UMZCH circuits on transistors with explanations. Datagor Practical Electronics Magazine. Amplifier operating principle

High input impedance and shallow feedback are the main secret of warm tube sound. It's no secret that the highest quality and most expensive amplifiers, which belong to the HI-End category, are manufactured using tubes. Let's understand what a quality amplifier is? A low-frequency power amplifier has the right to be called high-quality if it completely repeats the shape of the input signal at the output without distorting it; of course, the output signal is already amplified. On the Internet you can find several circuits of really high-quality amplifiers, which can be classified as HI-End and do not necessarily require tube circuitry. To obtain maximum quality, you need an amplifier whose output stage operates in pure class A. Maximum linearity of the circuit gives a minimum amount of distortion at the output, therefore, in the design of high-quality amplifiers, special attention is paid to this factor. Tube circuits are good, but not always available even for self-assembly, and industrial tube UMZCHs from branded manufacturers cost from several thousand to several tens of thousands of US dollars - this price is certainly not affordable for many.
The question arises: is it possible to achieve similar results from transistor circuits? the answer will be at the end of the article.

There are quite a lot of linear and ultra-linear circuits of low-frequency power amplifiers, but the circuit that will be considered today is a high-quality ultra-linear circuit, which is implemented with only 4 transistors. The circuit was created back in 1969 by British audio engineer John Linsley-Hood. The author is the creator of several other high-quality circuits, in particular class A. Some experts call this amplifier the highest quality among transistor ULFs, and I was convinced of this a year ago.

The first version of such an amplifier was presented at. A successful attempt to implement the circuit forced me to create a two-channel ULF using the same circuit, assemble everything in a housing and use it for personal needs.

Features of the scheme

Despite its simplicity, the scheme has several features. Correct operation may be disrupted due to incorrect board layout, poor placement of components, incorrect power supply, etc.
It is the power supply that is a particularly important factor - I strongly advise against powering this amplifier from all kinds of power supplies, best option battery or power supply with a battery connected in parallel.
The amplifier power is 10 watts with a 16 Volt power supply into a 4 Ohm load. The circuit itself can be adapted for 4, 8 and 16 Ohm heads.
I created a stereo version of the amplifier, both channels are located on the same board.

The second one is intended for driving the output stage, I installed KT801 (it was quite difficult to get hold of it.
In the output stage itself I installed powerful bipolar switches of reverse conduction - the KT803 undoubtedly received it with them high quality sound, although I experimented with many transistors - KT805, 819, 808, even installed powerful components - KT827, with it the power is much higher, but the sound cannot be compared with KT803, although this is just my subjective opinion.

An input capacitor with a capacity of 0.1-0.33 μF, you need to use film capacitors with minimal leakage, preferably from well-known manufacturers, the same with the output electrolytic capacitor.
If the circuit is designed for a 4 Ohm load, then you should not increase the supply voltage above 16-18 Volts.
I decided not to install a sound regulator; it, in turn, also affects the sound, but it is advisable to install a 47k resistor parallel to the input and minus.
The board itself is a prototype board. I had to tinker with the board for a long time, since the lines of the tracks also had some influence on the sound quality as a whole. This amplifier has a very wide frequency range, from 30 Hz to 1 MHz.

Setup couldn't be easier. To do this, you need to use a variable resistor to achieve half the supply voltage at the output. For more precise settings, you should use a multi-turn variable resistor. We connect one multimeter lead to the minus power supply, put the other one to the output line, i.e. to the plus of the electrolyte at the output, thus, slowly rotating the variable we achieve half of the power supply at the output.

The amplifier offered to your precious attention is easy to assemble, terribly simple to set up (it actually doesn’t require it), does not contain particularly scarce components, and at the same time has very good characteristics and can easily match the so-called hi-fi, so dearly loved by the majority of citizens .The amplifier can operate at 4 and 8 Ohm loads, can be used in a bridge connection to an 8 Ohm load, and it will deliver 200 W to the load.

Main characteristics:

Supply voltage, V................................................... ............... ±35
Current consumption in silent mode, mA.................................... 100
Input impedance, kOhm................................................... .......... 24
Sensitivity (100 W, 8 Ohm), V............................................ ...... 1.2
Output power (KG=0.04%), W.................................... ........ 80
Reproducible frequency range, Hz.................................... 10 - 30000
Signal-to-noise ratio (not weighted), dB..................... -73

The amplifier is entirely based on discrete elements, without any op-amps or other tricks. When operating at a 4 Ohm load and a 35 V supply, the amplifier develops power up to 100 W. If there is a need to connect an 8 Ohm load, the power can be increased to +/-42 V, in this case, we will get the same 100 W.It is very strongly not recommended to increase the supply voltage above 42 V, otherwise you may be left without output transistors. When operating in bridge mode, an 8-ohm load must be used, otherwise, again, we lose all hope for the survival of the output transistors. By the way, we must take into account that there is no short-circuit protection in the load, so you need to be careful.To use the amplifier in bridge mode, it is necessary to screw the MT input to the output of another amplifier, to the input of which the signal is supplied. The remaining input is connected to the common wire. Resistor R11 is used to set the quiescent current of the output transistors. Capacitor C4 determines the upper limit of the gain and you should not reduce it - you will get self-excitation at high frequencies.
All resistors are 0.25 W except for R18, R12, R13, R16, R17. The first three are 0.5 W, the last two are 5 W each. The HL1 LED is not for beauty, so there is no need to plug a super-bright diode into the circuit and bring it to the front panel. The diode should be the most common green color - this is important, since LEDs of other colors have a different voltage drop.If suddenly someone was unlucky and could not get the output transistors MJL4281 and MJL4302, they can be replaced with MJL21193 and MJL21194, respectively.It is best to take a multi-turn variable resistor R11, although a regular one will do. There is nothing critical here - it’s just more convenient to set the quiescent current.

There was a desire to assemble a more powerful class “A” amplifier. Having read a sufficient amount of relevant literature and selected the most from what was offered latest version. It was a 30 W amplifier corresponding in its parameters to high-class amplifiers.

In the available trace of the original printed circuit boards I did not intend to make any changes, however, due to the lack of original power transistors, a more reliable output stage was chosen using 2SA1943 and 2SC5200 transistors. The use of these transistors ultimately made it possible to provide greater output power amplifier Schematic diagram my version of the amplifier below.

This is an image of boards assembled according to this circuit with Toshiba 2SA1943 and 2SC5200 transistors.

If you look closely, you can see on the printed circuit board along with all the components there are bias resistors, they are 1 W carbon type. It turned out that they are more thermostable. When any high-power amplifier operates, a huge amount of heat is generated, so maintaining a constant rating of the electronic component when heating it is an important condition for the high-quality operation of the device.

The assembled version of the amplifier operates at a current of about 1.6 A and a voltage of 35 V. As a result, 60 W of continuous power is dissipated on the transistors in the output stage. I should note that this is only a third of the power they can handle. Try to imagine how much heat is generated on the radiators when they are heated to 40 degrees.

The amplifier case is made by hand from aluminum. Top plate and mounting plate 3mm thick. The radiator consists of two parts, its overall dimensions are 420 x 180 x 35 mm. Fasteners - screws, mostly with a countersunk stainless steel head and M5 or M3 thread. The number of capacitors was increased to six, their total capacity is 220,000 µF. A 500 W toroidal transformer was used for power supply.

Amplifier power supply

The amplifier device, which has copper busbars of the appropriate design, is clearly visible. A small toroid is added for controlled flow under the control of a DC protection circuit. There is also a high-pass filter in the power supply circuit. For all its simplicity, it must be said deceptive simplicity, the board topology of this amplifier produces sound as if without any effort, implying in turn the possibility of its infinite amplification.

Oscillograms of amplifier operation

3 dB roll-off at 208 kHz

Sine wave 10 Hz and 100 Hz

Sine wave 1 kHz and 10 kHz

100 kHz and 1 MHz signals

Square wave 10 Hz and 100 Hz

Square wave 1 kHz and 10 kHz

60 W total power, 1 kHz symmetry cutoff

Thus, it becomes clear that a simple and high-quality design of UMZCH is not necessarily made using integrated circuits- only 8 transistors allow you to achieve decent sound with a circuit that can be assembled in half a day.

TRANSISTOR LOW FREQUENCY AMPLIFIERS. POWER AMPLIFIERS

At the request of site visitors, I present to your attention an article entirely devoted to transistor amplifiers. In the 8th lesson we touched a little on the topic of amplifiers - amplification stages on transistors, so with the help of this article, I will try to eliminate all the gaps regarding transistor amplifiers. Some theoretical basis presented here are valid for both transistor amplifiers and tube amplifiers. At the beginning of the article, the main types and methods of switching on amplifier stages will be reviewed; at the end of the article, we will consider the main pros and cons of single-ended transformer and transformerless amplifiers, and we will consider in particular detail push-pull transformer and transformerless amplifiers, since they are quite often used and represent a large interest. At the end of the article, as in previous lessons, there will be practical work. Actually, this article is no different from the lessons, with the only difference being that this and all subsequent articles will have specific names, which allows you to choose a topic to study at will. In any case, in order to confidently choose any of the following topics, you must complete the full course consisting of 10 lessons.

Amplifier transistor stage It is customary to call a transistor with resistors, capacitors and other parts that provide it with operating conditions as an amplifier. To play vibrations loudly audio frequency transistor amplifier must be at least two - three-stage . In amplifiers containing several stages, stages are distinguished pre-amplification and output, or final, stages . The output stage is the last stage of the amplifier, which operates on telephones or the dynamic head of a loudspeaker, and the preliminary stages are all stages in front of it. The job of one or more preamp stages is to increase the audio frequency voltage to the value required to drive the output stage transistor. The transistor of the output stage is required to increase the power of audio frequency oscillations to the level required for the operation of the dynamic head. For the output stages of the simplest transistor amplifiers, radio amateurs often use low-power transistors, the same as in the pre-amplifier stages. This is explained by the desire to make amplifiers more economical, which is especially important for portable battery-powered designs. The output power of such amplifiers is small - from several tens to 100 - 150 mW, but it is also sufficient to operate telephones or low-power dynamic heads. If the issue of saving energy from power supplies is not so significant, for example, when powering amplifiers from an electric lighting network, powerful transistors are used in the output stages. What is the operating principle of an amplifier consisting of several stages? You can see the diagram of a simple transistor two-stage low-frequency amplifier in (Fig. 1). Look at it carefully. In the first stage of the amplifier, transistor V1 operates, in the second, transistor V2. Here the first stage is the pre-amplification stage, the second is the output stage. Between them - decoupling capacitor C2. The principle of operation of any of the stages of this amplifier is the same and is similar to the familiar principle of operation of a single-stage amplifier. The only difference is in the details: the load of transistor V1 of the first stage is resistor R2, and the load of transistor V2 of the output stage is phones B1 (or, if the output signal is powerful enough, the loudspeaker head). The bias is applied to the base of the transistor of the first stage through resistor R1, and to the base of the transistor of the second stage - through resistor R3. Both stages are powered from a common UiP source, which can be a battery galvanic cells or straightener. The operating modes of the transistors are set by selecting resistors R1 and R3, which are indicated in the diagram by asterisks.

Rice. 1 Two-stage transistor amplifier.

The effect of the amplifier as a whole is as follows. The electrical signal supplied through capacitor C1 to the input of the first stage and amplified by transistor V1, from the load resistor R2 through the separating capacitor C2 is supplied to the input of the second stage. Here it is amplified by transistor V2 and telephones B1, connected to the collector circuit of the transistor, and is converted into sound. What is the role of capacitor C1 at the amplifier input? It performs two tasks: it freely passes alternating signal voltage to the transistor and prevents the base from being shorted to the emitter through the signal source. Imagine that this capacitor is not in the input circuit, and the source of the amplified signal is an electrodynamic microphone with low internal resistance. What will happen? Through the low resistance of the microphone, the base of the transistor will be connected to the emitter. The transistor will turn off as it will operate without the initial bias voltage. It will open only with negative half-cycles of the signal voltage. And the positive half-cycles, which further close the transistor, will be “cut off” by it. As a result, the transistor will distort the amplified signal. Capacitor C2 connects the amplifier stages via alternating current. It should pass well the variable component of the amplified signal and delay the constant component of the collector circuit of the first stage transistor. If, along with the variable component, the capacitor also conducts direct current, the operating mode of the output stage transistor will be disrupted and the sound will become distorted or disappear completely. Capacitors that perform such functions are called coupling capacitors, transition or isolation capacitors . Input and transition capacitors must pass well the entire frequency band of the amplified signal - from the lowest to the highest. This requirement is met by capacitors with a capacity of at least 5 μF. The use of large capacitance coupling capacitors in transistor amplifiers is explained by the relatively low input resistances of the transistors. The coupling capacitor provides capacitive resistance to alternating current, which will be smaller the greater its capacitance. And if it turns out to be greater than the input resistance of the transistor, a portion of the AC voltage will drop across it, greater than at the input resistance of the transistor, which will result in a loss in gain. The capacitance of the coupling capacitor must be at least 3 to 5 times less than the input resistance of the transistor. Therefore, large capacitors are placed at the input, as well as for communication between transistor stages. Here, small-sized electrolytic capacitors are usually used with mandatory observance of the polarity of their connection. These are the most characteristic features of the elements of a two-stage transistor low-frequency amplifier. To consolidate in memory the principle of operation of a transistor two-stage low-frequency amplifier, I propose to assemble, set up and test in action the simplest versions of amplifier circuits below. (At the end of the article, options for practical work will be proposed; now you need to assemble a prototype of a simple two-stage amplifier so that you can quickly monitor theoretical statements in practice).

Simple, two-stage amplifiers

Schematic diagrams of two versions of such an amplifier are shown in (Fig. 2). They are essentially a repetition of the circuit of the now disassembled transistor amplifier. Only on them the details of the parts are indicated and three additional elements are introduced: R1, SZ and S1. Resistor R1 - load of the source of audio frequency oscillations (detector receiver or pickup); SZ - capacitor that blocks loudspeaker head B1 at higher sound frequencies; S1 - power switch. In the amplifier in (Fig. 2, a) transistors of the p - n - p structure operate, in the amplifier in (Fig. 2, b) - in the n - p - n structure. In this regard, the polarity of switching on the batteries powering them is different: a negative voltage is supplied to the collectors of the transistors of the first version of the amplifier, and a positive voltage is supplied to the collectors of the transistors of the second version. The polarity of switching on electrolytic capacitors is also different. Otherwise the amplifiers are exactly the same.

Rice. 2 Two-stage low-frequency amplifiers on transistors of the p - n - p structure (a) and on transistors of the n - p - n structure (b).

In any of these amplifier options, transistors with a static current transfer coefficient h21e of 20 - 30 or more can operate. A transistor with a large coefficient h21e must be installed in the pre-amplification stage (first) - The role of load B1 of the output stage can be performed by headphones, a DEM-4m telephone capsule. To power the amplifier, use a 3336L battery (popularly called a square battery) or network power supply(which was proposed to be made in the 9th lesson). Pre-assemble the amplifier on breadboard , and then transfer its parts to the printed circuit board, if such a desire arises. First, mount only the parts of the first stage and capacitor C2 on the breadboard. Between the right (according to the diagram) terminal of this capacitor and the grounded conductor of the power source, turn on the headphones. If you now connect the input of the amplifier to the output jacks of, for example, a detector receiver tuned to some radio station, or connect any other source of a weak signal to it, the sound of a radio broadcast or a signal from the connected source will appear in the phones. By selecting the resistance of resistor R2 (the same as when adjusting the operating mode of a single-transistor amplifier, what I talked about in lesson 8 ), achieve the highest volume. In this case, a milliammeter connected to the collector circuit of the transistor should show a current equal to 0.4 - 0.6 mA. With a power supply voltage of 4.5 V, this is the most advantageous operating mode for this transistor. Then mount the parts of the second (output) stage of the amplifier, and connect the telephones to the collector circuit of its transistor. Phones should now sound significantly louder. Perhaps they will sound even louder after the collector current of the transistor is set to 0.4 - 0.6 mA by selecting resistor R4. You can do it differently: mount all the parts of the amplifier, select resistors R2 and R4 to set the recommended transistor modes (based on the currents of the collector circuits or the voltages on the collectors of the transistors) and only then check its operation for sound reproduction. This way is more technical. And for a more complex amplifier, and you will have to deal mainly with such amplifiers, this is the only correct one. I hope you understand that my advice on setting up a two-stage amplifier applies equally to both options. And if the current transfer coefficients of their transistors are approximately the same, then the sound volume of telephones and amplifier loads should be the same. With a DEM-4m capsule, the resistance of which is 60 Ohms, the quiescent current of the cascade transistor must be increased (by decreasing the resistance of resistor R4) to 4 - 6 mA. The schematic diagram of the third version of a two-stage amplifier is shown in (Fig. 3). The peculiarity of this amplifier is that in its first stage a transistor of the p - n - p structure operates, and in the second - a n - p - n structure. Moreover, the base of the second transistor is connected to the collector of the first not through a transition capacitor, as in the amplifier of the first two options, but directly or, as they also say, galvanically. With such a connection, the range of frequencies of amplified oscillations expands, and the operating mode of the second transistor is determined mainly by the operating mode of the first, which is set by selecting resistor R2. In such an amplifier, the load of the transistor of the first stage is not the resistor R3, but the emitter p-n junction of the second transistor. The resistor is needed only as a bias element: the voltage drop created across it opens the second transistor. If this transistor is germanium (MP35 - MP38), the resistance of resistor R3 can be 680 - 750 Ohms, and if it is silicon (MP111 - MP116, KT315, KT3102) - about 3 kOhms. Unfortunately, the stability of such an amplifier when the supply voltage or temperature changes is low. Otherwise, everything that is said in relation to the amplifiers of the first two options applies to this amplifier. Can amplifiers be powered from a 9 V DC source, for example from two 3336L or Krona batteries, or, conversely, from a 1.5 - 3 V source - from one or two 332 or 316 cells? Of course, you can: with more high voltage power source, the load of the amplifier - the loudspeaker head - should sound louder, with a lower one - quieter. But at the same time, the operating modes of the transistors should be somewhat different. In addition, with a power supply voltage of 9 V, the rated voltages of electrolytic capacitors C2 of the first two amplifier options must be at least 10 V. As long as the amplifier parts are mounted on a breadboard, all this can be easily verified experimentally and the appropriate conclusions can be drawn.

Rice. 3 Amplifier with transistors of different structures.

Mounting the parts of an established amplifier on a permanent board is not a difficult task. For example, (Fig. 4) shows the circuit board of the amplifier of the first option (according to the diagram in Fig. 2, a). Cut the board out of sheet getinax or fiberglass with a thickness of 1.5 - 2 mm. Its dimensions shown in the figure are approximate and depend on the dimensions of the parts you have. For example, in the diagram the power of the resistors is indicated as 0.125 W, the capacitance of the electrolytic capacitors is indicated as 10 μF. But this does not mean that only such parts should be installed in the amplifier. The power dissipation of resistors can be any. Instead of electrolytic capacitors K5O - 3 or K52 - 1, shown on the circuit board, there may be capacitors K50 - 6 or imported analogues, also for higher rated voltages. Depending on the parts you have, the amplifier's PCB may also change. You can read about methods for installing radio elements, including printed circuit installation, in the section "ham radio technology" .

Rice. 4 Circuit board of a two-stage low-frequency amplifier.

Any of the amplifiers that I talked about in this article will be useful to you in the future, for example for a portable transistor receiver. Similar amplifiers can be used for wired telephone communication with a friend who lives nearby.

Stabilization of the transistor operating mode

An amplifier of the first or second option (according to the diagrams in Fig. 2), mounted and adjusted indoors, will work better than outdoors, where it will be exposed to the hot rays of the summer sun or in the cold in winter. Why does this happen? Because, unfortunately, as the temperature increases, the operating mode of the transistor is disrupted. And the root cause for this is the uncontrolled reverse collector current Ikbo and the change in the static current transfer coefficient h21E with temperature changes. In principle, the current Ikbo is small. For low-frequency low-power germanium transistors, for example, this current, measured at a reverse voltage at the collector p-n junction of 5 V and a temperature of 20 ° C, does not exceed 20 - 30 μA, and for silicon transistors it is less than 1 μA. But it changes significantly when exposed to temperature. With an increase in temperature by 10°C, the current Ikbo of a germanium transistor approximately doubles, and a silicon transistor increases by 2.5 times. If, for example, at a temperature of 20°C the current Ikbo of a germanium transistor is 10 μA, then when the temperature rises to 60°C it increases to approximately 160 μA. But the current Ikbo characterizes the properties of only the collector p-n junction. In real operating conditions, the power source voltage is applied to two p-n junctions - collector and emitter. In this case, the reverse collector current also flows through the emitter junction and, as it were, reinforces itself. As a result, the value of the uncontrolled current, changing under the influence of temperature, increases several times. And the greater its share in the collector current, the more unstable the operating mode of the transistor is in different temperature conditions. An increase in the current transfer coefficient h21E with temperature increases instability. What happens in the cascade, for example, on transistor V1 of the amplifier of the first or second options? As the temperature rises, the total collector circuit current increases, causing an increasing voltage drop across the load resistor R3 (see Fig. 3). The voltage between the collector and emitter decreases, which leads to signal distortion. With a further increase in temperature, the voltage at the collector may become so small that the transistor will no longer amplify the input signal at all. Reducing the effect of temperature on the collector current is possible either by using transistors with a very low current Ikbo in equipment designed to work with significant temperature fluctuations. for example, silicon, or the use of special measures that thermally stabilize the mode of transistors. One of the methods thermal stabilization of the operating mode a germanium transistor of the p - n - p structure is shown in the diagram in Fig. 5, a. Here, as you can see, the base resistor Rb is connected not to the negative conductor of the power source, but to the collector of the transistor. What does this give? With increasing temperature, the increasing collector current increases the voltage drop across the load Rн and reduces the voltage across the collector. And since the base is connected (through resistor Rb) to the collector, the negative bias voltage on it also decreases, which in turn reduces the collector current. The result is feedback between the output and input circuits of the cascade - the increasing collector current reduces the voltage at the base, which automatically reduces the collector current. The specified operating mode of the transistor is stabilized. But during operation of the transistor, negative AC feedback occurs between its collector and base through the same resistor Rb, which reduces the overall gain of the cascade. Thus, the stability of the transistor mode is achieved at the cost of loss in gain. It’s a pity, but you have to make these losses in order to maintain normal work amplifier

Rice. 5 Amplifier stages with thermal stabilization of the transistor mode.

There is, however, a way to stabilize the operating mode of the transistor with slightly lower losses in amplification, but this is achieved by complicating the cascade. The circuit of such an amplifier is shown in (Fig. 5, b). Transistor rest mode DC and the voltage remains the same: the collector circuit current is 0.8 - 1 mA, the negative bias voltage at the base relative to the emitter is 0.1 V (1.5 - 1.4 = 0.1 V). But the mode is set using two additional resistors: Rb2 and Re. Resistors Rb1 and Rb2 form a divider with the help of which a stable voltage is maintained at the base. The emitter resistor Re is an element thermal stabilization . Thermal stabilization of the transistor mode occurs as follows. As the collector current increases under the influence of heat, the voltage drop across the resistor Re increases. In this case, the voltage difference between the base and emitter decreases, which automatically reduces the collector current. The same feedback is obtained, only now between the emitter and the base, thanks to which the transistor mode is stabilized. Cover the capacitor Se with paper or your finger, connected in parallel with the resistor Re and, therefore, shunting it. What does this diagram remind you of now? A cascade with a transistor connected according to the OK circuit (emitter follower). This means that during operation of the transistor, when across the resistor Re there is a voltage drop of not only the constant, but also the variable components, a voltage drop occurs between the emitter and the base. 100% negative AC voltage feedback , at which the cascade gain is less than unity. But this can only happen when there is no capacitor C3. This capacitor creates a parallel path along which, bypassing the resistor Re, the alternating component of the collector current flows, pulsating with the frequency of the amplified signal, and negative feedback does not occur (the alternating component of the collector current goes into the common wire). The capacitance of this capacitor should be such as not to provide any noticeable resistance to the lowest frequencies of the amplified signal. In the audio frequency amplification stage, this requirement can be met by an electrolytic capacitor with a capacity of 10 - 20 or more microfarads. An amplifier with such a system for stabilizing the transistor mode is practically insensitive to temperature fluctuations and, moreover, and no less important, to changing transistors. Is this how the operating mode of the transistor should be stabilized in all cases? Of course not. After all, it all depends on what purpose the amplifier is intended for. If the amplifier will only operate at home, where the temperature difference is insignificant, strict thermal stabilization is not necessary. And if you are going to build an amplifier or receiver that would work reliably both at home and on the street, then, of course, you need to stabilize the mode of the transistors, even if the device will have to be complicated with additional parts.

Push-pull power amplifier

Talking at the beginning of this article about the purpose of the amplifier stages, I, as if looking ahead, said that in the output stages, which are power amplifiers, radio amateurs use the same low-power transistors as in the voltage amplification stages. Then, naturally, a question might arise in your mind, or perhaps arose: how is this achieved? I'm answering it now. Such stages are called push-pull power amplifiers. Moreover, they can be transformer-based, i.e. using transformers in them, or transformerless. Your designs will use both types of push-pull audio frequency oscillation amplifier. Let's understand the principle of their work. A simplified diagram of a push-pull transformer power amplification stage and graphs illustrating its operation are shown in (Fig. 6). As you can see, it contains two transformers and two transistors. Transformer T1 is interstage, connecting the pre-terminal stage with the input of the power amplifier, and transformer T2 is the output one. Transistors V1 and V2 are connected according to the OE circuit. Their emitters, like the middle terminal of the secondary winding of the interstage transformer, are “grounded” - connected to the common conductor of the power supply Ui.p. - negative supply voltage is supplied to the transistor collectors through the primary winding of the output transformer T2: to the collector of transistor V1 - through section Ia, to the collector of transistor V2 - through section Ib. Each transistor and the associated sections of the secondary winding of the interstage transformer and the primary winding of the output transformer represent a regular, already familiar single-ended amplifier. This is easy to verify if you cover one of these cascade arms with a piece of paper. Together they form a push-pull power amplifier.

Rice. 6 Push-pull transformer power amplifier and graphs illustrating its operation.

The essence of the operation of a push-pull amplifier is as follows. Sound frequency oscillations (graphics in Fig. 6) from the pre-terminal stage are fed to the bases of both transistors so that the voltages on them change at any time in opposite directions, i.e. in antiphase. In this case, the transistors operate alternately, for two cycles for each period of the voltage supplied to them. When, for example, there is a negative half-wave at the base of transistor V1, it opens and the current of only this transistor flows through section Ia of the primary winding of the output transformer (graph b). At this time, transistor V2 is closed, since there is a positive half-wave voltage at its base. In the next half-cycle, on the contrary, the positive half-wave will be based on transistor V1, and the negative half-wave will be based on transistor V2. Now transistor V2 opens and the collector current flows through section Ib of the primary winding of the output transformer (graph c), and transistor V1, closing, “rests”. And so on for each period of sound vibrations supplied to the amplifier. In the transformer winding, the collector currents of both transistors are summed (graph d), as a result, more powerful electrical oscillations of audio frequency are obtained at the amplifier output than in a conventional single-ended amplifier. Dynamic head B, connected to the secondary winding of the transformer, converts them into sound. Now, using the diagram in (Fig. 7), let’s understand the principle of operation transformerless push-pull amplifier power. There are also two transistors, but they are of different structures: transistor Vl - p - n - p, transistor V2 - n - p - n. For direct current, the transistors are connected in series, forming, as it were, a voltage divider of the direct current source feeding them. In this case, a negative voltage equal to half the power source voltage is created at the collector of transistor V1 relative to the midpoint between them, called the symmetry point, and a positive voltage is created at the collector of transistor V2, also equal to half the voltage of the power source Unp. Dynamic head B is connected to the emitter circuits of transistors: for transistor V1 - through capacitor C2, for transistor V2 - through capacitor C1. Thus, the AC transistors are connected according to the OK circuit (emitter followers) and work on one common load - head B.

Rice. 7 Push-pull transformerless power amplifier.

At the bases of both transistors of the amplifier, an alternating voltage of the same value and frequency operates, coming from the pre-terminal stage. And since the transistors are of different structures, they work alternately, in two cycles: with a negative half-wave voltage, only transistor V1 opens and in the circuit head B - capacitor C2 a collector current pulse appears (in Fig. 6 - graph b), and with a positive half-wave At half-wave, only transistor V2 opens and in the head-capacitor C1 circuit a pulse of the collector current of this transistor appears (in Fig. 6 - graph c). Thus, the total current of the transistors flows through the head (graph d in Fig. 6), which represents power-amplified sound frequency oscillations, which it converts into sound vibrations. Practically, the same effect is obtained as in an amplifier with transformers, but, thanks to the use of transistors of different structures, there is no need for a device for supplying a signal to the base of the transistors in antiphase . You may have noticed one contradiction in my explanation of push-pull power amplifiers: no bias voltage was applied to the bases of the transistors. You are right, but there is no particular mistake here. The fact is that push-pull transistors can operate without an initial bias voltage. But then distortions like "step" , especially strongly felt with a weak input signal. They are called steps because on the oscillogram of a sinusoidal signal they have a stepped shape (Fig. 8). The simplest way to eliminate such distortions is to apply a bias voltage to the bases of the transistors, which is what is done in practice.

Rice. 8 “Step” type distortion.

Now, before we start talking about amplifiers that provide loud sound reproduction, I want to introduce you to some parameters and amplification classes that characterize a low-frequency amplifier. All the advantages of push-pull amplifiers will be discussed in detail below.

MAIN PARAMETERS OF LF AMPLIFIERS

The quality and suitability of an amplifier for certain purposes is judged by several parameters, the most important of which are three: output power Pout, sensitivity and frequency response. These are the basic parameters that you should know and understand. Output power is the electrical power of an audio frequency, expressed in watts or milliwatts, that an amplifier delivers to a load—usually a direct-radiation driver. In accordance with established standards, a distinction is made between nominal Rnom and maximum power Pmax. Nominal power is the power at which the so-called nonlinear distortion of the output signal introduced by the amplifier does not exceed 3 - 5% relative to the undistorted signal. As the power increases further, the nonlinear distortion of the output signal increases. The power at which distortion reaches 10% is called maximum. The maximum output power can be 5 - 10 times higher than the rated power, but with it distortion is noticeable even by ear. When talking about amplifiers in this article, I will generally report their average power outputs and simply refer to them as power outputs. The sensitivity of an amplifier is the audio frequency signal voltage, expressed in volts or millivolts, that must be applied to its input in order for the power at the load to reach the rated value. The lower this voltage, the better, naturally, the sensitivity of the amplifier. For example, I will say: the sensitivity of the vast majority of amateur and industrial amplifiers intended for reproducing signals from the linear output of a tape recorder, DVD player and other sources can be 100 - 500 mV and up to 1V, the sensitivity of microphone amplifiers is 1 - 2 mV. Frequency response - frequency response (or operating frequency band of the amplifier) ​​is expressed graphically by a horizontal, slightly curved line showing the dependence of the output signal voltage Uout on its frequency at a constant input voltage Uin. The fact is that any amplifier, for a number of reasons, amplifies signals of different frequencies unequally. As a rule, vibrations of the lowest and highest frequencies of the sound range are the worst amplified. Therefore, the lines - the frequency characteristics of the amplifiers - are uneven and necessarily have dips (blockages) at the edges. Oscillations of extreme low and high frequencies, the amplification of which compared to fluctuations of middle frequencies (800 - 1000 Hz) drops to 30%, are considered to be the boundaries of the amplifier frequency band. The frequency band of amplifiers intended for reproducing musical works must be at least from 20 Hz to 20 - 30 kHz, amplifiers of network broadcasting receivers - from 60 Hz to 10 kHz, and amplifiers of small-sized transistor receivers - from approximately 200 Hz to 3 - 4 kHz. To measure the basic parameters of amplifiers, you need an audio frequency oscillator, an alternating voltage voltmeter, an oscilloscope and some other measuring instruments. They are available in production radio laboratories, radio electronics clubs, and for more productive radio electronics studies, you should try to purchase them for yourself so that they are always at hand.

Gain classes of low-frequency amplifiers. The role of amplification class in achieving power parameters and high efficiency

Until now, we have not talked about how much energy is spent on creating an amplified signal, on creating a “powerful copy” of the input signal. As a matter of fact, we never had such a question. It must be said that the energy supplier for creating an amplified signal can be a battery or power supply. At the same time, it is considered obvious that the battery has large reserves of energy and there is nothing to spare it just to create an amplified signal. Now that the goal has been achieved, when we have learned to use a transistor to amplify weak signal, let's try to find out what kind of energy should be supplied by its supplier - the collector battery. Let's try to find out how much a watt of amplified signal costs, how many watts of DC power the battery must pay for it. Having made a number of assumptions, assuming that the straight section of the input characteristic starts straight from “zero”, that there are no bends in the output characteristic, that an element (for example, a transformer) is included as a collector load, on which the constant voltage is not lost, we will come to the conclusion that that in the best case, only half of the power consumed from the battery goes into the amplified signal. This can be said differently: efficiency (coefficient useful action) transistor amplifier does not exceed 50%. For every watt of output signal power, you have to pay double the price, two watts of collector battery power (Fig. 9).

Rice. 9 The higher the efficiency of an amplifier, the less power it consumes to create a given output power.

Proving the validity of this conclusion is quite simple. To calculate the power consumed from a battery, you need to multiply its DC voltage Ek on the consumed current, that is, on the quiescent collector current Ik.p. . transistor (Ppot. = Ek * Ik.p.) . On the other hand, the amplitude of the alternating component of the collector current cannot in any way be greater than the quiescent current, otherwise the transistor will operate with a cutoff. In the best case, the amplitude of the variable component is equal to the quiescent current Ik.p. and in this case the effective value of the alternating component of the collector current is equal to In.ef. = 07 * Ik.p .. In the same way, the amplitude of the alternating voltage on the load cannot be greater than the battery voltage, otherwise at some moments not a “minus”, but a “plus” will appear on the collector. And this, at best, will lead to severe distortions. Thus, the effective value of the output voltage Uneff. cannot exceed Uneff. = 07 * Ek . Now all that remains is to multiply 07 * Ik.p.. on 07 * Ek. and find that the maximum effective power that the amplifier can deliver does not exceed Ref. = 0.5 * Ik.p. * Ek = W.eff. , that is, does not exceed half of the power consumption. This decision is final, but it is subject to appeal. It is possible, at the cost of certain sacrifices, to increase the efficiency of the amplifier, to cross the line of fifty percent efficiency. To increase the efficiency, it is necessary for the amplifier to create a more powerful signal at the same power consumption. And for this you need, without increasing the quiescent current Ik.p. and constant voltage Ek , increase the alternating components of the collector current In and load voltage Un. What prevents us from increasing these two components? Distortions . We can also increase the current In (for this it is enough, for example, to increase the input signal level), and the voltage Un (to do this, it is enough again to increase the input signal or increase the load resistance for (alternating current). But in both cases, the signal shape will be distorted, its negative half-waves will be cut off. And although such a sacrifice seems unacceptable (who needs an economical amplifier, if it produces defective products?), we will still go for it. Firstly, because by allowing distortion (and then getting rid of it), we will be able to switch the amplifier to a more economical mode and increase its efficiency. Gain without distortion, when the amplitude of the alternating component of the collector current does not exceed the quiescent current Ic.p., is called gain class (A). A single amplifier operating in class A is called a single-ended amplifier. If, during amplification, part of the signal is “cut off”, if the amplitude of the alternating component of the collector current is greater than Ic.p., and a current cutoff occurs in the collector circuit, then we get one of the amplification classes (AB), (B) or (C). With amplification in class B, the cutoff is equal to half-cycle, i.e. In half the period there is current in the collector circuit, and in the other half of the period there is no current. If there is current in more than half the period, then we have amplification class AB, if less, class C. (More often, gain classes denote with Latin letters A, AB, B, C). Imagine that we have not one, but two identical amplifiers operating in class B: one reproduces positive half-cycles of the signal, the other - negative ones. Now imagine that both of them work for a common load. In this case, we will receive a normal, undistorted alternating current in the load - a signal as if stitched from two halves (Fig. 10).

Rice. 10 Push-pull cascade and amplification classes.

True, in order to obtain an undistorted signal from two distorted ones, we had to create a relatively complex circuit for stitching the halves together (such a circuit, as discussed above in this article, is called push-pull), essentially consisting of two independent amplification stages. But as explained above, our loss (in this case, the complication of the amplifier circuit) brings a significantly greater gain. The total power that a push-pull amplifier develops is greater than the power that both halves would produce separately. And the “cost” of one watt of the output signal turns out to be significantly less than in a single-ended amplifier. In an ideal case (switch mode), one watt of output signal can be obtained for the same watt of power consumption, that is, in an ideal case, the efficiency of a push-pull amplifier can reach 100 percent. The real efficiency, of course, is lower: practically it is 67%. But in a single-ended amplifier operating in a class A, we obtained an efficiency equal to 50%, also only in the ideal case. But in reality, a single-ended amplifier allows you to obtain an efficiency of no more than 30 - 40%. And therefore in a push-pull amplifier, each watt of output power costs us two to three times “cheaper” than in a single-cycle amplifier. For portable transistor equipment, increasing efficiency is especially important. The higher the efficiency, the lower the energy consumption of the collector battery at the same output power. And this, in turn, means that the higher the efficiency, the less often this battery will need to be changed or the smaller the battery can be with a constant service life. That is why in miniature transistor equipment, in particular in miniature receivers, where it would seem that it is necessary to save weight and space, push-pull amplifiers are used, including a number of unnecessary parts in the circuit for this purpose. Circuits of push-pull amplifiers for repetition will be given in practical work. In almost all circuits of push-pull, transistor final amplifiers, class AB or B is used. However, when working in class B some hard-to-remove distortions appear (due to the bending of the input characteristic), and this class is used less frequently in low-frequency amplifiers. Class C is not used at all in these amplifiers due to the appearance of unavoidable distortion. The control voltage is supplied to the output transistors from the so-called phase inversion cascade , made on a transistor according to a transformer circuit. There are other schemes bass reflexes , but they all perform the same task; they create two antiphase voltages that must be applied to the bases of the push-pull transistors. If the same voltage is applied to these transistors, then they will not operate through a clock, but synchronously, and therefore both will amplify only positive or, conversely, only negative half-cycles of the signal. In order for the transistors of the push-pull cascade to operate alternately, it is necessary to apply to their bases, as mentioned above antiphase voltages . In a phase inverter with a transformer, two control voltages are obtained by dividing the secondary winding into two equal parts. And these voltages become antiphase because the middle point of the secondary winding is grounded. When a “plus” appears at its upper (according to the diagram) end relative to the midpoint, a “minus” appears at the lower end relative to this point. And since the voltage is variable, “plus” and “minus” always change places (Fig. 11).

Rice. 11 The phase inverter creates two alternating voltages, 180 degrees out of phase.

Transformer bass reflex simple and reliable, it practically does not need to be set up. A push-pull amplifier for a transistor receiver or a small radio can be assembled using any of the low-frequency amplifier circuits that will be given in practical work or the circuits of an industrial receiver. For example, according to the scheme of the receivers “Alpinist”, “Neva-2”, “Spidola”, etc.

A little more about the negative feedback which was mentioned at the beginning of this article when describing single-ended amplifiers. How does negative feedback reduce distortion and correct the signal shape? To answer this question, we need to remember that waveform distortion essentially means the appearance of new harmonics , new sinusoidal components. Along the negative feedback chain, new ones that appeared as a result harmonic distortion are supplied to the input of the amplifier in such a phase (antiphase) that they attenuate themselves. The power of these harmonics at the output of the amplifier is less than it would be without feedback. At the same time, of course, the useful components from which an undistorted signal should be composed are also weakened, but this is a fixable matter. To compensate for this harmful negative feedback activity, you can increase the level of the signal entering the amplifier's input, maybe even adding another stage to do this. Negative feedback in low-frequency amplifiers, especially push-pull amplifiers operating in classes AB And B, finds very wide application: negative feedback allows you to do something that cannot be achieved by any other means, it allows reduce waveform distortion, reduce so-called nonlinear distortion . Negative feedback allows you to perform another important operation: adjust the tone, that is, in the desired direction change the frequency response of the amplifier Fig. 12 .

Rice. 12. Approximate graph of amplitude-frequency response (AFC) of amplifiers. A similar graph can characterize the frequency response of any amplifier.

This characteristic shows how the gain changes with the frequency of the signal. For an ideal amplifier, the frequency response is simply a straight line: the gain at all frequencies is the same for such an amplifier. But in a real amplifier, the frequency response is bent, swamped in the region of the lowest and highest frequencies. This means that the low and high frequencies of the audio range are less amplified than the mid frequencies. The reasons for the appearance of such blockages in the frequency response may be different, but they have a common root. Uneven gain at different frequencies is obtained because the circuit contains reactive elements, capacitors and coils, the resistance of which varies with frequency. There are many ways to correct the frequency response, including introduction of frequency-dependent elements into the feedback circuit. An example of such elements is the chain R13, C9 in the amplifier shown in (Fig. 13).

Rice. 13 Practical design of a transformerless push-pull amplifier.

The resistance of this chain increases with decreasing frequency, the feedback decreases, and due to this a certain increase in the frequency response is created in the region lower frequencies. The amplifier has several more negative feedback circuits. This is capacitor C6, connecting the collector of transistor T2 to its base; resistor R12, which supplies not only a constant bias to the bases of the output transistors, but also some part of the output signal. A chain that creates feedback from the third stage to the second, but not in alternating current, but in direct current (such feedback increases the thermal stability of the amplifier). The dynamic head is connected to the collector circuits of the output transistors through an isolation capacitor C4. The resistance of the voice coil in this circuit can be 6 - 10 ohms. The amplifier develops power up to 100 mW. at an input signal voltage of about 30 - 50 mV. There are quite a large number of transformerless amplifier circuits using transistors of different conductivities. Most of them use composite transistors in the output stage, that is, two transistors are included in each arm. The absence of transformers and a reduction in the number of coupling capacitors allows such amplifiers to obtain a very good frequency response. However, for a novice radio amateur this gain comes at a rather high price. Transformerless amplifiers, and even those with composite transistors, are not always easy to set up. And therefore, if you do not yet have much experience in setting up transistor equipment, it is better to assemble the amplifier using a classic push-pull circuit with transformers (Fig. 14).

Rice. 14 Push-pull ULF with transformer output stage.

The main feature of this amplifier is a fixed bias from a separate battery B2 to the base of the first stage T1. Due to this, the collector current of transistor T1 remains practically unchanged when the voltage of the collector battery decreases down to 3.5 V. From the bottom of the divider R4, R5, connected to the emitter circuit T1, a bias is applied to the bases of the output stage transistors. And therefore, when the collector voltage decreases, the bias of transistors T2, T3 does not change. As a result, the amplifier operates at a reduced voltage, although with less output power (at 3.5 V, 20 mW), but without distortion. The current consumed from battery B2 does not exceed 500 μA. The amplifier has a simple tone control R6 and a feedback circuit R8, C8 that reduces distortion. Resistor R9 is necessary so that when B2 is turned off (it may happen that Bk2 opens the circuit some fractions of a second earlier than Bk1, transistor T1 does not end up with a “hanging base.” Capacitors C7, C6 are negative feedback elements that prevent self-excitation at supersonic frequencies. The same task is performed by capacitor C3. Transformers Tr1 and Tr2 are taken from the Alpinist receiver. The dynamic head with a voice coil resistance of about 4 - 6 ohms. At a collector voltage of 9 V, the amplifier develops a power of 180 mW. batteries B2 current is no more than 20 - 25 mA. If you need to increase the output power, you can turn on powerful transistors as T2 and T3, for example P201. In this case, you need to halve R7 and select R5 in such a way that the total quiescent collector current. T2 and T3 was 15 - 25 mA. For powerful transistors, you need a different output transformer, for example, with the following data: core with a cross-section of about 3.5 cm2 (W17 x 17); primary winding 330 + 330 turns PEV 0.31, secondary winding 46; turns PEV 0.51. With P201 transistors, the amplifier develops an output power of 1.52 - 2 W. Setting up all low-frequency amplifiers comes down to selecting transistor modes. For push-pull circuits, it is advisable to first select transistors for both arms with similar parameters: current gain and reverse collector current. If all the parts are in working order and the circuit is assembled correctly, then the amplifier, as a rule, immediately starts working. And the only serious trouble that can be detected when turning on the amplifier is self-excitation. One way to combat this is to introduce decoupling filters, which prevent communication between stages through power supplies.

Practical work

In practical work, I would like to present a few more simple amplifiers to repeat and consolidate the theoretical part of this article. The examples of push-pull amplifiers given at the end of the article are also quite suitable for repetition. These diagrams, like many other drawings, were taken from literary sources of the 60s and 70s, but they have not lost their relevance. Why, you ask, do I use such outdated drawings? I will say there are at least 2 reasons: 1). I desperately don’t have enough time to draw them myself, although I still try to draw some of them. 2). Oddly enough, it is the drawings from the literature of past, long-forgotten years that fully reflect the essence of the processes being studied. Probably, it is not the pursuit of fees, as is customary now, that has an effect, but the importance of high-quality presentation of the material. And it was not for nothing that censorship workers in those years. ate their bread.

So, instead of transistors P13 - P16 indicated on the diagrams, you can use MP39 - 42, MP37, MP38; from silicon transistors, you can use KT315, KT361, respectively, pay attention to the type of conductivity and power of the transistors used. If the amplifier has powerful output transistors like P213 - 215 in the circuit, they can usually be replaced with silicon ones powerful transistors type KT814 - 817 or KT805, KT837, observing the type of conductivity, respectively. In any case, when replacing germanium transistors with silicon ones, it is necessary to adjust the resistor values ​​in the circuits of the replaced transistors.

A simple transformerless push-pull amplifier with a power of 1.5 W. The high-frequency transistor P416 is used here for the reason of reducing the noise of the input stage as much as possible, because in addition to being high-frequency, it is also low-noise. In practice, it can be replaced with MP39 - 42, with a deterioration in noise characteristics, respectively, or with silicon transistors KT361 or KT3107 with any letter. used in detector receiver, due to which a bias voltage is formed at the bases of the transistors. The voltage at the midpoint (the negative terminal of capacitor C2) will be equal to 4.5V. It is installed by selecting resistors R2, R4. The maximum permissible operating voltage of capacitor C2 can be 6V.

More amplifier options 1st, 2nd, available for repetition by beginning radio amateurs, including those using silicon transistors. Options are also shown preamp and a simple passive tone block. (will open in a separate window).

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I would like to offer novice lovers of high-quality sound reproduction one of the developed and tested ULF circuits. This design will help make a high-quality amplifier that can be modified with minimal costs and use the amplifier for circuit research.

This will help you on your way from simple to complex and more perfect. Attached to the description are files of printed circuit boards that can be transformed to fit a specific case.

In the presented version, the housing from Radiotekhnika U-101 was used.

I developed and made this power amplifier in the last century from what could be purchased without difficulty. I wanted to make a design with the highest possible price-quality ratio. This is not High-End, but not third grade either. The amplifier has high-quality sound, excellent repeatability and is easy to set up.

Amplifier circuit diagram

The circuit is completely symmetrical for the positive and negative half-waves of the low-frequency signal. The input stage is made using transistors VT1 – VT4. It differs from the prototype in transistors VT1 and VT4, which increase the linearity of the stages on transistors VT2 and VT3. There are many circuit types of input stages with various advantages and disadvantages. This cascade was chosen because of its simplicity and the possibility of reducing the nonlinearity of the amplitude characteristics of transistors. With the advent of more advanced input stage circuits, it can be replaced.

The negative feedback signal (NFS) is taken from the output of the voltage amplifier and enters the emitter circuits of transistors VT2 and VT3. The rejection of general OOS is due to the desire to get rid of the influence on the OOS of all unnecessary things that are not the output signal of the circuit. This has its pros and cons. With this configuration this is justified. If you have higher quality components, you can try with various types feedback.

A cascode circuit was chosen as a voltage amplifier, which has a high input resistance, low pass-through capacitance and lower nonlinear distortions in comparison with the OE circuit. The disadvantage of the cascode circuit is the lower amplitude of the output signal. This is the price to pay for less distortion. If you install jumpers, you can also assemble an OE circuit on a printed circuit board. Powering the voltage amplifier from a separate voltage source was not introduced due to the desire to simplify the design of the ULF.

The output stage is a parallel amplifier, which has a number of advantages over other circuits. One of the important advantages is the linearity of the circuit with a significant spread in the parameters of the transistors, which was checked when assembling the amplifier. This cascade should perhaps have greater linearity, because there is no overall OOS and the quality of the amplifier’s output signal greatly depends on it. Amplifier supply voltage 30 V.

Amplifier Design

I developed printed circuit boards for “affordable” cases from Radiotekhnika U-101 amplifiers. The circuit was placed on two parts of the printed circuit board. The first part, which is fixed to the radiator, houses a “parallel” amplifier and a voltage amplifier. The second part of the board houses the input stage. This board is attached to the first board using corners. This division of the board into two parts allows the amplifier to be improved with minimal design changes. In addition, this arrangement can also be used for laboratory studies of cascades.

The amplifier must be assembled in several stages. Assembly begins with a parallel amplifier and its setup. In the second stage, the rest of the circuit is assembled and adjusted and the final minimization of circuit distortions is carried out. When placing the transistors of the output stage on the radiator, it is necessary to remember the need for thermal contact between the housings of transistors VT9, VT14 and VT10, VT13 in pairs.

Printed circuit boards were developed using the Sprint Layout 6 program, which will allow you to adjust the placement of elements on the board, i.e. customized for a specific configuration or case. See archives below.

Amplifier parts

The parameters of the amplifier depend on the quality of the radio elements used and their location on the board. The applied circuit solutions make it possible to do without selecting transistors, but it is advisable to use transistors with a cut-off amplification frequency from 5 to 200 MHz and a margin of maximum operating voltage of more than 2 times in comparison with the cascade supply voltage.

If there is a desire and opportunity, then it is advisable to choose transistors according to the principle of “complementarity” and identical amplification characteristics. We tried manufacturing options with and without selecting transistors. The version with selected “complementary” domestic transistors showed significantly better performance than without selection. Only KT940 and KT9115 of the domestic transistors are complementary, while the rest have conditional complementarity. There are a lot of complementary pairs among foreign transistors, and information about this can be found on manufacturers’ websites and in reference books.

As VT1, VT3, VT5 it is possible to use transistors of the KT3107 series with any letters. As VT2, VT4, VT6 it is possible to use transistors of the KT3102 series with letters that have characteristics similar to the used transistors for another half-wave sound signal. If it is possible to select transistors according to parameters, then it is better to do so. Almost all modern testers allow you to do this without problems. With large deviations, the time spent on setting up will be greater and the result will be more modest. Transistors KT9115A, KP960A are suitable for VT6, and KT940A, KP959A are suitable for VT7.

Transistors KT817V (G), KT850A can be used as VT9 and VT12, and KT816V (G), KT851A can be used as VT10 and VT11. For VT13, transistors KT818V (G), KP964A are suitable, and for VT14 - KT819V (G), KP954A. Instead of zener diodes VD3 and VD4, you can use two AL307 LEDs connected in series or the like.

The circuit allows the use of other parts, but correction of the printed circuit boards may be required. Capacitor C1 can have a capacity from 1 µF to 4.7 µF and must be made of polypropylene or another, but of high quality. You can find information about this on amateur radio websites. The supply voltage, input and output signals are connected using printed circuit terminals.

Setting up the amplifier

When turned on for the first time, the ULF should be connected through powerful ceramic resistors (10 - 100 Ohms). This will save the elements from overloads and failure due to an installation error. On the first part of the board, resistor R23 sets the quiescent current ULF (150-250 mA) when the load is off. Next, you need to establish that there is no constant voltage at the output of the amplifier when an equivalent load is connected. This is done by changing the value of one of the resistors R19 or R20.

After installing the rest of the circuit, set resistor R14 to the middle position. Using the load equivalent, the absence of excitation of the amplifier is checked and resistor R5 is used to establish the absence of constant voltage at the output of the amplifier. The amplifier can be considered configured in static mode.

To set up in dynamic mode, a serial RC circuit is connected in parallel to the load equivalent. Resistor with a power of 0.125 W and a nominal value of 1.3-4.7 kOhm. Non-polar capacitor 1-2 µF. We connect a microammeter (20-100 µA) in parallel to the capacitor. Then, by applying a sinusoidal signal with a frequency of 5-8 kHz to the amplifier input, you need to estimate the threshold saturation level of the amplifier using an oscilloscope and an AC voltmeter connected to the output. After this, we reduce the input signal to a level of 0.7 from saturation and use resistor R14 to achieve a minimum reading of the microammeter. In some cases, to reduce distortion at high frequencies, it is necessary to carry out phase correction in advance by installing capacitor C12 (0.02-0.033 μF).

Capacitors C8 and C9 are selected for the best transmission of a pulse signal with a frequency of 20 kHz (installed if necessary). Capacitor C10 can be omitted if the circuit is stable. By changing the value of resistor R15, the same gain is established for each of the channels of the stereo or multi-channel version. By changing the value of the quiescent current of the output stage, you can try to find the most linear operating mode.

Sound rating

The assembled amplifier has a very good sound. Listening to the amplifier for a long time does not lead to fatigue. Of course, there are better amplifiers, but in terms of the ratio of costs and resulting quality, many will like the circuit. With better quality parts and their selection, even more significant results can be achieved.

Links and files

1. Korol V., “UMZCH with compensation for nonlinearity of the amplitude characteristic” - Radio, 1989, No. 12, p. 52-54.

06/09/2017 - The scheme has been corrected, all archives have been re-uploaded.
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