2018　Multibody Systems

Font size  SML

Instructor(s)
Okuma Masaaki  Furuya Hiroshi
Class Format
Lecture
Media-enhanced courses
Day/Period(Room No.)
Mon5-8(S422)
Group
-
Course number
MEC.H432
Credits
2
2018
Offered quarter
2Q
Syllabus updated
2018/4/9
Lecture notes updated
-
Language used
English
Access Index

Course description and aims

All machines are "Systems" which inevitably consists of multi number of mechanical parts relatively linked and connected. That is, "Multibody Systems." The relative motion of the mechanical parts creates the motion and function of machines. This course is to lecture the motion, mechanics and control of the systems as follows:
1. Multi particle systems
3. Dynamics and inverse dynamics
The aim of this course is to give students enough ability to solve the mechanics of multibody systems by means of not only lecturing but also offering some excercises using computational analysis.

Student learning outcomes

At the end of this course, students' will be able to:
1) express and transform the coordinate systems mathematically
2) analyze the kinematics and dynamics of multi particle and body link systems
3) analyze the synthesis of ribid body systems' kinematics
4) understand the basic analysis of flexible multi body systems

Keywords

Rigid link system, Kinematics, Dynamics, Control, Robot

Competencies that will be developed

 ✔ Specialist skills Intercultural skills Communication skills Critical thinking skills Practical and/or problem-solving skills

Class flow

This course mainly consists of lecturing. In addition, exercise and homework (report) are provided appropriately for students' good understanding.

Course schedule/Required learning

Course schedule Required learning
Class 1 Basic expression of kinematics Understand the method to express kinematics.
Class 2 Transformation between coordinate systems Understand how to transform from a coordinate system to another.
Class 3 Expression of velocity, acceleration and angular velocity Understand and derive the velocity, acceleration and angular velocity mathematically.
Class 4 Kinematics and dynamics of particle motion Understand and analyze the motion of particle.
Class 5 Kinmematics and dynamics of multi-particle connected systems Understand multi-particle connected systems
Class 6 Expression of generalized coordinates of rigid body link systems Express rigid body link systems in generalized coordinate system.
Class 7 Kinematics of rigid bodies' link systems Understand the analysis of rigid body link system's kinematics.
Class 8 Moment of inertia regarding rigid body link systems Understand the analysis of the moment of inertia.
Class 9 Dynamics of rigid body link systems Understand basic dynamic analysis of rigid body link systems.
Class 10 Dynamic analysis of rigid body link systems Understand the methods of dynamic analysis.
Class 11 Inverse dynamics of rigid body link systems Understand the inverse dynamics.
Class 12 Path control and planning of rigid body link systems Understand the theory of path control and planning.
Class 13 Linear control of rigid body link systems Understand linear control theory.
Class 14 Nonlinear control of rigid body link systems Understand nonlinear control theory.
Class 15 Dynamics of flexible multi body link systems Understand flexible link systems.

Textbook(s)

Several materials are proveded by lecturers

Reference books, course materials, etc.

John J. Craig著　Introduction to Robotics: Mechanics and Control
Ahmed A. Shabana著　Dynamics of Multibody Systems

Assessment criteria and methods

Students' achievement scores are determined by final examination (about 60%) plus exercise and reports (about 40%).

Related courses

• LAS.M102 ： Linear Algebra I / Recitation
• LAS.M106 ： Linear Algebra II
• LAS.P101 ： Fundamentals of Mechanics 1
• LAS.P102 ： Fundamentals of Mechanics 2
• MEC.A201 ： Engineering Mechanics
• MEC.B214 ： Vector Analysis
• ZUL.A201 ： Motion and Vibration Control
• MEC.I333 ： Robot Dynamics and Control
• SCE.S203 ： Kinematics and Dynamics of Robotic systems
• MEC.I211 ： Robot Kinematics

Prerequisites (i.e., required knowledge, skills, courses, etc.)

Successful completion of learning the undergraduate level subjects listed the related courses above.

Other

It is required to bring a note PC in which Matlab has been intalled.