SU60963A1 - Radio - Google Patents

Description

In the proposed radio receiver, for separate reception of each of the two radiotelephone transmissions conducted on the same wave with a phase shift at 90 ° over the carrier frequency, an l-linear resonant circuit consisting of a constant inductance, ohmic resistance and periodically varying with a certain frequency is used. capacity.

In the radio receiver, as the periodically varying capacitance of such a circuit with parametric regeneration, the input reactive conductivity of the multigrid electron tube is used, whose slope or anode load periodically changes.

Periodic change of the slope of the characteristic is carried out by applying to one of the grids of a multigrid lamp, for example, a heterodyne grid of a mixing lamp, a voltage twice as high as that of the control grid. A change in the resistance of the anode load can be achieved by changing the internal resistance of the auxiliary triode, on the control grid of which the voltage of double frequency is applied.

A phase-selective loop made in one of these methods is introduced into the intermediate-frequency amplification path as the anode circuit of one of the stages. Periodic change in the parameters of the circuit should occur perfectly in sync with the voltage of the signal applied to it. The synchronization is carried out by capturing the voltage of the local oscillator signal with a voltage followed by a doubling of the frequency of the current, which is then used to change the parameters of the phase-selective circuit. In our case, for a voltage generated by a signal and containing two transmissions, the amplitude and phase change according to laws depending on the modulation functions of both channels.

If this complex oscillation captures oscillations of the local heterodyne, its voltage will also be modulated n in amplitude and phase. As a result, the amplitude and phase of the variation of the parameters of the phase-selective circuit will also be modulated by the legal modulation of both channels and complete mixing of the two transmissions will occur.

No. 60963-2 -

In the proposed device, the decay used to change the parameters of the phase-selective circuit is obtained using a quartz filter and the subsequent doubling of the carrier frequency of the signal apr. The contours of the square filter itself are used as the discriminator circuits. The proposed phase-selective superheterodyne receiver circuit shows an amplifier / high frequency, frequency converter 2, intermediate frequency amplifier 3, heterodyne converter 4. In the anode circuit of lamp 5, also an intermediate frequency amplifier, an inductively coupled phase-selective circuit consisting from the inductance 5. and the input equivalent capacitance of the hexode 7, in the anode circuit of which there is an active load 8. The input capacitance of the hexode is periodically changed by leading to its hetero Ina grid voltage twice the intermediate frequency.

From the phase-selective circuit, through the capacitor 9, the intermediate frequency voltage is supplied to the grid of the lamp 10, which is a conventional intermediate frequency amplifier with a band-pass filter 11 ′ of the anode circuit. Diode 12 is a conventional linear detector. The voltage of the low frequency from the diode 12 is supplied to the low frequency amplifier 13.

The intermediate frequency voltage modulated by the transmissions of both channels through the synchronization channel amplifier 14 is supplied to the grid of the lamp 15. The anode circuit of the lamp 15 is connected to the circuit 16, which consists of two identical inductances of the coils and a constant capacitor and tuned to the intermediate frequency. Circuit 16 is inductively coupled to circuit 17, consisting of two inductors and quartz, whose parallel capacitance is neutralized with a coil 18 and a capacitor 19. A quartz filter formed by circuits 16 and 17 passes the carrier frequency and delays the sidebands. The filtered carrier frequency is doubled by a doubler consisting of a lamp 20, in the anode circuit of which a circuit 21 is connected, tuned to the second harmonic.

Through the phase shifter, consisting of inductance 22, capacitor 23 and resistance 24, the doubled voltage is applied to the grid of the lamp 25, which is an automatic voltage regulator that varies the parameters of the phase-selective circuit. The reactance of inductance 22 is twice as large as the reactance of capacitor 23. Therefore, a change in resistance 24 ranging from zero to infinity changes the phase from zero to jt.

The communications wrench 26 applies a varying voltage to the heterodyne grid of the phase-selective circuit lamp. To switch from receiving one channel to the second channel, it is necessary to change the phase of variation of the parameters by 90 ° according to the frequency of the applied signal voltage or 180 ° at the double frequency. This is accomplished by switching the ends of the coil 26 with a bipolar switch 27.

The circuits of the quartz filter 16 and 17, together with the dual diode 28, form the discriminator of the frequency auto-tuning. The high-frequency voltage at each of the anodes of the differential detector is equal to the geometric sum of the voltages at the output of the quartz filter and at one of the coils of circuit 16. If the intermediate frequency exactly equals the resonant frequency of the quartz filter, the voltage at its output is shifted in phase by 90 on each of the coils of the circuit 16. The amplitudes of the voltages on both anodes are the same

and the constant voltage across the discriminator load is zero. When the intermediate frequency changes, the voltage phase at the output of the quartz filter changes dramatically; A rectified voltage appears through the filter 29 to the lamp controlling the local oscillator frequency.

The boundaries of instability regions of an ideal contour with periodically varying parameters without attenuation, near which the real contour with low attenuation has rather pronounced phase-selective properties, are very close to the regions of parametric excitation. This means that with very small changes in the mode (amplitude of the varying voltage or power), the phase-selective circuit can switch to parametric excitation mode. Since these changes in operation take place in real conditions, to eliminate the possibility of parametric excitation, a phase selective circuit stabilizer 5 / consisting of a double diode, throttles D, and resistors 32 and 33 is included in the circuit through capacitor 30.

Around the areas of parametric excitation there are small areas in which the contour is not yet excited, but its attenuation is already partially compensated by the parametric action and the contour gain increases. The boundaries of the regions of partial compensation of attenuation approximately coincide with the granites of the instability regions of the ideal contour. An increase in the gain when the circuit is shifted towards the parametric excitation region can be detected by comparing the voltages at the input and output of the phase-selective cascade.

An intermediate frequency voltage is applied to the left anode of the differential detector from the output of the quartz filter, which is proportional to the voltage at the input of the phase-selective cascade. A voltage is applied to the right anode from the // circuit, proportional to the voltage at the output of the phase-selective cascade.

The voltage difference across the load on the left diode and on the load portion of the right diode is applied to one of the grids of the lamp 25, which regulates the amplitude of the varying voltage, as an additional negative bias. When the mode is changed in the direction of the parametric excitation region, the gain of the phase-selective voltage on the load of the right diode increases. On the grid of the lamp 25, an additional negative bias appears, which reduces the amplitude of the varying voltage.

The voltage applied to the left diode eliminates the effect of interference on the stabilization system.

The diode detector 34 serves to destroy the residual amplitude modulation of the varying voltage, which occurs because the quartz filter cannot ideally filter out the carrier frequency from the side frequencies, especially at low modulating frequencies. The residual amplitude modulation causes a change in the parameters of the circuit with a frequency of residual modulation, changing the gain of the phase-selective cascade. This entails a strong non-linear distortion and mutual interference from the "orthogonal channel." The diode detector 34, by obtaining the voltage from the anode circuit 2} of the frequency doubler 35 through the capacitor 36, creates a low frequency voltage corresponding to the residual amplitude modulation, which is fed in reverse phase to the grid of the regulating lamp 25 through the capacitor.

No. 60963 4 -

The supply to the grid of the regulating lamp 25 is a part of the constant component voltage on the resistance 37 through the resistance 38, it is possible to obtain an additional stabilization of the amplitude of the varying voltage.

In addition to the phase selectivity properties described above, a circuit with periodically varying parameters has the ability to transform periodic disturbances disturbed with respect to the received signal so that, after detection with a linear detector, not interference modulation frequencies are obtained, but only frequencies equal to the frequency differences of individual interference components and carrier frequency of the received signal. Therefore, if the frequencies of the modulated periodic disturbance fall directly into the receiver's bandwidth, such interference can be eliminated by inserting a low-pass filter into the low-frequency part of the receiver, which delays all frequencies beyond the frequency band that should. playable by receiver. Thus, a contour with periodically varying parameters makes it possible to significantly improve the frequency-selective properties of the receiver.

In the proposed device, the nonlinearity of the characteristics of a phase-selective circuit lamp cannot cause interference from the orthogonal channel, since the voltage generated on the grid of this lamp only transmits one received channel, i.e., the phase selection process does not occur in the lamp, but in the circuit itself. Therefore, a sufficiently large signal voltage can be applied to the phase-selective contour.

Subject invention

Claims (3)

1. A superheterodyne-type radio receiver for separate reception of each of the two radiotelephone transmissions conducted on the same wave with a phase shift at a carrier frequency of 90 °, using as a phase-selective element — a circuit with parametric regeneration and a limiting filter in the low-frequency part to improve the frequency selective properties, characterized in that as a periodically varying parameter of the circuit with parametric regeneration used reactive input conductivity multigrid electr lamp constant, the steepness of characteristics or resistance of the anode which periodically vary the load applying control voltage to one of the meshes -etoy headlight or auxiliary headlight mesh. 2. The form of the radio receiver under item 1, characterized by the use of automatic stabilization of the control voltage, eliminating the possibility of parametric excitation circuit with parametric regeneration. 3. The radio receiver of claim 1, characterized by using for parametric regeneration the voltage of the double carrier frequency of the received signal extracted before doubling using a quartz filter used simultaneously as a discriminator to automatically adjust the local oscillator frequency.