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Power Electronics

In contrast to traditional electronics, which is all about handling data, power electronics is all about handling power: generating it, converting it, and moving it from source to load. This technology finds applications in a wide range of industries including power utility generation and distribution; automotive; and consumer electronics. Thus, the power handling ranges from terawatts to milliwatts. Several trends are increasing the challenges that designers of power electronic devices must overcome, as detailed below.

  • Power utility generation and distribution - For the power grid, renewable sources such as photovoltaics (PV) and wind turbines present challenges not found in traditional power stations where the fuel can be bought close to the point of use. Locations with favorable wind and sunshine are not necessarily close to locations of consumption, so the plant must be brought to the “fuel”, and an extended distribution span is needed. PV sources are generally DC, necessitating high-power inverters to join them the AC grid.
  • Automotive - Even conventional-fuelled vehicles contain dozens of small- to medium- sized electric motors, an alternator, a traditional battery, and electronic subsystems, with the amount increasing every model year. Designers of electric vehicles (EVs) and hybrid electric vehicles (HEVs) face the additional challenges of high-power drive motors, generators in regenerative braking configuration, and high capacity batteries. The problem of drive train control becomes one of mechatronics: the combination of electromechanical components, power electronics, microcontroller chips (e.g. engine control units or ECUs), and control software.
  • Consumer electronics - Devices such as smart phones and a new class of devices that will form the “Internet of things” (IoT) are generally battery powered and of a compact form factor. Power conversion efficiency is key to long battery life and to prevent overheating. Power management units (PMUs) are specialized ICs, customized for these high-volume applications. The designs are tightly constrained by efficiency, form-factor and of course, given the short product cycles in the consumer space, time-to-market. 

Keysight offers multiple product families and solutions to help with your power electronic design and test needs.

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Accuracy matters: Calibration Options for Lab Standards Webcast 
Original broadcast May 19, 2016

Webcast

 
Designing Switched-Mode Power Supplies in the High di/dt Era Seminar 
The increasing demand for reliable, low cost, high power density power electronics is driving up the edge speed (di/dt) of switched mode power supplies. In this high di/dt era, layout parasitics become increasingly troublesome. Traditional design techniques are not adequate. A new methodology that adds post-layout design and simulation is required. In this seminar, we will present four papers that address these challenges.

Seminar Materials 2018-10-11

 
Solving IoT Device Test Challenges Webinar Series 
Webcast series

Webcast

 
Tips to Generate High Accuracy Waveforms to Test your Medical IoT Device 
Original broadcast January 25, 2018

Webcast - recorded

 
Optimize Your Battery Management System Webcast 
Original broadcast December 6, 2017

Webcast - recorded

 
Overcome Critical Power Consumption Testing Challenges Webcast 
Original broadcast December 13, 2017

Webcast - recorded

 
Switch Mode Power Supply Measurements and Analysis using Oscilloscopes 
Original broadcast November 18, 2014

Webcast - recorded

 
Power Integrity Challenges, Measurements and Labs Webcast 
Original broadcast February 23, 2016

Webcast - recorded

 
How to Design Power Electronics: HF Power Semiconductor Modeling Webcast 
Original broadcast September 3, 2015

Webcast - recorded