We've seen in the previous articles how Ada can be used to describe high-level semantics and architecture. The beauty of the language, however, is that it can be used all the way down to the lowest ...

Most embedded systems are reactive by nature. They measure certain properties of their environment with sensors and react on changes. For example, they display something, move a motor, or send a ...

Analytics-driven embedded systems bring analytics to embedded applications, moving many of the functions found in cloud-based, big-data analytics to the source of data. This allows for more efficient ...

Defining device drivers Discussing the difference between architecture-specific and board-specific drivers Providing several examples of different types of device drivers Most embedded hardware ...

In this course, students will design and build a microprocessor-based embedded system project managing real-time constraints while analyzing the system in-order to meet them. Students are expected to ...

Explore the core differences between embedded systems and robotics engineering. Understand their unique applications, fundamental concepts, and how these fields intersect and diverge in technology and ...

The embedded systems industry has been going through some rapid changes as modern software techniques are finding their way into our industry. While the specific techniques that will transform your ...

Because the operating system controls the resources (e.g., memory, CPU) of the embedded system, it has the power to prevent unauthorized use of these resources. Conversely, if the operating system ...

Usable product life is a critical factor in the success of any portable device, and managing power efficiency is a key requirement for embedded systems today. Historically, power management was seen ...

This course will give you the foundation for FPGA design in Embedded Systems. You will learn what an FPGA is and how this technology was developed, how to select the best FPGA architecture for a given ...