The course offers the knowledge on kinematic and dynamic analysis of planar and spatial link mechanisms and methods to control redundant and over/underactuated mechanisms.
The characteristic of motion mechanisms affects the performance of advanced mechanical systems such as robots, which students learn in Mechanical Engineering Course. It is thus required to quantitatively evaluate the characteristics and to design and control mechanisms based on the evaluation criteria. For this purpose, students will understand how to analyze the kinematics and dynamics of planar and spatial closed-loop link mechanisms by utilizing the systematic kinematic analysis method and will experience to apply them to kinematic and dynamic analyses and motion control of redundant mechanisms, overactuated mechanisms of which actuator inputs are more than mobility of mechanism and underactuated mechanisms constrained by elastic elements.
By the end of this course, students will be able to:
1. Explain mobility of mechanism and relation between input/output motions of mechanism
2. Analyze displacement, velocity and acceleration of planar/spatial closed-loop link mechanisms with the systematic kinematic analysis method
3. Analyze the dynamics of planar/spatial closed-loop link mechanisms utilizing the systematic kinematic analysis method
4. Explain the optimum motion control of redundant link mechanisms
5. Explain motion control of overactuated or underactuated mechanism with elastic elements
Close-loop link mechanism, kinematics, dynamics, systematic kinematic analysis, motion control, optimum control, redundancy, overactuated mechanism, underactuated mechanism, wire-driven mechanism
|Intercultural skills||Communication skills||Specialist skills||Critical thinking skills||Practical and/or problem-solving skills|
Important issues are summarized at the end of lecture every week. Sample software to analyze link mechanisms, which are explained in this lecture, will be offered to students, and students are expected to try to analyze various mechanisms with the software by themselves so as to understand what they learn.
|Course schedule||Required learning|
|Class 1||Kinematic analysis of planar link mechanism with the systematic kinematic analysis method - Displacement, velocity and acceleration analyses of planar closed-loop link mechanisms with the systematic kinematic analysis method -||Understanding of geometric and differential equations of planar link chains|
|Class 2||Kinematic analysis of spatial link mechanisms with the systematic kinematic analysis method - Expansion of the systematic kinematic analysis method to spatial mechanisms -||Understanding of three-dimensional angular motion and vector expression of spatial motion|
|Class 3||Dynamic analysis of planar/spatial link mechanisms - Driving force and joint force analysis using the systematic kinematic analysis -||Derivation of equation of motion of each link|
|Class 4||Evaluation of redundancy and motion control of redundant link mechanisms - Optimum motion control to utilize redundancy -||Understanding of input/output velocity relation and manipulability measure, objective function and optimization method|
|Class 5||Kinematic analysis and motion control of underactuated mechanisms with elastic elements - Motion control of underactuated mechanisms constrained by elastic elements –||Understanding of kinetostatics analysis with virtual external force|
|Class 6||Kinematic analysis and motion control of overactuated mechanisms Kinematic analysis and motion control of underactuated wire-driven mechanisms - Motion control of wire-driven underactuated mechanisms under gravitational force -||Understanding of kinematic analysis by minimizing potential energy|
Several handouts will be often distributed. The following textbook is recommended as a reference book:
JSME Textbook series 'Kinematics od Machinery', edited by the Japan Society of Mechanical Engineers (2007).
Students' knowledge of kinematic and dynamic analyses of planar/spatial closed-loop link mechanisms with the systematic kinematic analysis method and their application to analyses and motion controls of redundant and over/underactuated mechanisms is accessed via submitted reports on several issues(100%).
Students must have successfully completed 'Mechanical elements and draftings（MEC.H201 ）' or have equivalent knowledge.
Nobuyuki Iwatsuki: nob[at]mep.titech.ac.jp, 03-5734-2538
Contact by e-mail in advance to schedule an appointment.