Published by Monash University, Australia
Maintained by wwwdev@monash.edu.au
Approved by R Chaffey, Faculty of Engineering
Copyright © Monash University 1997 - All Rights Reserved - Caution
B Shirinzadeh
4 points
* 22 lectures, 8 tutorial/laboratory hours
* First semester
* Clayton
Objectives The subject is intended to provide the fundamental concepts in the field of robotics. The student is expected to acquire the knowledge and understanding of the basic theory, together with applications in practical situations.
Synopsis Spatial descriptions and transformations. Manipulator forward and inverse kinematics. Differential relationships and Jacobian. Manipulator dynamics: Lagrangian and Newton Euler formulations. Design of manipulators and end-effectors. Actuation, sensing and control. Computational geometry for design, manufacture, and path planning. Robotics in manufacturing and automation. Techniques for modelling, simulation and programming of robotic tasks. Image processing and analysis. Advanced mathematical formulations: quaternions, screw theory, linear and non linear programming, etc. Introduction to advanced robotics: skilled robotic manufacturing, autonomous systems, and robots for subsea and space engineering.
Assessment Examinations: 60%
* Assignments and
laboratory work: 40%
Recommended texts
Craig J Introduction to robotics Addison-Wesley
Stadler W Analytical robotics and mechatronics McGraw-Hill
Published by Monash University, Australia
Maintained by wwwdev@monash.edu.au
Approved by R Chaffey, Faculty of Engineering
Copyright © Monash University 1997 - All Rights Reserved -
Caution