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You're reading from Practical Python Programming for IoT Build advanced IoT projects using a Raspberry Pi 4, MQTT, RESTful APIs, WebSockets, and Python 3

Product type Paperback

Published in Nov 2020

Publisher Packt

ISBN-13 9781838982461

Length 516 pages

Edition 1st Edition

Languages

Python

Tools

MQTT

Concepts

IoT Development

Author (1):

Gary Smart

View More author details

Table of Contents (20) Chapters

Preface

1. Section 1: Programming with Python and the Raspberry Pi

2. Setting Up your Development Environment FREE CHAPTER

3. Getting Started with Python and IoT

4. Networking with RESTful APIs and Web Sockets Using Flask

5. Networking with MQTT, Python, and the Mosquitto MQTT Broker

6. Section 2: Practical Electronics for Interacting with the Physical World

7. Connecting Your Raspberry Pi to the Physical World

8. Electronics 101 for the Software Engineer

9. Section 3: IoT Playground - Practical Examples to Interact with the Physical World

10. Turning Things On and Off

11. Lights, Indicators, and Displaying Information

12. Measuring Temperature, Humidity, and Light Levels

13. Movement with Servos, Motors, and Steppers

14. Measuring Distance and Detecting Movement

15. Advanced IoT Programming Concepts - Threads, AsyncIO, and Event Loops

16. IoT Visualization and Automation Platforms

17. Tying It All Together - An IoT Christmas Tree

18. Assessments

19. Other Books You May Enjoy

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Calculating the resistor value

In the preceding circuit diagram, we have the following parameters:

Supply voltage of 3.3 volts
LED typical forward voltage of 2.1 volts
LED current of 20 mA (test condition for mA is mentioned in the datasheet for voltage drops)

Here is the process to calculate the resistor value:

Our resistor (labelled R1) needs to drop 1.2 volts, which is a simple application of Kirchhoff's voltage law that we mentioned briefly previously; that is, The algebraic sum of all voltages in a loop must equal zero. So, if our source voltage is +3.3 volts and the LED drops 2.1 volts, then the resistor must drop 1.2 volts. This means we get the following equation:

+3.3V + -2.1V + -1.2V = 0V

We can arrange Ohm's Law algebraically so that we get the following:

Using this formula, we calculate our resistor's value:

= 60Ω (hence, resistor R1 in the preceding circuit is 60Ω)

But this is not 200Ω. Our example so far is a simple LED and...

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Authors (1)

Gary Smart

Gary Smart is a senior software engineer and an IoT and integration expert. The commencement of Gary's IT career coincided with the birth of the World Wide Web and has grown in line with the internet and emerging technologies ever since, including the rise of mobile phones and tablets, embedded technologies, SaaS and business migration to the cloud, and in recent years, the IoT revolution. Gary's practical experience includes both technical and management positions and experience in both small and large organizations, including Hewlett-Packard, Deakin University, and Pacific Hydro-Tango, boutique consulting firms, and innovative internet and IoT start-ups.

See other products by Gary Smart