DE381010C - Method for suppressing the influence of atmospheric disturbances during reception in wireless telegraphy - Google Patents

Description

Procedure for suppressing the influence of atmospheric disturbances when receiving in wireless telegraphy. In wireless telegraphy are often used current limiters, which the by the telephone or by the Recorder prevent the current received from reaching an amplitude that goes over a predetermined maximum limit, regardless of the strength of the Vibration picked up by the receiving station. Such current limiters can e.g. B. consist of a three-electrode tube or two in R - ihe switched tubes. The output circuit of the current limiter can only be limited Current variation j, n (Fig. I) provide, and the setting is generally like this made that the total current change for the potential difference achieved II \ ' which is caused by you ch the Sig: 7al between the input terminals of the Stroinbegreuzer «-: approx.

Such devices are quite effective for small waves and small transmission speeds. However, it cannot be used safely? - operation more @r: .iel @ will-i as soon as the wave length and @encleesch wind speed increase. Strong disturbances are then no longer eliminated because these disturbances call out in the resonator free se: hwinguiigen of large initial amplitude emerge, their Sometimes the duration of a point or a pause between two consecutive ones Character exceeds.

According to the invention, this drawback is eliminated in that the Impedance and the natural frequency of the resonator, which such disturbances is subjected to the action of an electromotive reaction force which comes from the current amplitude limiter. Such reaction forces, the z. B. can be achieved by feedback, are with receiving devices Three-electrode tubes übli @, h. However, you are not yet a three-electrode tube or a similar part, which is called the current amplitude starter serves. Compared to the known facilities this: arrangement is new, as well as the way in which benefits are derived from this. The new procedure there a particularly beneficial and effective means of suppressing the atmospheric Disruptions.

The invention will be explained in more detail with reference to the drawing. from In the figures, _ Fig. i shows the characteristics of a current limiter, Fig. 2 shows an example of a circuit arrangement of a receiving device for implementation the invention.

Fig. 3 shows the decay curve of an emerging from the amplitude limiter Fault current.

Fig.q. shows the reaction voltage caused in the resonator by this current.

It is assumed that in Fig. 2 the resonator i, 2, 3 simultaneously influenced by a signal and an aperiodic atmospheric disturbance. It can be this resonator z. B. an antenna with a self-induction i, a tuning capacitor 2 and an ohmic resistor 3. This resonator becomes an amplifier 5 influences and here-au` "in imnlitud-nbeg: enz ^ r the current i of this amplitude limiter changes according to the characteristic shown in Fig. i as a function of the 1? input voltage of the amplitude limiter. The receiving device then has no -h to the usual parts, such as B. tuned to the frequency of the signal @ch: @: ing @ mkreis g, a detector io and a register galvanometer ii; aside from that the following control devices are provided.

i. Regularly based on the ZIN limit value by the signal at the terminals of the amplitude limit 7 created potential difference. The Switch h, which allows the primary winding of the transformer 14 to be set so that that the gain changes. Of course, other equivalents could also be used Control devices can be provided for this purpose.

2. Regulation of the electromotive reaction force, by means of which the amplitude limiter acts on the resonator i, 2. This scheme can, for. B. can be carried out by suitable adjustment of the mutual induction coefficient between a winding i, - ^ "which forms part of the resonator, and a winding 12, through which part i of the anode current y flows. The windings 12, 13 form the primary and secondary windings of an adjustable feedback device .4.

3. Regulation of the phase of the river ice i. This phase can be approximated to i8o 'can be shifted by adjusting the capacitor 8, and one can also reverse the coil 12.

Although the invention is independent of the theory on which it is based, the mode of operation of the device can be explained in the following way, which also allows: - To determine the best method of use and control. The following designations are assumed: R, L, C are the ohmic resistance, the self-induction and the capacitance of the resonator 1, 2, ö, the logarithmic decrement of the resonator, xo - - the natural oscillation, e = E sin (@, S t - ü-) the electromotive force which is caused by signals of a frequency "j", v - V sin v, t is the potential difference which is caused in the resonator 1, 2 and is passed on by it to the receiving device.

f = the electromotive reaction force which is produced in winding i3 by winding i2 through which current i flows. The oscillation in the resonator 1, 2 is given by the equation regulated. As long as the voltage transmitted to the amplitude limiter does not exceed the value AIIV (Fig. 1), i.e. for all oscillations whose amplitude does not exceed that of the signal, the amplitude limiter 7 works in the straight-line part of its characteristics, so that the currents i and j are always proportional to the voltage difference v. The electromotive reaction force has the following form f = K, s V sin (w, s t -E- ü).

K, means a constant coefficient as long as there is no element of the Receiving device is changed.

ip is a phase that can be regulated by means of the capacitor 8.

If this value of f is transferred to equation 1, then one has the equation for the amplitude V of the amplitude caused by the signal in the resonator In order for the signal to have the greatest possible strength can be reduced to zero and the expression of very little value. Sin #b is assumed to be positive (sign of the suitably chosen mutual induction q.). The double condition indicated above is achieved by suitable setting of the adjustable capacitor 2 and by a closer or looser coupling between the windings 13 and 12 in order to give the reaction K i the appropriate value. The result obtained is the better, the sharper the setting of the capacitor 2. If after this setting, the amplitude MN of the oscillation at the terminals of the amplitude limiter 7 is insufficient, which z. B. can be determined by the deflection at the galvanometer 11, then the amplitude is increased by means of the switch 6 and an attempt is made to set it again to where and K. When the setting for the received signal is ready, the resonator 1, 2 has a natural oscillation which is different from that of the signal and is due to the formula is given. The overvoltage is VIE or about It's stronger than if the reaction weren't there. In addition, the amplitude limiter can absorb oscillations whose amplitude differs little from that of the saturation current.

The free oscillation created in the resonator 1 and a by a strong atmospheric disturbance is damped under the conditions as shown in FIGS. 3 and q. are shown. Instead the amplitudes Aa, Bb to obtain ..., which would be expected if the saturation effect were not present, the change of the outgoing current from the amplitude limiter does not exceed the amplitude Jzn. It follows that instead of the damped sinusoidal shape, which is shown in dotted lines, the electromotive force, which is proportional to is, the irregular, solid lines in Fig. -q. takes the specified form. namely up to the time B, at which the amplitude of the waveform no longer reaches that of the signal.

The phenomena occurring after the time instant d can be neglected because a free oscillation of an amplitude equal to that of the signal oscillation is the same, but is dampened, soon disappears. So all that remains is the passage of time between o and B. Since the response is no longer sinusoidal, so it can no longer be represented by a formula K V sin (crt -i- # @). An examination of Fig. Q. shows that it is the smaller, the stronger the wave train is, so that the components K., cos dL and K, sin ip are replaced by other components X and Y of low amplitude can be replaced.

X <K, cos d, I '<K, sin d, The pulsation w, the free oscillation must be in every moment of the equation suffice. It therefore assumes a variable value up to the instant d which is different from the value j "of the signal and is closer to the eigenvalue", -o of the resonator.

In addition, the proportional damping increased.

In short, the dangerous part of the wave train becomes fast attenuated and at a frequency different from that of the signal: the atmospheric Disturbance can therefore no longer interfere with the subsequent coordinated circuits act, e.g. B. does not affect the signal frequency (e.g. that of the resonator g, Fig. 2) or the modulation frequency resulting from the interference between the Signal and a local current results.

The operating conditions are all the more favorable than the inherent resistance 3 (Fig. 2) of the resonator is larger and the lead @L, the electromotive Reaction force with reference to the potential difference v deviates from 90 °. Would be the Angle ip equals 90 ° (which is the case when the capacitor 8 according to Fig. 2 is removed would be), the improvement, as far as the attenuation is taken into account, would be retained be, but not by the difference between the frequencies of the free Oscillation and the signal achieved.

Similar circuits as shown in Fig. 2 could can also be used for the resonators behind the detector, which respond to the modulation frequency of the signal are matched. It is not necessary that the between the Electromotor reaction exposed resonator and the voltage limiter arranged Circuits are aperiodic. The receiving arrangement can, as usual, have several in Have series-connected resonators, in front of the amplifier circuit or within the same. The new technical effect would also be achieved if the electromotive reaction force from one arranged behind the amplitude limiter Would be removed from the circuit.

The invention is not based on the illustrated and explained for example Embodiment limited, but allows numerous variants in the combination of the essential parts of the same. The apparatus, such as B. the amplifier amplitude limiter and detectors can be chosen at will, provided that they are one of them fulfill the required role.

Claims (3)

PATENT CLAIMS: i. Method of suppressing the influence of atmospheric Disturbances in reception in wireless telegraphy, characterized in that in the primary resonator (antenna, frame coil, etc.) one through a fraction of the electromotive current created from an amplitude limiter Force is fed back, the amplitude and phase of which can be regulated, the by The vibration supplied to the amplitude limiter is independent of the regulation of the electromotive Force can be set arbitrarily in its amplitude. 2. The method according to claim i, characterized in that the return of the electromotive reaction force takes place on a different from the antenna resonator, which is the receiving arrangement listening and lying in front of or behind the detector. 3. The method according to claim i and 2, characterized in that a three-electrode tube is used as the amplifier and amplitude limiter is provided.