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Power fundamentals - buck regulator architectures

This series provides an overview of the various buck regulator architectures, including:

  • Multi-Phase Buck Regulators
  • Hysteretic Buck Regulators
  • COT Buck Regulators
  • Current/Emulated Current Mode Buck Regulators
  • Voltage Mode Buck Regulators

Power fundamentals - DC-DC fundamentals

This five-part series provides an overview of DC-DC converters.

Switching Power Supply Component Selection

This 7-part series discusses tips and best practices for selecting the appropriate components for your switching power supply.

Not All Regulators Are Created Equal

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.

Engineer It - How to Test Power Supplies

TI's Bob Hanrahan describes how to properly test a DC/DC power supply, and ensure that it works reliably over various operating conditions. This four-part series is intended to provide the designer with a suffici

Fixed Frequency vs Constant On-Time Control of DC/DC Converters

In depth comparison of voltage mode, current mode control vs DCAP2 and DCAP3 control modes for step down DC/DC converters.

Designing with TI's Series Capacitor Buck Converter

Learn the features and benefits of TI's new DC/DC power topology, the series capacitor buck converter, and get started using it in your space-constrained design. 

How to power your PMBUS

Series discusses provides an introduction and subsequent details on how to power the PMBUS.

How to Power Automotive Front-End Systems

This training series provides tips and tricks on how to power automotive front-end systems through designing an ADAS processor or an infotainment power supply as well as designing a pre-boost solution. 

Optimizing DC/DC Converters for EMI in Automotive systems

Optimizing DC/DC Converters for EMI in Automotive Systems

EMI (electromagnetic interference) mitigation is a critical step in the design process in most electronic systems, and especially so in the automotive world. In many cases, automotive OEM emissions requirements are even more stringent than both national and international standards bodies like the FCC. Unfortunately, by their nature, switching regulators are sources of EMI; but, in order to keep power supply designs small and efficient, switchers are a critical component. So how can you reap the benefits of a switching regulator while still meeting challenging EMI requirements?

Automotive front end power stage

Riding Out Automotive Transients : Architecting Front End Power Conversion Stage for Automotive Off-Battery Loads

With rapidly expanding electronic content in latest generation of cars, there is an ever increasing need for power conversion from the car battery rail. The 12-V battery rail is subject to a variety of transients. This presents a unique challenge in terms of the power architecture for off-battery systems. This presentation introduces the different types of transients that occur in automotive battery rails, the causes of those transients, and the standards and specifications defining the test conditions for those transients.

Practical Comparisons of 3 different DC-DC Control Modes

Certain end-equipment, like communications, server, industrial, and personal electronics have design challenges solved by the DC/DC converter’s control-mode.  This session will compare and contrast 3 different devices using 3 different control modes under the same design criteria to see how each control mode solves particular size, efficiency, external component, ripple and transient response design challenges.

MicroSiP Power Modules Decrease Solution Size and Increase Power Density

MicroSiP Power Module Evolution from Discrete Power Converters

Learn about MicroSiP power module construction and how they have greatly increased the power density of power supplies over the years.  See the evolution of discrete power converters to their MicroSiP power module counterparts.  Specific comparisons and tradeoffs for the TPS82130, TPS82085, and TPS82671 are discussed.

Low EMI and Noise performance with DC/DC switching regulators

Achieving low noise and low EMI performance with DC/DC switching regulators

Mitigating switching regulator EMI and noise is seen by engineers as a black art. Mess with the feng shui of the PCB layout too much, and the system may not pass CISPR standards. Because of this, many power designers simply turn to linear regulators as a guaranteed way to avoid the headache of reducing emissions.

Multiphase 101

In today’s computing environment, CPUs, FPGAs, ASICs and even peripherals are growing increasingly complex and, consequently, so do their power delivery requirements. To handle the higher demands, multiphase regulators are becoming increasingly common on motherboards in many areas of computing--from laptops and tablets to servers and Ethernet switches. Designing with these regulators is more challenging than using conventional switchers and linear regulators, but the benefits of multiphase outweigh the complexity for high-performance power applications.

Managing heat dissipation with DC/DC switching regulators

Managing heat dissipation has always been a critical concern for any power supply designer, and this concern has only grown in importance as output current levels have increased while IC package sizes have gotten smaller. This page serves as your ultimate resource for all training materials and technical documentation related to keeping your switching regulator running cool.  

There are numerous ways to address thermals. This library of training content is broken out by some of these key approaches to improving the thermal performance of your switching regulator.

DC/DC Buck Converters: What do all of these features mean?

As switching converters have evolved, they have taken on a host of new features to operate more efficiently and quietly. To some, however, all these new features listed on the front page of the datasheet may seem foreign. This training series dives into those features to explain the true benefits of each and help you decide which are necessary for your power supply design. Specifically covered in this series are the buck converter topics of:

Layout, power loss, and packaging to address thermal concerns with integrated FET DC/DC converters

This training series dives into how to get the best thermal performance with TI’s latest buck converters. Special focus given to the HotRod package.

Power Distribution for SoC and FPGA applications

In this training series, we examine the power requirements of SoC and FPGA devices discuss the optimal approach to powering them for specific use cases.
107 Results
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