Learn about design tips from Texas Instruments' leading power experts to help with all your power design challenges and get you to market faster.
Power Switching Device Cannot Drive Themselves - Mastering the Art of High Voltage Gate Driver Design in UPS, Telecom, and Servers
We live in a world where designers are constantly pursuing higher efficiencies and higher power densities. Our customers want more power out with less power loss, while achieving smaller solution sizes! They strive to reduce switching losses while maintaining signal integrity. The need for higher efficiency and power density is a trend seen across isolated and non-isolated power systems in Uninterruptible Power Supplies (UPS), Telecom Rectifiers, and Server PSUs.
Applications Engineer Jason Tao discusses PFC basics, topology comparisons and design considerations to achieve a cost-optimized and efficient PFC design.
Shunt sensors are rapidly replacing current transformers as the preferred current sensing solution for electricity meters(e-meters) around the world.
Learn about opportunities for low voltage motors in major appliances, small appliances and power tools. Understand power stage architectures, topologies and control methods for low voltage brushed DC, stepper and brushless DC motors as well as the system design aspects, challenges and solutions.
Explore several subtle nuances to significantly improve power supply performance. Examples include: the hidden advantages of synchronous regulators, a module that features the best attributes of a switcher AND an LDO, and tips to reduce system noise by manipulating output capacitor combinations.
Join our webinar series, as we explore different industry trends and technologies across our diverse product portfolio. Over the coming months, our experts will cover the latest analog and embedded processing topics across industrial applications.
The mmWave training series is designed for you to learn the fundamentals of FMCW technology and mmWave sensors, and start development quickly. TI's portfolio of mmWave sensors features the AWR automotive radar sensor family and the IWR industrial mmWave sensor family, which are intended to be used for detecting range, velocity and angle of objects. Learn more about the silicon, tools, software and some of the applications for both mmWave families in the mmWave training series.
This training series discusses the key requirements of local oscillator in microwave/RF and GHz clocks in radio applications. The topics covered establish the key relationships between the requirements of a signal source and their impact in a radio system. After this training, you will be armed with the ability to understand the system requirements of your customer and how they pertain to a signal source so you can engage with your customer in a very meaningful way.
We live in a world where design engineers are on a seemingly constant pursuit for higher efficiency. Everyone wants to do more with less power. Higher system efficiency is a team effort that includes (but is not limited to) better-performing gate drivers, controllers and new wide-bandgap technologies. In this multi-part video series, we will focus on the gate drivers and how choosing the right driver can help your whole system design. You will learn about important gate driver specs, why they’re important, and how they can influence the systems around them.
This training series covers critical power supply design parameters such as EMI mitigation, heat dissipation, and loop compensation. Each training module features guidance using the LM4360x/LM4600x Synchronous SIMPLE SWITCHER® step-down voltage regulator as an example device.
Provides details of the software, hardware, tools, and resource components that make up the SimpleLink SDK software development kit, with an overview of TI-RTOS concepts and labs illustrating how to use the SDK to build and port applications between SimpleLink devices.
This training series provides an introduction to spectroscopy in food and agriculture industries using DLP® technology. Key training sections include:
- Fundamentals of DLP Technology-Based Spectroscopy
- Sampling Techniques in Near-Infrared (NIR) Spectroscopy
- Analyzing Food Traits using Near-Infrared (NIR) Spectroscopy
- Analyzing Agricultural Crop and Soil using Near-Infrared (NIR) Spectroscopy
Power electronics impacts our lives in so many ways - from new power circuits that extend battery life to voltage regulators that help manage and distribute energy more efficiently from the grid to the consumer. This four-part Power 101 fundamentals course covers several topics that a design engineer needs to understand when it comes to power management design.
These video series will talk about the different types of motors used in the industry; DC, Brushless DC, Steppers, Permanent Magnet Synchronous, and AC Induction. To gather a better understanding of motors, differences of these motors with advantages and disadvantages of each will be shown. Basic motor drive circuits will be discussed from full H-Bridge drive to half-bridge for 3-phase motors. Other drive concepts such as 6-step commutation along with drive issues such as current recirculation will be discussed. Field Oriented Control will also be discussed and how
This training series will discuss the design considerations for global EV charging station standards and the differences to consider for AC versus DC charging stations and for residential vs. public stations. The training also includes deep dives into the block diagrams with subsystem analysis and recommendations.
Welcome to this training series: How to Measure ECG: A Guide to the Signals, System Blocks, and Solutions.
We are all well aware that the demand for Electric Vehicles (EV) is increasing rapidly. This eight-part training session begins with a description of a typical EV system in part 1. Part 2 is a brief description of how both Lead Acid and Lithium Ion batteries are charged. Part 3 focuses on the types of power factor and harmonic currents. Part 4 discusses power factor correction and the typical boost PFC stage. Part 5 concentrates on the Phase Shifted Full Bridge topology, including the reasons why it is used and a detailed description of how it operates.