The "Python" programming language has enjoyed an enormous upswing in recent years. Not least, various single-board systems such as the Raspberry Pi have contributed to its popularity. But Python has also found widespread use in other fields, such as artificial intelligence (AI) or machine learning (ML). It is obvious, therefore, to use Python or the "MicroPython" variant for use in SoCs (Systems on Chip) as well. Powerful controllers such as the ESP32 from Espressif Systems offer excellent performance as well as Wi-Fi and Bluetooth functionality at an affordable price. With these features, the Maker scene has been taken by storm. Compared to other controllers, the ESP32 has a significantly larger flash and SRAM memory, as well as a much higher CPU speed. Due to these characteristics, the chip is not only suitable for classic C applications, but also for programming with MicroPython. This book introduces the application of modern one-chip systems. In addition to the technical background, the focus is on MicroPython itself. After the introduction to the language, the programming skills learned are immediately put into practice. The individual projects are suitable for use in the laboratory as well as for everyday applications. So, in addition to the actual learning effect, the focus is also on the joy of building complete and useful devices. By using laboratory breadboards, circuits of all kinds can be realized with little effort, turning the testing and debugging of the 100% homebrew projects into an instructive pleasure. The various applications, such as weather stations, digital voltmeters, ultrasound range finders, RFID card readers or function generators, make the projects presented ideally suited for practical courses or subject and study work in the natural sciences, or in science and technology classes.

lgli/micropython-microcontrollers-projects-esp32.rar

lgrsnf/micropython-microcontrollers-projects-esp32.rar

Spanner, Günter

Elektor Verlag GmbH

Germany, Germany

{"isbns":["389576437X","9783895764370"],"last_page":229,"publisher":"Elektor International Media"}

Content
Notices and Disclaimers
Demo Programs Download Archive
Chapter 1 • Introduction
1.1 Python, C, or Arduino?
1.2 Requirements
Chapter 2 • A Variety of ESP Boards
2.1 Commissioning and function test
2.2 ESP32 on battery power
Chapter 3 • Programming and Development Environments
3.1 Installing the uPyCraft IDE
3.2 MicroPython for the ESP32
3.3 "Hello World" for the controller
3.4 For professionals: Working with esptool
3.5 Thonny — a Python-IDE for beginners
3.6 Working with Thonny
3.7 Working with files
3.8 Troubleshooting tips for the Thonny IDE
Chapter 4 • First Steps in Programming
4.1 Never without: Comments
4.2 The Print() statement
4.3 Indentations and blocks
4.4 The hardware under control: digital inputs and outputs
4.5 Time control and sleep
4.6 Important values: variables and constants
4.7 Numbers and types of variables
4.8 Converting number types
4.9 Little Big Data: Arrays
4.10 Operators
4.11 With format, please: appealing text and data output
4.12 Characters in chains: strings
Chapter 5 • The Controller in Practical Use
5.1 LED flasher as alarm system simulator
5.2 Useful in an emergency: automatic SOS signal
Chapter 6 • Program Structures
6.1 Conditions and loops
6.2 Running lights and airport lighting
6.3 Electronic rainbow: RGB LED in use
6.4 SOS compact-style
6.5 Trial and error: try and except
Chapter 7 • Analogue-Signal Generation
7.1 Pulsewidth modulation
7.2 For romantic evenings: heartbeat simulator
7.3 Light alarm clock for a relaxed wake-up
7.4 Mood-Light with multicolour LED
7.5 Clean and smooth: analogue values from the DAC
7.6 Output of time-dependent voltages
7.7 For interesting curves: An arbitrary function generator
Chapter 8 • Interrupts and Timers
8.1 Disruption wanted: Interrupts
8.2 Automatic night light
8.3 Masters of Time: Timers
8.4 A multifunctional flashing light
Chapter 9 • Using Sensors
9.1 Acquisition of measurement and sensor values
9.2 Precise recording of voltages: a DIY voltmeter
9.3 Linearity correction
9.4 Linearization by limitation of the value range
9.5 Linearization of the ADC input by means of compensation polunomial
9.6 Voltage measurement
9.7 Cross-interferences: side effects in sensor technology
9.8 Touching permitted: capacitive touch sensors
9.9 Well chilled or overheated: temperature sensors provide clarity
9.10 Digital temperature recording for error-free data transmission
9.11 The DS18×20 One-Wire sensor
9.12 Data power: multi-sensor array with the DS18x20 thermal sensor
9.13 In full view: optical sensors
9.14 For film and photo professionals: electronic luxmeter
9.15 Electronic bats: distance measurement with ultrasound
9.16 No more dents and scratches: distance warning device for garages
9.17 Optimum indoor climate for flora and fauna
9.18 "Trust me ...": sensor comparison
9.19 Air pressure and altitude measurement
9.20 Detecting magnetic fields with the Hall sensor
9.21 Alarm detectors monitor door and gate
Chapter 10 • Display Technology and Small-Size Screens
10.1 Graphical representations
10.2 OLED display as data plotter
10.3 The exact time please: digital clock with OLED display
10.4 Not just for athletes: a stopwatch
10.5 Just touch: stop watch with sensor keys
10.6 Great climate with the BME280 sensor!
Chapter 11 • LED Matrices and Large Displays
11.1 LED matrix in action
11.2 Running scripts and animated graphics
Chapter 12 • Physical Computing: Servos bring movement into play
12.1 A servo tester
12.2 Mega-display servo thermometer
Chapter 13 • RFID and Wireless Data Transmission
13.1 Reading cards and chips
13.2 Contactless and secure: RFID lock
Chapter14 • MicroPython and the Internet of Things (IoT)
14.1 For modern detectives: a network scanner
14.2 Connected but no cables: WLAN
14.3 Switch and control with the web server
14.4 The WLAN web server in action
14.5 Reading out sensor data via WLAN
14.6 Recording environmental parameters: WLAN Thermo/Hygrometer
Chapter 15 • Simple and Good: The MQTT Protocol
15.1 MQTT via ThingSpeak
Chapter 16 • Sending Data to the Internet via ThingSpeak
16.1 Rain or storm? Virtual weather station available worldwide
16.2 Graphical representation of data in ThingSpeak
16.3 Data for the smartphone with the ThingView app
16.4 Against unwanted visitors: Optical room surveillance
Chapter 17 • Micropower Techniques and Sleep Modes
17.1 Saving power protects the environment: low-power technologies
17.2 Disabling unnecessary consumers
17.3 Weather station with battery or solar operation
Chapter 18 • Bus Systems for Efficient Communication
18.1 Basics and applications of the I2C bus
18.2 The SPI bus
18.3 The members of the SPI family
18.4 Controlling SD and μSD cards via SPI
Chapter 19 • Building Circuits with Components and Breadboards
19.1 Breadboards
19.2 Wire jumpers and jumper cables
19.3 Resistors
19.4 Light-emitting diodes (LEDs)
19.5 Capacitors and electrolytic capacitors
Chapter 20 • Troubleshooting
Chapter 21 • Hardware Resources
Chapter 22 • List of Figures
Chapter 23 • Bill of Materials
Index

2023-07-07