2019 | Kinematics and Dynamics of Robotic systems

2019　Kinematics and Dynamics of Robotic systems

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Academic unit or major: Undergraduate major in Systems and Control Engineering

Instructor(s): Yamakita Masaki Tsukagoshi Hideyuki

Class Format: Lecture

Media-enhanced courses

Day/Period(Room No.): Mon7-8(S516) Thr7-8(S516)

Group: -

Course number: SCE.S203

Credits: 2

Academic year: 2019

Offered quarter: 4Q

Syllabus updated: 2019/3/20

Lecture notes updated: -

Language used: Japanese

Access Index

Syllabus

Course description and aims

I. Structure, actuator and sensor for robots are understood.
II. Modeling, kinematics and dynamics of robots are understood.

Student learning outcomes

Basic elements, structure and modeling for analysis for robots to construct and control are mastered.

Keywords

Robot, structure, actuator, sensor, kinematics, dynamics

Competencies that will be developed

✔ Specialist skills

Intercultural skills

Communication skills

Critical thinking skills

Practical and/or problem-solving skills

Class flow

For each topic in a class, exerｃise or programming with Mathematica is conducted.

Course schedule/Required learning

	Course schedule	Required learning
Class 1	Introduction to robot engineering	Reserach fields in robotics are surveied and several robot systems are studied.
Class 2	Mean of speed reduction and selection of speed reduction	Mean of speed reduction is understood and how to select the speed reduction is studied.
Class 3	Speed reduction mechanism and mechanical elements	Speed reduction mechanisms and mechanical elements are studied.
Class 4	Strucure	Structures for robots are studied.
Class 5	Actuatorｓ	Basic properties of actuators for robots are studied.
Class 6	Sensors	Basic properties of sensors for robots are studied.
Class 7	Expression of position and rotation of rigid body	Mathematical expression of position and rotation of a rigid body is studied.
Class 8	Homogenous coordinate and homogenious transformation matrix	Concept of homogeneous coordinate and its transformation matrix are studied.
Class 9	Angular vector and coordinate transformation	Definition of angular velocity and its coordinate transformation are studied.
Class 10	D-H notation and forward and inverse transformation	Definition of D-H notation and properties of forward and inverse transformations are studied.
Class 11	Velocity relationship (1): Numerical methods for inverse transformation	As an application of velocity relationship, numerical method to solve inverse transformations is studied.
Class 12	Velocity relationship (2): Manupilability	As an application of velocity relationship, definition and properities of manipulability are studied.
Class 13	Variational method and derivation of Lagrange's dynamic equation	Concept of variationa method and its application to derive Lagrange's dynamic equation are studied.
Class 14	Derivation of dynamic equations of muli-link systems	How to derive dynamic equations of multi-link systems is explained and properties of the dynamic equations are studied.
Class 15	Port Hamiltonian systems and passivity	Definition of port Hamiltonian systems and properties of passivity are studied.

Textbook(s)

Document is distributed in each class.

Reference books, course materials, etc.

Spong,Vydiasagar:Robot Dynamics & Control (Wiley)

Assessment criteria and methods

Report : 20%
Exercise: 30%
Exam.: 50%

Related courses

MEC.A201 ： Engineering Mechanics

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

Not required

TOKYO INSTITUTE OF TECHNOLOGY