The SimpleLink SDK includes TI Drivers, a robust set of intuitive, functional APIs that offer portable, feature-rich access to peripherals. The TI Drivers API exposes the functionality of the hardware-specific drivers in the same way across all TI SimpleLink devices, giving developers portable, feature-rich access to a variety of peripherals. TI drivers are open source [Berkeley Software Distribution license (BSD)] and built on a hardware abstraction layer, offering full access to the device’s complete capability.
The SimpleLink™ SDK features POSIX (Portable Operating System Interface), which is a family of standards specified by the IEEE Computer Society for maintaining compatibility between operating systems. Through POSIX-compliant APIs, developers can maintain 100% application code portability between various OS/kernels.
The SimpleLink SDK comes integrated with TI-RTOS. Checkout the trainings below to learn about multi-threaded applications & the features available with TI-RTOS.
This section covers wireless network trends, key technologies, and problem statements for smart grid IoT.
This section covers system-level deep dive on key wireless network protocols of 6LoWPAN, RPL, and CoAP for smart grid IoT.
This section covers system-level examples for wireless networks on smart grid IoT. We will provide software- and system-level details for two system examples: 6LoWPAN-Contiki and sub-1GHz sensor to cloud industrial IoT gateway reference design.
This section summarizes the wireless network challenges and solutions for a smarter grid IoT training series.
Debugging Embedded Linux Systems training series teaches the techniques of debugging kernel issues that may be encountered in embedded Linux systems. It explains the Linux kernel logging system and logging API, illustrates how to locate a particular device driver, and demonstrates how to read kernel oops logs.
This section contains task-specific videos that demonstrate how to perform debugging techniques on embedded Linux systems.
The purpose of this module is to learn software development methodology and understand how to set up an Integrated Development Environment (IDE), to then import and export Code Composer Studio (CCS) projects, as well as critical debugging information to understand the memory usage and performance of the software on the processor.
The purpose of this course is to review basic electronic components and the electrical properties needed to interface sensors and actuators to a microcontroller. You will learn how to measure reactance of a capacitor and use your project to measure current and voltage. The electrical properties of the capacitor will help you design circuits that “filter” or remove noise from your robot.
This module serves as a brief introduction to the ARM Cortex-M microcontroller, assembly programming language and some debugging techniques. Understanding how the processor works is essential for the design of embedded systems, such as the one used in your robot.
This module is an introduction to C, a general-purpose programming language, in addition to the concepts of compiling and debugging using the MSP432 and TI Code Composer Studio™. Debugging skills are a valuable tool when developing complex systems involved with robotics.
The purpose of this module is to learn how to power your robot. To run the robot (motor and other systems) you will need batteries and a regulator to provide constant voltage. Understanding the relationship between voltage current and power is an essential component of robot system design.