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586 Results
See how to use our new Power over Ethernet PSE system GUI in online mode

PSE system firmware GUI training: Online mode

Date:
October 1, 2019

Duration:
06:27
This quick training demos how to utilize the TI's PSE system software GUI in online mode.
Learn how to use the GUI for our new Power over Ethernet PSE system

PSE system firmware GUI training: Offline mode

Date:
October 1, 2019

Duration:
13:19
This quick video demos how to configure TI's new PSE system via the PoE PSE GUI tool in offline mode.
Multi-cell Charge Controller Training, Charger Topologoes

Hybrid boost and narrow-voltage DC architecture of multi-cell chargers

Date:
September 29, 2019

Duration:
08:07
This training provides an overview of the hybrid boost and narrow-voltage DC topologies using the popular BQ24800 and BQ25710 devices as examples.
Rapid prototyping functions WiFI

Rapid prototyping function based on optional Wi-Fi

Date:
September 29, 2019

Duration:
09:27
Step-by-step walk-through continues with an optional section that describes and demonstrates Wi-Fi functionality for rapid prototyping.

Processor SDK for KeyStone Processors

TI provides key runtime software components and documentation to further ease development. TI’s online training provides an introduction to the Processor SDK and how to use this software to start building applications on TI processors.

PRU for 66AK2Gx Processors

The Programmable Real-Time Unit (PRU) is a small processor that is tightly integrated with an IO subsystem, offering low-latency control of IO pins on TI’s SoC devices including the 66AK2Gx, AM335x, AM437x, and AM57x Processors. The PRU is customer-programmable and can be used to implement simple and flexible control functions, peripherals, and state machines that directly access IO pins of the device, as well as can communicate with the application cores.

High Frequency Challenges

Learn about how to overcome high frequency challenges using TI's series capacitor buck converter.

Introduction, value proposition and benefits

Series introduction to Mobile Smart TV and the market

Design considerations

Mobile Smart TV design considerations

Benefits of DLP Pico technology for Mobile Smart TV

Benefits of DLP in the Mobile Smart TV  application space

Introduction

This section covers wireless network trends, key technologies, and problem statements for smart grid IoT. 

System-Level Examples for Wireless Networks on 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. 

Summary

This section summarizes the wireless network challenges and solutions for a smarter grid IoT training series. 

Detecting magnetic tampering using hall-effect sensors

For anti-tampering, it is common to try to detect the presence of a strong magnet. In this section, we will cover the use of hall sensors for low-power detection of strong magnetic fields in three dimensions.  Details on our magnetic tamper detection reference design, TIDA-00839, will be provided as well as some of the design considerations that were kept in mind when creating this reference design.  

Hardening a meter against magnetic tamper attacks

In this section, we will cover how to harden a meter against these magnetic tamper attacks by using shunts for current sensors. For poly-phase implementations, I will go over how to use isolated delta sigma modulators to add the necessary isolation to use shunt current sensors and create magnetically immune poly-phase energy measurement systems. The TIDA-00601 and TIDA-01094 reference designs, which show how to implement a poly-phase isolated shunt measurement system, will be discussed as well as the associated AMC1304 high-side power supplies used in these designs.

TI-RSLK MAX Module - 1 Running code on the LaunchPad using CCS

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.

TI-RSLK MAX Module 2 – Voltage, current, and power

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.

TI-RSLK MAX Module 3 – ARM Cortex M

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.  

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