DE673986C - Receiver for amplitude and phase modulated vibrations - Google Patents

Description

Receiver for amplitude- and phase-modulated oscillations The invention relates to a receiver that is both amplitude modulated and phase modulated Can absorb and demodulate vibrations. Different types of modulation can be used on the one hand already exist at the various broadcasters. But also originally purely amplitude-modulated oscillations take z. B. by processes in the spread in the atmosphere often at the receiver the character of a predominantly phase-modulated Vibration on. This manifests itself in the usual recipients responsible for the reception amplitude.modulated oscillations are suitable in strong distortions. - Naturally can also reverse an originally phase-modulated oscillation in their Modulation so that it temporarily has more of the character of an amplitude modulated Vibration.

Since the previously known receivers only receive one type of modulation are suitable, you get if for some reason, z. B. as a result of shrinkage, the type of modulation changes, with such a receiver a completely distorted reception.

According to the invention, the receiver is equipped with a switching device, by alternating with a frequency above the audibility limit to the reception of phase-modulated oscillations and to the reception of amplitude-modulated Vibrations is switched.

The advantage of the invention is that the recipient without any switchover to be made by the operator is necessary, both vibrations, which wholly or predominantly have the character of an amplitude-modulated oscillation; as also those vibrations which wholly or predominantly have the character of a phase modulated Own and receive vibration. Of course, all intermediate stages of the Modulation type are received, since one. Such a modulated oscillation is always can decompose into a part that represents a pure amplitude-modulated oscillation, and a second component, which represents a pure phase-modulated oscillation.

An embodiment of the invention is shown in Fig. I. To the antenna i a heterodyne receiver is connected to the intermediate frequency oscillation the two double lines 3 and 4. Part of the intermediate frequency voltage is via the double line q. the primary winding of a transformer io-fed. The secondary winding this transformer carries the generated in it Energy in phase to the control grids of the rectifier tubes i i and z2.

Another part of the intermediate frequency oscillation - is via the Double line 3 is fed to a unit 5, which has, for example, a quartz filter and an amplitude limiter or contains a device for automatic gain control. The ones in theirs Frequency and its amplitude-limited oscillation is controlled by a phase regulator 6 and fed from there to a phase modulator 7. The phase of oscillation in 7 is modulated by vibrations from the source 8 with a frequency that cannot be heard.

The output oscillation of the phase modulator 7 becomes the primary winding a transformer 9 is supplied, the secondary winding of which the oscillation is in phase opposition the control grids of the rectifier i i and 12 feeds. In this way, the Vibration fed in phase by the transformer io with that Combined energy that is supplied in phase opposition by the transformer 9. the Output electrodes of i i and 12 are connected to the primary winding of a transformer 13 connected, the secondary winding of which is connected to a pawl 14, to which the display device can be connected.

The phase modulator 7 with its duels 8 can also be through another Device replaced by the phase of energy in 7 with an overhearable Frequency can be shifted by about 9o °.

The embodiment according to fig. 2 contains two separate demodulators, of which the one only amplitude-modulated and the other only phase-modulated Can receive vibrations. The signals are again via the antenna i from the Recorded over storage receiver 2 and fed to the double lines 3 and 4. Part of the oscillation is transmitted via the double line 3 to the filter and amplitude limiter 5 is supplied, and the oscillation, which is limited in frequency and amplitude, is then applied fed from the output of 5 to a phase regulator 15, which consists of a chain, which as series elements are inductive reactances and as cross elements are capacitive Contains reactances and a terminating impedance. The vibrations are with the desired phase shifts taken by lines connected to the shiftable Taps of the coil 15 are connected, and then the control grids of the modulator tubes 16 and 17 supplied. These are designed as screen grid tubes, their screen grids connected to the secondary winding of a transformer 18, the primary winding of which is connected to a source 19 for the overhearing frequency modulation oscillation. S represents the DC voltage source for the screen grid. Anode and cathode of the Tube 16 are through the primary winding of a transformer T and a voltage source S1 connected, as well as the anode and cathode of the tube 17 by the primary winding of a Transformer T1 and the voltage source Si. The secondary winding of T connects the control grid of two rectifier tubes 2o and 2o 'in push-pull circuit, the Secondary winding of T1 the control grid of a second pair of rectifiers 21 and 2i 'also in push-pull. The unfiltered intermediate frequency is used by the heterodyne receiver fed through the double line 4 to the primary windings of the transformers 28 and 29. The secondary winding of 28 leads this energy in phase to the control grids of 2o and 2o 'closed, as well as the secondary winding of 29 in phase with the control grids of 21 and 21 ': The anodes of 2o and 2o' are through the primary winding of a transformer 22 and the anodes of 21 and 21 'through the primary winding of a transformer 23 switched in push-pull. The outputs of both pairs of rectifiers are connected by connection of the secondary windings of the transformers 22 and 23 are combined and then supplied via the pawl 14 of the display device.

In the embodiment according to Figure 3, the rectifier pairs of the circuit according to Figure 2 are replaced by multi-grid tubes. After conversion to intermediate frequency, the signal is fed to the primary winding of a transformer 30 via the double line 4, the secondary winding of which is connected to the control grids of the tubes 26 and 27 in such a way that the energy is fed to them in phase. A second part of the intermediate frequency is fed via the filter circuit and amplitude limiter 5 to a line 31 which is connected to the inputs of two phase regulators 24 and 25. The output voltages of these phase regulators are applied to the braking grids of the tubes 26 and 27 via transformers 34 and 33. A generator 36 for the overhearing-frequency modulation oscillation is connected via the transformer 35 to the screen grids of the tubes 26 and 27 and modulates the voltages on these screen grids in phase opposition with a frequency that can be overheard. The anodes of the tubes 26 and 27 are connected via resistors and capacitors to the control grids of the amplifier tubes 40 and 41, the anodes of which are connected in push-pull through the primary winding of a transformer 43. The secondary winding of this transformer is connected to the display device via a pawl 14. The phase regulators 24 and 25 can be of any type, e.g. B. in the manner of the chain conductor 15 in Fig. Z.

In the embodiment according to Fig.4, the oscillation of the intermediate frequency amplifier s via the double line 44 to a filter 35 for the upper sideband (and thereby at the same time part of the carrier) and via the double line 45 a filter 36 for the lower sideband (and thereby also part of the girder) fed. The control grids of the rectifiers 46 and 47 are connected to these filters. The resulting low-frequency oscillations are taken from the output of the rectifier 46 is fed to a coupling tube 51 via a transformer 49. The low frequency output voltage of the rectifier 47 is fed to the primary winding of a transformer 52, its secondary winding in push-pull circuit with the control grids of the coupling tubes 54 and 55 is connected. The screen grids of these tubes are out of phase with the Secondary winding of a transformer 57 connected, the primary winding of which with the Source 56 is connected for the overhearing frequency modulation oscillations. These Modulation oscillations are superimposed in phase opposition to the DC voltage, which the Screen grids of 54 and 55 is provided by source 58. These overlaid Modulation oscillations regulate the amplification of the tubes 54 and 55 in such a way that they alternate their source circles of vibration energy in the overhearing-frequency rhythm deliver. The anode of 51 and the anodes of 54 and 55 are in parallel with the primary winding of a transformer 59 connected, the secondary winding of which again with the pawl 14 is connected.

Operation of a receiver according to the invention shall first can be described with reference to Fig. i. The signal is filtered in 5 so that the Modulation sidebands are removed; after limiting the amplitude, the filtered carrier combined with the unfiltered signal, which the control electrodes of ii and 12 is supplied in the correct phase relationship. For receiving phase modulation the additional carrier must be 90 ° compared to the carrier of the unfiltered oscillation, the through the lines 4 of the primary winding of the transformer io and from there in phase the control grids of ii and 12 is fed to be shifted. These with a 90 ° phase shift The limited filtered and unfiltered signal energy are combined generates an amplitude modulation, which is the phase modulation of the unfiltered oscillation is equivalent to. To receive amplitude modulation, the control grid of i Additional carriers supplied to i and i2 are either in phase or by 180 ° with respect to the Carrier of the unfiltered oscillation; which the control grids of ii and 12 over which Line 4 reached, be moved. The receiver is accordingly both phase-modulated as well as being responsive to amplitude modulated waves when provided which is the phase of the filtered carrier that controls the rectifier grid reached, so shifts that this additional carrier in the one moment opposite the carrier of the unfiltered oscillation is shifted by 90 ° and in the next Moment is in phase with it or out of phase with it by 180 °. So that Phase of the additional carrier automatically between these two values of o (or i 8o) and 9o ° fluctuates, namely in the overhearing-frequency rhythm, is on the line between the carrier filter 5 and the demodulators i i and 12 on the one hand the phase shifter 6, which produces a fixed phase shift, and on the other hand the phase modulator 7 switched on, which is able to reach the wearer over a range of 9o ° in the Modulate phase. The modulation frequency is determined by the ultra tone generator 8, which is preferably voltages of rectangular waveform and such amplitude should produce; that in the modulator 7, the phase of the carrier shifted from + 45 to -45 ° as shown in Figure 5. At -f- 45 ° the receiver is then used for phase modulation and be set at -45 ° for amplitude modulation if the constant phase shift, which is generated by the phase shifter 6 is -j-45 °. The recipient will thus switched by the phase modulator so that it alternates phase modulation and receives amplitude modulation, at equal time intervals, the length of which is determined by the frequency of the vibrations generated by the generator 8. Since the switching frequency cannot be heard, the relevant modulation does not interfere.

In the circuit according to Fig. 2, as already mentioned, two demodulator arrangements are used used, one of which is used to receive phase-modulated oscillations and the other amplitude-modulated vibrations are set for reception. The unfiltered Vibration is transmitted from the double line 4 to the control grids of the rectifier pair 2o and 20 'with a phase shift of 90 ° with respect to the filtered carrier fed to the control grids of 20 and 20 'from the modulator tubes 16 and 17 is fed. Accordingly, the unfiltered carrier becomes the control grid of the rectifier pair 2, 1 and 21 'in phase or shifted by 180 ° with respect to fed to the filtered carrier. The tubes 16 and 17 are attached to their screen grids modulated in such a way that first one pair of rectifiers and then the other pair of rectifiers receives carrier energy: The output voltages of these two rectifier pairs are combined so that the currently switched on rectifier pair of the pawl 14 a signal oscillation pulse supplies. As a result, the receiver is alternately receiving phase modulation and adjusted by amplitude modulation because the two rectifier pairs respectively if there is no additional support, do not supply any output energy. The generator r9 can again have square waveform. so that the period during which both reception branches are simultaneously ineffective, is brief, during the period during which one the reception branch is effective is relatively long.

The circuit shown in Fig. 3 differs from that shown in Fig. 2 essentially in that the demodulator arrangements are designed as multi-grid tubes are. These are alternately made effective and ineffective that the screen grids are modulated in push-pull by giving them voltages from the modulation voltage source are supplied via the transformer 35. The phase regulator 24 can be adjusted that the tube 26 demodulates phase modulated waves, while the phase controller 25 can be set so that the demodulator 27 amplitude-modulated waves demodulated. After such a setting, if alternately one and then the other multigrid tube is activated in time with the modulation frequency the receiver can receive both types of modulation. The ones on the anodes of the Both multigrid tubes occurring low-frequency voltages are over the Amplifiers 4o and 41 fed to the display device. Here too, the tone generator has preferably a square waveform and works with a frequency that cannot be heard.

In the circuit according to FIG. 4, the upper sideband of the intermediate frequency is filtered out and a rectifier 46 and the lower sideband is filtered out and fed to a rectifier 47. In order for a demodulation of the individual sidebands to take place, a part of the carrier oscillation must of course also reach the rectifier in each case. If the output energy of these rectifiers is combined in phase, the receiver can receive amplitude-modulated oscillations. If, on the other hand, the output energy of the rectifiers 46 and 7 is combined in antiphase, the receiver can receive phase-modulated oscillations. As a result,. if the modulation device 56, 57, 58, which is connected to the control grids of the amplifier tubes 51, 54 and 55, alternately switches from an in-phase to an anti-phase combination, the receiver respond to both types of modulation. The modulation device couples the output voltages of the two rectifiers 46 and 47 alternately in phase and in phase opposition with the aid of the tube 51 and the tubes 54 and 55, which are connected in push-pull and activated alternately. When the output voltages of the coupling tubes 5r and 54 are combined, an in-phase combination results so that the receiver responds to amplitude modulated waves. If, on the other hand, the output voltages of the tubes 5 1 and 55 are combined, the combination results in an anti-phase combination so that the receiver responds to phase modulated waves. By push-pull modulation of the tubes 54 and 55 in such a way that first one and then the other tube is ineffective, the desired switching is obtained and the receiver responds to both phase-modulated and amplitude-modulated waves.

Each of the circuits just described can still be connected to a device for automatic frequency control of any kind.

The present invention is also practicable when received with multiple Antennas with different fading properties.

With the circuit according to Fig. 2, the signal energy can also be used instead of the carrier energy can be switched to the two demodulators in phase opposition. In In this case, the modulator tubes 16 and 17 are placed in the double line 4, which feed the unfiltered signal oscillation to the demodulators instead of into the Double line 3; which transmits the carrier oscillation.

Claims (1)

PATENT CLAIMS: e.g. Receiver for amplitude and phase modulated Vibrations, characterized in that it is equipped with a switching device by which it alternates with a frequency above the flammability limit to the reception of phase-modulated oscillations and to the reception of amplitude-modulated ones Vibrations is switched. a. Receiver according to claim i, characterized characterized in that the received modulated carrier wave before rectification an additional carrier of the same frequency is added, its phase against the received Carrier is wobbled with overhearing frequency that the carrier of the resulting Vibration with respect to the original carrier a phase shift of alternating about, o or i8o and about 9o °. 3. Receiver according to claim 2, characterized in that that the additional carrier by filtering out the carrier frequency from the incoming Frequency mixture is obtained. q .. Receiver according to claim i to 3, characterized in that that a push-pull rectifier pair the incoming oscillation in phase and the filtered out carrier oscillation is supplied in phase opposition or vice versa and that the phase of the incoming oscillation or the filtered out carrier oscillation is modulated by the overhearing frequency oscillation in such a way that the mutual Phase difference between the two carrier oscillations between about -o or i8o and go ° fluctuates in the overhearing-frequency rhythm (Fig. i). 5. Receiver according to claim i, characterized characterized in that two demodulation devices are provided, of which the one for demodulation a, amplitude-modulated oscillations and the other for the demodulation of phase-modulated oscillations is suitable, and that a switching device is provided that alternately one of the two demodulation devices in the overhearing-frequency rhythm can take effect. 6. Receiver according to claim 5, characterized in that each of the two demodulation devices contains a rectifier arrangement in which an additional carrier is added to the incoming oscillation, which in one demodulation device a phase difference of about o or 180 ° and in the case of the other demodulation device has a phase difference of about go ° compared to the original oscillation. 7. Receiver according to claim 6, characterized in that by the in the overhearing frequencies Switching device acting rhythm alternately an additional carrier of the same frequency is switched to the two demodulation devices in push-pull mode (Fig. 2). B. Receiver according to claim 5 and 6, characterized in that each of the two Demodulation devices contains a multi-grating tube, in which separate control grids the incoming oscillation, the additional carrier and the switching voltage with a high frequency of hearing loss can be supplied (Fig. 3). G. Receiver according to claim i, characterized in that that two rectifier arrangements are provided, one of which is the upper one Sideband of the received modulated carrier wave is demodulated and the other the lower sideband of the received modulated carrier, and that one Overhearing frequency switching device is provided, which the low-frequency Output voltages of the two rectifier arrangements alternately in common mode and interconnected in push-pull (Fig. 4). ok Receiver according to claims i to g, characterized in that the switching device by an overhearing frequency Generator is formed, the voltages of preferably rectangular waveform generated.