Reprint
Mechanism Design for Robotics
Edited by
June 2019
210 pages
- ISBN978-3-03921-058-9 (Paperback)
- ISBN978-3-03921-059-6 (PDF)
This is a Reprint of the Special Issue Mechanism Design for Robotics that was published in
Computer Science & Mathematics
Engineering
Summary
MEDER 2018, the IFToMM International Symposium on Mechanism Design for Robotics, was the fourth event in a series that was started in 2010 as a specific conference activity on mechanisms for robots. The aim of the MEDER Symposium is to bring researchers, industry professionals, and students together from a broad range of disciplines dealing with mechanisms for robots, in an intimate, collegial, and stimulating environment. In the 2018 MEDER event, we received significant attention regarding this initiative, as can be seen by the fact that the Proceedings contain contributions by authors from all around the world.The Proceedings of the MEDER 2018 Symposium have been published within the Springer book series on MMS, and the book contains 52 papers that have been selected after review for oral presentation. These papers cover several aspects of the wide field of robotics dealing with mechanism aspects in theory, design, numerical evaluations, and applications.This Special Issue of Robotics (https://www.mdpi.com/journal/robotics/special_issues/MDR) has been obtained as a result of a second review process and selection, but all the papers that have been accepted for MEDER 2018 are of very good quality with interesting contents that are suitable for journal publication, and the selection process has been difficult.
Format
- Paperback
License and Copyright
© 2019 by the authors; CC BY-NC-ND license
Keywords
hexapod walking robot; 3-UPU parallel mechanism; kinematics; stability; gait planning; shape changing; rolling; robot; cylindrical; elliptical; velocity control; economic locomotion; actuation burden; inadvertent braking; humanoid robots; parallel mechanisms; cable-driven robots; robotic legs; painting robot; collaborative robot; image processing; non-photorealistic rendering; artistic rendering; robot wrists; spherical parallel mechanism; orientational mechanisms; computer-aided design; workspace analysis; iCub; shape memory alloy; compliant mechanism; SMA actuator; pneumatic artificial muscle; McKibben muscle; haptic glove; hand exoskeleton; teleoperation; force reflection; human-machine interaction; robot kinematics; robot singularity; singularity analysis; robot control; mobile manipulation; human-robot-interaction; learning by demonstration; compliance control; trajectory planning; energy efficiency; redundancy; robotic cell; kinematic redundancy; cable-driven parallel robots; fail-safe operation; exercising device; cobot; V2SOM; safety mechanism; safe physical human–robot interaction; pHRI; variable stiffness actuator; VSA; collaborative robots; humanoid robotic hands; underactuated fingers; graphical user interface; grasp stability; safe physical human–robot interaction (pHRI); variable stiffness actuator (VSA); collaborative robots; robot-assisted Doppler sonography; n/a