Jack H
2.1.1 What is it?
Linux is an open source operating system. It is open because users and developers can use the source code any way they want. This allows anyone to customize it, improve it and add desired features. As a result Linux is dynamic, evolving to respond to the desires and needs of the users. In contrast, closed operating systems are developed by a single corporation using static snapshots of market models and profit driven constraints.
Linux is free. This allows companies to use it without adding cost to products. It also allows people to trade it freely. And, with the profit motive gone, developers have a heightened sense of
Содержание
- 1.3 PRACTICE PROBLEMS
- 2. AN INTRODUCTION TO LINUX/UNIX
- 2.1 OVERVIEW
- 2.1.1 What is it?
- 2.1.7 Distributions
- 2.1.8 Installing
- 2.2 USING LINUX
- 2.2.1 Some Terminology
- 2.2.4 Processes
- 2.3 NETWORKING
- 2.3.1 Security
- 2.4 INTERMEDIATE CONCEPTS
- 2.4.1 Shells
- 2.4.4 Desktop Tools
- 2.5 LABORATORY - A LINUX SERVER
- 2.8 REFERENCES
- 3.7 ARCHITECTURE OF ‘C’ PROGRAMS (TOP-DOWN)
- 3.9 CASE STUDY - THE BEAMCAD PROGRAM
- 3.9.1 Objectives:
- 3.9.2 Problem Definition:
- 3.9.3 User Interface:
- 3.9.3.1 - Screen Layout (also see figure):
- 3.9.7 Documentation
- 3.9.7.1 - Users Manual:
- 3.9.7.2 - Programmers Manual:
- 3.10 PRACTICE PROBLEMS
- 3.11 LABORATORY - C PROGRAMMING
- 4. NETWORK COMMUNICATION
- 4.1 INTRODUCTION
- 4.2 NETWORKS
- 4.2.1 Topology
- 4.2.3 Networking Hardware
- 4.2.6 SLIP and PPP
- 4.3 INTERNET
- 4.3.2 Computer Ports
- 4.3.3 Security
- 4.4 FORMATS
- 4.4.1 HTML
- 4.4.5 Java
- 4.4.6 Javascript
- 4.6 DESIGN CASES
- 4.9 LABORATORY - NETWORKING
- 5. DATABASES
- 5.2 DATABASE ISSUES
- 6. COMMUNICATIONS
- 6.1 SERIAL COMMUNICATIONS
- 6.2 SERIAL COMMUNICATIONS UNDER LINUX
- 6.3 PARALLEL COMMUNICATIONS
- 7. PROGRAMMABLE LOGIC CONTROLLERS (PLCs)
- 7.12.1 Data Files
- 7.12.1.4 - PLC Status Bits (for PLC-5s)
- 7.12.1.5 - User Function Memory
- 7.13 INSTRUCTION TYPES
- 7.13.1 Program Control Structures
- 7.13.2 Branching and Looping
- 7.13.3 Basic Data Handling
- 7.13.3.1 - Move Functions
- 7.15 LOGICAL FUNCTIONS
- 7.20 DESIGN TECHNIQUES
- 7.20.1 State Diagrams
- 7.23.1 SWITCHED INPUTS AND OUTPUTS
- 7.25 PRACTICE PROBLEMS
- 8.2 PROPRIETARY NETWORKS
- 8.2.0.1 - Data Highway
- 8.4 LABORATORY - DEVICENET
- 8.5 TUTORIAL - SOFTPLC AND DEVICENET
- 9. INDUSTRIAL ROBOTICS
- 9.1 INTRODUCTION
- 9.1.1 Basic Terms
- 9.2.2 Types of Robots
- 9.2.2.1 - Robotic Arms
- 9.3 MECHANISMS
- 9.5.2 Movemaster Programs
- 9.5.2.0.1 - Language Examples
- 9.5.3 Command Summary
- 9.6 PRACTICE PROBLEMS
- 9.7 LABORATORY - MITSUBISHI RV-M1 ROBOT
- 10. OTHER INDUSTRIAL ROBOTS
- 10.1 SEIKO RT 3000 MANIPULATOR
- 10.1.1.2 - Commands Summary
- 10.2 IBM 7535 MANIPULATOR
- 10.2.1 AML Programs
- 10.3 ASEA IRB-1000
- 10.6 LABORATORY - SEIKO RT-3000 ROBOT
- 11. ROBOT APPLICATIONS
- 11.0.1 Overview
- 11.1 END OF ARM TOOLING (EOAT)
- 11.1.1 EOAT Design
- 11.1.2 Gripper Mechanisms
- 11.1.3 Magnetic Grippers
- 11.1.3.1 - Adhesive Grippers
- 11.1.4 Expanding Grippers
- 11.3 INTERFACING
- 12. SPATIAL KINEMATICS
- 12.1 BASICS
- 12.2.1 Denavit-Hartenberg Transformation (D-H)
- 12.3 SPATIAL DYNAMICS
- 12.3.1 Moments of Inertia About Arbitrary Axes
- 12.4 DYNAMICS FOR KINEMATICS CHAINS
- 12.4.1 Euler-Lagrange
- 12.4.2 Newton-Euler
- 13.1.3 Modeling the Robot
- 13.2.2 Computer Control of Robot Paths (Incremental Interpolation)
- 13.4 LABORATORY - AXIS AND MOTION CONTROL
- 14. CNC MACHINES
- 14.1 MACHINE AXES
- 14.2 NUMERICAL CONTROL (NC)
- 14.3 EXAMPLES OF EQUIPMENT
- 14.3.1 EMCO PC Turn 50
- 14.4 PRACTICE PROBLEMS
- 14.5 TUTORIAL - EMCO MAIER PCTURN 50 LATHE (OLD)
- 14.6.1 LABORATORY - CNC MACHINING
- 15.3 PROPRIETARY NC CODES
- 16.5 DISCRETE IO
- 16.6 COUNTERS AND TIMERS
- 16.7 ACCESSING DAQ CARDS FROM LINUX
- 16.8 SUMMARY
- 16.9 PRACTICE PROBLEMS
- 17. VISIONS SYSTEMS
- 17.1 OVERVIEW
- 17.11 PRACTICE PROBLEMS
- 18. INTEGRATION ISSUES
- 18.1 CORPORATE STRUCTURES
- 18.2 CORPORATE COMMUNICATIONS
- 19. MATERIAL HANDLING
- 19.1 INTRODUCTION
- 19.3 PRACTICE QUESTIONS
- 19.4 LABORATORY - MATERIAL HANDLING SYSTEM
- 19.4.1 System Assembly and Simple Controls
- 19.5 AN EXAMPLE OF AN FMS CELL
- 19.5.1 Overview
- 19.6 THE NEED FOR CONCURRENT PROCESSING
- 20. PETRI NETS
- 20.1 INTRODUCTION
- 20.2 A BRIEF OUTLINE OF PETRI NET THEORY
- 20.4.3 An Exclusive OR Transition:
- 20.4.5 RELATIONAL NETS
- 20.7 PRACTICE PROBLEMS
- 21. PRODUCTION PLANNING AND CONTROL
- 21.1 OVERVIEW
- 21.2 SCHEDULING
- 21.3 SHOP FLOOR CONTROL
- 21.3.1 Shop Floor Scheduling - Priority Scheduling
- 22. SIMULATION
- 22.3 DESIGN OF EXPERIMENTS
- 23. PLANNING AND ANALYSIS
- 23.1 FACTORS TO CONSIDER
- 24. REFERENCES
- 25. APPENDIX A - PROJECTS
- 25.1 TOPIC SELECTION
- 25.1.1 Previous Project Topics
- 25.2 CURRENT PROJECT DESCRIPTIONS