The increasing demand for physical interaction between humans and robots has led to an interest in robots whose behavior is guaranteed to be safe when they are in close proximity with humans. However, attaining sufficiently high levels of performance while ensuring safety creates formidable challenges in mechanical design, actuation, sensing, and control. To promote safety without compromising performance, a new actuation concept, referred to as hybrid actuation, has been developed. Since low impedance output at high frequencies is essential for robot safety, while optimal passive stiffness is needed for robot performance, the new actuation approach employs a pneumatic artificial muscle as a macro actuator to provide low-frequency torques. Artificial pneumatic muscles provide high force-to-weight ratio and inherent compliance, both of which allow for low impedance actuation. To compensate for the slow and non-linear dynamics of pneumatic actuation, a small electromagnetic actuator collocated at the robot's joint is employed as a mini actuator, which provides high mechanical bandwidth for high performance without increasing the inertia and size of the manipulator. To achieve the appropriate balance between safety and performance, design methodologies were developed that optimally determine key design parameters such as the required mini motor torque capacity, the joint stiffness introduced by an antagonistic pair of muscles, and the pulley radius. Using a testbed, referred to as the Stanford Safety Robot (S2rho), the hybrid actuation was evaluated for position tracking performance, force tracking performance, and impact behavior. The experimental results demonstrate that by significantly improving control performance with the hybrid actuation over performance with pneumatic muscles alone, while reducing the effective inertia significantly, the competing design objectives of safety and performance can be successfully integrated into a single robotic manipulator. As an extension of the hybrid actuation concept, the new design of dual four-degree-of-freedom robotic arms with torso is presented and detailed descriptions of the design are included.

The increasing demand for physical interaction between humans and robots has led to an interest in robots whose behavior is guaranteed to be safe when they are in close proximity with humans. However, attaining sufficiently high levels of performance while ensuring safety creates formidable challenges in mechanical design, actuation, sensing, and control. To promote safety without compromising performance, a new actuation concept, referred to as hybrid actuation, has been developed. Since low impedance output at high frequencies is essential for robot safety, while optimal passive stiffness is needed for robot performance, the new actuation approach employs a pneumatic artificial muscle as a macro actuator to provide low-frequency torques. Artificial pneumatic muscles provide high force-to-weight ratio and inherent compliance, both of which allow for low impedance actuation. To compensate for the slow and non-linear dynamics of pneumatic actuation, a small electromagnetic actuator collocated at the robot's joint is employed as a mini actuator, which provides high mechanical bandwidth for high performance without increasing the inertia and size of the manipulator. To achieve the appropriate balance between safety and performance, design methodologies were developed that optimally determine key design parameters such as the required mini motor torque capacity, the joint stiffness introduced by an antagonistic pair of muscles, and the pulley radius. Using a testbed, referred to as the Stanford Safety Robot (S2rho), the hybrid actuation was evaluated for position tracking performance, force tracking performance, and impact behavior. The experimental results demonstrate that by significantly improving control performance with the hybrid actuation over performance with pneumatic muscles alone, while reducing the effective inertia significantly, the competing design objectives of safety and performance can be successfully integrated into a single robotic manipulator. As an extension of the hybrid actuation concept, the new design of dual four-degree-of-freedom robotic arms with torso is presented and detailed descriptions of the design are included.

This book discusses biologically inspired robotic actuators designed to offer improved robot performance and approaching human-like efficiency and versatility. It assesses biological actuation and control in the human motor system, presents a range of technical actuation approaches, and discusses potential applications in wearable robots, i.e., powered prostheses and exoskeletons. Gathering the findings of internationally respected researchers from various fields, the book provides a uniquely broad perspective on bioinspired actuator designs for robotics. Its scope includes fundamental aspects of biomechanics and neuromechanics, actuator and control design, and their application in (wearable) robotics. The book offers PhD students and advanced graduate students an essential introduction to the field, while providing researchers a cutting-edge research perspective.

This book is a printed edition of the Special Issue "Bio-Inspired Robotics" that was published in Applied Sciences

Robotic engineering inspired by biology—biomimetics—has many potential applications: robot snakes can be used for rescue operations in disasters, snake-like endoscopes can be used in medical diagnosis, and artificial muscles can replace damaged muscles to recover the motor functions of human limbs. Conversely, the application of robotics technology to our understanding of biological systems and behaviors—biorobotic modeling and analysis—provides unique research opportunities: robotic manipulation technology with optical tweezers can be used to study the cell mechanics of human red blood cells, a surface electromyography sensing system can help us identify the relation between muscle forces and hand movements, and mathematical models of brain circuitry may help us understand how the cerebellum achieves movement control. Biologically Inspired Robotics contains cutting-edge material—considerably expanded and with additional analysis—from the 2009 IEEE International Conference on Robotics and Biomimetics (ROBIO). These 16 chapters cover both biomimetics and biorobotic modeling/analysis, taking readers through an exploration of biologically inspired robot design and control, micro/nano bio-robotic systems, biological measurement and actuation, and applications of robotics technology to biological problems. Contributors examine a wide range of topics, including: A method for controlling the motion of a robotic snake The design of a bionic fitness cycle inspired by the jaguar The use of autonomous robotic fish to detect pollution A noninvasive brain-activity scanning method using a hybrid sensor A rehabilitation system for recovering motor function in human hands after injury Human-like robotic eye and head movements in human–machine interactions A state-of-the-art resource for graduate students and researchers.

Bioinspired Legged Locomotion: Models, Concepts, Control and Applications explores the universe of legged robots, bringing in perspectives from engineering, biology, motion science, and medicine to provide a comprehensive overview of the field. With comprehensive coverage, each chapter brings outlines, and an abstract, introduction, new developments, and a summary. Beginning with bio-inspired locomotion concepts, the book's editors present a thorough review of current literature that is followed by a more detailed view of bouncing, swinging, and balancing, the three fundamental sub functions of locomotion. This part is closed with a presentation of conceptual models for locomotion. Next, the book explores bio-inspired body design, discussing the concepts of motion control, stability, efficiency, and robustness. The morphology of legged robots follows this discussion, including biped and quadruped designs. Finally, a section on high-level control and applications discusses neuromuscular models, closing the book with examples of applications and discussions of performance, efficiency, and robustness. At the end, the editors share their perspective on the future directions of each area, presenting state-of-the-art knowledge on the subject using a structured and consistent approach that will help researchers in both academia and industry formulate a better understanding of bioinspired legged robotic locomotion and quickly apply the concepts in research or products. - Presents state-of-the-art control approaches with biological relevance - Provides a thorough understanding of the principles of organization of biological locomotion - Teaches the organization of complex systems based on low-dimensional motion concepts/control - Acts as a guideline reference for future robots/assistive devices with legged architecture - Includes a selective bibliography on the most relevant published articles

This eBook is a collection of articles from a Frontiers Research Topic. Frontiers Research Topics are very popular trademarks of the Frontiers Journals Series: they are collections of at least ten articles, all centered on a particular subject. With their unique mix of varied contributions from Original Research to Review Articles, Frontiers Research Topics unify the most influential researchers, the latest key findings and historical advances in a hot research area! Find out more on how to host your own Frontiers Research Topic or contribute to one as an author by contacting the Frontiers Editorial Office: frontiersin.org/about/contact.

By the dawn of the new millennium, robotics has undergone a major transformation in scope and dimensions. This expansion has been brought about by the maturity of the field and the advances in its related technologies. From a largely dominant industrial focus, robotics has been rapidly expanding into the challenges of the human world. The new generation of robots is expected to safely and dependably co-habitat with humans in homes, workplaces, and communities, providing support in services, entertainment, education, healthcare, manufacturing, and assistance. Beyond its impact on physical robots, the body of knowledge robotics has produced is revealing a much wider range of applications reaching across diverse research areas and scientific disciplines, such as: biomechanics, haptics, neuros- ences, virtual simulation, animation, surgery, and sensor networks among others. In return, the challenges of the new emerging areas are proving an abundant source of stimulation and insights for the field of robotics. It is indeed at the intersection of disciplines that the most striking advances happen. The goal of the series of Springer Tracts in Advanced Robotics (STAR) is to bring, in a timely fashion, the latest advances and developments in robotics on the basis of their significance and quality. It is our hope that the wider dissemination of research developments will stimulate more exchanges and collaborations among the research community and contribute to further advancement of this rapidly growing field.

This three volume set LNAI 9244, 9245, and 9246 constitutes the refereed proceedings of the 8th International Conference on Intelligent Robotics and Applications, ICIRA 2015, held in Portsmouth, UK, in August 2015. The 46 papers included in the third volume are organized in topical sections on mobile robots and intelligent autonomous systems; intelligent system and cybernetics; robot mechanism and design; robotic vision; recognition and reconstruction; and active control in tunneling boring machine.