DE694786C - Method for generating phase-modulated vibrations - Google Patents

Description

Method for generating phase-modulated oscillations The invention relates to a method for generating phase-modulated vibrations by transfer an amplitude-modulated oscillation into a phase-modulated oscillation. In both The modulated oscillation can be thought of as being composed of one cases Carrier oscillation of constant amplitude and two sideband oscillations. The relationship between the two, modulation types occurs most clearly in a vector diagram in which the three vibration components are represented by a vector each. In the case of pure amplitude modulation, the carrier vector is symmetrical the two sideband vectors. The pure phase modulation differs in that The carrier vector is rotated by 90 °, i.e. on the bisector of the sideband vectors stands vertically. There is thus the possibility of an amplitude modulation to be converted into a phase modulation in that the carrier vector is rotated by 90 ° will.

It is already known to have an amplitude-modulated oscillation to add primordial modulated oscillation of the same frequency in such a way that the vector of the An additional oscillation with the carrier vector .dpr amplitude-modulated oscillation Includes an angle of 9o °. However, the result of this composition is not one pure phase-modulated oscillation, because the resultant of the two carrier frequencies Vibrations. is shifted from the original carrier vector by less than 90 °. In order to keep this deviation from the right angle small, one must with the known Method give the additional oscillation an amplitude that is a multiple of the carrier oscillation amplitude amounts to, and this means a considerable compared to the proposed method Expenditure.

In contrast, the invention consists in a method of production phase-modulated oscillations, in which an amplitude-modulated oscillation with composed of a phase-shifted, unmodulated oscillation of the same frequency and that is characterized by the fact that the unmodulated additional oscillation with such a phase position is added, then the original carrier oscillation is completely extinguished and only one to the original carrier wave vertical component remains.

Another advantage over the known method is that that by the choice of the phase position of the additional oscillation with simultaneous perfect , Elimination of the original carrier oscillation of the degree of modulation when achieved a pure phase modulation can be chosen arbitrarily.

An exemplary embodiment of a circuit for carrying out the method identified above is shown in the drawing. In its basic features, this circuit is constructed in the same way as the modulation circuit which was previously assumed to be known. The main difference lies in the choice of the size of the phase shift: the carrier oscillation used for the transmission of messages is generated in a control transmitter 6 and fed to the grid circle of the separately excited transmitter tube i. In this, the carrier oscillation is modulated in terms of amplitude in a manner known per se, for example in that the signal voltages supplied via the transformer 7 are superimposed on the grid voltage. Of course, any other type of amplitude modulation can also be used, for example influencing the anode spamming. The amplitude-modulated oscillations are guided from the anode circle of the tube i to the points a, b of a bridge arrangement a in equilibrium, which are in a bridge diagonal. On the other bridge diagonal, namely points c, d, a primordial modulated oscillation of the same frequency expediently taken from the control transmitter 6 via the coupling coil 4 is applied. Because of the mutual decoupling of the two diagonals of the bridge z, there is no disruptive reaction from the main transmitter to the control transmitter. The amplitude and phase of the primary modulated applied at points c, d. Oscillations must be set so that the resultant of the additional oscillation and the carrier oscillation applied to points a, b is phase-shifted by 90 ° with respect to the latter, i.e. a pure phase modulation results. The phase shift between the additional oscillation and the carrier oscillation should therefore be more than 11s 90 °. The amplitude of the additional oscillation can be adjusted by changing the coupling of the coil ¢ to the control transmitter 6, while the phase can be shifted by adjusting the element consisting of the L, longitudinal inductance 3 and the transverse capacitance 5. The phase-modulated oscillation can be applied to one of the four bridge branches, e.g. B. between points a and d. U

Claims (1)

PATENT CLAIMS: i. Method for generating phase-modulated oscillations, in which an amplitude-modulated oscillation is combined with a phase-shifted, unmodulated oscillation of the same frequency, characterized in that; that the unmodulated additional oscillation is added with such a phase position that the original carrier oscillation is completely extinguished and only a component perpendicular to the original carrier oscillation remains, a. Circuit for carrying out the method according to Claim i, characterized in that a balanced bridge is provided; the amplitude-modulated carrier oscillation is supplied to the one diagonal and the unmodulated additional oscillation is supplied to the other diagonal, and the phase-modulated oscillation is picked up at one of the bridge branches. 3. Circuit according to claim z, characterized by a special element consisting of a longitudinal inductance (3) and a transverse capacitance (5) for setting the phase of the additional oscillation relative to the carrier wave in the feed path of the additional oscillation to the bridge.