Phone

    00852-6915 1330

Switch Mode Power Supply Circuit Design Tutorial

  • Contents

Many engineers who have not used the switching power supply may have some worry about it, such as the PCB layout, the parameter and type selection of components, and so on. In fact, as long as you understand the basic principle, the use of switching power supply design is very convenient.

 

In today's article, we will introduce you to some basic knowledge of switch-mode power supply, along with some experience sharing when using the switch-mode power supply.

 

SMPS Tutorial: Switch Mode Power Supplies and Power Conversion

 

 


Catalog

 

I. What is the Switch Mode Power Supply

II. How to Debug the Switching Power Supply Circuit?

III. What Needs to Be Grounded?

3.1 Definition of Grounding

3.2 Grounding Mode

3.3 How is the Signal of the Single Board Grounded?

3.4 How Do the Single Board Interface Devices   Grounding?

3.5 How to Grounding the Shield Layer?

IV. Introduction of Signal Backflow and Transpartition

V. Should Analog Separate from the Digital , and How?

FAQ

 


I. What is the Switch Mode Power Supply

 

 

A switch-mode power supply usually consists of a controller and an output part. Some controllers integrate MOSFET into the chip, which makes it easier to use and simplify the PCB design, but the flexibility of components is weakened.

 

The switching controller is actually a closed-loop feedback control system, so there is a sampling circuit of output-voltage feedback and a feedback-loop control circuit. Therefore, this part of the design is to ensure an accurate sampling circuit and to control the feedback depth, because if the feedback loop response is too slow, it will have a great impact on the transient response-ability.

 

The output parts include output capacitance, output inductor, MOSFET, and so on. The selection of these devices is basically to balance the performance need and cost. For example, the high switching frequency can use small inductance (which means small package and low cost), but a high switching frequency will increase interference and the switching loss of MOSFET, result in reducing efficiency and increasing cost. Lower switching frequency has the opposite effect.

 

The selection of Rds_on parameters of MOSFET and the ESR for output capacitance is also very important. ESR is small can reduce output ripple, but the cost of the capacitor will increase. And It is important to note that switching power controllers can not be well driven with too much MOSFET.

 

In general, suppliers of switching power supply controllers will provide specific formulas and usage options for engineers.

 

Switch Mode Power Supply Circuit

Figure. 1 Switch Mode Power Supply Circuit

 


 

 

II. How to Debug the Switching Power Supply Circuit?

 

(1)The output of the power supply circuit is installed to the board through the low resistance and high power resistor, so that the power circuit can be debugged first before welding resistance, avoiding the influence of the latter circuit. 

 

(2)The switching controller is a closed-loop system. If the output deterioration beyond the range that the closed-loop can control, the switching power supply will work improperly. This situation requires careful examination of feedback and sampling circuits. Especially, if the output capacitance with a large ESR, lots of ripple of power supply will be produced, which will also affect the operation of switching power supply.

 

 


III. What Needs to Be Grounded?

 

At the very start, the introduction of grounding technology is a protective measure to prevent lightning strikes on electric power or electronic equipment. The purpose is to introduce lightning current through the lightning rod to the earth to protect buildings. And meanwhile, grounding is also an effective way to protect personal safety.

 

When the phase line touches the shell of the equipment causing by some reason (such as poor insulation of the wire, line aging, etc.), there will be a dangerous voltage in the shell of the equipment. Having grounding, the resulting fault current will flow to the earth, thus it plays a protective role.

 

For example, in communication systems, the interconnection of signals between a large number of devices requires each device to have a point as a reference, and with the complication of electronic equipment, the signal frequency is becoming higher and higher, therefore, grounding design as special attention paid to the electromagnetic compatibility problems such as mutual interference between signals.

 

In addition, improper grounding will seriously affect the reliability and stability of system operation. Recently, the concept of "grounding" has also been introduced into high-speed signal backflow technology.

 

 

3.1  Definition of Grounding

In the modern concept of grounding, for line engineers, the term usually means "reference point for line voltage"; for system designers, it is often a cabinet or frame; for electrical engineers, it is a green and safe ground line or a wire connected to the earth. A more general definition is that "grounding is the low impedance channel which the current returns its source." Noting that the points are "low impedance" and "channel".

 

 

3.2  Grounding Mode

There are many ways of grounding: single-point grounding, multi-point grounding, and mixed type of grounding. Single-point grounding is divided into a series of single-point grounding and parallel single-point grounding. In general, single-point grounding is used in simple circuits, and low frequency (f10MHz) circuits use multipoint grounding or multilayer (complete a ground plane layer).

 

 

3.3   How is the Signal of the Single Board Grounded?

For the general device, the near ground is the best. After adopting the multilayer design with a complete ground plane, the grounding of the general signal is very easy. The basic principle is to ensure the continuity of the line, reduce the number of holes, approach the ground plane or the power plane, etc.

 

3.4  How Do the Single Board Interface Devices  Grounding?

Some veneers will have external input-output interfaces, such as serial port connectors, RJ45 connectors, etc. If their grounding is not well designed, it will also affect normal operation, such as error codes, packet loss, etc. And it will become an external source of electromagnetic interference sending the noise out. In general, a single interface grounding will be made, and the signal is connected by a thin wire connection, string 0 ohms, or small resistance. Thin lines can be used to block signal ground noise. At the same time, the interface and the interface power filter should also be considered seriously. 

 

3.5  How to Grounding the Shield Layer?

 

The shielding layer of cables is connected to the interface grounding instead of the signal grounding, because there are various noises on the signal grounding. If the shield layer is connected to the signal ground, the noise voltage will drive the common-mode current to interfere outward along the shield layer. Therefore, the poorly designed cable is generally the maximum noise output source of electromagnetic interference. Of course, the interface ground should keep clean.

 


IV. Introduction of Signal Backflow and Transpartition

For an electronic signal, it needs to find a way with the lowest impedance to return current to the ground, so how to deal with the signal backflow becomes very important.

 

First, according to the formula, we can know that the radiation intensity is proportional to the area of the loop. Specifically, the longer the path the return is, the bigger the ring is formed, and the greater the external radiation interference is, thus the power-circuit flow back and signal loop area should as small as possible when design PCB.

 

Second, for a high-speed signal, providing a good signal backflow can guarantee its signal quality. Because the characteristic impedance of the transmission line on the PCB is generally calculated by reference to the ground (or power layer), if there is a continuous ground plane near the high-speed line, the impedance of this line can be kept continuous, and if there is no ground reference near the section line, the impedance will change and the signal will be affected as well. Therefore, the high-speed lines should be distributed to the layer near the ground plane, or they should be walked in parallel next to each other, to shield interference and provide backflow nearly. 

 

Third, do not divide wires when having power supply in wiring way, this is because the signal backflow path across different power layers will be longer, and be vulnerable to interference. For low-speed signals, it is not strictly required that, because the resulting interference signal can not be concerned about. But for high-speed signals should be checked carefully, do not cross as far as possible, you can adjust the power part of the wire. (this is for multiple power supplies on multilayer boards).

 

 


V. Should Analog Separate from the Digital , and How?

 

Whether analog signal or digital signal should return to the ground. Because the digital signal changes quickly and the noise caused by the digital signal will be very large, if analog and digital mixing, the noise will affect the analog signal. 

 

In general, the grounding of analog and digital processing must be separated, then connected by a thin line, or a single point. The general idea is to try to block the noise from the digital ground to the analog ground. But it is not a very strict requirement that analog and digital ground must be separated, if the analog section near the digital ground is still very clean, they can be combined.

 


FAQ

 

1. What are the 3 types of power supply?

There are three subsets of regulated power supplies: linear, switched, and battery-based. Of the three basic regulated power supply designs, linear is the least complicated system, but switched and battery power have their advantages.

 

2. What is meant by switch mode power supply?

A switch mode power supply is a power converter that utilises switching devices such as MOSFETs that continuously turn on and off at high frequency; and energy storage devices such as the capacitors and inductors to supply power during the non-conduction state of the switching device.

 

3.What are the advantages and disadvantages of switch mode power supply?

Advantages & disadvantages of switch mode power supply (SMPS)

a. The switch mode power supply has a smaller in size.

b. The SMPS has light weight.

c. It has a better power efficiency typically 60 to 70 percent.

d. It has a strong anti interference.

e. SMPS has wide output range.

f. Low heat generation in SMPS.

 

4. What is a DC switching power supply?

A Switching DC power supply (also known as switch mode power supply) regulates the output voltage through a process called pulse width modulation (PWM). The PWM process generates some high frequency noise, but enables the switching power supplies to be built with very high power efficiency and small form factor.

 

5. What is the difference between a switching power supply and a linear power supply?

Linear power supplies deliver DC by passing the primary AC voltage through a transformer and then filtering it to remove the AC component. Switching power supplies feature higher efficiencies, lighter weight, longer hold up times, and the ability to handle wider input voltage ranges.

 

6. Do I need a switching power supply?

The switching power supply implies higher efficiency due to the high switching frequency, enabling it to use a smaller, less-costly high-frequency transformer as well as lighter, less-costly filter components. Switching power supplies contain more overall components, therefore are usually more expensive.

 

7. Is a switching power supply regulated?

A switch mode power supply regulates an output voltage with pulse width modulation (PWM). This process creates high-frequency noise but it provides a high-efficiency rating in a small form factor. ... The low DC voltage is finally converted into a steady DC output with another set of diodes, capacitors, and inductors.

 

8. How do I know if my power supply is regulated?

You can generally stick one probe into the middle of the connector, and hold the other against the outside. With a few exceptions, the middle is positive, so use the red lead there, and use the black lead on the outside shell. Regulated supplies, without any load, should measure very close to the target voltage of 12v.

 

9. Can I use a switching power supply to drive a DC motor?

A simple unregulated analog power supply may be easier and be able to supply the large starting under load current more that the switching one. DC motors are not too fussy about the supply, and will usually run quite well on unfiltered DC.

 

10. Are switch mode power supplies any good?

Switch mode power supplies, SMPS provide improved efficiency & space saving over traditional linear supplies, but care has to be taken to ensure noise on the output is low. Switch mode power supplies are widely used because of the advantages they offer in terms of size, weight, cost, efficiency and overall performance.

 


You May Also Like

Switching Power Supply Guide: Protection Circuit

Switching Power Supply Tutorial: 4V~16V

Switched Mode Power Supply Tutorial: Principles & Functions of SMPS Circuits

Kynix

Kynix was founded in 2008, specializing in the electronic components distribution business. We adhere to honesty and ethics as our business philosophy and have gradually established an excellent reputation and credibility in our international business. With the accurate quotation, excellent credit, reasonable price, reliable quality, fast delivery, and authentic service, we have won the praise of the majority of customers.

Join our mailing list!

Be the first to know about new products, special offers, and more.

Leave a Reply

We'd love to hear from you! Feel free to share your thoughts and comments below. Rest assured, your email address will remain private.

Name *
Email *
Captcha *
Rating:

Kynix

  • How to purchase

  • Order
  • Search & Inquiry
  • Shipping & Tracking
  • Payment Methods
  • Contact Us

  • Tel: 00852-6915 1330
  • Email: info@kynix.com
  • Follow Us

authentication

Kynix

© 2008-2026 kynix.com all rights reserved.