LM358 microcircuit: datasheet in Russian, application, analogues, pin assignments

DESCRIPTION These circuits consist of two independent, high gain, internally frequency compensated which were designed specifically to operate from a single power supply over a wide range of voltages.
The low power supply drain is independent of the magnitude of the power supply voltage. Application areas include transducer amplifiers, dc gain blocks and all the conventional op-amp circuits which now can be more easily implemented in single power supply systems. For example, these circuits can be directly supplied with the standard +5V which is used in logic systems and will easily provide the required interface electronics without requiring any additional power supply. In the linear mode the input common-mode voltage range includes ground and the output voltage can also swing to ground, even though operated from only a single power supply voltage. ■ INTERNALLY FREQUENCY COMPENSATED ■ LARGE DC VOLTAGE GAIN: 100dB ■ WIDE BANDWIDTH (unity gain): 1.1MHz (temperature compensated) ■ VERY LOW SUPPLY CURRENT/OP (500µA) ESSENTIALLY INDEPENDENT OF SUPPLY VOLTAGE ■ LOW INPUT BIAS CURRENT: 20nA (temperature compensated ) ■ LOW INPUT OFFSET VOLTAGE: 2mV ■ LOW INPUT OFFSET CURRENT: 2nA ■ INPUT COMMON-MODE VOLTAGE RANGE INCLUDES GROUND ■ DIFFERENTIAL INPUT VOLTAGE RANGE EQUAL TO THE POWER SUPPLY VOLTAGE ■ LARGE OUTPUT VOLTAGE SWING 0V TO (Vcc – 1.5V)

Many device parameters will depend on which specific LM358 connection circuit is used. This operational amplifier can be used to implement many designs that can be used without problems in microcontroller technology and even in speaker systems.

This is not a very demanding element - its performance is not great, its operating voltage range is also small, but it has the main qualities - simplicity and low cost. The cost of one op amp wholesale is about 15 rubles. Therefore, unsuccessful experiments with it will not hurt your pocket.

Operational Amplifier Features

The LM358 chip is widely used among radio amateurs, as it has many advantages. Among all, the following can be distinguished:

1. Extremely low price of the item.
2. When implementing devices on a chip, there is no need to install additional circuits for compensation.
3. It can be powered from either a unipolar or bipolar source.
4. Power can come from a source whose voltage is 3.32V. This allows you to use almost any power supply.
5. At the output, the signal increases at a rate of 0.6 V/µs.
6. The maximum current consumption does not exceed 0.7 mA.
7. The input bias voltage is no more than 0.2 mV.

These are the key features that you need to look for when choosing this chip. If you are not satisfied with some parameter, it is better to look for analogues or similar operational amplifiers.

Comparator with and without hysteresis

The initial data for the calculation are presented in the tables.

Table. Initial data for calculating the comparator

Table. Thresholds

Description of the scheme

Comparators are used to compare two input signals and generate an output signal depending on which of the input signals is larger (Figure 84). Noise or bounce on the input signals can cause the comparator to switch multiple times. To combat such switchings, hysteresis is used, which sets the upper and lower switching limits.

Rice. Comparator circuits with hysteresis (left) and without hysteresis (right)

We recommend that you pay attention to:

• a comparator with minimal intrinsic current consumption should be used;
• the accuracy of setting the hysteresis threshold values ​​is determined by the accuracy of the resistor values;
• The response delay is determined by the parameters of the comparator used.

Principle of operation

To demonstrate how a high-speed comparator with hysteresis works, you need to take a circuit with two outputs.

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The connection diagram, from which you can understand the principle of operation of the comparator, is shown above. Using an analog signal at the + input, called "non-inverting", and the output, called "inverting", the device uses two similar signals of opposite polarity. However, if the analog input is greater than the analog output, then the output will be “1” and this will turn on the open collector of transistor Q8 on the LM339 equivalent circuit to be turned on. But, if the input is at a negative level, then the signal will be equal to “0”, which is why the collector will be closed.

Almost always, a two-threshold or phase comparator (for example, on transistors, without an amplifier) ​​acts on the inputs in logic circuits, and accordingly, operates at the level of a certain power network. This is a kind of transition element between analog and digital signals. This principle of operation makes it possible not to specify the certainty or uncertainty of signal outputs, since the comparator always has some capture of the hysteresis loop (regardless of its level) or a final gain.

Procedure for calculating a comparator with hysteresis

• Select the value of resistor R1 = 100 kOhm. The threshold voltage values ​​were determined in the source data table: VL = 2.3 V, VH = 2.7 V.
• Let's calculate R2 using formula 1:

• Let's calculate R3 using formula 2:

• We check the obtained hysteresis value according to formula 3:

How to calculate a comparator without hysteresis

1. We select the threshold value Vth = 2.5 V.
2. We select the value of resistor R4 = 100 kOhm.
3. We calculate R5 using formula 4:

Circuit Simulation

Timing diagrams of the circuit operation are presented in Figures 1 and 2.

Rice. 1. Timing diagrams of the circuit operation: noise is present only in the initial short time interval 0...120 μs

Rice. 2. Enlarged voltage oscillogram: interval 40…110 µs

In what packages are microcircuits produced?

The housing can be either DIP8 - designation LM358N, or SO8 - LM358D. The first is intended for the implementation of volumetric installation, the second - for surface installation. The characteristics of the element do not depend on the type of housing - they are always the same. But there are many analogues of the microcircuit, whose parameters are slightly different. There are always pros and cons. Typically, if an element has a large range of operating voltages, for example, some other characteristic suffers.

There is also a metal-ceramic case, but such microcircuits are used if the device will be used in difficult conditions. In amateur radio practice, it is most convenient to use microcircuits in surface-mount packages. They solder very well, which is important when working. After all, it turns out to be much more convenient to work with elements whose legs are longer.

Voltage indicator on two-color LED

Another popular indication scheme is one that uses a two-color LED to display the state of charge of the battery or to signal when a lamp is turned on or off in another room. This can be very convenient, for example, if the light switch in the basement is located before the stairs leading down (by the way, do not forget to read an interesting article on how to illuminate the stairs with LED strip). Before you go down there, you turn on the light and the indicator lights up red, when off you see a green glow on the key. In this case, you don’t have to go into a dark room and feel for the switch there. When you leave the basement, you know by the color of the LED whether the light in the basement is on or not. At the same time, you monitor the health of the light bulb, because if it burns out, the red LED will not glow. Here is a diagram of a voltage indicator on a two-color LED.

In conclusion, we can say that these are only the basic possible schemes for using LEDs to indicate voltage. All of them are simple, and even an amateur can do them. They didn't use any expensive integrated circuits or anything like that. We recommend that all amateur and professional electricians acquire such a device so that they never endanger their health by starting repair work without checking the presence of voltage.

What analogues are there?

There are many analogues to the LM358 chip. Their connection diagram is exactly the same, but it’s still better to check the datasheet so as not to make a mistake. Among the complete analogues of the microcircuit, the following can be distinguished:

You can also select analogues of the LM358D element - these are UPC358G, KIA358F, TA75358CF, NE532D. There are many similar microcircuits that differ slightly from the 358. For example, LM258, LM158, LM2409 have completely similar characteristics, but the operating temperature range is slightly different.

Characteristics of analogues

From the datasheet LM358 and its analogues you can find out the following characteristics:

1. LM158 – operates in the temperature range from -55 to +125 degrees. The supply voltage can fluctuate in the range of 3.32V.
2. LM258 – operating temperature range -25. +85, supply voltage – 3.32V.
3. LM358 – temperature 0. +70, voltage – 3. 32V.

In the event that the temperature range of 0. +70 is not enough, it makes sense to find an analogue operational amplifier. The LM2409 performs well; it has a wider range of operating temperatures. It’s just that it’s a little smaller for food. This significantly reduces the possibility of using the device in amateur radio designs. The LM358 connection circuit is the same as most of its analogues.

In the event that you need to install only one operational amplifier, you should pay attention to analogues like LMV321 or LM321. They have five pins, and only one op-amp is contained inside the SOT23-5 package. But in the event that a larger number of opamps are needed, you can use dual elements - LM324, in which the case has 14 pins. With the help of such elements you can save on space and capacitors in the power circuit.

Thursday, February 14, 2022

Sound amplifier for lm358

The idea came to my mind to build a headphone amplifier using the lm358. The idea was caused by the fact that I urgently needed a device to test operational amplifiers, and since I don’t currently have an oscilloscope, I decided to assemble such a device with my own hands. The device will be an amplifier based on lm358, since this is the op amp I need to check.

First, let's look at the characteristics of the LM358. To do this, let’s find the datasheet for this op-amp and pay attention to this table.

From the table we see what voltage the lm358 can be powered with, this is from 3 volts to 30 with unipolar power supply. My choice was 5 volts, since this voltage can be taken from anywhere - even from a USB port, even from a power bank. Next, you need to decide on the circuit; it will be a classic op-amp amplifier circuit with negative feedback. Let's take the diagram from the datasheet as a basis and modify it a little.

Resistors RG and RF are responsible for the depth of feedback by adjusting the gain. Resistor RIN limits the input signal. We will put a capacitor in front of RIN in order to cut off the direct current, and RG can be made variable to regulate the volume. For power supply, we will definitely install an electrolytic capacitor so that there are no short-term drops in the supply voltage.

After assembling the test sample, the sound was so terrible that the circuit had to be significantly redesigned. As a result, we had to deviate a little from the example in the datasheet. Through calculations and trial and error, this scheme was formed. The result was a full-fledged amplifier, which I loaded not with headphones, but with 15-watt speakers with a resistance of 4 Ohms. The amplifier, of course, will not produce such power, these speakers were simply available.

Amplifier circuit based on LM358

Let's look at this diagram in order, what is there and why. First, let's start with capacitors C1 and C2. Initially, it was planned to install small-capacity ceramic capacitors, but practice has shown that large-capacity capacitors were best suited. First I set the non-polar one to 1 mF and this led to enormous distortion; when I tried to send a signal bypassing the capacitor, the distortion disappeared. I tried various capacitors, in the end the electrolytic capacitors that I bought for the motherboard sounded best. Perhaps it’s a matter of ESR or harmonic distortion, which directly depend on the quality of the capacitors, and these simply turned out to be of better quality than the others available. Unfortunately, it is not possible to measure ESR or harmonic input coefficient due to the lack of appropriate measuring equipment.

Non-inverting amplifier circuit

1. A signal is sent to the positive input.
2. Two fixed resistors R2 and R1 connected in series are connected to the output of the operational amplifier.
3. The second resistor is connected to the common wire.
4. The connection point of the resistors is connected to the negative input.

To calculate the gain, you need to use a simple formula: k=1+R2/R1.

If there is data on the value of resistances and input voltage, then it is easy to calculate the output: U(out)=U(in)*(1+R2/R1). When using the LM358 microcircuit and resistors R1=10 kOhm and R2=1 MOhm, the gain will be equal to 101.

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Circuit of a powerful non-inverting amplifier

Elements that are used in the design of a non-inverting amplifier and their parameters:

1. The chip used is LM358.
2. Resistance value R1=910 kOm.
3. R2=100 kOm.
4. R3=91 kOm.

To amplify the signal, a semiconductor bipolar transistor VT1 is used.

In terms of voltage, the gain, provided such elements are used, is equal to 10. To calculate the gain in the general case, you need to use the following formula: k=1+R1/R2. To calculate the current coefficient of the entire circuit, you need to know the corresponding parameter of the transistor used.

Working conditions

VCC = ±15 V, TA = 25°C

Unity gain amplifier

Circuit for checking noise

Voltage-to-current converter circuit

The circuit is shown in the figure and is somewhat similar to the one described in the design of a non-inverting amplifier. But here a bipolar transistor is added. The output current is directly proportional to the voltage at the input of the operational amplifier.

And at the same time, the current strength is inversely proportional to the resistance of resistor R1. If we describe this in formulas, it looks like this:

With a resistance value of R1 = 1 Om, for every 1V of voltage applied to the input, there will be 1A of current at the output. The LM358 connection circuit in voltage-to-current converter mode is used by radio amateurs to design chargers.

Popular circuits for lm358

There are various devices assembled on the LM358 N that perform specific functions. In this case, these can be all kinds of amplifiers, both UMZCH and in intermediate circuits for measuring various signals, an LM358 thermocouple amplifier, comparing circuits, analog-to-digital converters, etc.

Non-inverting amplifier and voltage reference

These are the most popular types of wiring diagrams used in many devices to perform various functions. In a non-inverting amplifier circuit, the output voltage will be equal to the product of the input voltage and the proportional gain formed by the ratio of two resistances included in the inverting circuit.

The voltage reference circuit is highly popular due to its high practical performance and stability in various modes. The circuit perfectly maintains the required output voltage level. It has been used to build reliable and high-quality power supplies, analog signal converters, and in devices for measuring various physical quantities.

Sine Wave Generator

One of the highest quality sine wave generator circuits is the Wien bridge device . With the correct selection of components, the generator produces pulses in a wide range of frequencies with high stability. Also, the LM 358 chip is often used to implement a rectangular pulse generator of various duty cycles and durations. At the same time, the signal is stable and high quality.

Amplifier

The main applications of the LM358 chip are amplifiers and various amplification equipment. This is ensured due to the inclusion features and selection of other components. This circuit is used, for example, to implement a thermocouple amplifier.

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Thermocouple amplifier on LM358

Very often in the life of a radio amateur it is necessary to monitor the temperature of some devices. For example, on a soldering iron tip . You can’t do this with an ordinary thermometer, especially when you need to create an automatic control circuit. For this, you can use the LM 358 op-amp. This microcircuit has a low thermal zero drift, and therefore is classified as high-precision. Therefore, it is actively used by many developers for the manufacture of soldering stations and other devices.

The circuit allows you to measure temperature in a wide range from 0 to 1000 °C with a fairly high accuracy of up to 0.02 °C. The thermocouple is made of a nickel-based alloy: chromal, alumel. The second type of metal has a lighter color and is less susceptible to magnetization; chromal is darker and magnetizes better. Features of the circuit include the presence of a silicon diode, which should be placed as close as possible to the thermocouple. When heated, the chromal-alumel thermoelectric pair becomes an additional source of emf, which can make significant adjustments to the main measurements.

Simple current regulator circuit

The circuit includes a silicon diode . The transition voltage from it is used as a source of a reference signal, supplied through a limiting resistor to the non-inverting input of the microcircuit. To adjust the stabilization current of the circuit, an additional resistor is used, connected to the negative terminal of the power supply, to the non-inverting input of the MS.

The circuit consists of several components:

• A resistor supporting the op-amp with a negative terminal and a resistance of 0.8 Ohms.
• A resistive voltage divider consisting of 3 resistances with a diode serving as a reference voltage source.

An 82 kOhm resistor is connected to the negative of the source and the positive input of the MS. The reference voltage is formed by a divider consisting of a 2.4 kOhm resistor and a directly connected diode. After which the current is limited by a 380 kOhm resistor. The op-amp controls a bipolar transistor, the emitter of which is connected directly to the inverting input of the MS, forming a negative deep connection. Resistor R 1 acts as a measuring shunt. The reference voltage is formed using a divider consisting of a diode VD 1 and a resistor R 4.

In the presented circuit, provided that resistor R2 with a resistance of 82 kOhm is used, the stabilization current in the load is 74 mA at an input voltage of 5V. And when the input voltage increases to 15V, the current increases to 81mA. Thus, when the voltage changes by a factor of 3, the current changes by no more than 10%.

Charger for LM 358

Chargers with high stabilization and control of the output voltage are often made using the LM 358 op-amp As an example, you can consider a USB-powered Li-ion charger. This circuit is an automatic current regulator. That is, as the voltage on the battery increases, the charging current drops. And when the battery is fully charged, the circuit stops working, completely closing the transistor.

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What characteristics of the LM358 brought it such popularity:

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• low cost;
• no additional compensation circuits;
• single or bipolar power supply;
• wide range of supply voltages from 3 to 32 V;
• Maximum output slew rate: 0.6 V/µs;
• Current consumption: 0.7 mA;
• Low input offset voltage: 0.2 mV.

Gain adjustment

The previous design has one drawback - there is no way to adjust the gain. The reason is the complexity of the implementation, because you need to use two variable resistors at once. But if suddenly there is a need to adjust the coefficient, you can use a design circuit based on three op-amps:

Here the adjustment occurs using a variable resistor R2. It is necessary to take into account that the following equalities are satisfied:

In this case k=(1+2*R1/R2).

Amplifier output voltage U(out)=(1+2*R1/R2)*(Uin1-Uin2).

A simple current stabilizer charger made from scrap materials

There are a huge number of ready-made circuits and designs that allow you to charge a car battery. This article is on the topic of converting a computer power supply to an automatic car battery charger. It tells how to assemble an automatic current stabilizer with the ability to adjust the output current.

The stabilizer circuit used in our assembled charger is quite simple and is based on an open-loop operational amplifier (OP-amp) with a high gain.

The LM358 microcircuit is used as such an operational amplifier, or it would be more correct to call it a comparator. The image shows that it has:

• two inputs (inverting and non-inverting);
• one exit.

The job of the LM358 is to balance the output by increasing or decreasing the voltage at the inputs.

A charger or simple stabilizer is a device that:

• smoothes out network ripples;
• maintains a straight line of the current graph at the same level.

How is this done? In our case, a reference voltage is supplied to one input, set using a zener diode. The second input is connected after the shunt, intended to act as a current sensor. When a discharged battery is connected to the output, the current in the circuit increases and, accordingly, a voltage drop occurs across the low-resistance resistor. On the LM358 chip, a voltage difference appears between the two inputs. The device seeks to balance this difference, thereby increasing the output parameters.

Looking at the diagram, we see that a field-effect transistor is connected to the output, which controls the load. As the battery charges, the voltage at the terminals of the device begins to increase, therefore, it begins to increase at one of the inputs of the op-amp. A voltage difference arises between the inputs, which the op-amp tries to equalize by reducing the output voltage, thereby reducing the current in the main circuit.

As a result, the battery is charged to the required voltage, that is, the set value at the charger terminals. The voltage drop across resistor R3 becomes minimal or will not exist at all. When the voltage at the inputs is equalized, the transistor closes, thereby disconnecting the load from the charger.

A feature of this circuit is that it allows you to limit the charge current. This is done using a variable resistor, which is connected in series to the divider. And by actually turning the knob of this resistor, you can change the parameters at one of the inputs. The resulting difference is again equalized by increasing or decreasing the parameters.

There are no universal schemes. Someone is interested in the issue of increasing the load current. For example, what needs to be changed in the circuit for 15 A? It will be necessary to install a variable not 5, but 10 kOhm. By also making a preliminary calculation and replacing the corresponding elements, you can easily customize the circuit to suit your needs.

Current monitor circuit

Another circuit that allows you to measure the current value in the supply wire. It consists of a shunt resistor R1, an operational amplifier LM358, an NPN transistor and two resistors. Element characteristics:

• chip DA1 – LM358;
• resistor resistance R=0.1 Ohm;
• resistance value R2=100 Ohm;
• R3=1 kOhm.

The op-amp supply voltage must be at least 2 V higher than that of the load. This is a prerequisite for the functioning of the scheme.

Voltage to frequency converter circuit

This device will be required when there is a need to calculate the period or frequency of a signal.

The circuit is used as an analog-to-digital converter. Parameters of elements used in the design:

• DA1 – LM358;
• C1 – 0.047 µF;
• R1=R6=100 kOhm;
• R2=50 kOhm;
• R3=R4=R5=51 kOhm;
• R6=100 kOhm;
• R7=10 kOhm.

These are all designs that can be built using an op-amp. But the scope of the LM358 is not limited to this; there are a large number of much more complex circuits that allow you to implement various possibilities.

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The LM358 chip, as written in its DataSheet, is a universal solution, since the connection circuit of most popular devices is very simple, in cases where there are no strict requirements for high speed, power dissipation and non-standard supply voltage. Low cost, no need to connect additional frequency correction elements, the ability to use it over the entire range of standard supply voltages (up to +32V) and low current consumption make it the number one candidate for electronic projects with op-amps.

Purpose

Why do you need a comparator and how to use it without an amplifier?
In most cases, this device is used in simple computer circuits where it is necessary to compare incoming voltage signals. This can be a charger for a laptop or phone, a scale (mass meter), an AVR mains voltage sensor, a timer (composer type lm 358, microcontroller, etc. It is also used by various integrated circuits to control input pulses, providing communication between the signal source and its destination center. The most popular example is the comparator trigger (regulator) Shimmer. It operates in multi-channel mode, accordingly, it can compare a large number of signals. In particular, this trigger is used to restore a digital signal that distorts the connection depending on voltage level and distance of the power source.

This is an analogue of a standard comparator, just with more advanced functionality, which provides measurement of several incoming signals.

There is also a roughness comparator. This is a device that helps to visually determine the condition of a surface that has already been treated. The use of this device is justified by the need to determine the tolerances of previously processed surfaces.

LM358 pinout

LM358 consists of two op-amps, each with 4 pins that have their own purpose. There are 8 contacts in total. They are produced in several types of housing designs, for volumetric DIP and surface mounting on an SO board. They can also be found in improved SOIC, VSSOP, TSSOP packages.

The assignment of contacts for all types of housings is the same: 2.3, 5.6, - inputs, 1.7 - outputs, 4 - minus power supply, 11 - plus power supply.

Specifications

The following are the maximum permissible operating conditions for the ambient operating temperature range TA from 0 to +70 °C, unless otherwise stated.

Basic electrical characteristics, at ambient temperature TA = 25 °C.

Recommended operating conditions within the ambient operating temperature range unless otherwise noted:

Device susceptibility to electrostatic discharge (ESD) damage:

This device also has thermal characteristics:

Connection diagrams

Below are some simple lm358 connection diagrams that may be useful to you. These are all previews, so be sure to test everything before implementing it in production.

Circuit in a powerful non-inverting amplifier.

Voltage - current converter.

Circuit with differential amplifier.

Non-inverting medium power amplifier.

List of previously published chapters

1. The Analog Designer's Cookbook: Op-Amps
2. Inverting amplifier
3. Non-inverting amplifier
4. Inverting adder
5. Differential amplifier
6. Integrator
7. Differentiator
8. Transimpedance amplifier
9. Unipolar current measurement circuit
10. Bipolar current measurement circuit
11. Unipolar current measurement circuit with a wide operating range (3 decades)
12. PWM generator on op-amp
13. AC Voltage Inverting Amplifier (Active High Pass Filter)
14. Non-inverting AC voltage amplifier (active high-pass filter)
15. Active bandpass filter
16. Half Wave Inverting Rectifier
17. Op-amp rectifier
18. Low voltage rectifier with single supply
19. Voltage rate limiter
20. Differential signal generation circuit
21. Inverting amplifier circuit with inverting input bias
22. Non-inverting amplifier circuit with inverting input bias
23. Non-inverting amplifier circuit with non-inverting input biased
24. Inverting amplifier circuit with non-inverting input biased

Translated by Vyacheslav Gavrikov at the request of COMPEL JSC

•••

Analogs

Analogues of LM358 can be considered microcircuits in which identical characteristics are indicated. These include: LM158, LM258, LM2904, LM2409. These microcircuits differ slightly from the one described in their thermal parameters and are suitable as a replacement for most projects.

To replace it you can use: GL 358, NE 532, OP 04, OP 221, OP 290, OP 295, OPA 2237, TA7 5358-P, UPC 358C, AN 6561, CA 358E, HA 17904. Domestic analogs of lm358: KR 1401UD5 , KR 1053UD2, KR 1040UD1.

An analogue in terms of electrical parameters, but with four op-amps in one chip - LM324 - may also be suitable for replacement.

Marking

The LM prefix was first used in general purpose markings by National Semiconductor. The numbers “358” are its serial number. In 2011, this company was acquired by another electronics manufacturer, Texas Instruments. Since this year, the prefix “LM” has been the Texas Instruments manufacturer code, but despite this, other manufacturers also use this code when marking their products. LM358, LM358-N and LM358-P chips have the same technical parameters. Most manufacturing companies use the symbols “-N” and “-P” to designate plastic PDIP enclosures.

In the technical descriptions the following types are found: LM358A, LM358B, LM358BA. This indicates the next generation version of the industry standard LM358. "B" devices may be available in more modern TSOT and WSON micro packages.

Application

Lm358 is widely used in:

• devices such as “flashing beacon”;
• power supplies and chargers;
• engine control circuits;
• motherboards;
• split systems for indoor and outdoor use;
• household appliances: dishwashers, washing machines, refrigeration units;
• various types of inverters;
• uninterruptible power supplies;
• controllers, etc.

Manufacturers usually indicate the possibilities of using the microcircuit in the technical descriptions of their devices.