SU77502A3 - Receiver phase-modulated oscillations - Google Patents

Description

The subject of the invention is a device for demodulating phase-modulated oscillations.

If a lamp generator is associated with some other source of oscillations of a certain frequency, very closely to the frequency of the lamp generator, then, as is well known, it is easy to create conditions under which the frequency of the lamp generator will be synchronized with the frequency of the said external oscillation source. In this case, if the natural frequency of the generator and the frequency of the nonstop source are somewhat different from each other, then the anode current of the generator lamp will vary more or less in accordance with the change in the frequency difference.

Such detectors, designed to convert frequency modulated oscillations, can also be used to detect phase modulated oscillations. This is possible because the phase modulated oscillations are essentially equivalent to frequency modulated oscillations, in which the change in frequency is reversible ironore to the frequency of the modulating oscillations.

The present invention provides a new and advanced receiver for receiving phase modulated oscillations.

According to the invention, a push-pull demodulator consisting of two push-pull, generating detectors, in the anode circuit of which a circuit is tuned to a carrier frequency with a very small loss factor, for example, with quartz, is applied in the proposed phase-modulated oscillation receiver. Carrier frequency oscillations modulated in phase are applied to the grids of a push-pull demodulator. If the relative phase shift between the colo№ 77502-2 -

the banks generated by the demodulator, and: the oscillations received by the receiver and change to vary, then on the grid of one lamia two iodable voltages will converge in phase, and the grid of the other will diverge, i.e. the voltage on the yllpalzlJ and x grids will change according to the change in the phase of received oscillations In accordance with the change in voltage on the control grids, the anode current will also change, but not only in phase, but in amnlitude.

Voltage, Breznkayush, its output of a push-pull demodulator is used to hold both oscillations to the spichroism.

The scheme of the proposed phase demodulator is shown in the drawing. Here is the 1-output amplifier circuit at the intermediate frequency; Z and 3-seater local oscillators; 4-niezokhartsvtsy contour with a low damping factor, 5-output transformer low frequency, 6-ii-Bnnomogatelnye circuit elements.

As can be seen from the proposed scheme, the control grids of the electron tubes 2 n 3 are connected but a two-stroke circuit by means of a reactive sonar inductance 6 and the ground circuits 7 and 8. The anodes of the lamps are connected to a high-frequency piezo-quartz circuit 4, which is characterized by a low loss factor. In addition, the anodes of the lamps are connected to a low-frequency circuit consisting of a transformer 5, the nervous windings 11 and 12 of which are connected between the anodes of lamps 2 and 3 (through blocking capacitors 9 and 10) and their cathodes. Prn excited pamp 2 and 3 oscillatory voltage appearing on inductance 6, excites control grids of lamps with a certain phase shift. The direction of current can be indicated by arrows, depicted with the nature of the inductance 6. For the implementation of regeneration, oscillations can be fed into the grid circuit either due to the presence of intra-electrode coupling, or due to the presence of a feedback loop.

The frequency of the oscillations generated by lamps 2 and 3 is determined by the magnitude of the reactive sonar inductance of 6 n circuits with a low coefficient of noti.

Oscillations modulated in phase from any external source can be fed to tuned circuit 1. From this loop, oscillations in the same phase are fed to control grids of lamps 2 and 3. Ratio between the oscillation phases, nrnl Enpykh to control grids from circuit 1 and the oscillations generated by the lamps 2 and 3 applied to the same grids may vary widely. It is preliminarily, however, between the incoming and the generated oscillations to have a phase shift of a quarter neron.

If loop 1 is stranded from the first detector (or the amplifier is a woofer frequency amplifier), then it must be tuned to an intermediate frequency. This circuit can also be connected to a high frequency amplifier. In the other case, it must be borne in mind that the frequency of the generated oscillations can be equal to the frequency of the received oscillations that are modulated in phase. This is necessary in order to appropriately combine the phase shift between those and other oscillations on the equalizing grids.

The contour 4 with a small loss coefficient consists of a Qiazar that is connected between the anodes of the lamps.

The principle of operation of the proposed phase modulated oscillator receiver is as follows.

Lamps 2 II 3 form a push-pull oscillator cascade stabilized by quartz, which is switched on on the anode day and equals the tuned anode circuit, if the distributed inductance and capacitance of the connections, lamps, etc. are taken into account. control grids of the lamps, according to the shown two-cycle scheme in normal conditions, it is not preferable to have on the control grids an average phase shift between received and generated oscillations of about 90. At the same time, of course, generate s kolebapp must be in synchronism with nrinimaemymi wobbles, disregarding uiomnnavshnys above phase shift.

In order to achieve synchronism, the first heterodyne of the receiver is first regulated until the frequency in circuit 1 corresponds to the frequency of the oscillations created by the 2N 3 detectors. Under these conditions, the voltages 7 and 8 of the grid component of the grid current. Further, if the relative phase shift between the oscillations generated and applied begins to change, then on the same grid the two voltages applied will converge on the phase, while on the other grid, on the contrary, will diverge more and more on the phase. Thus, the nanometers that are applied to the control lamps will vary according to the change in the phase of the applied oscillations around a certain average value. With a change in the phase of the incoming signal, the average grid offset will change due to the presence of grids 7 and 8, and at the same time as the grid of one lamp increases, the shift decreases on the grid of the other lamp. As a result, this leads to an imbalance of anode currents. If the relative phase shift changes rapidly, then the anode current will change just as quickly, which will result in a current in the secondary winding of the transformer 5.

Thus, the modulation of the phase, the applied oscillations applied to the circuit 1, will cause a corresponding change in the current linearly in the secondary winding of the transformer 5.

The corresponding bias voltage to the lamp grids is supplied from source 13 blocked by a capacitor. Grids 7 and 8 can practically be lowered n, giving the appropriate bias, use the non-linear part of the lamp characteristic to get unbalanced anode currents, if there is a positive phase shift between the received and generated oscillations.

A constant anode voltage can be supplied by any method, but it is nevertheless important to include resistance 14 in the nutritional value.

If the relative phase shift between incoming and generated oscillations has a tendency to replace within the time interval more closely than the modulated oscillation phase, then in this case, stable unbalanced currents will be generated at the anodic value. These currents will create at the ends of the coercive 14 the difference of the potentials, which can be used to adjust the phase or frequency of the local heterodyne connected to the nerve detector of the receiver.

Subject invention

1. Acceptance of phase-modulated oscillations, in which a single-cycle received oscillations of a pnrotnatattno carrier vibration, shifted in phase by 90, with a low frequency removed odinotaktno, differs from that the two-stroke demodulator is completed, to the dehumulator of the demodulator; on # 77502

built on the carrier frequency, and constant at the output of the push-pull demodulator, is used to hold down the oscillations exactly in synchronism.

2. The receiver of claim 1, characterized in that the stationary voltage arising at the output of the push-pull modulator is used in the case of the use of a heterodyne receiver for controlling the frequency of the second phase of the local oscillator.

3. Receiver of claim 1, characterized in that between the anodes of the two lamps of the push-pull demodulator, a tuning oscillator circuit with a small own attenuation is included.

4. Receiver but also. 1, characterized in that between the anodes of the two demodulator lamps there is a quartz crystal tuned to the carrier frequency of the incoming oscillation.

5. The receiver of claim 1, characterized in that in order to obtain a rectifying action in the control grids of both lamps, the leakage resistance applied by the capacitors and the bias voltage of both lamps are selected so that the lamps work as detectors .

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