Industry Briefing

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

Developing active and flexible microrobots

Developing active and flexible microrobots

Researchers at Leiden University, led by Professor Daniela Kraft and Mengshi Wei, have developed innovative microscopic robots that operate autonomously without the need for sensors, software, or external control. These robots exhibit movement driven solely by their unique shapes and interactions with their surroundings. This groundbreaking advancement, unveiled recently, holds significant potential for biomedical applications, paving the way for new methods in medical treatment and diagnostics. The team’s work represents a significant leap in the field of robotics, showcasing how design and environmental factors can create intelligent behavior in microscopic machines.

‘Predator-like’ light-powered micromotors to mine uranium from oceans, wastewater

‘Predator-like’ light-powered micromotors to mine uranium from oceans, wastewater

Researchers at the Qinghai Institute of Salt Lakes in China have made a significant breakthrough by developing a new microscopic material that has the potential to revolutionize various industries. This innovative material, created using advanced techniques, was unveiled during a recent scientific conference held in Xining, the capital of Qinghai Province. The development aims to address challenges in fields such as energy storage, environmental protection, and biomedical applications. The motivation behind this research stems from the growing need for more efficient and sustainable materials that can enhance performance while reducing environmental impact. By leveraging unique properties at the microscopic level, the scientists have demonstrated that this new material can improve energy efficiency and offer enhanced functionality compared to existing alternatives. The team utilized a combination of nanotechnology and material science to synthesize the material, which exhibits remarkable strength and versatility. Initial tests have shown promising results, indicating its potential for practical applications in batteries, water purification systems, and drug delivery mechanisms. As the research progresses, the scientists are optimistic about the material's future applications and its ability to contribute to technological advancements. They plan to collaborate with industry partners to further explore its commercial viability and to bring this innovative solution to market, potentially transforming how various sectors approach material challenges.

Micro Grippers with Parkour Abilities? BIT Team Proposes New Mechanism for Magnetic-Driven Microrobots Integrating Morphology and Function!

Micro Grippers with Parkour Abilities? BIT Team Proposes New Mechanism for Magnetic-Driven Microrobots Integrating Morphology and Function!

A research team at the Beijing Institute of Technology has unveiled an innovative magnetic-driven microrobot that demonstrates autonomous decision-making and adaptive movement capabilities in challenging environments. Drawing inspiration from natural organisms, this microrobot can seamlessly transition between various movement modes, allowing it to navigate efficiently and execute tasks effectively. The development of this technology aims to enhance robotic performance in complex terrains, potentially expanding its applications in fields such as search and rescue, environmental monitoring, and medical assistance. The team's work represents a significant advancement in robotics, showcasing how nature-inspired designs can lead to improved functionality and versatility in robotic systems.

Magnetic Microrobots Autonomous Robotics Soft Robotics Biomedical Applications
Oversonic Robotics: STMicroelectronics, Fondazione ENEA Tech Biomedical and SpotInvest acquire a stake in the Company

Oversonic Robotics: STMicroelectronics, Fondazione ENEA Tech Biomedical and SpotInvest acquire a stake in the Company

A group of new shareholders has committed to advancing the industrial development of RoBee, a cognitive humanoid robot. This initiative aims to broaden the robot's applications within the manufacturing and healthcare sectors. The shareholders also plan to enhance RoBee's market presence in the United States. This strategic move reflects a growing interest in integrating advanced robotics into various industries, driven by the potential for increased efficiency and innovation. The shareholders are expected to leverage their resources and expertise to facilitate RoBee's expansion and adoption in these critical markets.

Biomedical jellyfish-inspired robot hits record swim speeds without onboard power

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.

STMicroelectronics Invests in Oversonic Robotics to Enhance Humanoid Robot Development

STMicroelectronics Invests in Oversonic Robotics to Enhance Humanoid Robot Development

Oversonic Robotics, an Italian cognitive robotics firm known for RoBee, has announced a strategic investment from STMicroelectronics, Fondazione ENEA Tech Biomedical, and SpotInvest. This investment aims to accelerate Oversonic's industrial, technological, and international growth, particularly in the cognitive humanoid robotics sector. The involvement of STMicroelectronics, a leader in semiconductors, is expected to bolster Oversonic's technological advancements and support its expansion into the U.S. market. The partnership will enhance the development of RoBee, the first certified cognitive humanoid robot designed for complex environments, and facilitate applications in manufacturing and healthcare. Looking ahead, Oversonic plans to focus on expanding its technological platform and applications while strengthening its team and industrial capacity. The company views the U.S. as a key market for its cognitive humanoid robotics, aiming for significant growth in both commercial and industrial sectors. No further timeline was disclosed at the time of publication.

Humanoids News artificial intelligence automation cognitive robotics deep tech
Soft Graphene Muscle Enables Robots to Maintain Stability for Over 13 Hours

Soft Graphene Muscle Enables Robots to Maintain Stability for Over 13 Hours

Researchers from Sun Yat-sen University and Tsinghua University have developed a soft robot capable of maintaining stability against disturbances for over 13 hours. This innovation utilizes an ultrathin soft muscle, known as Soft Graphene Muscle (SGM), which integrates self-sensing, electrothermal actuation, and disturbance control without the need for external sensors. The significance of this development lies in its potential to enhance the operational capabilities of soft robots in real-world environments. Traditional soft robots often struggle with stability due to their flexible structures, which can amplify disturbances. The SGM's ability to adaptively balance objects heavier than itself marks a significant advancement in soft robotics, moving closer to practical applications. Future developments to watch include the potential for further integration of sensing and control within soft materials, as well as the implications for deploying soft robots in complex environments. The research was published in eScience, highlighting the collaborative efforts of experts in biomedical engineering and integrated circuits from both universities.

Soft Robotics Adaptive Control Robotics Engineering AI Material Science
IEEE Honors Robotics Pioneer Toshio Fukuda

IEEE Honors Robotics Pioneer Toshio Fukuda

Toshio Fukuda has been blazing trails for most of his career. He is considered to be one of the most prolific scholars in robotics, writing more than 2,000 research papers and authoring several books on the field. He’s an influential figure thanks to his pioneering work developing biomedical robotic systems, industrial robots, micro-nano robotics, mechatronics, and AI-driven automation.Fukuda launched one of the first robotics conferences, the IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS). It is still popular almost 40 years later.Toshio FukudaEmployerEgypt-Japan University of Science and Technology, in Alexandria TitleProfessor and vice president of research Member gradeLife Fellow Alma matersWaseda University, in Tokyo; University of Tokyo An IEEE Life Fellow, he is a professor emeritus in the department of micro-nano systems engineering and a visiting professor at Nagoya University, in Japan, where he taught for nearly 25 years. Currently, he is a vice president of research at the Egypt-Japan University of Science and Technology, in Alexandria, Egypt.Within IEEE, Fukuda has held top volunteer positions including the organization’s highest office: He served as IEEE president in 2020, becoming the first person of Asian descent to hold the role.He’s a former program director of Japan’s Moonshot program, which by 2050 intends to develop advanced AI robots.Born in Japan, Fukuda has been recognized by the country for his contributions to science with two of its highest awards: the Medal of Honor with a purple ribbon in 2015 and the Order of the Sacred Treasure in 2022.IEEE honored him with this year’s Richard M. Emberson Award for “distinguished service advancing the technical objectives of IEEE, especially in the area of robotics.” The IEEE Board-level award is sponsored by the IEEE Technical Activities Board. Fukuda received the award on 24 April at a ceremony in New York City.As a former IEEE president who has served as a master of ceremonies at several of the organization’s major award events, Fukuda noted that he is more accustomed to bestowing awards than receiving them.“It’s very interesting to be on the receiving end,” he says.The journey into robotics researchAs a teenager, Fukuda spent his summer breaks teaching himself how to build things including transistor radios and steam engines.“It was very nice to have a hands-on hobby and make these kinds of things myself,” he says. His experimentation led him to study engineering.He earned a bachelor’s degree in engineering in 1971 from Waseda University, in Tokyo. He says one of his professors there—Ichiro Kato, regarded as the father of Japanese robotics research—was a good mentor who made a positive impact.Fukuda’s research interests were robotics and mechatronics, a field that combines robotics, electronics, computer science, and control systems.He went on to earn a master’s degree and a doctorate in science from the University of Tokyo, in 1971 and 1977. During those years, he also attended Yale, where he conducted research on advanced control theory in 1973.He reflects fondly on his time at Yale: “It was a very nice environment and a kind of free-thinking atmosphere. It motivated me to study more.”“IEEE doesn’t care who you are, what you do, what country you are from, or whether you are male or female. IEEE accepts people who have energy and passion.”While at Yale, Fukuda served as an assistant to his advisor—which led him to consider a career in academia, he says, because he enjoyed the freedom that research work afforded him.But he realized that such freedom comes with a price. University researchers are expected to raise the money that funds their work. He compares researchers to small-business owners who have to bring in money to keep their enterprise afloat.That realization led him to select robotics as his field because he intended to develop technologies useful to industry, he says.After earning his doctorate, he returned to Japan in 1977 to work as a research scientist at the government’s Mechanical Engineering Laboratory, later renamed the National Institute of Advanced Industrial Science and Technology, in Tsukuba.“There was a lot of research going on at the lab, including practical robotics and theory,” he says.He left Japan in 1979 to become a visiting research fellow at the University of Stuttgart, in Germany. During his year there, he studied systems, software problems, and related topics.He returned to Japan and was hired as an associate professor of mechanical engineering at the Tokyo University of Science. He conducted research into practical uses for robots by visiting industrial plants. He decided to develop robots that inspect industrial equipment such as those used in assembly plants, oil refineries, and power stations—places that “can be hostile environments for humans,” he says.His work drew interest from chemical, oil, and utility companies.“I got a lot of money from them for this very practical application, which funded my research,” he says, laughing.Developing popular robotic systemsFukuda grew tired of making those robots, he says, so he switched to creating ones for scientific applications. He developed many techniques, but he probably is best known for his modular, cellular robotic systems (CEBOTs), which he introduced in 1985.He has described how CEBOTs work in numerous papers published in the IEEE Xplore Digital Library.The CEBOT system is composed of a number of autonomous robotic cells that stick together like interlocking Lego plastic bricks, he says.Each cell is a fundamental modular unit that has a function. When a simple task is given, the system can analyze it and generate the structure of the cellular manipulator. The cells connect to and detach from each other through connection mechanisms and cooperate mutually, creating complex structures and configurations.“You start developing from the component-wise to the cell-wise to a small functional unit—and then you come up with clusters that make bigger systems. We can make a society of robot beings like that,” he explained in his oral history published on the Engineering and Technology History Wiki. “It’s a distributed robotic system, a self-organized robotic system, and also an evolutionary robotic system.“It’s also a fault-tolerant robot system because if something is wrong, you just remove those things and make a new one. You keep the system working. That’s a great thing.”Today CEBOTs are used for a variety of tasks such as delivering medication in hospitals, assisting with planting crops, and transporting products in distribution centers. Check out IEEE Spectrum’s Robots Guide for news from the world of robotics.In 1989 Fukuda joined Nagoya University as a professor of mechanical engineering and micro-nano systems engineering. During his 24-year career there, he was director of the university’s Center for Micro-Nano Mechatronics. He developed a long list of technologies at the university, including many for medical applications. He also conducted groundbreaking research into intelligent robotic systems and micro- and nano-robotics.Another technology he is known for is brachiation robots, which he helped develop in 1988. He calls them monkey robots because they’re based on the pendulum-like movement of monkeys swinging from tree to tree. The gravity-based locomotion enables continuous movement.Brachiation robots now are inspecting high-voltage transmission towers and bridges, searching damaged buildings for survivors, and performing maintenance on pipelines and cables.Fukuda retired from the university in 2013 and was named professor emeritus.He didn’t stay retired for long, though. He next held a teaching appointment at Meijo University, in Nagoya, until he left in 2022 to join the Egypt-Japan University.A prominent volunteerHe joined IEEE in 1980 at the encouragement of one of his research advisors, Professor Fumio Harashima, now an IEEE Life Fellow. After attending conferences and reading the organization’s publications, Fukuda says, he looked forward to becoming more involved.“I wanted to know how to organize a conference and how to edit a paper for one of its Transactions,” he says. “I wanted to know what was going on from inside the organization, not just the outside.”In 1988 he was the founding chair and organizer of IROS, in Tokyo. The conference had 330 attendees that year, and was supported by Harashima. Today it is one of the largest and most prestigious conferences on the topic, attracting more than 9,000 people annually. Out of 120,000 conferences, it was the only conference in the Nature Index database for this year, Fukuda says.In 1996 he and other members launched IEEE Transactions on Mechatronics.He was the founding president of the IEEE Nanotechnology Council, which was established in 2002. He is considered a pioneer in nanotechnology research, particularly regarding how it relates to robotics.Over the years, he has held numerous volunteer positions on IEEE editorial boards and committees.He was the 1998–1999 president of the IEEE Robotics and Automation Society, becoming the first non-U.S. member to hold the title.He was director of IEEE Division X (2001–2002 and 2017–2018), which covers intelligent systems, biological engineering, robotics, control systems, and photonic technologies. He served as the 2013–2014 director of IEEE Region 10 (Asia-Pacific).As the 2020 IEEE president, Fukuda saw the organization through the early part of the COVID-19 pandemic. Because of travel restrictions, he realized IEEE should change how it offered its in-person services, specifically educational programs. He encouraged IEEE Educational Activities to develop an online learning platform. The IEEE Learning Network started with just three courses and now offers nearly 2,000 courses, webinars, and learning materials.An award-winning memberThe Emberson Award joins a slew of other recognitions Fukuda has received from IEEE. They include several from the IEEE Robotics and Automation Society: a 2004 Pioneer Award, a 2009 Saridis Leadership Award, and the 2011 Harashima Award for Innovative Technologies. He is also a recipient of the Board-level 2010 IEEE Robotics and Automation Technical Field Award.He says he feels strongly that IEEE should be a diverse organization that is welcoming to all. As IEEE president, he led efforts to devise a diversity, equity, and inclusion program. Several policies, procedures, and bylaws were revised to give members a safe, inclusive place for discourse.“It’s important for IEEE to make everyone feel comfortable,” he says. “DEI programs are important. All people should be equal. IEEE doesn’t care who you are, what you do, what country you are from, or whether you are male or female. IEEE accepts people who have energy and passion.“It accepted me, from the Far East. That’s why I like it.”You can learn more about Fukuda and his career from the oral history conducted by the IEEE History Center.

Robotics Robots Ieee-member-news Type-ti Ieee-awards Toshio-fukuda
Deep learning co-design helps scientists project 28-layer 3D images without crosstalk

Deep learning co-design helps scientists project 28-layer 3D images without crosstalk

Engineering researchers at the University of California, Los Angeles (UCLA) have unveiled a groundbreaking three-dimensional printing technology that significantly enhances the production of complex structures. This innovative method, introduced in October 2023, aims to revolutionize various industries by allowing for the rapid and precise fabrication of intricate designs that were previously difficult or impossible to achieve. The researchers' motivation stems from the growing demand for more efficient manufacturing processes that can produce high-quality components while minimizing waste and time. By leveraging advanced materials and techniques, the team has demonstrated that their new approach can streamline production workflows and reduce costs, making it an attractive option for sectors such as aerospace, automotive, and biomedical engineering. This development not only showcases the potential of 3D printing technology but also emphasizes UCLA's commitment to leading research in engineering and technology. The researchers plan to further refine their technique and explore its applications across various fields, aiming to set new standards in manufacturing efficiency and innovation.

Science
New heat-pressed silk material outperforms wood, rivals Kevlar and carbon fiber

New heat-pressed silk material outperforms wood, rivals Kevlar and carbon fiber

A team of researchers from Tufts University, Imperial College London, and the University of Michigan has unveiled a groundbreaking development in the field of biomedical engineering. This innovation, announced on October 15, 2023, focuses on creating a new type of biodegradable material that could significantly enhance medical implants and devices. The research aims to address the growing concern over the environmental impact of traditional plastic implants, which can take centuries to decompose. By utilizing advanced materials science, the team has engineered a substance that not only meets the necessary medical standards for safety and efficacy but also naturally breaks down in the body over time, reducing the need for surgical removal. This advancement is expected to revolutionize the way medical professionals approach implantable devices, offering a sustainable alternative that aligns with the increasing emphasis on eco-friendly practices in healthcare. The findings were published in a peer-reviewed journal, highlighting the collaborative efforts of the researchers and their commitment to addressing both health and environmental challenges. As the medical community continues to seek innovative solutions, this new biodegradable material stands out as a promising step towards more sustainable healthcare practices. The research team plans to conduct further studies to explore the full potential and applications of this material in various medical fields.

Inspired by Fish Diversity: Beijing Institute of Technology Team Develops Morphology-Encoded Soft Microrobots

Inspired by Fish Diversity: Beijing Institute of Technology Team Develops Morphology-Encoded Soft Microrobots

A research team at the Beijing Institute of Technology has unveiled a groundbreaking system of soft microrobots that mimic the various swimming styles of fish. This innovative development allows for the selective control of the robots by adjusting their body proportions within a uniform magnetic field. The advancements in this technology hold significant promise for future applications in the biomedical field, potentially enhancing medical procedures and therapies.

Soft Robotics Biomedical Engineering Microrobots Control Systems
Solving hard problems in soft electronics

Solving hard problems in soft electronics

Camille Cunin, a PhD candidate from the class of 2026, is pioneering advancements in biomedical technology by developing innovative stretchable devices that enhance signal amplification. This groundbreaking work aims to address the limitations of traditional rigid circuitry, making these new devices more adaptable for practical applications in healthcare. Cunin's research, which is ongoing, seeks to improve the integration of technology in medical settings, potentially leading to better patient outcomes. By focusing on the creation of flexible circuitry, Cunin is contributing to a significant shift in how biomedical devices can be utilized in real-world scenarios, ultimately enhancing their functionality and effectiveness in monitoring and treating various health conditions.

School of Engineering DMSE Neuroscience Biomedical engineering Electronics Wearables
MIT engineers develop 3D-printed micro-robots that can be controlled by magnets

MIT engineers develop 3D-printed micro-robots that can be controlled by magnets

A team of engineers has successfully developed an innovative soft magnetic hydrogel that can be 3D-printed into intricate microscopic structures. This breakthrough, announced in October 2023, opens new avenues for applications in various fields, including biomedical engineering and robotics. The hydrogel's unique properties allow it to respond to magnetic fields, making it particularly useful for creating responsive materials and devices. By utilizing advanced 3D printing techniques, the engineers demonstrated the ability to fabricate complex shapes that were previously difficult to achieve with traditional materials. This advancement not only enhances the versatility of hydrogels but also paves the way for future research and development in smart materials.

A flexible lens controlled by light-activated artificial muscles promises to let soft machines see

A flexible lens controlled by light-activated artificial muscles promises to let soft machines see

Researchers at the Georgia Institute of Technology have developed an innovative artificial eye designed to enhance the vision capabilities of soft robots. This adaptive lens, inspired by the human eye, is made from a soft, light-responsive material that allows for improved visual perception. The project, led by biomedical engineering experts Corey Zheng and Shu Jia, aims to bridge the gap between robotics and biological systems, enabling robots to interact more effectively with their environments. The development of this technology could significantly advance the field of robotics, particularly in applications requiring nuanced visual processing.

RobotToday Initiative

Robotics needs a service framework.

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