I’m almost completely clueless regarding transistor circuits over and above using it as a switch. Before delving into the books and learning the theory and application of transistors, I decided to build a simple amplifier circuit, tweak it, and just test it out to see how it performs. Here follows what I ended up with.
Logic Gates. They’re all around us in many electronic devices. They make up the digital building blocks for circuits used in eg. counters, calculators, computers. In this
Logic Gates Tutorial, I will quickly touch on the basics of logic gates and their theory.
The Arduino will be the primary microcontroller platform that I will use for my electronics projects. The Arduino is an excellent platform with different boards and Atmel microcontrollers to suit most hobby needs. My personal board of choice is the Arduino Mega2560 and my posts will focus on that board but should in most cases be compatible with other Arduino boards as well.
- Based on ATmega2560
- 54 digital input/output pins incl 15 PWM outputs
- 16 analog inputs
- 4 Hardware serial ports (UARTs)
- 16 Mhz Crystal Oscillator
- USB connection and power jack
- ICSP header
- 256KB flash memory (8KB used by bootloader)
- 8 KB SRAM
- 4 KB EEPROM
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Development tools for Arduino is free! Just head on down to http://arduino.cc/ for more.
In my previous post, I showed how to connect seven segment displays to your Arduino microcontroller and how to drive them through multiplexing to display numerical values from your program.
In this post, I will build on that circuit and reduce the number of pins used on your microcontroller, as promised.
The circuit so far had 12 microcontroller pins used up to drive the seven segments (and decimal point) and select each individual digit display. What if you can reduce the number of pins to just 3? Easy! We can do this using shift registers.