Linear vs. Switch-Mode Power Supplies

Intro

Linear power supplies were the mainstay of power conversion until the late 1970’s when the first

commercial switch-mode became available. Now apart from very low power wall mount linear power

supplies used for powering consumer items like cell phones and toys, switch-mode power supplies are

dominant.

So what is the difference in how they work?

Linear power supplies have a bulky steel or iron laminated transformer. This transformer has two purposes

- It provides a safety barrier for the low voltage output from the AC input and reduces and the input from

typically 115V or 230VAC to a much lower voltage around say 30VAC.

The low voltage AC output from the transformer is then rectified by two or four diodes and smoothed into

low voltage DC by large electrolytic capacitors.

That low voltage DC is then regulated into the output voltage of choice by a dropping the difference in

voltage across transistor or IC (the shunt regulator).

Switch-mode supplies are a lot more complicated. The 115V or 230VAC voltage is rectified and smoothed

by diodes and capacitors resulting in a high voltage DC. That DC is then converted into a safe, low

voltage, high frequency (typically switching at 100kHz to 500kHz) voltage using a much smaller ferrite

transformer and FETs or transistors. That voltage is then converted into the DC output voltage of choice by

another set of diodes, capacitors and inductors. Corrections to the output voltage due to load or input

changes are achieved by adjusting the pulse width of the high frequency waveform.

Sounds complicated? Yes, but the payoff is worth it!

The advantages and drawbacks of both technologies

Size: - A 50W linear power supply is typically 3 x 5 x 5.5”, whereas a 50W switch-mode can be as small as

3 x 5 x 1”. That’s a size reduction of 80%.

Weight: - A 50W linear weighs 4lbs, a corresponding switcher is 0.75lb. As the power level increases, so

does the weight. I personally remember a two-man lift needed for a 1000W linear. Today I carry a 2000W

in my carry-on luggage when I fly!

Input Voltage Range: - A linear has a very limited input range requiring that the transformer taps be

changed between different countries. Normally on the specification you will see

100/120/220/230/240VAC. This is because when input voltage drops more than 10%, the DC voltage to

the shunt regulator drops too low & the power supply cannot deliver the required output voltage. At input

voltages greater than 10%, too much voltage is delivered to the regulator resulting in overheating.

If a piece of equipment is tested in the US and shipped to Europe, or even to Mexico in some cases, the

transformer “taps” have to be manually changed. Forget to set the taps? The power supply will most

certainly blow the fuse, or may well be damaged.

Most switch-mode supplies will operate anywhere in the world (85 to 264VAC), from industrial areas in

Japan to the outback of Australia without any adjustment.

The switch-mode supply will also be able to withstand small losses of AC power in the range of 10-20ms

without affecting the outputs. A linear will not. No one will care if the AC goes missing for 1/100th of a

second when charging your phone, it will take 100 of these interruptions to delay the charge by one second!

Having a piece of equipment reboot 100 times a day will cause some heartbreak!

Efficiency: - A linear power supply because of its design will normally operate at around 60% efficiency

for 24V outputs, whereas a switch-mode is normally 80% or more. Efficiency is a measure of how much

energy the power supply wastes. This has to be removed with fans or heat sinks from the system.

For a 100W output linear, that waste would be 67W. A 100W switch-mode would be just 25W.

67W – 25W = 42W is the extra power lost

Doesn’t sound much, but don’t try touching a 40W light bulb! If the equipment were running 24 hours a

day, then the extra losses would be 367kW hours, even at $0.1 per kW hour, that’s an extra $37 a year for a

power supply that costs around $80.

As a quick note, in Europe, they are trying to limit those losses of all power supplies used by consumers

particularly when operating off load (as many products are left plugged in 24 hours a day). Imagine 250

million power supplies eating up a couple Watts. That equates to the output of a whole power station!

Reliability: - If reliability is calculated using a part count method, then the linear power supply will win.

With the design & quality improvements made in the last few years with switch-mode parts & technology,

in reality this advantage has been negated. I have demonstrated life testing data showing no failures after

over 1,000,000 hours on some Lambda products.

Electrical Ripple and Noise: - This is where the linear really scores!

                                    5v Linear                                                              5v Switch-mode

The linear obviously is a lot “quieter”, by up to a 10,000 times. The topology of the switch-mode supply

with its high frequency switching technology had to have a downside right? So if the noise is 10,000 times

worse, how can anyone use it? Sounds so bad.

In truth, there are some applications (studio mixers and very sensitive test equipment) where low electrical

noise is critical. The others? One of my first sales calls in the USA was to a manufacturer who built

semiconductor fabrication equipment. They used 8 really big linear units in a large box measuring 2x3x4

feet, it was heavy & actually being dictating the size of their end equipment. I told the engineer that I could

replace all eight units with two modular products measuring 5x5x10”. He laughed and said the noise

would be too great. I sent him samples and went to visit three weeks later. He was delighted with the

performance and has been a long term Lambda customer ever since.

Transient Response:

Transient response is how a power supply reacts to a (fast) change in load.

If the output load quickly changes from say full load to half load, the output voltage of the power supply

will rise (overshoot) before the internal control circuit has time to compensate, and then undershoot a little

less as the circuit over compensates. The length of time is takes from the instant of the load change to the

time the output voltage settles back into the load regulation limits can be critical to some loads. Here the

linear again outperforms the switch-mode.

For a 50% change in load the switch-mode will often take 3000us to recover. A linear supply will recover

in 50us.

Is this critical for all applications? There are a few specialized technologies where this is important and

most engineers will advise you if this is critical. For the other instances on board capacitors at the end load

& the inductance of cables is enough to reduce overshoot down ten-fold to where it no longer is a concern.

Low leakage currents and Conducted EMI:

A widely used technique in the design of switch-mode power supplies is to connect special capacitors from

the AC input terminals to Earth. This is a cost effective method to reduce noise from being fed back

through the input wires and potentially affecting other equipment.

These capacitors have a side effect of allowing a “leakage current” to be passed through the Earth or

ground cable. Many safety specifications have limits on the amount of this current that is allowed.

UL1950 allows 3mA, medical industrials less than a tenth of that. The gaming industry is even tighter.

As linear power supplies are “quieter” and do not need these capacitors, they simplify the system filtering,

and allow more of the system leakage current “budget” to be used for other parts like monitors. The overall

size of the system filter can also be reduced. How much that impacts cost & performance varies from

customer to customer.

Some switch-mode power supplies (like Lambda’s Vega series) are now available with increased internal

filtering that allows for low leakage versions to be offered to meet medical specifications.

In Summary:

	Linear	Switch-mode	Comments
Size	x	OK	Typically, 80% smaller
Weight	x	OK	Typically, 80% lighter
Input Voltage Range	x	OK	10% vs. up to 300% range
Efficiency	x	OK	Calculate it long term!
Reliability	OK	x / OK	Component count method, demonstrated probably equal
Ripple & Noise	OK	x / OK	Up to 10,000 times - often possible to overcome though
Transient Response	OK	x	Up to 100 times - necessary in specialized areas
Low leakage Current	OK	x / OK	Often used in medical systems, switch-mode gaining share

Hope that is useful all those aspects presented here.

As reference for the entire document, you can take a look on https://us.tdk-lambda.com

In this section, below I will share all tests and additional research made so far.