DE709623C - Receiving device for carrier current telegraphy with intermediate frequency modulation - Google Patents

Description

Receiving device for carrier current telegraphy with intermediate frequency modulation The present invention relates to a receiving device for carrier stream telegraphy, where for level control bz-% 7 ".- to achieve independence of the character length Automatic control devices in the receiving relay from the input level fluctuations are used, which essentially consist of one in the grid. Or anode circuit of the Amplifier tubes arranged combination of a capacitor with an ohmic resistance exist. This arrangement acts in such a way that when the alternating control voltage grows via one mainly determined by the sensitivity of the receiving relay In addition to the minimum value, an automatic change in the degree of amplification of the tube occurs, by z. B. generated its displacement voltage by the onset of grid currents will. This ensures that the alternating control voltages occurring at the output of the control tube which are to be fed to the receiving rectifier, regardless of the fluctuations in the input level stay constant.

This type of level control has particular advantages in such systems as well To use systems that consist of several different types of amplifier stages. This is e.g. B. the case with receiving devices in carrier flow telegraphy, applies the intermediate modulation. In this system, the pure high frequency is not used sent out, but this first with an intermediate frequency, preferably his Audio frequency, modulated and then either one of the two frequencies before the Modulation or the modulated high frequency keyed.

In the case of receiving devices for carrier current telegraphy with intermediate modulation, especially for high-frequency traffic over power lines, where for automatic level control capacitor resistor arrangements in different receiving stages are provided, the invention now provides a control both in the carrier frequency part as well as in the intermediate frequency part, each with a different time constant.

Due to the different measurement of the time constant of the individual Control loops are particularly advantageous for the control. You can z. B. regulate rapid changes in the carrier frequency part and at the same time through Corresponding dimensioning of the time constant of the intermediate frequency part there is a favorable one Achieve control in such a way that the grid bias of the switching frequency part: it does not change during a sign, so that one also remains insensitive of the receiver against interference currents in the pauses between characters. So one becomes preferential the time edge of the control tube of the carrier frequency part, it is smaller than the shortest Select the character pulse or the shortest pulse pause, so that the regulation is more here the individual fluctuations the signal amplitude follows, while the time constant of the regulating tube of the intermediate frequency component is expediently greater than the longest symbol pulse or the most annoying, # = "interpulse period is selected. The last-mentioned, i dimensioning of the Time constant for at least qs;.; a control stage is therefore important, so not at the end of a pulse pause due to the onset of a new pulse, an impermissible high current impulses are transmitted to the receiving rectifier or the receiving relay will when. meanwhile the control device is noticeably approaching its idle state and could change the displacement voltage significantly.

If, in the case just mentioned, a small time constant for the control tube of the carrier frequency part aims, so you can expediently through this Achieve reducing the capacity of the control element. You may even be able to go so far that the parallel capacitor for the control element of the control tube of the Carrier frequency part is only formed by the tube capacitance and a special capacitor is omitted. In this case the size of the for the automatic level control provided resistance with regard to the to choose the desired potential shift effect. This calculation results in practically a resistance value that is substantial, possibly even several Powers of ten, higher than the impedance of the tube capacitance and therefore that with regard to the transmission of the high frequency is no longer relevant. Here in the fundamental difference between a level control circuit is in the carrier frequency part without a parallel capacitor to the resistor and the normal CW coupling, with which always the grid resistance of the same order of magnitude as the impedance of the Grid cathode capacitance is chosen at the frequency in question.

An amplifier tube can be used for the regulation in the carrier frequency part the demodulator tube can also be used, since the level control is already inherent is connected to a certain rectifying effect.

Two exemplary embodiments of the invention are shown in the drawing. It may be assumed that it is a high-frequency telegraphy system over high voltage lines, in which the high frequency with a tone frequency is modulated.

In the circuit according to FIG. I, the incoming high frequency comes first into an input circuit F_, which has the necessary filter means, adjustable damping circuits and if necessary also contains further amplifier stages. The tube V, amplifies the ..- high frequency pulses and pushes them to the Git - #; 1; circle of the demodulator tube D, from whose anode circuit the pulses obtained by the demodulation to the Grid circle of the amplifier tube V2 are transmitted. From the output of this amplifier The audio frequency pulses then reach the rectifier G, the corresponding direct current pulses to the actual receiving device R, z. B. a polarized relay, passes.

In order to effect an automatic level control, both the high-frequency amplifier tube V and the audio frequency amplifier tube V2 are provided with a capacitor resistor combination Cl, W or C2, W2 in the grid circuit. The time constant of the regulating member is Cl, W is suitably dimensioned to control däß at this stage already amplitude variations within a signal pulse to follow, while the time constant of the control element C2, W2 is so high that at the time of a mark pulse to the next no disruptive drop in the displacement voltage can occur at the grid of the tube V2. The capacitor C, in the lattice circle of the tube V, may, as indicated by a dashed line, also be absent under certain circumstances if the lattice cathode capacitance of the tube V itself already has a sufficient size. The setting of the grid bias is expedient in such a way that, within a certain control range, only tube V2 is initially effective as a control tube, while the control process in tube V only begins when the supplied signal voltages rise beyond the control range of tube V2.

Fig. E shows a modification of this circuit, which consists in that the high-frequency regulation takes place in the grid circle of the demodulator tube D. According to the circuit shown, the high-frequency amplifier tube V, is completely omitted come, but of course it can also be retained and subordinated if necessary Can also be equipped with a capacitor resistor combination. Otherwise, the structure of the circuit is the same as in Fig. I.

Claims (2)

PATENT CLAIMS: i. Receiving device for carrier current telegraphy with intermediate modulation, in particular for high-frequency traffic over power lines, in which capacitor resistance arrangements are provided in different receiving stages for automatic level control, characterized in that regulation both in the carrier frequency part (Wi, Cl) and in the intermediate frequency part (W2, C.) with each different time constant is made. 2. Receiving device according to claim i, characterized in that that the time constant of the control tube of the carrier frequency component is less than the shortest character impulse or the shortest impulse pause and the time constant of the control tube of the intermediate frequency part is greater than the longest character pulse or the longest Pulse pause is. 3 :. Receiving device according to: Claim i, characterized in that that the parallel capacitor for the control element of the control tube of the carrier frequency part is formed by the tube capacitance.