System
Networked control systems with Arduino: an introduction to technology, programming and robotics
Descripción de curso Traditional control systems are nowadays becoming in global data sharing solutions based on open platforms and free data repositories. In this context, Arduino is one of the most employed electronic devices in order to implement simple control solutions. This platform includes the most common communication ports (like UART or I2C) and supports the most popular communication protocols such as MQTT. This course describes all these details and shows how designing and implementing control system using Arduino devices. Moreover, the technique to connect to the global Internet the constructed control systems and allow a global data sharing is also described.
The Arduino Platform and C Programming
The Arduino is an open-source computer hardware/software platform for building digital devices and interactive objects that can sense and control the physical world around them. In this class you will learn how the Arduino platform works in terms of the physical board and libraries and the IDE (integrated development environment). You will also learn about shields, which are smaller boards that plug into the main Arduino board to perform other functions such as sensing light, heat, GPS tracking, or providing a user interface display. The course will also cover programming the Arduino using C code and accessing the pins on the board via the software to control external devices. Please note that this course does not include discussion forums.
Upon completing this course, you will be able to:
1. Outline the composition of the Arduino development board
2. Describe what it means to program the board's firmware
3. Read board schematics
4. Install Arduino IDE
5. Describe what "shields" are and how they are used
6. Specify the role of libraries in the use of shields
7. Compile and run a program
8. Name C Variables and Types
9. Name common C operators
10. Use conditionals and loops
11. Explain functions, their definition and invocation
12. Explain the implications of global variables
13. Undertake the Arduino build process
14. Describe the role of the tools behind the IDE
15. Describe how to invoke functions in classes
16. Explain the structure of an Arduino sketch
17. Access the pins of the Arduino
18. Differentiate between digital and analog pin
19. Debug embedded software
20. Explain the importance of controllability and observability in the debugging process
21. Describe common debugging architectures for embedded systems
22. Explain how the UART Serial communication protocol works 23. Describe how the Arduino Serial library performs serial communication