DE635498C - Method for determining the degree of modulation of a double modulated oscillation - Google Patents

Description

Procedure. to determine the degree of modulation of a double modulated Vibration The invention relates to a method for determining the degrees of modulation a doubly modulated oscillation by evaluating the deflection figure on the luminescent screen a cathode ray tube.

In many cases it is known to be beneficial in a wireless Transmission channel to introduce an intermediate frequency. The main purpose of this measure is the utilization of a highly selective amplification on the receiving side, whereby it is known to proceed in such a way that by a local superposition in the receiver the Intermediate frequency is generated. In cases where such local overlay difficulties makes, e.g. B. with ultrashort waves, where the required frequency constancy is only below to achieve a great deal of stabilization equipment, one is on the The way out expires, the intermediate frequency required on the receiving side is already on the transmission side to introduce and from the transmitter on the actual carrier, its frequency must of course be an order of magnitude higher to broadcast with. This intermediate modulation happens in such a way that the actual transmitter does not respond directly to the modulation frequency, but is controlled by an auxiliary transmitter that supplies the intermediate shaft and this in turn only modulates with the low frequency actually to be transmitted is. Another application example for intermediate modulation is when Simultaneously transmit several calls or programs on a single carrier wave should be. By having a special intermediate wave for each transmission channel and the actual transmitter with all these intermediate frequencies, which in turn the various modulations carry, modulated, can be on the receiving side perform a selective separation of the individual transmissions.

With such an intermediate modulation it is now of great importance to know the modulation levels in order to fully understand the transmitter emitting the carrier wave to be able to exploit. The relationships are for the case of simple intermediate modulation considered more closely. Anolage considerations apply to the multiple intermediate modulation.

The simple intermediate modulation is three different Frequencies, namely no = speech frequency with the amplitude E0, n1 = intermediate frequency with the amplitude C1, no = carrier frequency with the amplitude E'2.

In the worst case, in which the intermediate shaft is fully controlled, d. H. when Eo and E'i are geometrically add up the carrier amplitude E2 cannot be exceeded. Lies the operating point in the middle of the linear applied modulation characteristic, so -Eo + E1 = -, 'E ,.

If M = Eo; Ei means the degree of modulation of the intermediate frequency n1 and N = EJE, that of the carrier wave iz ,, then one obtains by substituting N (z + M) @. Although this formula regulates the relationship between the two modulation floors, it does not say anything about their absolute size. Taking the rectifier characteristic as a basis, it can be shown that the maximum output voltage at the receiver is obtained when 1V1 is selected to be as large as possible compared to N. One will therefore set M as equal to i as possible, in which case N is equal to 0.5 according to the relation derived above.

The easiest way to check the degree of modulation of a transmitter is with the Braun cathode ray tube, in that the deflection is effected in the ordinate direction by the modulated high frequency and in the direction of the abscissa axis by the modulation frequency. The well-known trapezoidal figure then arises, from whose parallel edge lengths a and b the degree of modulation m is calculated If this method is to be used for the intermediate modulation, the measurement must be carried out separately for both degrees of modulation, ie for M and N. The Braun tube must either be switched to the various voltages or two separate oscilloscope systems must be used.

Here the present invention brings a substantial relief by combining the measurement of M and N, so that both degrees of modulation can be recognized from a single deflection figure. For this purpose, the intermediate frequency n1 is not used in the measurement, and only the doubly modulated carrier frequency n2 is applied to the ordinate plates and the low frequency no to the abscissa plates. The result is a double trapezoid figure with the appearance of fig: i, in which the intermediate frequency is set off from the base surface by bright lines. The two degrees of modulation are determined from the sizes given in Fig. I When the degrees of modulation are of the most favorable magnitudes given above; the oscilloscope figure assumes the appearance of Fig. 2, -from 4's M and N equals i and o, 5 follows. The setting of the transmitter system has to be done in such a way that this figure is reached as far as possible.

Of course, the computational evaluation shown above must the deflection figure cannot be repeated in all cases, but one can either attach a template or a scale to the fluorescent screen that matches the existing Modulation degrees. Immediately recognizable permitted. For operational purposes it is for example sufficient to ascertain whether the distraction figure is still a certain prescribed one Shape, for example the shape shown in Fig.2.

Claims (1)

YATLNTANSPRUCJ1: Procedure for measuring or observing the degrees of modulation a double modulated oscillation by means of a cathode ray tube, thereby characterized in that the cathode ray in the one coordinate direction through the double modulated oscillation and in the other coordinate direction by the low frequency Deflected modulation voltage and the trapezoidal, is observed the fluorescent screen image traversed by two diverging lines.