Tuning the radio using instruments. Setting up the high frequency block. Radio station preset buttons
WinAmp. It is very convenient for listening to music files in mp3 format. But it also has one interesting feature - listening to radio stations. Of course, such functions will not surprise anyone; sometimes it is enough to go to the website of a popular radio station and listen to the Internet broadcast. But WinAmp offers users almost 9000 radio stations. And it doesn’t just offer, but sorts by style, direction, language and country.
How to set up a radio in WinAmp
To configure the radio correctly, you need to additionally install the WinAmp Library component for the WinAmp player. It is available for downloading from the Internet from the manufacturer's website. After downloading and installing the additional component, launch WinAmp. Let's start setting up the radio. Go to “Settings” and in the Online Media tab set the number of radio stations to listen to. By default, there are only 600 stations installed, but on the Internet their number is in the thousands. We set the value with a margin of 20 thousand. We exit the player and start searching for radio stations.
Select Internet Radio from the menu. Then in the window on the right we activate the Refresh button. The list of available radio stations will begin to download. From now on you can listen to radio stations.
To configure the radio correctly, you need to filter the list by style and direction. To do this, you can specify several types in the Genre menu - classical, rock, pop, jazz, etc., and you can also select countries. If the list of priorities includes not only news, but also news, then you can filter by topic - politics, sports, regional news. In addition, there is a function to search for radio stations by name. Having selected the radio station you are interested in, activate playback either using the Play button or double-clicking the mouse. You can add your favorite radio stations to your “Favorites” list.
Using the WinAmp player, you can find many unexpected radio stations on the Internet. Foreign radio amateurs often broadcast “intercepted” police or air traffic control radio communications on the Internet. In a word, surveying radio broadcasts is as entertaining as simply “surfing” on the Internet. It will take several months of time and a solid gigabyte to study radio stations.
Please note that WinAmp in radio mode consumes approximately 62 megabytes of Internet traffic per hour of listening. Radio stations transmit at 128 kbit/s, so owners of limited packages should take this fact into account.
A correctly assembled receiver, when connecting antenna 1 and grounding, should immediately work: by turning the tuning knob, you can receive the local station. You can verify that the station is currently working by receiving it on a regular tube receiver.
1 To increase the signal voltage supplied to the circuit, the antenna can be temporarily connected to the stator of the capacitor C5, either directly or through a capacitor with a capacity of 50-100 pF.
If it turns out that the receiver does not work, then you must first calmly and carefully check the installation and parts. Most often, the following malfunctions may occur: poor contacts in the antenna, grounding or telephone sockets; unreliable contacts during installation due to poor soldering; unreliable contacts in the switch due to its contamination, invisible to the eye; break of the installation wire (meaning single-core copper wire in vinyl chloride insulation); short circuit between the stator and rotor of the tuning capacitor or between the plates of the filter capacitor; malfunction in the semiconductor diode; break in the loop coil or headphone winding.
All these faults come down to two main ones: open circuit and short circuit, and they can be easily detected using any ohmmeter or probe consisting of a battery and some kind of indicator - a dial gauge (sheet 98) or even an ordinary light bulb. The simplest probe for checking circuits can be assembled from a battery and a telephone. If you connect such a probe to a working circuit, then at the moment of connection a strong click will be heard in the phones; If the chain is broken there will be no click. When checking small capacitors, on the contrary, the presence of strong clicks will indicate a short circuit between the plates.
The simplest probes can only be used as a last resort. The best way to set up a receiver is to have an avometer - a universal measuring instrument that includes an ammeter, a voltmeter and an ohmmeter (hence the name “avometer”). Our industry produces many different types of avometers: TT-1, TT-2, Ts-20, Ts-315, etc. Any of them can be extremely useful both when setting up homemade detector and tube receivers, and when checking and repairing industrial radio equipment - tape recorders, receivers, televisions, radio units, etc.
When you are convinced that the constructed detector receiver is working, and for this it is enough to receive at least one radio station, you can begin setting it up. It basically boils down to the fact that by changing the inductance of the coils (this is done by moving the moving sections or tuning cores, and in extreme cases, selecting the number of turns of the coils), as well as by adjusting the capacitance of the tuning capacitors, it will be necessary to ensure that the position of the needle on the scale coincides with the frequency of the received station .
So, for example, if reception is at a frequency of 150 kHz (2000 m), the arrow associated with the rotor of the tuning capacitor shows a frequency of 200 kHz (1500 m), which means that the circuit parameters are selected incorrectly and its limiting resonant frequencies, that is, frequencies corresponding The settings of the capacitor rotor that are fully inserted and fully removed are shifted relative to the boundaries of the range we need towards lower frequencies.
As we have already noted (), the section of the long-wave range where radio broadcasting stations operate is limited by frequencies: minimum 150 kHz (2000 m) and maximum 420 kHz (740 m). Let's assume that in our receiver the boundaries are shifted by 50 kHz, that is, it can accept that the receiver will operate in the 100-150 kHz area, where there are no broadcast stations, and, conversely, the receiver will not receive stations operating in the 370-420 kHz area will. Indeed, when we set the arrow on the scale to its extreme position, corresponding to a frequency of 420 kHz, the circuit will actually be tuned to a frequency of 370 kHz, and we will not be able to tune to a higher frequency, since for this we need to reduce the capacitance of the circuit, and the capacitor rotor is already removed to end.
At the other end of the range, the opposite picture will be observed: the rotor has not yet been fully inserted and the arrow points to a frequency of 200 kHz, but the circuit is already tuned to the lowest frequency we need - 150 kHz. If we continue to increase the capacity of the circuit by introducing a capacitor rotor, we will tune the circuit to even lower frequencies 140, 130... 100 kHz, where radio broadcasting stations, as already noted, do not work.
Is it possible to get rid of all these shortcomings? It is possible, and relatively simple.
Let's move the needle again to the "200 kHz" division and thus tune in to a station operating on a frequency of 150 kHz. Now let's try, gradually unscrewing the core from the loop coil, to reduce its inductance. You, of course, have not forgotten that the resonant frequency of a circuit depends equally on its inductance and capacitance. If we reduce the inductance and want to maintain tuning to the station, then we will have to increase the circuit capacitance, that is, introduce a tuning capacitor rotor. In this case, naturally, the needle will move towards longer waves, closer and closer to the frequency of 150 kHz, at which our station operates. It is necessary to reduce the inductance of the circuit until the precise adjustment to the station corresponds to the desired position of the arrow on the scale.
When setting the boundaries we need for the resonant frequency of the circuit, we can also use a tuning capacitor, since the total capacitance of the circuit is equal to the sum of the capacitances of the tuning and trimming capacitors. Indeed, if we reduce the capacitance of the tuning capacitor, then, in order to keep the resonant frequency unchanged, we will have to increase the capacitance of the tuning capacitor, that is, introduce its rotor. This means that the needle will move along the scale in the desired direction - towards longer waves.
When adjusting the input circuit of the detector receiver, you should remember the general rule for tuning all circuits: with the rotor removed, the resonant frequency of the circuit is adjusted using a tuning capacitor, and with the rotor inserted, by changing the inductance of the coil (Fig. 57, 58, sheet 99).
It is more convenient to start with the long-wavelength section of the range (the rotor is inserted, the inductance is selected), after which you should move on to adjusting the frequency in the short-wavelength section (the rotor is removed, the capacitance of the tuning capacitor is selected), then it is advisable to return back to the long-wavelength section and finally adjust the shortwave again plot.
Of course, it is almost never possible to carry out this entire program in a detector receiver due to the very limited number of received stations. Therefore, in such a receiver it is advisable to only approximately select the inductance of the coils. We will make more precise adjustments to the circuits in tube receivers, where the coils we make will be used without changes. It should be remembered that when tuning the receiver, the antenna can no longer be connected directly to the circuit, since the antenna’s own capacitance can greatly upset it.
Every radio receiver has settings for a certain frequency, most of them even have fixed settings, which is very convenient. If the receiver is digital, that is, it has electronic tuning, then fixing a particular radio station on a specific channel will not be difficult. This process will be a little more difficult to occur on receivers with a regular tuning scale. But, in any case, the user manual describes in detail how to set up the radio and how many stations you can store in its memory. However, all this can be done only after purchasing this very radio. Many people are faced with the problem of choice these days, because there are so many different models in stores.
For those who want to listen to all radio stations, an all-wave receiver is the best option. And if it has the ability to receive VHF waves, then it will be simply happiness, because such receivers can also pick up radio conversations. Therefore, it is worth thinking about how to choose a radio receiver, for what purposes will it be used and what should it be like? If this is a “cabinet” receiver, then the standard FM and AM bands will be quite enough for it. For “portable” and “hiking” receivers, it is better to be able to “listen” to all frequencies, since hiking can also be in unfamiliar areas, where the radio can broadcast on any frequencies. With “portable” ones, you can just play around and eavesdrop on other people’s conversations if they use walkie-talkies.
If you can’t buy such a receiver, then you should think about how to assemble a radio receiver so that it can “hear” in the required range. To do this, you need to be a radio amateur, or have one of them as very close friends. You can, of course, scour the Internet and look for step-by-step instructions for assembling the radio. But there are also pitfalls, because not all the necessary parts can be bought; some you have to make yourself. Therefore, if you have a friend who is a radio amateur, then you can ask him how the radio works, what parts you can buy, and which parts you need to make yourself and how, and most importantly, from what? After the answers to the questions have been received, you can begin to search for the necessary parts, both for the receiver and parts for the parts for your radio.
You will have to do a lot of shopping, look in the pantry for old equipment and rummage through it in search of the necessary parts. After this, you will have to spend a lot of time with a soldering iron in your hands and use up several grams of tin and wires. And now, when all the parts are ready, you will need to turn to a friend with the question of how to make a radio receiver so that it works reliably and for a long time. It doesn’t matter much what the radio receiver will be like. Both homemade and purchased receivers receive radio waves. If he brings pleasure to his owner, then he will fulfill his purpose.
Adjustments in radio receivers .
In radio receiving devices, with the help of adjustments, the required operating modes of individual circuit elements are established and maintained, providing both the best conditions for receiving the useful signal and converting it into information.
All types of adjustments can be divided into two main groups:
Adjustments that change the seme parameters, forming the frequency and phase characteristics of the receiver;
Adjustments that provide the required operating modes of the receiver elements.
The first group includes tuning to a given frequency or tuning to an operating frequency within certain limits. Adjusting the selective properties of the receiver and its bandwidth, setting certain phase relationships.
The second group includes setting the specified electrical modes of active devices (transistors and lamps), setting the modes of individual components, adjusting the gain of the receiving path, and matching individual circuit elements. Depending on the intended purpose, the listed adjustments are divided into production, technological and operational. The first are carried out during the production process or during the repair process. These include adjusting the circuits with trimming capacitors or coil cores, adjusting filters, setting the required voltages on the electrodes, matching feeder lines, etc.
Operational adjustments can be either manual or automatic.
The main ones are:
Adjusting the receiver tuning frequency;
Selectivity adjustment;
Gain adjustment.
Frequency adjustment.
Frequency adjustment includes pre-tuning to the nominal frequency of the received signal and adjustment during operation.
The receiver can be tuned both by the reference generator and by the received useful signal. The number of tunable elements is determined by the receiver circuit and frequency range. Tuning to a given frequency can be either smooth within the operating range of the receiver, or fixed, ensuring the installation of a finite number of frequencies.
Tuning can be carried out either manually or using an electromechanical drive, with fixation of pre-set operating frequencies. In superheterodyne receivers of the centimeter and millimeter ranges, the preselector is in most cases wideband and the receiver is tuned by setting the local oscillator frequency. In a klystron local oscillator, this can be done by mechanically adjusting the resonator, or by changing the voltage on the reflector.
When using quartz local oscillator frequency stabilization in receivers, tuning is carried out either by changing quartz crystals or by using several quartz oscillators that provide a grid of stable frequencies in a given range.
In superheterodyne receivers with a tunable preselector, the tuning of the UHF and local oscillator circuits is coupled. Changing frequencies during tuning should ensure a constant intermediate frequency.
In most cases, circuit adjustment is carried out using variable capacitors, structurally combined into one unit. Depending on the type of receiver and its purpose, the capacitors can be air or film dielectric, discrete capacitors or varicaps.
Variable capacitors have a sufficient coefficient of coverage of the range of capacitances, high quality factor and linearity of capacitance change. The disadvantages are the rather large dimensions of the tuning unit, the complexity of the design with a large number of simultaneously tunable circuits, and the long tuning time.
When using a block of variable-capacitance capacitors, the parameters of the individual elements of the block are approximately the same; the overlap coefficients of the capacitance and, consequently, the frequency range will be approximately the same. However, these capacitors do not provide a constant frequency difference in the converters of superheterodyne receivers.
At intermediate frequency f etc=f G-f With the range overlap coefficients must be different.
With the same overlap coefficient, the difference between the tuning frequencies of the UHF and local oscillator circuits will be in range, since the UHF circuits will be detuned relative to the signal frequency. This will lead to a decrease in gain, which decreases the more the wider the amplifier bandwidth.
To eliminate this drawback, the circuit settings are paired. One of the pairing options is to introduce additional capacitors into the local oscillator circuit.
Inductance L G L is selected such that in the middle of the range both circuits have a difference in setting equal to f etc. Capacitors are selected as follows: C V» C min, and C A« C Max. In this case, at low frequencies of the operating range, when C = C Max capacitor capacity C A does not matter, but the capacitance of the capacitor C V reducing the resulting capacitance of the oscillatory circuit increases its resonant frequency and, consequently, the local oscillator frequency, bringing the frequency difference closer to the value of the intermediate frequency.
A discrete capacitor is a store of constant-capacity capacitors with series-parallel connection of groups. The use of these capacitors reduces the tuning time, which is primarily determined by the speed of the control circuit and the switch itself. Displaced options are possible when discrete capacitors and discrete inductors are used simultaneously to rearrange oscillatory systems.
The main disadvantage of tuning using discrete capacitors is the limited number of settings and the complexity of the switching circuits.
In relatively low-power cascades, a varicap is used as a frequency-tuning element, which is practically inertia-free in changing capacitance and requires a low-power source of control voltage. The use of varicaps allows you to automate the setup process.
A significant disadvantage of a varicap is the significant nonlinearity of its characteristics, which improves the selective properties of the receiver. One option to reduce the influence of the nonlinearity of the characteristic is to increase the bias voltage applied to the diode. It is possible to include an additional linear capacitor in the capacitive part of the circuit, but this reduces the frequency range coverage coefficient.
The best result of compensating for the nonlinearity of the characteristic is obtained by the cross-current sequential inclusion of varicaps.
In this case, thanks to compensation of even current harmonics, the influence of nonlinearity of characteristics is reduced. In this case, it is necessary to ensure the symmetry of the shoulders by selecting varicaps according to the parameters.
Tuning by changing inductance is carried out using variometers or discrete inductors. In the first case, mechanical movement of the coil core inside its frame or closing of part of the turns using a current collector is used. In this case, the overlap coefficient is about 4÷5. However, it must be taken into account that simultaneously with a change in the inductance of the coil, its quality factor also changes, and the tuning mechanism itself is quite complex and cumbersome, which limits the number of simultaneously tunable circuits. The use of a discrete inductor allows for electronic tuning, which is similar to tuning with a discrete capacitor, but is even more cumbersome.
In professional microwave receivers, a non-tunable input and switched filters are used. With a non-tunable wideband preselector, the antenna, UHF and frequency converter are matched using wideband transformers, and tuning is achieved using local oscillator tuning.
In practice, the filter method of tuning a receiver is widely used, in which the entire range of operating frequencies is covered by a number of non-tunable filters, the bandwidth of which is selected with a margin for mutual overlap. The number of filters is determined by the selectivity requirement of the receiver and is limited by the complexity of the control circuit.
Thus, to receive signals in the frequency range, it is necessary to perform a number of operations, including switching the corresponding circuits, switching antennas, etc.
An important step in the operation of any receiving device is precise tuning to the operating frequency, which includes setting the required local oscillator frequencies (there may be several of them in professional receivers) and tuning the resonant preselector circuits to the signal frequency. When working using frequency synthesizers in the local oscillator, it is possible to tune relatively easily within a short period of time. However, it is more difficult to quickly adjust the preselector by switching on the desired sub-range and adjusting the resonant circuits. In this case, various switching circuits are used, the elements of which are required to have a high contact resistance for the switched current in the open state and a minimum in the closed state. They must also have a small throughput capacitance between the contacts at the operating frequency. In selective circuits, switching is carried out by mechanical or electrical elements.
Reed switches are sealed and magnetically controlled contacts made of a soft magnetic alloy. The capsule is filled with inert gas or evacuated. When the capsule is introduced into a magnetic field, the petals close, and when the field strength weakens, they open due to their own elasticity. The magnetic field is created by a special control coil.
Electronically controlled switching diodes have high resistance at reverse bias voltage and low differential resistance at forward bias current.
Adjusting the receiver bandwidth.
The selective properties of the receiver are usually ensured during its design, but in some cases such a need arises during operation. So, in receivers of connected radio links, this makes it possible to weaken the influence of interfering stations neighboring in frequency.
Adjustment can be carried out discretely or smoothly and, as a rule, manually. The adjustable elements can be selective systems of the linear part of the receiving path, mainly in the amplifier, as well as in low-frequency cascades.
To smoothly adjust the passband in the amplifier path, adjustable filters are used, which are a system of two tunable circuits connected to each other using a quartz resonator and are the load of one of the amplifier stages. Thus, when changing the detuning of the circuits, you can adjust the passband, since when they are tuned to an intermediate frequency, the passband is maximum, and when detuned, it narrows. The limits of bandwidth adjustment are determined by the allowable gain losses.
In receivers that have concentrated selection filters in the IF path, selectivity is adjusted by switching filter elements while maintaining the rectangularity of the resonant characteristic within certain limits.
In the post-detector part of the receiver, the bandwidth is adjusted by changing the frequency response in the region of high and low frequencies (timbre control). Passive tone controls are included in the amplifier's input circuit. A regulator that reduces the gain in the high-frequency region is connected in parallel to the input circuit of the amplifier and is represented in the following form.
The values of R p and C are chosen much larger than the similar input parameters of the amplifier. At R p =0, the decrease in frequency response is practically determined by the time constant τ = c R y. If R p ≠0 the decline will only be up to frequency f 1 , after which the resistance Χ c =1/ωc becomes significantly less than R p and does not affect the resulting resistance of the circuit with R p. The frequency response does not change until the frequency, after which it decreases due to the capacitance Cy. A passive tone control that increases the gain in the low-frequency region has the following form and works similarly to the R f C f circuit.
Gain adjustments in the RPU.
For a given amplification stage circuit, K 0 =p 1 p 2 SR e, where p 1 and p 2 are the corresponding switching coefficients, S is the slope of the collector characteristic of the transistor, R e is the equivalent load resistance, taking into account the shunting of the circuit by the transistor and the load. The gain can be adjusted by changing any value included in this expression. When choosing control methods, it is necessary to obtain a significant change in K 0 from the control voltage, a small control current, and a small dependence of other amplifier parameters when the gain changes.
Adjusting the gain by changing the slope of the characteristic.
This adjustment is carried out by changing the operating mode of the active element, so it can be considered modal. In this case, it is necessary to change the bias voltage on the control electrode, which will lead to a change in the slope at the operating point (in a bipolar transistor, in addition to S, q input and q output change). The regulating voltage can be supplied to both the base circuit and the emitter circuit.
In this circuit, the bias voltage at the E-B junction will be U eb =U 0 -E ρ. As E ρ U increases, the eb decreases, which will lead to a decrease in the collector current I k0 and S k, and as a consequence, a decrease in K 0. The gain control circuit must provide a current in this circuit approximately equal to I 0e, which means that I ρ must be relatively large. It is preferable to supply E ρ to the base circuit when U eb =U 0 -E ρ. The adjustment current I ρ =I g is I g ≈(5÷10)I 0b and is small.
This circuit provides less stability due to the absence of a resistor in the emitter circuit, because its presence will lead to a decrease in the adjustment effect. Otherwise, it is necessary to increase E ρ.
Adjustment by changing R e can be carried out in various ways.
By including a diode in the circuit.
When E ρ >U k the diode is closed and does not bypass the circuit. R e and K 0 are large.
At E ρ
Adjustment by changing switching factors.
The voltage from the circuit is supplied to the divider Z 1 Z 2. By changing one of the resistances you can change p 1. The adjustment circuit for p 2 is similar. Coils with variable inductance or capacitors with variable capacitance can be used as resistances. However, this cannot avoid contour detuning. The best results are obtained by using an attenuator with a variable gain connected between the stages. Adjustable dividers, capacitive dividers on varicaps, and bridge circuits are used as an attenuator.
When |E ρ |<|U 0 | диоды Д 1 и Д 2 открыты, а Д 3 закрыт. Коэффициент передачи максимален. По мере увеличения E ρ динамическое сопротивление диодов Д 1 и Д 2 увеличивается, а Д 3 – уменьшается, reducing the attenuator gain.
It is possible to use a field-effect transistor as a controlled resistance when the resistance of its channel changes under the influence of E ρ.
Attenuators based on pin diodes, which have a large range of resistance changes and low capacitance, are widely used.
The operation of pin diodes is controlled by changing the bias in the transistor base circuit. At zero voltage, adjustments D 1 and D 2 are closed, and D 3 is open (attenuation is minimal). When E ρ is maximum, D 1 and D 2 are open, D 3 is closed (attenuation is maximum).
Adjustment K 0 using an adjustable OOS circuit.
The OOS is introduced into the emitter circuit of the transistor. The depth of feedback is adjusted by changing the capacitance of the varicap. As Ereg increases, the diode closes more strongly, while its capacitance decreases, and the feedback voltage increases, thereby decreasing K0.
In the post-detector part of the receiver, the methods for adjusting K 0 are similar to resonant amplifiers. Smooth potentiometric gain control is more often used, and in broadband amplifiers it is usually used in low-resistance circuits. In wideband stages, gain control is often used using adjustable feedback.
An adjustable voltage divider is used to change the constant voltage at the base.
Gain adjustment is carried out by changing the alternating current resistance in the emitter circuit, as a result of which the depth of feedback and the cascade gain change.
The voltage is supplied to the other stage through a controlled divider. Z 2 includes the input impedance of the subsequent stage.
Automatic gain control (AGC).
AGC is designed to maintain the output signal level of the receiving device or amplifier near a certain nominal value when the input signal level changes. The use of AGC is necessary because the input signal level can change quite quickly and chaotically, which cannot be responded to using manual adjustment.
There are many reasons for changes in the input signal level:
Changing the distance between the radiation source and the receiver;
Changes in radio wave propagation conditions;
Changing the receiver from one station to another;
Changing the mutual direction of the receiving and transmitting antennas; etc.
In radar receivers, to the listed reasons one can add fluctuations in the effective reflective surface of the target, changes in targets with different effective surfaces, and random changes in the polarization of received waves.
Ideally, the receiver output voltage should remain constant after reaching a certain output voltage value that ensures normal operation of the terminal device. In this case, the gain must change according to the law
K=U out min /U in at U in ≥ U in min
AGC circuits are built according to two principles: “backward” adjustment and “forward” adjustment. Otherwise, they are also called reverse and direct. Inverse AGC systems (systems with feedback) in them, the point at which the voltage that forms the regulating action is picked up is located further from the receiver input than the point at which the regulating action is applied.
In direct AGC systems, the point at which the AGC trigger voltage is picked up is located closer to the receiver input than the point at which the control voltage is applied.
Reverse AGC systems cannot ensure complete constancy of U out, since it is an input to the AGC system and must contain information for a corresponding change in the regulatory action. In addition, this system cannot simultaneously provide a large depth of adjustment at U out ≈const and high performance for reasons of stability. At the same time, this system protects from overload all cascades located further from the input than the point of application of the control action.
Direct AGC systems can, in principle, provide ideal control when U out ≈const with U in ≥ U in min and arbitrarily high speed. In reality, this is not feasible, since the degree of constancy of the output voltage is determined by the specific data of the elements of the AGC circuit and receiver circuits, subject to technological variations in parameters, time and mode changes. When using this AGC system, cascades located further than the point of application of the regulatory influence are protected from overloads.
The AGC system itself is exposed to a signal with a wide dynamic range, is subject to overload and must contain its own feedback. This system itself turns into a separate receiver channel with a rather complex circuit.
In practice, inverse AGC systems are more widely used, and it is possible to use combined AGC systems.
The block diagram of reverse AGC can be presented as follows
The control voltage is supplied to the amplifier from the output side. The AGC detector ensures that E ρ is proportional to the output voltage, i.e. E ρ =K d U out. The AGC filter filters out the components of the modulation frequencies. This scheme is called a simple AGC. Before or after the detector, an amplifier can be turned on in the AGC circuits, and then the AGC is considered amplified.
The block diagram of a direct simple AGC includes the same elements.
The functional diagram of the combined AGC includes the following elements.
The reverse AGC system is formed by the detector D ARU1, filter F 1 and all cascades of the main path located between the input point of the control voltage U ρ1 and the output of the high frequency unit (HFB).
The direct AGC circuit includes a detector D ARU2, a filter F 2 and a constant voltage amplifier U ARU2. The regulating voltage U ρ2 is introduced into the UHF and ULF, which may or may not be present. Filters Ф 1 and Ф 2 give the AGC circuits the necessary inertia, due to both the stability of AGC 1 and the lack of demodulation of amplitude-modulated signals in AGC 1 and AGC 2.
There is no need to reduce the gain of weak signals (Uin< U вх мин), не обеспечивающих номинального выходного напряжения при максимальном усилении всех каскадов. Для придания цепям АРУ пороговых свойств они запираются принудительным смещением и отпираются тогда, когда напряжение входного сигнала превысит напряжение запирания. Как правило напряжения запирания (задержки) подаются на детекторы или усилители (На схеме E 31 и E 32).
The delay can be entered based on the average value of the signal or the maximum. AGC circuit 1 does not have a special amplifier and is not an amplified system. AGC 2 system is strengthened, it has a greater depth of regulation and is capable of providing a smaller dynamic range of the output signal.
With a weak signal at the receiver input and maximum gain at its output, noise created by external interference and the receiver's own noise is heard. To eliminate this defect, silent AGC systems are used.
