Basics of Power Conversion: Power Semiconductors

Figure 1: The basic building blocks of power
conversion circuits are the power MOSFET and
the IGBT; shown are (left) an N-channel
enhancement-mode MOSFET and (right)
a P-channel (minority carrier) IGBT

There are a multitude of circumstances that make power conversion a necessity. Power conversion, of course, is the converting of electric power from one form to another, from one voltage to another, or one frequency to another; it also encompasses any/all combinations of these.

IoT Digital Power Management and Power Integrity

Figure 1: The half-bridge output
current from each DC-DC phase
is known as the inductor current

An Internet of Things (IoT) device derives its power either from a 12-V DC supply or from a battery. In either case, power is fed to one or more power rails that operate at different voltages. These rails power the CPU and other functional blocks on the PC board. In this post, we'll take a look at how to examine an IoT's power supply for proper digital power management implementation and for power integrity.

Analyzing Pulse-Width Modulation Signals

Figure 1: Persistence display provides
a quick-and-dirty view of a PWM signal

Pulse-width modulation (PWM), a favorite technique for achieving analog ends through digital means, finds application in all kinds of end systems. Motor control might be the number-one application, but PWM turns up in telecommunications, audio systems and amplifiers, and any number of other uses. Armed with a capable oscilloscope, one can thoroughly analyze and understand the behavior of PWM circuits.

Testing Techniques For Switch-Mode Power Supplies

Figure 1: A simplified schematic of
a switch-mode power supply circuit

On its journey from wall socket to the device being powered, power typically passes through a switch-mode power supply, where the AC signal is rectified into DC before it reaches the device. After that, the DC signal (often 5 V) is passed on to DC-DC converters on the device's PC board for feeding various voltages to branches of the device's power-delivery network. Let's look at some of the measurement techniques and considerations relative to testing switch-mode power supplies.

Testing Challenges in Motor Drive Systems (Part III)

Figure 1: An example of PWM for

a single power semiconductor

As noted in an earlier post, variable-frequency motor drives (VFDs) display a good amount of variation in terms of architectures and topologies. Another differentiator between VFDs is their application of pulse-width modulation (PWM) techniques.

Testing Challenges in Motor Drive Systems (Part II)

Figure 1: This image depicts the complete design and
debug challenge posed by a variable-frequency motor drive

In our first post on motor drive systems, we broke down the major subsystems in a "generic" variable frequency drive (VFD) and discussed some of the test requirements in those subsystems (Figure 1). Next, let's have a look at some of the variations in real-world VFDs in terms of architectures and topologies.

Testing Challenges in Motor Drive Systems

Figure 1: The power section of a motor drive system requires
measurements of line input, PWM output, and efficiencies

Motors are everywhere in our world, and nowhere more so than in  our vehicles. For example, when's the last time you had to crank a car window up and down to pay a highway toll? Or, for that matter, when did you last manually adjust the seat position or rear-view mirror angles? These aspects of vehicles are all typically motorized these days.

Waveform Generator Tricks: Pulse-Width Modulation

Figure 1: Teledyne LeCroy's WaveStation
waveform generator

Imagine that you're designing a digital control circuit but you really want it to behave like an analog circuit. Say, something like light dimmers, or a motor controller. A tried-and-true approach is to use pulse-width modulation (PWM) to have your digital control logic emulate the behavior of analog control. And your handy-dandy waveform generator, if so equipped, is a great way to generate a PWM signal to test out your design.

Zero in on Power Analysis

Given the emphasis on "green" initiatives, in which anything and everything is touted as "energy efficient," there's been lots of chatter about low-power design. Naturally, much attention is focused on switched-mode power supplies, power devices, and power-conversion circuitry of all kinds. This is where a lot of power efficiency is either lost or gained, depending on how carefully you approach the design task. You know, a milliohm here, a milliohm there, and pretty soon you're talking about real voltage drops that are going to affect the performance of a power-distribution system.