DE854668C - Transmitter for alternating current telegraphy with simultaneous frequency and phase shift keying - Google Patents

Description

Transmission device for alternating current telegraphy with simultaneous frequency and phase shift keying The subject of the main patent is a method for alternating current telegraphy, with the simultaneous application of a frequency modulation and a phase modulation an exact character formation is achieved and at the same time an ongoing monitoring of the correct phase assignment is made possible in the receiving arrangement. On the sending side this procedure is carried out in such a way that when the telegraph characters are sent the frequency and the phase position of the alternating carrier current is changed at the same time, and preferably in such a way that both the frequency change and the phase change, apart from short-term transition phenomena, it takes place in leaps and bounds. One embodiment The invention according to the main patent relates to a transmission device for alternating current telegraphy, in which a pushbutton circuit is connected to the alternator, which when Transition from separating stream to character stream at the same time that corresponding to the separating stream Frequency of the alternating current on a transmittable within the bandwidth of the same channel, the frequency corresponding to the character stream and the phase position corresponding to the separating current of the alternating current to that corresponding, preferably opposite, to the character current Phase shifted.

The circuit example shows one way of realizing this Thought in the way that by two simultaneously effective switching means the frequency-determining element of a feedback buzzer to another resonance frequency switched and at the same time a keying circuit effecting the phase shift keying is actuated in the output of the buzzer.

The invention has a further development and improvement of a transmission device for alternating current telegraphy with simultaneous frequency and phase shift keying according to the main patent on the subject and is characterized in that one for itself only the phase shift keying effecting keying circuit with the frequency-determining one Member of the alternator interacts in such a way that the phase shift keying at the same time a frequency change of the generated alternating voltage is forced.

In order to achieve the most symmetrical working of the arrangement, it is advisable to use the phase shift keying circuit with a one additional fixed phase shift of preferably about 90 ° causing phase rotator connect to. In this way it is achieved that the phase position is behind the phase rotator removed AC voltage used for controlling the frequency change at Keys of the telegraphic characters in relation to the phase position of the input voltage of the Key circuit in opposite directions of rotation by approximately the same angle preferably is changed by about any °.

When using a feedback alternator, the Transmitting device according to the invention can be implemented in such a way that the Phase shift keying serving keying circuit arranged in the feedback circuit and with the frequency-determining member is so interacted that by the Phase shift keying a phase and at the same time a frequency change of the alternating voltage arises at the frequency-determining member. Here, the frequency-determining element together with the effective resistance form a voltage divider, the effective Feedback voltage is tapped at the frequency-determining member.

The keying circuit used for phase shift keying can be of various types Way with or without moving switches. A particularly useful one An embodiment in which moving parts are completely avoided consists in that the key circuit designed as a ring modulator and by direct current double current characters is controlled.

The invention is now intended to be based on exemplary embodiments in conjunction with the drawing are explained in more detail.

Fig. 1 shows a feedback tube buzzer with a relay-controlled Push button circuit; 2 shows a vector diagram to explain the mode of operation the circuit shown in Fig. 1; Fig. 3 shows a modification of the in Fig. 1 shown .Röhrensummers avoiding moving switching means; Fig. 4 illustrates Another possible embodiment of a tube buzzer with a different version compared to FIG mutual position of the key circuit and the frequency-determining element.

In the circuit according to FIG. 1, R represents a three-electrode tube, the cathode circuit of which contains a resistor W1 in a known manner and the anode circuit of which is fed back to the grid circuit via a transformer T1. In the anode circuit there is a winding I which is connected to the cathode circuit via an anode voltage source AB. The feedback voltage U1 is taken from winding II, the correct phase position being ensured by the polarity of the winding, and fed to a voltage divider consisting of an effective resistor W2 and an oscillating circuit formed by a choke L and a capacitor C. A voltage U3 is tapped from this oscillating circuit and fed to the grid of the tube R as a partial voltage.

The oscillation circuit L, C is not direct with the cathode circuit, but connected via the output terminals of a phase shifter P. The phase rotator P, which is supposed to cause a fixed phase rotation of about go °, is connected to the output circle connected to the actual push-button circuit, which is mediated by a relay E is controlled by the direct current signals supplied via terminals K1. the Push-button circuit itself consists of a winding III of the tapped in the middle Anode transformer Ti and a changeover switch e, which is controlled by said relay F. is pressed and according to the telegraphic characters a phase jump keying the AC voltage removed from the winding III caused by the moving Contact piece alternately on one or the other free winding end of the winding III is laid. The phase jump in this case is 180 °, since it is a is pure polarity reversal.

The sampled AC voltages are applied to winding I of an intermediate transformer T2 is fed to the output winding 1I of which the aforementioned phase rotator P connected. From a further output winding III the keyed Characters can be picked up via a pair of terminals K2.

Although the actual push-button circuit is only a pure one on its own Causes phase shift keying, the desired frequency shift keying comes in at the same time in the following way: The via the push button circuit to the terminals of the winding The alternating voltage applied to the intermediate transformer T2 is correct depending on the situation of the pushbutton switch e either with the phase position of the voltage U1 on the winding II of the anode transformer T1 matches or is shifted by 180 ° with respect to it. The same applies to the phase position of that taken from the output winding 1I AC voltage, considering possible small phase rotations due to the transformer T2 refrains. This alternating voltage at the output winding II of the transformer T2 is replaced by the Phase rotator P in a certain, always constant Sense and rotated by a certain angle of preferably about 9o °, so that the Phase position of the alternating voltage U4 at the output terminals of the phase rotator P. the phase position of the alternating voltage U1 at the winding 1I of the transformer T1 at Keys of telegraph characters alternately depending on the key state by about 9o ° forwards. or lagging.

This partial alternating voltage (.'4 is now set up with the already mentioned Partial voltage U3 at the output of the oscillating circuit L, C vectorial to the grid voltage (. '"together. Since the feedback condition requires that this alternating grid voltage U "is always in phase with the voltage U1 taken from the anode circuit, results inevitably also a phase position change for the partial voltage U.3 accordingly the specified phase position changes of the partial voltage U4. These phase changes the partial voltage U3 at the oscillation circuit L, C are only possible if this Oscillating circuit not with its resonance frequency, but with one above or below. below) the resonance frequency is excited. These two possible Operating states of the feedback circuit arise depending on the phase position of the partial voltage U4 inevitably and automatically and thus result in the desired Frequency change of the generated alternating voltage depending on the in one Part of the feedback loop caused phase shift keying.

This process is illustrated by the vector diagram in FIG. It should be expressly noted here that neither the angles nor the lengths of the vectors are shown on a certain scale.

The vector Ui represents the phase position of the one taken from the anode circle AC voltage represents and lies, of possible phase rotations of the transformer Apart from T1, almost in phase opposition to the anode alternating voltage. The vector of Grid voltage U. = must have the same phase position according to the feedback condition mentioned have and is therefore drawn parallel to the vector U1.

>;)) he the key circuit in connection with the phase rotator, whose Effect has already been explained, arises when the telegraphic characters are pressed on Output of the phase shifter P depending on the switching state of the pushbutton circuit one opposite the voltage U1 and thus also the partial voltage leading to the grid voltage U_ U4 "or a partial voltage which is opposite to this in terms of its phase position, that is, a lagging voltage U4 ". If the circuit is completely symmetrical, these two exist alternately Partial voltages are the same size and in their phase position compared to the phase position of the Voltage ('z shifted leading or lagging by go ° each.

Since this partial voltage U4 is vectorially added to the grid voltage U2, which is fixed in phase in accordance with the feedback condition, the partial voltage U3 can never be in phase with the required grid voltage, as in a normal feedback circuit, but must be around a certain level Leading or lagging angles, as the diagram in FIG. 2 illustrates. If the partial voltage U4 leads U2, as the vector U4v shows, the generated oscillation must adjust to a frequency such that a partial voltage U3 "arises on the oscillating circuit L, C, which by vectorial addition with the partial voltage U4, the grid voltage Uz results. This partial voltage U3 ″ is thus phase-shifted with respect to U2 and thus also with respect to U , by the angle l, namely in the lagging sense. The oscillating circuit L, C acts as a capacitive reactance, and the size of the phase angle l and the distance between the frequency of the generated alternating voltage and the resonance frequency of the oscillating circuit L, C depend both on the proportions of the partial voltage and on the quality of the oscillating circuit L. , C and on the ratio of its resonance resistance to the upstream effective resistance W2 . By choosing these ratios and sizes, one has the ability to give the frequency shift the desired size depending on the phase shift keying.

In the opposite shaft state of the pushbutton circuit, the alternating voltage at the output of the phase shifter P that shown in the diagram by the vector U4 " Location. Here, the feedback circuit is forced at the output of the oscillation circuit L, C to output a voltage which leads to the voltages U1 or U2, such as the vector U3v illustrates. The lead angle 2 is the same as that explained above, for the opposite case, the lag angle 1 applies if the circuit is completely operated symmetrically. This lead of the voltage U3 ″ also results again inevitably because the oscillation circuit L, C is in the now existing Switching state is operated below its resonance frequency and as a result acts as an inductive reactance.

The mentioned complete symmetry of the operation, that in the vector diagram 2 results in two mirror-inverted vector triangles, is for practice in no way necessary, it is rather sufficient if through the cooperation of the im Feedback circuit existing switching means when pressing the pushbutton circuit at the same time with the phase shift keying a frequency change of the generated alternating current from the desired size is achieved.

The phase rotator P can be implemented in a manner known per se and, for example, a quadrupole reactance, a complex bridge circuit or a voltage divider composed of active and reactive resistances.

The circuit according to FIG. 3 agrees with that in I # ig. i illustrated Circuit essentially the same, but here is the mechanically moved one counter replaced by a ring modulator circuit M in the key circuit. To this end receive both the output winding III of the anode transformer T1 and the Output winding I of the intermediate transformer T2 center taps to which the Terminals K1 are supplied with the direct current dual current characters. The ring modulator circuit effected in a known manner according to the change of direction of the supplied direct current symbols polarity reversal of the sampled AC voltage. The rest of the circuit works in the manner already described, so that the keyed at terminals K2 Two-way switching at the same time as the phase jumps of i8o ° each time, there is also a frequency change in the desired size.

4 illustrates a further circuit variant in which the the phase shift keying serving keying circuit M, the phase rotator P and the frequency determining Members L, C are arranged one after the other in such a way that the frequency-determining Element is fed by the output voltage of the phase shifter. The output voltage the phase shifter P is therefore depending on the switching state of the pushbutton circuit in their Phase position with respect to the anode alternating voltage by approx. 9o ° leading or lagging postponed. A partial voltage is added to this voltage vectorially, the Anode circuit through a winding II of the transformer Ti with the feedback condition prescribed phase position is taken. The voltage divider, consisting of the Oscillating circuit L, C and the effective resistance W2, is therefore through an alternating voltage fed whose phase position compared to a mean value by less than ± 9o ° in the tactile rhythm is shifted, and the part of the circuit containing the oscillating circuit L, C is forced to fall below or above its resonance frequency Set the operating frequency, which is an alternating voltage with the grid on each required phase position results.

Similarly, numerous circuit variants are also within the scope of the invention possible. For example, the frequency-determining or phase-rotating ones need Parts of the circuit by no means in any case in the manner shown in the grid circle be arranged, but can just as well be wholly or partially in the anode circuit be placed. Also the division of the frequency-determining and phase-rotating ones Parts of the circuit on different 'different' grids of a tube Partial circuits are possible within the scope of the invention.

Claims (7)

PATENT CLAIMS: i. Transmitting device for alternating current telegraphy with simultaneous frequency and phase shift keying according to patent 848968, characterized in that a key circuit which only effects phase shift keying interacts with the frequency-determining element of the alternator in such a way that phase shift keying also forces a frequency change of the alternating voltage generated. 2. Transmitting device according to claim i, characterized in that that the keying circuit used for phase shift keying with an additional fixed Phase shift of preferably about 9o ° causing phase rotator connected is. 3. Sending device according to claim i or 2, characterized in that the the phase shift keying serving keying circuit in the feedback circuit of a feedback Arranged alternating current generator and with the frequency-determining member in such a way Interaction is brought about that through the phase shift keying a phase and at the same time a change in frequency of the alternating voltage occurs on the frequency-determining element. 4. Sending device according to claim 3, characterized in that in the feedback circuit of the feedback alternator containing the frequency-determining element Circuit and the circuit of the key circuit are interconnected so that the effective feedback voltage by vectorial addition of the output voltages of both circuits. S. Transmitter device according to claim 4, characterized in that that the frequency-determining element and the phase shift keying serving keying circuit from the anode circuit of the feedback tube used to generate alternating current fed and in the grid circle with their output terminals between grid and cathode are connected in series. 6. Transmitting device according to claim 3, characterized in that that in the feedback circuit of the feedback alternating current generator that of the phase shift keying serving key circuit, the phase rotator and the frequency-determining member in such a way are arranged successively that the frequency-determining member by the Output voltage of the phase shifter is fed. 7. Transmitting device according to claim 3, characterized in that the frequency-determining member together with a Resistance forms a voltage divider and the effective feedback voltage is tapped at the frequency-determining member. B. transmitting device according to claim i, characterized in that the key circuit is designed as a ring modulator and is controlled by direct current double current characters.