Robotics

The word "robot" does not originate from a science or engineering vocabulary. It was rst used in the Czech drama R.U.R. (Rossum's Universal Robots) written by Karel Capek and was rst played in Prague in 1921 (the word itself was invented by his brother Josef). In the drama the "robot" is an arti cial human being which is a brilliant worker, deprived of all unnecessary qualities: feelings, creativity and capacity for feeling pain. In the prologue of the drama the following "de nition" of robots is given: Robots are not people (Roboti nejsou lide). They are mecha- cally more perfect than we are, they have an astounding intellectual capacity, but they have no soul. The creation of an engineer is technically more re ned than the product of nature. The textbook "Robotics" evolved through more than 10 years of teaching robotics at the Faculty of Electrical Engineering, of the University of Ljubljana, Slovenia. The way of presenting the rather demanding subject was successfully tested with several generations of undergraduatestudents.

• 1 Introduction
• 1.1 Degree of freedom
• 1.2 Robot manipulator
• 1.3 Robot arms
• 1.4 Robot manipulators in industrial environment
• 2 Homogenous transformation matrices
• 2.1 Translational transformation
• 2.2 Rotational transformation
• 2.3 Pose and displacement
• 2.4 Geometrical robot model
• 3 Geometric description of the robot mechanism
• 3.1 Vector parameters of a kinematic pair
• 3.2 Vector parameters of themechanism
• 4 Two-segment robot manipulator
• 4.1 Kinematics
• 4.2 Workspace
• 4.3 Dynamics
• 5 Robot sensors
• 5.1 Principles of sensing
• 5.2 Sensors of movement
• 5.2.1 Placing of sensors
• 5.2.2 Potentiometer
• 5.2.3 Optical encoder
• 5.2.4 Tachometer
• 5.3 Force sensors
• 5.4 Robot vision
• 6 Trajectory planning
• 6.1 Interpolation of the trajectory between two points
• 6.2 Interpolation by use of via points
• 7 Robot control
• 7.1 Control of the robot in internal coordinates
• 7.1.1 PD control of position
• 7.1.2 PD control of position with gravity compensation
• 7.1.3 Control of the robot based on inverse dynamics
• 7.2 Control of the robot in external coordinates
• 7.2.1 Control based on the transposed Jacobianmatrix
• 7.2.2 Control based on the inverse Jacobianmatrix
• 7.2.3 PD control of position with gravity compensation
• 7.2.4 Control of the robot based on inverse dynamics
• 7.3 Control of the contact force
• 7.3.1 Linearization of a robot system through inverse dynamics
• 7.3.2 Force control
• 8 Robot environment
• 8.1 Robot grippers
• 8.2 Feeding devices
• 8.3 Robot assembly
• 9 Standards and safety in robotics
• Robot vocabulary
• Further reading
• Index.