Industry Briefing
A single destination for timely, editor-curated robotics news from around the world.
PSYONIC partners with ABB Robotics to apply human touch to robot dexterity
PSYONIC has announced a collaboration with ABB Robotics to enhance robotic dexterity by integrating its Ability Hand prosthetic with ABB's GoFa collaborative robot arm. This partnership aims to leverage data collected from prosthetic users to improve the robot's grasping capabilities, effectively mimicking human touch. The initiative underscores the growing intersection of robotics and prosthetics, with the goal of creating more intuitive and responsive robotic systems. The collaboration reflects a commitment to advancing technology that not only aids individuals with disabilities but also enhances the functionality of robotic devices in various applications.
Arms / Manipulators Artificial Intelligence Automotive Cobot Arms Collaborative Robots End Effectors / Grippers
The tenured engineers of 2026
Ten faculty members at the Massachusetts Institute of Technology (MIT) have been awarded tenure, marking a significant milestone in their academic careers. This decision, announced recently, affects five different units within the School of Engineering, highlighting the institution's commitment to fostering academic excellence and innovation. The tenure grants are intended to recognize the contributions and potential of these faculty members, who have demonstrated exceptional research and teaching capabilities. By securing tenure, these educators will gain increased job security and the opportunity to pursue long-term projects that can further advance their fields. This announcement underscores MIT's ongoing efforts to support its faculty and enhance its educational environment.
Awards, honors and fellowships Faculty Aeronautical and astronautical engineering Civil and environmental engineering Electrical engineering and computer science (EECS) Mechanical engineering
US: Los Alamos lab’s new tool detects hallucinations in machine vision models
Researchers at Los Alamos National Laboratory have unveiled a groundbreaking tool named Prelim Attention, designed to enhance the analysis of complex data sets. This innovative tool, which leverages advanced machine learning techniques, aims to streamline the process of identifying significant patterns and insights within large volumes of information. The development was announced in October 2023, highlighting the laboratory's commitment to advancing data science and its applications in various fields. The motivation behind creating Prelim Attention stems from the increasing demand for efficient data analysis solutions in scientific research, national security, and other sectors that rely heavily on data interpretation. By improving the capability to focus on critical data points, the tool is expected to facilitate more informed decision-making and accelerate research outcomes. The researchers employed a combination of algorithms and user-friendly interfaces to ensure that Prelim Attention can be utilized effectively by both experts and non-experts alike. This approach not only enhances accessibility but also broadens the potential user base, allowing a wider range of professionals to benefit from its capabilities. The introduction of Prelim Attention marks a significant advancement in the field of data analysis, promising to transform how researchers and analysts approach complex data challenges in the future.
AI and Robotics
MIT affiliates win 2026 Hertz Foundation Fellowships
A new fellowship program has been launched to support doctoral students in applied sciences, engineering, and mathematics who are dedicated to addressing critical challenges in science and technology. This initiative aims to recognize and empower emerging researchers who are developing innovative solutions to pressing issues. The program is designed to enhance the educational and research opportunities for these students, providing them with the resources necessary to advance their work. By fostering a new generation of scientists and engineers, the fellowship seeks to contribute to the advancement of knowledge and technology, ultimately benefiting society as a whole. The initiative is expected to play a significant role in shaping the future of scientific research and technological development.
Awards, honors and fellowships Students Graduate, postdoctoral Alumni/ae Chemistry Mechanical engineering
Can Pepper the robot be a good playmate?
Researchers at the Norwegian University of Science and Technology (NTNU) recently conducted a controlled laboratory experiment to explore the dynamics of playing physical games with a humanoid robot named Pepper. The study aimed to understand how interactions with a robot that mimics human behavior and appearance influence gameplay experiences. By engaging participants in various physical games against Pepper, the researchers sought to assess both the emotional and cognitive responses elicited by the robot's presence. This investigation is part of a broader effort to enhance human-robot interaction, particularly in social and recreational contexts. The findings could have implications for the development of more effective robots in various fields, including education and therapy, by fostering a better understanding of how humans relate to robotic counterparts.
Consumer & Gadgets
How JPL Keeps the 13-Year-Old Curiosity Rover Doing Science
The Curiosity rover, which has been exploring Mars for 13 years, continues to operate effectively despite the challenges of its hostile environment. Since its successful landing in August 2012 at the Jet Propulsion Laboratory (JPL) in Pasadena, California, Curiosity has traveled nearly 37 kilometers, drilled into 42 rocks, and captured approximately 763,000 images. JPL engineers, including assistant team chief Alexandra Holloway, have implemented ongoing software updates and innovative solutions to keep the rover functional, even as it faces wear and diminishing power. Holloway highlighted the rover's longevity, attributing it to robust engineering and continuous maintenance efforts. While Curiosity and the younger Perseverance rover share similar hardware, Perseverance features additional capabilities for autonomous navigation, reflecting their distinct mission objectives. Curiosity's operational challenges include wheel wear from sharp rocks and power consumption from its nuclear source, which decreases over time. Engineers have developed strategies to optimize power usage, such as reducing computer activation time and parallel processing tasks. Looking ahead, Holloway noted that while Curiosity's arm may eventually fail, the rover still possesses valuable remote sensing instruments that will contribute to future Mars exploration. With its power source expected to remain viable through at least 2035, Curiosity's mission continues to yield significant scientific insights, paving the way for future missions.
Curiosity-rover Mars Jpl
Improving the performance of high-power electronics
Researchers have discovered that applying a thin layer of diamond can significantly enhance the speed and energy efficiency of next-generation wireless devices. This innovative approach addresses the challenge of excessive heat generated during device operation, which has been a limiting factor in the performance of modern technology. The findings, which emerged from ongoing studies in advanced materials science, highlight the potential for diamond to serve as an effective thermal management solution. This breakthrough could pave the way for faster and more efficient wireless communication, ultimately benefiting consumers and industries reliant on high-performance devices.
Research Computer chips Electronics Carbon materials Nanoscience and nanotechnology Mobile devices
Cambridge’s new robot could help solve millions of years old evolution mystery
A team of scientists from Cambridge University has unveiled a groundbreaking robot designed to assist in unraveling complex biological processes. This innovative technology, introduced on October 15, 2023, aims to enhance research in the field of genetics and molecular biology. The robot operates by automating intricate laboratory tasks, which traditionally required significant human intervention, thereby increasing efficiency and accuracy in experiments. The motivation behind this development stems from the growing need for advanced tools that can accelerate scientific discovery and improve the understanding of genetic disorders. By streamlining repetitive tasks, the robot allows researchers to focus on more critical aspects of their studies, potentially leading to faster breakthroughs in medical research. The team utilized cutting-edge artificial intelligence and machine learning algorithms to program the robot, enabling it to adapt and learn from its environment. This adaptability is expected to make the robot a valuable asset in various research settings, paving the way for more innovative approaches to tackling biological challenges. As the scientific community continues to seek solutions to pressing health issues, this robot represents a significant step forward in leveraging technology to enhance research capabilities and outcomes.
RoboChem Flex: democratisation of the autonomous synthesis robot
Researchers from the University of Amsterdam’s Van ’t Hoff Institute for Molecular Sciences, led by Professor Timothy Noël, have made significant advancements in autonomous laboratory systems aimed at optimizing synthesis processes. Their findings, published in the journal Nature Synthesis, introduce RoboChem Flex, a versatile and modular system that incorporates “human-in-the-loop” analytics. This innovative design allows for enhanced flexibility and efficiency in chemical synthesis, potentially transforming how laboratories conduct research and development. The study highlights the growing importance of automation in scientific research, driven by the need for more efficient and accurate synthesis methods.
Vbot Delivers First Robot Dog to Horizon Robotics Founder, Marking Consumer Embodied AI Milestone
Vbot, a company specializing in embodied artificial intelligence, has made a significant leap in the robotics industry by delivering its first quadruped robot dog to Dr. Yu Kai, the founder of Horizon Robotics. This milestone marks a pivotal transition from laboratory demonstrations to actual consumer delivery, highlighting the growing accessibility of advanced robotic technology. The delivery took place recently, showcasing Vbot's commitment to bringing innovative AI solutions into everyday life. The introduction of this robot dog not only represents a technological advancement but also reflects the increasing demand for personal robotics among consumers.
Robotics
NVIDIA releases new and updated tools for physical AI developers
NVIDIA has unveiled a suite of open-source tools and skills designed for developers working with physical AI agents, alongside the introduction of the Isaac GR00T humanoid reference robot. This announcement, aimed at enhancing the capabilities of AI in real-world applications, reflects NVIDIA's commitment to advancing robotics and AI technology. The release is part of the company's ongoing efforts to foster innovation within the AI community, providing developers with the resources necessary to create more sophisticated and capable physical AI systems. The tools and the humanoid robot were made available recently, signaling a significant step forward in the integration of AI into practical robotics.
Artificial Intelligence Artificial Intelligence / Cognition Automotive Autonomous Mobile Robots (AMRs) Development Tools / SDKs / Libraries Healthcare Robotics
NVIDIA Research Advances Robotics From Simulation to the Real World
At the International Conference on Robotics and Automation (ICRA), NVIDIA Research showcased advancements in robotics that signal a significant shift towards achieving reliable embodied autonomy in real-world applications. This transition marks a departure from traditional controlled demonstrations and scripted automation, emphasizing the need for robots to operate effectively in unpredictable environments. The event, held recently, highlighted eight innovative projects that illustrate how robotics can adapt and function autonomously outside of laboratory settings. This evolution is driven by the increasing demand for robots to perform complex tasks in diverse scenarios, enhancing their utility across various industries. By leveraging cutting-edge technology and research, NVIDIA aims to pave the way for a future where robots can seamlessly integrate into everyday life, improving efficiency and productivity.
China tests humanoid robots in tea farms before the 2026 World Robot Games
Humanoid robots are making significant strides beyond laboratory demonstrations, now being deployed in tea fields. This advancement marks a notable shift in the application of robotics, showcasing their potential to assist in agricultural tasks. The development comes as part of ongoing efforts to enhance efficiency and productivity in farming, particularly in regions where labor shortages are prevalent. By integrating advanced robotics into everyday agricultural practices, researchers and engineers aim to address the challenges faced by the agricultural sector, including the need for sustainable farming solutions. The implementation of these robots in tea cultivation is expected to streamline operations, allowing for more precise and consistent harvesting methods. As this technology continues to evolve, it holds promise for transforming not only tea production but also other agricultural industries worldwide.
Video Friday: Atlas Versus a Fridge
IEEE Spectrum robotics has released its latest edition of "Video Friday," showcasing a variety of innovative robotics videos and announcing upcoming robotics events scheduled for 2026. Notable events 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. Among the highlights, Boston Dynamics' Atlas robot demonstrates significant advancements in strength and adaptability, showcasing its ability to lift heavy objects and navigate complex environments using advanced reinforcement learning and control systems. This marks a pivotal moment for humanoid robots as they transition from laboratory settings to dynamic industrial applications. Additionally, the SpikerBot, a robot designed to be programmed by wiring neurons instead of traditional coding, has successfully reached its funding goal on Kickstarter. Other innovations include wheeled-legged robots that enhance mobility and a biomimetic robotic hummingbird developed at the Advanced Vertical Flight Laboratory, which mimics natural flight dynamics. The release also features advancements in construction technology, with Dusty Robotics introducing the FieldPrinter 2, a more efficient and intelligent version of its predecessor, and Noble Machines showcasing their autonomous robots designed for hazardous industrial tasks at NVIDIA GTC 2026. These developments reflect a broader trend in robotics, where technology is increasingly integrated into real-world applications, enhancing efficiency and safety across various industries.
Humanoid-robots Video-friday Robot-videos Educational-robots Biomimetics Quadruped-robots
DARPA’s robotic servicing spacecraft to finally fly this summer
The Robotic Servicing of Geosynchronous Satellites mission, a collaboration between DARPA and Northrop Grumman, is set to establish the United States' first on-orbit servicing capability for satellites. This groundbreaking initiative aims to enhance satellite maintenance and repair, extending the operational lifespan of critical space assets. Company officials announced the mission's significance, highlighting its potential to revolutionize satellite operations and reduce costs associated with launching new satellites. The project is expected to take place in the coming months, marking a pivotal advancement in space technology and satellite management.
Space darpa Defense Advanced Research Projects Agency Naval Research Laboratory Northrop Grumman on-orbit refueling
Opentrons launches Compliance Ready Software for Flex lab robots
Opentrons has announced the launch of its Compliance Ready Software, designed specifically for its Flex laboratory robots, which are now deployed in over 10,000 facilities globally. This new software enables these robots to adhere to stringent FDA regulations, enhancing their usability in regulated environments. The introduction of this software is a significant advancement for Opentrons, as it aims to streamline laboratory processes and ensure compliance with industry standards. By integrating this technology, the company seeks to expand the capabilities of its robotic systems, making them more accessible for laboratories that require adherence to strict regulatory frameworks.
Academia / Research Healthcare Robotics Laboratory / Cleanroom News Regulatory & Compliance Laboratory Automation
Single-molecule tracker illuminates workings of cancer-related proteins
A team of researchers has developed advanced microscopy and nanotechnology techniques to monitor the activity of individual proteins in real-time. This innovative approach allows scientists to gain unprecedented insights into protein dynamics, which are crucial for understanding various biological processes and diseases. The research, conducted in a state-of-the-art laboratory, aims to enhance the understanding of cellular mechanisms and potentially lead to breakthroughs in medical treatments. By tagging proteins with custom-built nanotechnology, the team can visualize and track their movements and interactions, providing valuable data that could inform future studies in biochemistry and molecular biology. This work represents a significant advancement in the field, promising to deepen our comprehension of life at the molecular level.
Research Proteins Cells Chemistry Imaging Cancer
Home Robot Safety Is All About Relationships
The International Standards Organization (ISO) is in the process of updating its safety requirements for personal care robots, a revision that has not occurred in 12 years. This update comes at a crucial time as manufacturers transition from laboratory prototypes to products designed for real-world domestic environments. The proposed changes focus on hazard identification and risk assessment but lack binding compliance criteria and testing methods to address the complexities of human-robot interactions. Jae-Seong Lee, a technology policy researcher from South Korea's Electronics and Telecommunications Research Institute, emphasizes that safety in domestic settings is not merely about avoiding collisions; it involves understanding the dynamic relationship between humans and robots. Current standards, such as ISO 13482, acknowledge various hazards but do not fully translate this knowledge into enforceable rules. The challenge lies in ensuring that robots can operate safely in unpredictable home environments, which differ significantly from controlled industrial settings. Moreover, the standards process has been criticized for not adequately representing the perspectives of older adults, who are often the primary users of these robots. Lee warns that if safety assumptions are embedded in products without thorough scrutiny, it could lead to significant risks, including potential injuries. He advocates for a shift in focus from machine-centric safety measurements to a more holistic approach that considers the interactions between humans and robots. This revision aims to address these pressing concerns, although many unresolved issues remain in advisory language rather than binding regulations.
Home-robots Domestic-robots Standards Iso Robot-safety
New research enables a robot to chart a better course
A new open-source system called “MIGHTY” has been developed to enhance efficiency in disaster recovery and parcel delivery by creating optimized travel routes. This innovative technology generates smooth path plans that significantly reduce travel time while effectively navigating around obstacles. The system aims to address the challenges faced during emergencies and improve logistics operations. By leveraging advanced algorithms, MIGHTY is designed to facilitate quicker responses in critical situations, ultimately aiming to save lives and resources. The initiative is expected to be particularly beneficial in areas prone to natural disasters, where timely assistance is crucial.
Research Computer science and technology Algorithms Drones Robotics Autonomous vehicles
US scientists are building autonomous robots that can learn directly from researchers
Researchers at Argonne National Laboratory are advancing the field of laboratory automation by creating AI-powered robotic assistants capable of learning and performing various laboratory procedures. This innovative project aims to enhance efficiency and accuracy in scientific research, addressing the growing demand for streamlined processes in laboratories. The development is part of a broader effort to integrate artificial intelligence into everyday scientific tasks, allowing researchers to focus on more complex problem-solving. As the project progresses, the team is exploring various machine learning techniques to enable these robots to adapt and improve their skills over time. This initiative is expected to revolutionize how experiments are conducted, ultimately accelerating the pace of scientific discovery.
Agentic AI for Robot Teams
Researchers at the Johns Hopkins Applied Physics Laboratory are making strides in the development of agentic artificial intelligence aimed at enhancing collaborative robotic teams. During a recent presentation, they outlined the significant challenges associated with achieving autonomy, coordination, and adaptability among diverse robotic systems. To address these issues, the team introduced a scalable architecture designed to facilitate agentic behaviors in multi-robot environments. The presentation also featured demonstrations of this innovative approach, showcasing its application in hardware with a varied group of robots. Additionally, the researchers shared valuable insights gained from their ongoing research and development efforts, highlighting key challenges faced and lessons learned throughout the process. This work not only advances the field of robotics but also sets the stage for future developments in agentic AI technology.
Type-webinar Agentic-ai Robotics Llms
Argonne Researchers to Develop Learning-Based Robots as Step Toward a Scientific Assistant
Researchers are exploring the potential of robots that can not only conduct experiments but also learn and adapt alongside human scientists. This initiative aims to develop advanced robotic systems capable of functioning in real laboratory settings, allowing them to respond to dynamic conditions and collaborate effectively with their human counterparts. By integrating machine learning and artificial intelligence, these robots could enhance scientific research, increasing efficiency and innovation in various fields. The project is currently in its developmental stages, with ongoing studies focused on refining the robots' capabilities to ensure they can seamlessly integrate into existing scientific workflows. As this technology evolves, it holds the promise of transforming the landscape of scientific inquiry and experimentation.
Fraunhofer IPA offers new test benchmark for humanoids
Fraunhofer IPA has introduced a new benchmark aimed at evaluating humanoid robots for industrial applications. This initiative addresses the need for standardized criteria that can be utilized by third-party analysts to assess the performance and suitability of these robots in various industrial settings. The development of this benchmark reflects the growing demand for reliable and efficient humanoid robots in the workforce, as industries seek to enhance productivity and automate processes. By providing a structured framework for evaluation, Fraunhofer IPA aims to facilitate the integration of humanoid robots into industrial environments, ensuring they meet specific operational requirements.
Actuators / Motors / Servos Arms / Manipulators Batteries / Power Supplies Cameras / Imaging / Vision Controllers End Effectors / Grippers
Biomedical jellyfish-inspired robot hits record swim speeds without onboard power
Researchers have developed a groundbreaking jellyfish-inspired soft robot capable of navigating through water at unprecedented speeds. This innovative technology, unveiled in a recent study, showcases the potential for advanced underwater exploration and environmental monitoring. The robot mimics the unique propulsion mechanism of jellyfish, allowing it to move efficiently and swiftly. The development took place in a laboratory setting, where scientists aimed to enhance robotic mobility in aquatic environments. By studying the biomechanics of jellyfish, the team was able to replicate their movement patterns, resulting in a soft robot that not only moves faster than existing models but also carries out tasks such as data collection and monitoring marine ecosystems. This advancement comes at a crucial time as researchers seek sustainable solutions for underwater exploration, driven by the need to better understand and protect marine life. The soft robot's design allows for flexibility and adaptability, making it suitable for various applications, from scientific research to environmental conservation efforts. As the technology progresses, the team envisions further enhancements that could lead to even greater speeds and capabilities, paving the way for a new era of robotic exploration in our oceans.
Japan: World-first fully automated medicine lab with humanoids, robots and no humans
A Japanese university has inaugurated a cutting-edge robotics laboratory aimed at advancing medical research through automation. This initiative, which commenced recently, allows robots to perform complex medical experiments that were traditionally conducted by human researchers. The university's goal is to enhance the efficiency and accuracy of medical studies, addressing the growing demand for innovative solutions in healthcare. By integrating robotics into the research process, the institution hopes to accelerate discoveries and improve patient outcomes. The laboratory is equipped with state-of-the-art technology designed to facilitate a wide range of experiments, showcasing the potential of robotics in transforming the medical field.
Video Friday: AI Gives Robot Hands Human-Like Dexterity
IEEE Spectrum robotics has released its weekly roundup of notable robotics videos, along with a calendar of upcoming robotics events scheduled for 2026. Key events 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. Among the highlights is the introduction of GENE-26.5, an AI brain that enables robots to perform complex tasks such as cooking, conducting lab experiments, and playing the piano, showcasing significant advancements in robotic capabilities. Another featured robot, Labububot, is a unique creation that critiques social robots through its design, merging various pop culture elements into a single entity. In other developments, NASA's Jet Propulsion Laboratory is testing next-generation helicopter rotor blades on Mars, achieving speeds that exceed Mach 1 in a simulated Martian atmosphere. Additionally, Boston Dynamics is balancing commercial interests with robotics research through its Atlas robot, while the Robomechanics Lab has introduced Sally, a magnetic-wheeled robot designed for inspecting steel structures, capable of navigating challenging interior corners. These innovations reflect the ongoing evolution in robotics, driven by advancements in AI and engineering, as the field continues to explore new applications and capabilities.
Humanoid-robots Video-friday Manipulation Robot-videos Autonomous-robots Quadruped-robots
Finnish AI Lab QuTwo Valued at $380M After Angel Round Backed by Yuri Milner and Xavier Niel
QuTwo, a Finnish artificial intelligence laboratory established by Peter Sarlin, the former CEO of AMD Silo AI, has successfully secured €25 million in an angel funding round, achieving a valuation of €325 million. The investment round attracted notable figures, including Yuri Milner, Xavier Niel, and Nico Rosberg, as well as founders from prominent companies such as Skype, Wolt, and Supercell. QuTwo's flagship product, QuTwo OS, serves as an AI orchestration layer designed to enhance the integration and functionality of AI technologies. This funding will enable the company to further develop its innovative solutions in the rapidly evolving AI landscape.
AI Funding & Investment AI AI-driven platform Angel round capital markets funding
UK Dstl develops AIM to unify messaging across military systems
The UK Defence Science and Technology Laboratory (Dstl) has developed a new digital messaging system called Assured Intent Messaging (AIM). This innovative platform aims to enhance communication across various military technologies, ensuring a more cohesive and efficient exchange of information. The initiative reflects the UK's commitment to improving military operations and interoperability among different systems. By integrating diverse communication methods, AIM seeks to address existing challenges in military coordination, ultimately enhancing operational effectiveness. The introduction of this system marks a significant advancement in military communication technology, with potential implications for future defense strategies.
News
New 3D-printed battery electrodes double storage capacity across 7,500 charge cycles
Researchers at Lawrence Livermore National Laboratory (LLNL) have unveiled an innovative 3D-printed electrode design aimed at enhancing electrochemical processes. This breakthrough, announced recently, promises to improve the efficiency and performance of energy storage systems, such as batteries and fuel cells. The development comes in response to the growing demand for advanced energy solutions that can support sustainable technologies and reduce reliance on fossil fuels. By leveraging 3D printing techniques, the team has created a more intricate and optimized electrode structure that allows for better ion flow and increased surface area, ultimately leading to higher energy density and faster charging times. This advancement could play a crucial role in the transition to cleaner energy sources, addressing both environmental concerns and the need for more efficient energy storage solutions in various applications.
Powering 160,000 hours of discovery at MIT.nano
The NanoFab Equipment Management and Operations (NEMO) system has been introduced to enhance the management of shared facilities, focusing on tool training, reservations, and lab communications. This innovative platform aims to streamline operations for users, ensuring efficient access to equipment and resources. The system is designed to support collaborative research environments by providing a centralized hub for managing various aspects of facility usage. With the implementation of NEMO, users can expect improved coordination and communication within the lab, ultimately fostering a more productive research atmosphere. The rollout of this system is expected to significantly benefit researchers and technicians alike, facilitating a smoother workflow and better resource allocation.
Facilities Research Open source Collaboration Software Nanoscience and nanotechnology
It took 40 years for technology to catch up to this zipper design
MIT Professor Bill Freeman has introduced an innovative fastener known as the "Y-zipper," which is designed to transform gear, robots, and art with ease. This three-sided fastener allows users to snap items into shape at the push of a button, significantly enhancing convenience and functionality. The concept draws inspiration from an old patent held by Freeman, showcasing the potential for advancements in design and technology. The development of the Y-zipper reflects a growing interest in creating user-friendly solutions that streamline the assembly and manipulation of various objects. As this technology gains attention, it could pave the way for new applications across multiple industries.
Research Invention Design Robotics 3-D printing Wearables
How neurons sense bacteria in the gut
A recent study has uncovered significant insights into how neurons interact with bacteria and their effects on animal brains. Researchers focused on nematodes to explore the mechanisms by which a specific neuron detects bacterial signals. This investigation sheds light on the intricate relationship between neural activity and microbial presence, highlighting the potential implications for understanding brain function in various organisms. The findings, which emerged from laboratory experiments conducted in October 2023, aim to deepen our comprehension of the sensory processes involved in neuronal responses to bacterial stimuli. This research could pave the way for future studies on the broader impacts of bacteria on neurological health and behavior.
Research Bacteria Neuroscience Microbiome Brain and cognitive sciences Picower Institute
A KUKA robot works as a lab assistant at Anton Paar
At Anton Paar GmbH, a KUKA robot named KR AGILUS is revolutionizing laboratory operations by automating the process of placing samples for testing and disposing of them afterward. This innovation significantly reduces the workload for lab technicians, allowing them to focus on more complex tasks. The robot operates continuously, ensuring quality control by utilizing a rheometer for precise measurements. This advancement not only enhances efficiency but also streamlines the testing process, demonstrating the growing integration of robotics in laboratory settings. As of October 2023, the KR AGILUS exemplifies how automation can transform traditional workflows in scientific research and quality assurance.
AI robotics: Moving from the lab to the real-world factory floor
Industry leaders from Universal Robots, PickNik, and Path Robotics gathered to discuss the complexities involved in transitioning AI robotics from laboratory settings to practical applications on factory floors. This event highlighted the significant infrastructure and effort necessary for successful deployment, addressing the challenges and innovations that accompany this technological shift. By sharing insights and experiences, these experts aim to foster a deeper understanding of how AI robotics can enhance manufacturing processes and improve operational efficiency. The discussions took place recently, reflecting a growing interest in integrating advanced robotics into real-world industrial environments.
Artificial Intelligence Artificial Intelligence / Cognition Educational Events News Software
Light-activated gel could impact wearables, soft robotics, and more
Researchers at the Massachusetts Institute of Technology (MIT) have made significant strides in the field of ionotronics, a burgeoning area of study focused on the transfer of data through ions. This innovative approach aims to create a seamless interface between electronic devices and biological tissues, potentially revolutionizing how data is communicated within and between living organisms. The advancements were reported recently, highlighting the ongoing efforts to enhance the integration of technology with biological systems. By harnessing the unique properties of ions, the team at MIT is exploring new pathways for data transmission that could lead to breakthroughs in medical devices and bioengineering. This work underscores the importance of interdisciplinary research in bridging the gap between traditional electronics and the complexities of biological functions.
Research Robotics Light Materials science and engineering Wearables Materials Research Laboratory
Human-machine teaming dives underwater
A team of researchers is advancing the capabilities of collaboration between divers and autonomous underwater vehicles (AUVs) for maritime missions. This initiative, which began in late 2023, aims to enhance operational efficiency and safety in underwater exploration and tasks. The research is taking place at a leading marine technology institute, where experts are focused on creating innovative hardware and sophisticated algorithms that facilitate seamless communication and coordination between human divers and AUVs. The motivation behind this development stems from the increasing complexity of underwater missions, which require precise teamwork to navigate challenging environments and accomplish objectives effectively. By integrating advanced technology, the researchers hope to improve the overall effectiveness of maritime operations, making them safer and more efficient for both divers and AUVs alike.
Research Sensors Lincoln Laboratory Oceanography and ocean engineering Robotics Computer science and technology
21 6 Axis Robot Arm Best Practices for Researchers and Academia
In an effort to enhance research efficiency and data reliability, academic institutions and laboratories are increasingly adopting automation technologies, particularly 6 axis robot arms. JAKA, a leading provider in this field, emphasizes the importance of flexibility over production speed when integrating robotic systems into experimental workflows. Researchers are prioritizing features such as stable motion control and compatibility with existing laboratory instruments, allowing for seamless inspection, sample handling, and measurement tasks. The integration of these robotic arms is designed to be straightforward, enabling connections with vision systems and data acquisition devices already in use. JAKA’s Zu7 Inspection solution exemplifies this approach, automating manual inspection processes to improve efficiency and ensure consistent quality. By alleviating repetitive tasks, researchers can focus more on analysis and validation. Given the dynamic nature of academic research, which often involves changing experiments and funding cycles, JAKA's robotic systems are built for expandability. This allows laboratories to scale automation according to project needs without significant hardware changes. The open interface design facilitates the integration of additional sensors or tools over time, ensuring that the robotic systems remain valuable and adaptable. By prioritizing flexibility, compatibility, and expandability, JAKA aims to support researchers in building reliable automation foundations that can evolve alongside their scientific endeavors, ultimately enhancing the accuracy of inspections and reducing manual workloads in laboratory settings.
From Lab to Pavement: PNDBotics Adam Humanoid Demonstrates Real-World Stair Navigation
PNDBotics has unveiled a new video demonstrating the impressive advancements of its Adam humanoid robot, which has progressed from tethered laboratory prototypes to successfully navigating complex outdoor stairs. This significant development highlights the rapid evolution of the robot's capabilities in 2026. The video showcases the robot's enhanced mobility and adaptability, marking a pivotal moment in the field of robotics as it moves towards real-world applications. The demonstration reflects ongoing efforts to improve humanoid robots for various tasks, emphasizing the potential for future integration into everyday environments.
pndbotics China adam
KUKA presents the future of packaging at interpack 2026 – fast, flexible, autonomous
At the upcoming interpack 2026, KUKA will showcase its advanced automation solutions designed to enhance efficiency in packaging processes. The event, scheduled to take place in Düsseldorf, Germany, will feature KUKA's innovations including fast pick-and-place systems, hygienic oil and cleanroom robots, palletizing solutions, heavy-duty robots, and autonomous mobile robots (AMRs). Visitors can explore these technologies at Hall 6, Booth B74. KUKA aims to demonstrate how its smart and clean automation can streamline operations in the packaging, food, and consumer goods sectors, addressing the growing demand for efficient and hygienic production methods.
NYU’s Quantum Institute Bridges Science and Application
New York University (NYU) has launched the NYU Quantum Institute (NYUQI) in Manhattan's West Village, positioning itself as a pivotal player in the rapidly evolving field of quantum technology. This initiative aims to harness the dense urban ecosystem surrounding the university, which is home to over 500 tech firms, banks, and hospitals, to accelerate advancements in quantum computing, sensing, and communications. The institute, led by Director Javad Shabani, seeks to break down traditional academic silos by fostering collaboration among physicists, engineers, and computer scientists. This integrated approach is designed to enhance the development of practical quantum solutions, which have been hindered by fragmentation in the field. NYUQI will operate from a newly renovated million-square-foot facility, complemented by a state-of-the-art Nanofabrication Cleanroom in Brooklyn, allowing for real-time testing and refinement of quantum technologies. Recently, New York Senators Charles Schumer and Kirsten Gillibrand secured $1 million in funding to introduce Thermal Laser Epitaxy technology at NYU, marking a significant advancement in the U.S. quantum research landscape. The institute also aims to address the skills gap in the quantum workforce by launching a Master of Science in Quantum Science & Technology program, preparing students to tackle complex challenges in this interdisciplinary field. By leveraging its urban location and fostering collaboration, NYUQI aims to transform theoretical quantum research into practical applications, ultimately contributing to advancements in finance, medicine, and security.
Nyu-tandon Quantum-computing Quantum-internet Semiconductors Quantum-communications
From Nuts to Needles: Kyber Labs Debuts Autonomous Wet Lab Assistant
Kyber Labs has recently unveiled a robotic hand capable of executing intricate tasks in wet lab environments, marking a significant advancement in laboratory automation. This demonstration follows the company's viral "nut-spinning" video, which highlighted the potential of their technology. The introduction of this robotic hand signifies a transition towards deterministic, "primitive-based" artificial intelligence, aimed at enhancing efficiency and precision in high-stakes laboratory settings. The development reflects a growing trend in the industry to leverage advanced robotics for complex scientific processes, ultimately aiming to streamline operations and improve outcomes in research and experimentation.
US hand hands Kyber Labs
Four Use Cases of Miniature Robotic Arm in Medical and Pharmaceutical Dispensing
JAKA, a leader in medical and pharmaceutical technology, is revolutionizing dispensing processes with its innovative miniature robotic arm, the JAKA MiniCobo. This advanced system enhances operational efficiency and safety by minimizing human interaction with hazardous materials, which is crucial in environments where precision is essential. The MiniCobo's flexible programming allows for quick adaptations to various medications and formulations, significantly reducing product modification cycles and the need for multiple equipment units. Operators can seamlessly switch tasks, from measuring liquids to sorting vials, without sacrificing accuracy or throughput. In addition to improving safety by reducing direct human exposure to dangerous chemicals, the MiniCobo ensures consistent processing quality through its precise handling of sensitive substances. By replacing manual labor in high-risk areas, JAKA aims to lower workplace incidents while maintaining the integrity of delicate operations. The integration of the MiniCobo extends beyond safety; it interfaces with laboratory information management systems and automated storage units, streamlining workflows and enhancing overall operational efficiency. Its compact design makes it suitable for deployment in space-constrained medical and pharmaceutical labs, ultimately reducing equipment costs by performing multiple tasks within a single unit. JAKA's commitment to advancing dispensing technology through miniature robotics not only enhances safety and precision but also supports complex workflows, contributing to improved outcomes in healthcare and pharmaceutical operations.
Hand Tracking Streamer: A Practical Bridge from Quest Hand Tracking to Robotics Teleoperation and Data Collection
In the field of research, the integration of high-fidelity hand-telemetry systems is frequently achieved through the use of specialized coding and tailored interfaces. These solutions are typically designed to function effectively within the confines of a specific laboratory setup, a particular machine, or a singular demonstration. This approach, while effective in isolated environments, raises concerns about scalability and adaptability across different research contexts. As researchers strive for more versatile and universally applicable systems, the reliance on bespoke solutions may hinder collaboration and innovation in the broader scientific community. The ongoing challenge is to develop standardized frameworks that can accommodate diverse setups while maintaining the high fidelity required for accurate telemetry data.
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.
Coding for underwater robotics
Ivy Mahncke, an intern at Lincoln Laboratory, has successfully developed and tested innovative algorithms designed to enhance navigation for both human divers and underwater robots. This project aims to improve safety and efficiency in underwater exploration and operations, addressing challenges faced in complex aquatic environments. Mahncke's work, which took place during her internship, showcases the potential for advanced technology to assist in deep-sea missions and research. By leveraging data and sophisticated programming techniques, she has created solutions that could significantly aid divers and robotic systems in accurately maneuvering through challenging underwater terrains.
Where Autonomous Vehicles Will Go Next
Todd Jochem, an alumnus of Carnegie Mellon University, has been a pioneer in the field of autonomous vehicles for over two decades. His significant contributions to the development of self-driving technology date back to 1995, when he played a crucial role in the ambitious "No Hands Across America" project, which successfully demonstrated the viability of autonomous driving through a 2,850-mile journey from Pittsburgh to San Diego. This early endeavor showcased the potential of self-driving cars beyond laboratory settings, laying the groundwork for advancements in the industry. As the conversation around autonomous vehicles continues to evolve, Jochem's experiences and insights are shaping the future of this transformative technology.
RI Life
What Is Laboratory Automation?
JAKA, a company specializing in robotic solutions, is at the forefront of laboratory automation, a technological shift aimed at enhancing efficiency and reliability in scientific research. This evolution is marked by the introduction of compact lab automation robots, which streamline tasks traditionally performed by humans, thereby increasing throughput and reducing repetitive strain on technicians. Laboratory automation encompasses a spectrum of technologies, from basic automated liquid handlers to sophisticated robotic systems. The primary goal is to minimize human involvement in repetitive and error-prone processes, resulting in improved consistency and the ability to conduct experiments unattended for extended periods. JAKA's robotic arms, such as the MiniCobo, exemplify this trend, offering lightweight and compact designs that integrate seamlessly into existing lab setups without significant reconfiguration. Implementing laboratory automation requires careful planning, starting with the identification of suitable protocols for standardization. JAKA emphasizes the importance of intuitive programming and flexible software, enabling researchers to easily adapt robotic systems to new tasks without extensive technical expertise. This user-friendly approach, combined with the precision of their robotic arms, ensures the safe handling of delicate samples and enhances overall research quality. By automating routine tasks, JAKA's solutions allow scientists to focus more on analysis and innovation, ultimately accelerating scientific progress and making research processes more reliable and scalable.
NVIDIA and Partners Show That Software-Defined AI-RAN Is the Next Wireless Generation
NVIDIA and Nokia have unveiled advancements in AI-driven wireless networks, emphasizing a software-defined approach as essential for the future of AI-native connectivity. This announcement comes just ahead of the Mobile World Congress (MWC), scheduled for March 2-5 in Barcelona. The collaboration aims to transition AI-RAN technology from laboratory settings to real-world applications, showcasing its potential to enhance network efficiency and performance. The push for this innovative technology is driven by the increasing demand for more intelligent and adaptable wireless networks capable of supporting the growing number of connected devices and applications. By integrating AI capabilities into their wireless infrastructure, both companies seek to redefine the landscape of telecommunications and address the challenges posed by modern connectivity needs.
Perseverance Smashes Autonomous Driving Record on Mars
NASA's Perseverance rover has achieved a remarkable milestone in autonomous navigation on Mars, completing approximately 90% of its travels without human intervention since landing on February 18, 2021. As of October 28, 2024, the rover has driven over 30 kilometers (18.65 miles) and collected 24 samples, significantly surpassing the 6.2% autonomy rate of its predecessor, Curiosity. This advancement is largely attributed to its Enhanced Autonomous Navigation (ENav) algorithm, which allows the rover to analyze its surroundings and evaluate thousands of potential paths using limited computing power equivalent to an outdated iMac G3. The rover's journey has been guided primarily by images it captures, as high-resolution data from Mars Reconnaissance Orbiter is often insufficient for navigation. Despite challenges posed by the uncharted Martian terrain, ENav enables Perseverance to assess travel time and terrain roughness, running complex calculations only on the most promising paths. This strategic design has resulted in unprecedented levels of autonomous driving, including a record-setting 331.74 meters in a single Martian day on April 3, 2023. Masahiro "Hiro" Ono, a supervisor at NASA’s Jet Propulsion Laboratory, emphasizes the importance of advancing autonomous navigation for future space exploration, particularly as missions venture farther from Earth where communication delays become significant. The ongoing success of Perseverance highlights the critical role of automation in expanding the frontiers of space exploration.
Mars Perseverance-rover Autonomous-robots Journal-watch
AI Copilot Keeps Berkeley’s X-Ray Particle Accelerator on Track
In Berkeley, California, researchers at the Lawrence Berkeley National Laboratory are utilizing an AI agent to enhance high-stakes physics experiments at the Advanced Light Source (ALS) particle accelerator. This innovative technology aims to improve the efficiency and accuracy of experiments conducted at the facility, which is renowned for its cutting-edge research in particle physics. The deployment of the AI agent marks a significant advancement in the integration of artificial intelligence within scientific research, as it assists scientists in analyzing complex data and optimizing experimental conditions. This initiative, launched in October 2023, reflects the growing trend of leveraging AI to accelerate discoveries in the field of physics and beyond. By streamlining processes and providing real-time insights, the AI agent is expected to contribute to groundbreaking findings at the ALS, further solidifying its position as a leader in particle acceleration research.
Robotics needs a service framework.
RSF defines a common language for robot service capability, lifecycle operations, certification pathways, and service-provider networks.
