Visual Cues

ETH Zurich's Proprioceptive Transformer Enhances Robotic Dexterity Without Visual Cues

Researchers at ETH Zurich have unveiled a groundbreaking Proprioceptive Transformer (PT) system that significantly enhances the capabilities of tendon-driven robotic hands. This innovative technology allows the robotic hand to execute complex manipulation tasks using only proprioceptive feedback, achieving performance levels that are three times superior to conventional methods that depend on visual input. The development addresses longstanding challenges in robotic dexterity by removing the need for external sensors, thereby enabling more efficient and precise control of robotic movements. This advancement could pave the way for more sophisticated applications in robotics, enhancing the functionality and versatility of robotic systems in various fields.

Robotic Manipulation Proprioception Soft Robotics AI Machine Learning
ETH Zurich's Breakthrough: Highly Biomimetic Pneumatic Muscle Robotic Hand Replicating Human Anatomy

ETH Zurich's Breakthrough: Highly Biomimetic Pneumatic Muscle Robotic Hand Replicating Human Anatomy

Researchers from ETH Zurich have unveiled a groundbreaking robotic hand that mimics human anatomy, utilizing advanced 3D printing techniques and 22 independently controlled pneumatic artificial muscles. This innovative development, which was announced recently, aims to significantly improve dexterity and adaptability in robotic applications. The design is rooted in detailed human anatomical data, allowing the robotic hand to perform a wide range of tasks with precision. The project is poised to advance the fields of prosthetics and enhance collaboration between humans and robots, addressing the growing need for more versatile and functional robotic systems in various sectors.

Soft Robotics Pneumatic Actuators 3D Printing Prosthetics Biomimicry
Robot Talk Episode 152 – Dexterous robot hands, with Rich Walker

Robot Talk Episode 152 – Dexterous robot hands, with Rich Walker

Claire recently spoke with Rich Walker, a key figure at Shadow Robot Company, regarding their innovative robotic hands designed for both research and industrial applications. Walker, who has been with the company since its inception, transitioned from a background in software and systems engineering to a management role, where he has played a pivotal part in the company's research and development initiatives. The discussion highlighted the advancements in robotic technology and the potential impact these developments could have across various sectors. Shadow Robot Company aims to enhance automation and precision in tasks traditionally performed by humans, showcasing the growing intersection of robotics and industry.

FingerEye bridges touch and vision to improve robot handling before and after contact

FingerEye bridges touch and vision to improve robot handling before and after contact

Researchers are advancing the capabilities of robots to perform a wider range of manual tasks by enhancing their ability to manipulate various objects. While many robotic systems have successfully mastered basic functions like picking up and transporting items, they still face challenges with more complex tasks that require dexterous handling. This development is crucial as it aims to improve the efficiency and versatility of robots in both household and professional environments. The ongoing efforts in robotics research are focused on overcoming these limitations, which could lead to significant improvements in how robots assist in everyday tasks and specialized applications.

Robotics
The Apple Peeling Milestone: How Sharpa’s "MoDE-VLA" Unlocks Bimanual Dexterity

The Apple Peeling Milestone: How Sharpa’s "MoDE-VLA" Unlocks Bimanual Dexterity

Sharpa Robotics has introduced an innovative hierarchical framework designed to enhance complex manipulation tasks that require contact-rich interactions. This new system integrates shared-autonomy data collection with a sophisticated "mixture-of-experts" AI model, enabling robots to perform intricate operations more effectively. The announcement was made in October 2023, showcasing the company's commitment to advancing robotic capabilities in various applications. By leveraging this cutting-edge technology, Sharpa Robotics aims to improve the efficiency and precision of robotic manipulation, addressing the growing demand for automation in industries that rely on complex physical tasks.

SharpaWave hand Sharpa Robotics hands Singapore
JAIST and King's College Develop EleTac Soft Gripper with Integrated Tactile Sensing

JAIST and King's College Develop EleTac Soft Gripper with Integrated Tactile Sensing

Researchers from Japan's JAIST and King's College London have developed EleTac, a soft robotic gripper inspired by the trunk of an elephant. This innovative design integrates grasping, external tactile perception, and proprioception within a single soft structure. The gripper can manipulate various objects, including tofu and fabric, while estimating contact position and force using a vacuum system operating at 30 kPa. The significance of EleTac lies in its ability to handle delicate and irregularly shaped items, addressing the challenges of soft robotics. Traditional rigid grippers utilize clear joints for sensing, while soft grippers often struggle with limited perception due to their material properties. EleTac's design allows for continuous tactile sensing across its surface, enhancing its ability to discern between self-induced deformations and external contacts. Future developments will focus on refining the visual-based tactile sensing capabilities of EleTac, which utilizes an internal optical system to monitor material deformation. This advancement could lead to improved performance in applications requiring precise manipulation of fragile objects. No further timeline was disclosed at the time of publication.

Soft Robotics Tactile Sensing Proprioception Robotic Grippers
1X Enhances NEO Humanoid Robot with Advanced 25-DOF Hands for Versatile Tasks

1X Enhances NEO Humanoid Robot with Advanced 25-DOF Hands for Versatile Tasks

Norwegian robotics firm 1X has introduced new 25-degree-of-freedom (DOF) tendon-driven hands for its NEO humanoid robot, marking a significant advancement in robotic dexterity. These hands feature 22 actuated joints across the fingers and palm, along with three at the wrist, enabling NEO to perform tasks such as assembling LEGO models and catching balls with precision and strength. The redesigned hands allow for force sensing and durability, overcoming previous hardware limitations in robotic manipulation. With a unique tendon-drive system and low gear ratios, the hands can detect contact forces and provide continuous proprioception, enhancing the robot's ability to manipulate objects safely and effectively. The hands' human-like joint distribution, particularly the opposable thumb, facilitates a wide range of fine manipulation tasks, making NEO suitable for various household applications. 1X has commenced mass production of the NEO robot at its new California facility, aiming to commercialize home robots for daily assistance. The company emphasizes the hands' combination of precision, strength, and safety features, including IP68 waterproofing and self-cleaning capabilities. No further timeline was disclosed at the time of publication.

AI and Robotics
CMU Researchers Train Robots With Internet Videos

CMU Researchers Train Robots With Internet Videos

Researchers at Carnegie Mellon University's School of Computer Science have developed an innovative system called VideoManip, which enables robots to learn manipulation skills by analyzing videos of human interactions with objects. This groundbreaking approach allows robots to reconstruct movements and understand how humans make contact with various items, significantly reducing the need for lengthy, hands-on demonstrations by humans. By utilizing readily available internet videos, the system streamlines the training process for robots, enhancing their ability to acquire new skills efficiently. This advancement marks a significant step forward in robotics, potentially transforming how machines are trained to perform tasks in diverse environments.

Research
Consistency, not complexity, is the key to teaching robots dexterity, new research suggests

Consistency, not complexity, is the key to teaching robots dexterity, new research suggests

Researchers in the field of robotics are making significant strides in teaching robots to manipulate objects with humanlike dexterity, a challenge that has persisted for years. This endeavor involves enabling robots to perform complex tasks such as rotating objects in-hand and coordinating multiple arms to handle bulky items. These tasks demand constant adjustments in grip, contact, and motion, which have proven difficult to program effectively and to demonstrate through human teleoperation. The advancements in this area are crucial for improving the functionality and versatility of robotic systems, potentially transforming industries that rely on precise manipulation, such as manufacturing and healthcare. As of October 2023, ongoing research continues to explore innovative methods to enhance robotic dexterity, paving the way for more sophisticated applications in the future.

Robotics
Video Friday: Heavy Robotic Machinery Operates Itself

Video Friday: Heavy Robotic Machinery Operates Itself

IEEE Spectrum robotics has released its latest edition of "Video Friday," showcasing a variety of innovative robotics videos and announcing upcoming robotics events. Notable conferences include ICRA 2026 in Vienna from June 1-5, and the Summer School on Multi-Robot Systems in Prague from July 29 to August 4, 2026. Among the featured content is a groundbreaking autonomous material-handling solution developed by ETH Zurich, capable of operating a 40-ton material handler, traditionally a labor-intensive task. Other highlights include the introduction of the world's first production-ready manned mecha by Unitree, and the launch of NIX, an embodied AI exploring dance and movement, which will be made available for free to select partners. NTNU has unveiled the Unified Autonomy Stack, a robust system designed for aerial and ground robots, enhancing their autonomy through advanced perception and navigation capabilities. This system has been validated in challenging environments, showcasing its effectiveness in exploration and object discovery. Robotics expert Rodney Brooks, cofounder of Robust AI, shared insights on the challenges of innovation in robotics and the implications of the current AI surge during a Q&A session ahead of his panel at the Forbes America Innovates event in San Francisco. As the field continues to evolve, the integration of data collection methods remains a significant challenge, with the Koala platform exemplifying innovative approaches to enhance robotic manipulation tasks.

Home-robots Humanoid-robots Video-friday Material-handling-technology Robot-videos Robot-grippers
Chinese University Develops OriCube Sensor to Enhance Robot Tactile Sensitivity

Chinese University Develops OriCube Sensor to Enhance Robot Tactile Sensitivity

Researchers from the University of Science and Technology of China have developed the OriCube, a compact six-dimensional force/moment sensor that mimics human fingertip sensitivity. Measuring just 14×14×12 mm and weighing 4 grams, it achieves a remarkable resolution of 3 millinewtons within a 23-newton range, allowing it to detect even the lightest touch, such as a feather. This innovation is significant as it addresses the limitations of current robotic tactile solutions, which often rely on electronic skin or array sensors that face challenges like complex wiring and data processing. By embedding the OriCube directly into the fingertips of robotic hands, the sensor captures minute force changes and calculates precise contact points and force vectors, offering a new approach to tactile perception in robotics. The OriCube has demonstrated low power consumption of 45 milliwatts, minimal crosstalk, and high measurement accuracy. Its ability to sense both delicate touches and withstand impacts positions it as a robust solution for enhancing robotic dexterity in uncertain environments. No further timeline was disclosed at the time of publication.

Robotics Tactile Sensors Force Sensing Artificial Intelligence
1X Launches Neo Robotic Hand Featuring 25 Degrees of Freedom and Force Transparency

1X Launches Neo Robotic Hand Featuring 25 Degrees of Freedom and Force Transparency

On July 9, 2026, 1X, a unicorn supported by OpenAI, unveiled the Neo robotic hand designed for humanoid robots. This advanced hand boasts 25 degrees of freedom, enabling it to perform a wide range of human-like tasks, such as delicately picking grapes without crushing them and lifting weights up to 20 pounds. The innovative design incorporates a tendon-driven system that enhances dexterity and responsiveness. The significance of the Neo robotic hand lies in its unique 'Force Transparency' technology, which allows for bidirectional communication between the hand and its environment. Unlike traditional robotic hands that operate with high gear ratios, the Neo hand utilizes a low gear ratio of approximately 5:1 to 15:1, enabling it to provide real-time feedback on applied forces. This design not only enhances the hand's functionality but also improves the training of AI models by providing rich physical interaction data. Looking ahead, while the Neo hand addresses fundamental perception challenges, real-world complexities remain a concern. The hand must operate effectively in various domestic environments, where it may encounter grease, sauces, or dust. Ensuring safety during interactions with children and maintaining functionality in challenging conditions will be critical for the widespread adoption of this technology. No further timeline was disclosed at the time of publication.

Robotic Hands Humanoid Robots AI Tactile Sensors Robotics Technology
New color-changing tactile sensor gives robots a real-time sense of touch

New color-changing tactile sensor gives robots a real-time sense of touch

Researchers have developed an innovative color-changing tactile sensor that enables machines to perceive and respond to their surroundings in real-time. This groundbreaking technology was unveiled in October 2023 and represents a significant advancement in the field of robotics and artificial intelligence. The sensor mimics the way humans and animals sense touch and texture, providing machines with the ability to "see" and interpret the materials they come into contact with. The motivation behind this development lies in enhancing the interaction between machines and their environment, allowing for more sophisticated and responsive robotic systems. By integrating this tactile sensor, robots can better understand the properties of objects, leading to improved performance in various applications, such as manufacturing, healthcare, and service industries. The process involves a combination of advanced materials and engineering techniques that allow the sensor to change color based on the pressure and texture of the surfaces it touches. This visual feedback not only aids in object recognition but also enhances the machine's ability to make informed decisions based on tactile information. As this technology continues to evolve, it holds the potential to revolutionize how machines interact with the world, paving the way for smarter, more adaptable robotic systems that can operate effectively in diverse environments.

AI and Robotics
Robots can now 'see' touch thanks to a new color-changing tactile sensor

Robots can now 'see' touch thanks to a new color-changing tactile sensor

Engineers at Queen Mary University of London have developed an innovative color-changing tactile sensor that enables robots to perceive their environment through both sight and touch in real-time. The groundbreaking invention, led by postdoctoral researcher Giacomo Sasso from the School of Engineering and Materials Science, utilizes a unique mechanism that converts invisible forces into vibrant color patterns. This technology allows for the immediate generation of high-resolution maps detailing contact, strain, and pressure, significantly enhancing robotic interaction with their surroundings. The advancement promises to improve the capabilities of robots in various applications, from manufacturing to healthcare, by providing them with a more nuanced understanding of their physical interactions.

Robotics
Robotic arm inspired by octopus uses tactile sensors in suction cups for autonomous underwater grasping

Robotic arm inspired by octopus uses tactile sensors in suction cups for autonomous underwater grasping

A research team led by Barbara Mazzolai at the Istituto Italiano di Tecnologia (IIT) has unveiled an innovative octopus-inspired soft robotic arm. This development, which emerged from the Bioinspired Soft Robotics unit, showcases advanced technology that allows the robotic arm to autonomously grasp objects in challenging environments, including underwater. The arm's artificial suction cups are equipped with sensors that can detect contact and assess the intensity and direction of applied forces. This breakthrough, announced recently, highlights the potential of oceanic biology to inspire future robotics solutions, emphasizing the importance of nature as a model for technological advancements.

Robotics
Why is Cobot Polishing Important for Electronics and Auto Parts Quality?

Why is Cobot Polishing Important for Electronics and Auto Parts Quality?

In the high-end electronics and automotive manufacturing sectors, the introduction of collaborative robots, or cobots, is revolutionizing the surface finishing process. Traditionally reliant on manual labor, which often resulted in inconsistencies and human error, these industries are now leveraging advanced technology to enhance quality and efficiency. The challenge of polishing complex geometries—such as intricate smartphone frames and engine components—has been addressed through the implementation of force-controlled cobots. Unlike conventional robots, these cobots can adjust their pressure in real-time, ensuring uniform contact with varying surface shapes. This capability is crucial for maintaining the integrity of delicate materials and achieving high-quality finishes. The benefits of adopting cobot polishing are significant. They provide consistent pressure across multiple parts, reducing batch variance and ensuring compliance with strict OEM standards. Additionally, the precision of these robots minimizes scrap rates, translating to substantial cost savings in industries where material expenses are critical. Furthermore, by automating the polishing process, human workers can avoid exposure to hazardous dust, allowing them to focus on higher-level tasks. JAKA has developed the S series of collaborative robots, specifically designed for force-sensitive applications. The JAKA S5 model, with its advanced force sensors and agile design, is particularly suited for the electronics and automotive industries. It offers features such as constant force tracking and wireless management through the JAKA App, enhancing the precision and adaptability of the polishing process. By integrating these intelligent robots into their operations, manufacturers are moving towards achieving near-zero defect rates, setting a new standard for quality in surface finishing.

Integrating Force/Torque Sensors into the Flange of an Articulated Robot Arm

Integrating Force/Torque Sensors into the Flange of an Articulated Robot Arm

In the evolving field of automation, the integration of force/torque (F/T) sensors into robotic systems has become essential for enhancing precision and safety in industrial applications. Traditional robots, which operate on pre-programmed coordinates, are now being outpaced by articulated robots equipped with these advanced sensors. By embedding the sensors directly into the mounting flange—where the robot arm connects to its tool—manufacturers can achieve unprecedented levels of responsiveness to physical resistance in real-time. These 6-axis F/T sensors measure both linear forces and rotational torques, allowing for accurate data collection at the point of contact. This capability is particularly crucial in tasks such as delicate component insertion and high-precision screwdriving, where even minor deviations in force can lead to damage. Additionally, the integration of these sensors enhances the robot's operational intelligence, enabling features like active gravity compensation and improved collision detection, which contribute to a safer collaborative environment for human operators. JAKA has taken significant strides in this area with its S series robots, which feature built-in high-accuracy force sensors that eliminate the need for bulky external attachments. This design not only preserves the robot's agility but also enhances its sensitivity, facilitating smoother operation during complex tasks in sectors like electronics and industrial welding. With an accuracy of 1% FS and a distinguishability of 0.1N, JAKA's technology allows for real-time force monitoring and simplifies the debugging process, ultimately leading to more efficient and reliable production lines.

Assembler Robots in Medical Device Manufacturing: Precision and Sterilization

Assembler Robots in Medical Device Manufacturing: Precision and Sterilization

In the rapidly evolving field of medical device manufacturing, JAKA is at the forefront of integrating assembler robots into production lines to enhance precision and maintain strict sterilization standards. These advanced 6-axis robot arms are designed to navigate the complexities of assembling miniature components and delicate materials, ensuring stable motion control and predictable positioning throughout long operating cycles. By minimizing human contact in sensitive environments, JAKA's automation solutions help reduce contamination risks and support adherence to sterilization protocols. The implementation of these robots allows manufacturers to adapt to cleanroom layouts while remaining flexible enough to accommodate product changes. JAKA's lightweight robotic structures can be quickly deployed and adjusted, making them ideal for small-batch and multi-variety manufacturing, which is prevalent in the medical sector. This adaptability not only prevents workpiece loss but also enhances productivity without compromising quality. As the demand for precision and efficiency in medical device assembly continues to grow, JAKA's focus on practical automation solutions positions them as a key player in the industry. Their commitment to developing reliable motion control and adaptive assembly logic ensures that manufacturers can achieve consistent performance while navigating the challenges of regulated production environments. By leveraging the capabilities of assembler robots, JAKA is paving the way for more controlled and efficient medical device manufacturing processes.

Three Essential Features of a High-Performance Robotic Arm Component

Three Essential Features of a High-Performance Robotic Arm Component

In the evolving landscape of modern manufacturing, JAKA is redefining the criteria for selecting industrial robot arms, emphasizing the importance of precision, flexibility, and safety over mere automation speed. The company focuses on developing robotic systems that ensure engineering reliability and practical usability, which are crucial for meeting the dynamic demands of production environments. Key features of high-performance robotic arms include the ability to maintain stable processing precision, which directly impacts product quality and defect control. JAKA’s design prioritizes controlled motion, allowing manufacturers to achieve consistent results and reduce defect rates, thereby enhancing overall process reliability with minimal manual intervention. Additionally, the adaptability of robotic arms is vital for responding to changing production needs. JAKA’s Pro5 model offers reprogrammable functions that enable quick adjustments to workflows, facilitating efficient product modifications without the need for extensive equipment investment. This flexibility is particularly beneficial in mixed-production settings where rapid changes are commonplace. Safety is another critical aspect of JAKA’s robotic arm components. By automating hazardous or repetitive tasks, these systems minimize direct operator contact with potentially dangerous equipment, thereby reducing the risk of accidents on the production floor. By integrating these essential features—precision, reprogrammability, and safety—JAKA aims to support manufacturers in achieving reliable production outcomes and fostering safer, more adaptable manufacturing processes. This approach not only enhances quality control but also enables companies to respond effectively to market changes over time.

RobotToday Initiative

Robotics needs a service framework.

RSF defines a common language for robot service capability, lifecycle operations, certification pathways, and service-provider networks.