As we continue the series on Embedded Systems Programming, this article will present the 2nd part, which is about the hardware or the peripheral circuitry required to run a microprocessor. It ...

The ESP32 by Example course, paired with Prof. Jim Solderitsch’s guidance, teaches you the hardware, code, and systems behind ...

The very first step in starting an embedded Linux system does not involve Linux at all. Instead, the processor is reset and starts executing code from a given location. This location contains a ...

At the end of the second article in this series, which outlines a step-by-step process for embedded Linux development, we had the LBox up and running, ready to use for application development. On some ...

This engineering specialization provides students with the fundamentals of embedded operating systems including a working understanding of how to configure and deploy a Linux based Embedded System.

In several of my previous posts, we’ve been looking at embedded software testing using Cpputest and build environments using Docker. Each topic is a building block ...

This module is intended to equip students with the core knowledge of 'how hardware works' in digital systems and introduce the concept of embedded systems using examples/case studies. The module ...

Counter/timer hardware is a crucial component of most embedded systems. In some cases a timer is needed to measure elapsed time; in others we want to count or time some external events. Here's a ...

When tasks share resources, as they often do, strange things can and will happen. Priority inversions in embedded systems can be particularly difficult to anticipate. Here’s an introduction to ...

The microcontroller’s basics, structure, operation, and software were already been covered in the previous parts of the series. Now, the 4th part of Embedded Systems Programming series, will discuss ...