DE720781C - Method for demodulating frequency-modulated vibrations - Google Patents

Description

The invention relates to frequency demodulators for receiving frequency-modulated signals, d. H. such signals, which instead of the amplitude, the frequency of the transmission oscillations change. The invention can be used in particular in those cases where the carrier wave of the first modulation stage is frequency modulated and this in turn, a high-frequency transmitter oscillation is amplitude-modulated.

In the known receivers for frequency-modulated oscillations, usually the frequency modulation is converted into an amplitude modulation with the help of filters, d. H. The frequency demodulator is a filter whose transmission capacity or attenuation curve is within the modulation used frequency band is approximately linear.

The use of filters as frequency demodulators has certain requirements to the equipment connected to them, e.g. the one supplied to the inlet of the filter The oscillation must be largely free of any change in amplitude, so that the output amplitude is only a function of the input frequency. Furthermore, the input oscillation should essentially embody a pure sine wave, otherwise the one in a distorted one Vibration existing higher-frequency components fall into the useful range of the filter curve and then demodulate the " can have a disruptive effect on the output current. These requirements can be satisfied

happen by ζ. Β. an amplitude limit or an automatic volume control is carried out.

In order to avoid these disadvantages, according to the invention as a frequency demodulator with two grid-controlled gas or vapor discharge paths working inverter with commutation capacitor is used, the grid circles of which are to be demodulated ίο vibration is fed in in phase opposition and a rectifier is connected to its output circuit at whose load resistor the demodulated current is taken.

When using such a frequency demodulator, a current limit or Volume control not required. The demodulator according to the invention is independent from an amplitude modulation of the oscillation to be demodulated. Furthermore, there is complete linearity between input frequency and output current reached. Furthermore, this demodulator only speaks to the fundamental oscillation of the frequency-modulated carrier so that distortion of the waveform does not interfere. The waveform of the carrier wave can therefore, for. B. be rectangular.

The invention will be explained in more detail with reference to the drawing.

Fig. Ι shows the block diagram of a transmitter, in conjunction with which the invention Demodulation method can be used.

Fig. 2 shows the block diagram of a receiver with the demodulator according to the invention.

Fig. 3 shows a circuit diagram of the demodulator.

It means 1 an image scanner or a

other signal current source that changes the frequency of a vibrator 2, the generates the low frequency carrier frequency for the first modulation stage. E.g. a band from 1600 to 2000 Hz can be used for image transmission, but other bands above or below this value can also be used. The way in which the frequency modulation of the carrier of the first modulation stage is carried out does not play a role in the invention. The output current of the frequency modulator 3 is used for the amplitude modulation of that generated by the oscillation generator 4 uses high-frequency carrier oscillation. This modulation can take place according to one of the known methods. The output current of the modulator 5 arrives at the transmitter 6, which transmits the signals by means of a suitable antenna.

In the case of the receiving arrangement according to FIG. 2, the signals are picked up by the antenna 7 and then in 8 amplified rectified and amplified again. The output current of the receiver 8 goes through a low-pass filter 9, which in the above case has a transmission limit slightly above 2θοοΗζ. This filter can be omitted if the carrier of the first modulation stage has a frequency in of the order of 120 to 200 Hz. The output lines 10 of the low-pass filter 9 are connected to the frequency demodulator 11 according to the invention, which the Converts frequency modulation into amplitude modulation. The output lines 12 of the demodulator are connected to a further low-pass filter 13, which is at the band assumed as an example has an upper pass limit of less than 1600 Hz in order to have the effect of the constant Current pulses of the demodulator 11 over the complete oscillation period to expand, d. H. the current pulses generated by the demodulator are more constant To preserve the amplitude in its shape as much as possible.

The output current of the low-pass filter 13 is supplied to the recording apparatus 14. Receiving apparatus 8, low-pass filters 9 and 13 as well as drawing apparatus 14 are of a well-known design so that they do not need to be discussed any more.

The details of the frequency demodulator 11 resulting from the Fig. 3. The input lines 10 are connected to the primary winding of a transformer, whose secondary side, the partial windings 15 and 16 up ⁹ ^. One end of the winding 15 is connected to the grid of the grid-controlled gas or vapor-filled discharge tube 18 via the resistor 17. The other end of the winding is connected to the cathode 21 'of the tube 18 ^{via resistors 19 Jo ° and 20.} Correspondingly, the ends of the winding 16 are connected via resistors 21 or 19 and 24 to the grid or to the cathode 25 of the gas or vapor-filled tube 2 ^ .

The secondary windings 15, 16 are connected so as to feed the lattice of the tubes 18 and 23 in opposite phase, as in an ordinary processing Gegentaktschal- ^no is the case.

The anodes 26 and 2 ″ of the tubes iS and 23 are connected in parallel to the positive pole 28. The negative pole 29 of the supply voltage source is grounded at 30 ″ 5 and at the same time connected to the center point 31 of the transformer. The resistor 19 is bridged by the capacitor 32.

The circuits of the two tubes are through the commutation capacitor 33 in Connection that ensures that a tube

goes out when the other ignites. The time constant of the capacitor with associated Circuit is dimensioned so that the positive ions disappear and the grid of the tube is controllable before the capacitor is discharged so far that the cathode voltage falls below the anode voltage drops.

The cathode 21 'is across the capacitor 34 and resistor 35 and accordingly

• to the cathode 25 via the capacitor 37 and the resistor 38 at 36 grounded. The time constant the capacitance-resistor combination is so small that the capacitors within a half period of the highest in the frequency-modulated Fully charge or discharge the carrier occurring frequency.

Furthermore, a full wave rectifier 39 is provided, one anode 40 of which with the ungrounded end of the resistor 35 and its other anode 41 with the ungrounded End of resistor 38 is connected. The rectifier cathode is grounded through resistor 42 at 43. on the other hand the cathode is connected to the grid 45 of the tube 46 via the resistor 44, which is used to amplify the output current of the rectifier 39. The cathode 47 of the Tube 46 is at the junction of resistor 19 with resistors 20 and 24, and the anode 48 is connected to one output line 12, while the other output line 12 at the positive pole 28 of the supply voltage source lies.

The operation of the circuit is as follows. The image scanner 1 of FIG. 1 generates an output current of variable amplitude, and this changes the frequency of the through the vibration generator 2 generated carrier. The output current fluctuating in its frequency, which includes a frequency band of, as has been assumed, 1600 to 2000 Hz; is fed to the modulator 5. By

4-5 the carrier, which fluctuates in its frequency, is that generated by the vibration generator 4 The amplitude of the generated high-frequency carrier is modulated. The output current of the modulator 5 is sent to the transmitter 6 fed and broadcast through the antenna. On the receiving side, the modulated high frequency carrier wave through antenna 7 recorded, amplified and, through rectification, the carrier wave of the first Modulation level gained, which is further amplified. This carrier contains in his fluctuating frequency the signal modulation and has moreover mostly still undesirable Amplitude modulations z. B. as a result of atmospheric disturbances. Of the So fluctuating carrier contains higher frequency components that are brought in from the outside are. The latter are removed by the low-pass filter.

The output current of the low-pass filter generates a voltage on the secondary windings 15, 16 through which the grids of the tubes

18 and 23 alternate between positive and negative. Let us assume that for a given Time the tube 23 is conductive, then the capacitor 33 is due to the voltage drop charged on resistor 24 with the lower end of the capacitor being positive. When the top of the winding 15 then becomes positive and the lower end becomes negative, the tube 18 ignites; but that negative potential at the grid cannot extinguish the tube 23, since the Lattice lost its controllability due to the presence of free positive ions Has. However, as soon as the tube 18 ignites, both the voltage at the negative end of the Commutation capacitor 33 and thus also at the positive end due to the voltage drop increased at resistor 20. This voltage drop is greater than the voltage drop at the anode-cathode path of the tube 23. Since the capacitor 33 is not due to its high time constant discharges quickly enough, the cathode 25 assumes a higher voltage than the anode 27, and the tube 23 goes out.

The cathode is held above the voltage of the anode 27 until the positive ions in the vicinity of the grid disappear. The negative voltage of the The grid, however, prevents the tube from re-entering during this negative half-cycle ignites. The capacitor 34 is now charging, while the capacitor 37 is discharging. Of the Charging current flows \ όπ 28 via anode 26, cathode 21 ', capacitor 34, resistor 35 and earth 36 to negative pole 29.Capacitor 37 discharges through resistors 24,

19 and 38. These two capacitors and their associated circles have time constants such that they are within half a Period of the highest occurring in the ■ frequency-modulated carrier wave Frequency completely discharged. So if the capacitor 34 is in the just described Way charges, the rectifier 39 generates a positive voltage pulse across the resistor 42 as a result of the Anode 40 to ground line 43 of flowing charge current. The resultant as a result of the discharge of the capacitor 37 at the resistor 38 A voltage drop gives the anode 41 a negative potential. As a result, can no current will flow through this half of the rectifier during this part of the period.

The will ignite in the next half-period

720 78Ϊ

Tube 23 and tube 18 go out due to the presence of the commutation capacitor 33, whose activity does not need to be described again in detail. When the capacitor 37 while recharging, a rectified current flows through resistor 42 to earth the voltage drop generated at resistor 35 by the discharge of capacitor 34 does not allow current to flow through the rectifier.

From the described mode of operation it can be seen that during each complete Period of the carrier fed to the transformer two current surges through the load resistance 42 flow. Appropriate amplification of the signal currents before demodulation through the tubes can be achieved that the tubes respond even with very weak signals during a strong fade period. The through the Resistor 42 flowing current surges have constant amplitudes, in other words, the voltage drop occurring at each current surge across resistor 42 is independent on the signal current. The mean value of the value flowing through the resistor 42 As a result, the current depends directly on the number of current surges occurring per second away. The greater the number of current surges, the greater is the resistance flowing through the resistor Current. The pulsating output current of the tube 46 is passed through the filter 13 smoothed so that the input of the recording device 14 is supplied with a voltage whose amplitude varies according to the frequency fluctuations of the input of the Demodulator supplied vibrations changes. Since the output current is independent of changes in the amplitude of the input voltage, as they can occur as a result of atrophy phenomena, there are no current limiters in the receiving equipment necessary. The demodulator according to the invention itself works in the conversion the frequency fluctuations in amplitude fluctuations as a current limiter. Also the others that occur with filter demodulators Difficulties are avoided here.

Instead of the low-pass filters described, suitable band filters can also be used. Furthermore, the amplifier 46 can be omitted and the filter 13 can be connected directly to the Resistor 42 can be connected. It is also permissible to use just one of the capacitors 34 and 37 to use. You then only get half of the rectified current impulses, otherwise nothing changes.

Claims (1)

Claim: Method for demodulating frequency-modulated oscillations, characterized in that that the vibrations to be demodulated correspond to the lattice circles one with two lattice-controlled gas or vapor-filled Discharge paths working inverter with commutation capacitor are supplied in phase opposition and the demodulated oscillations at the ballast resistor one at the output circuit the rectifier lying on the inverter can be removed. 1 sheet of drawings -