DE861884C - Stereophonic transmission system - Google Patents

Description

Stereophonic radio broadcasts are so far only experimental been carried out, as the provision of two channels and two receivers meant too much effort for a transfer.

In the following a transmission system is described, the only one requires high-frequency transmission channel and on the receiver side with a cheap " Addition to a normal receiver with VHF range can be realized.

Fig. I shows the arrangement on the transmitter. A completely normal VHF FM transmitter can be used with a frequency deviation of, for example, ± 75 kHz. In the normal modulation path (Mod. I) only a low-pass filter TP with a cut-off frequency of 15 kHz is connected in order to suppress any interfering frequencies of over 15 kHz.

The same low-pass filter is also in modulation channel 2, via which the Oscillator i 'at a medium frequency of zoo kHz, for example, with a stroke frequency-modulated by -I-- = o kHz.

The oscillator 2 oscillates at a frequency of = 60 kHz, so that in the mixer stage the frequency of 4o kHz + = o kHz is formed by a filter with a pass range of .15 to 65 kI-Iz of all interfering frequency components cleaned and also given to the modulation input of the transmitter. There. the high-frequency bandwidth of the transmitter is essentially determined by the frequency deviation If the modulation amplitudes are set appropriately, it is stereophonic Transmission not greater than with normal modulation.

As the frequencies. from 15 to 65 kI4z are not audible and besides are suppressed by the deemphasis of the normal receiver, then by the stereophonic transmission of the reception for the radio participants without stereophonic addition in no way affected.

As shown in Fig.2, the stereophony add-on a: n is connected to the low-frequency part of the receiver. In order to obtain the frequencies above i5 kHz with the highest possible level , the decrease can only take place after the low-frequency front pipe, and the deemphasis is then only carried out on the grille of the end pipe. The additional device essentially contains a high-pass filter, a demodulation arrangement and a low-frequency amplifier. It can be structurally combined with the loudspeaker L2. Since the loudspeaker in the radio, because of its relatively small baffle, is primarily suitable for radiating the medium and high frequencies, the loudspeaker L2 is expediently arranged in the corner of the room and designed in such a way that, in addition to the medium frequencies, which make the main contribution to stereophony, it also transmits the low frequencies well. Figure 3 shows a circuit example for the stereophony add-on. The capacitor z, together with the inductance 2, forms the high-pass element with a cut-off frequency of about 15 kHz. The pipe 3 is overridden, so that there is a limitation. The capacitor 4 is periodically reloaded with the square-wave voltage at the anode. This creates negative voltage peaks. at the resistor 5. The integration of these peaks through the resistor 6 and the capacitor 7 again results in the audio frequency modulation, which is amplified with the tubes 8 and g and fed to the loudspeaker L2. Instead of this demodulation circuit, the resistance reciprocal circuit can also be used at which flows through an inductance of a square-wave current and an average value rectification of the voltage peaks that occur is carried out.

Of course, the recipients can for the Stereophonic provided and, in the case of non-stereophonic broadcasts, both channels broadcast or be switched in parallel on the receiving side.

Instead of frequency modulation, the auxiliary frequency (4o kHz) can amplitude modulation also occurs; however, the frequency modulation allows better interference elimination and separation of the channels through the second limitation.

Claims (4)

PATENT CLAIMS: i. Stereophonic transmission system for ultrashort waves, characterized in that one audio-frequency voltage directly frequency-modulates the transmitter in the normal manner, while the second audio-frequency voltage first modulates an auxiliary carrier of about 40 kHz, which in turn frequency-modulates the transmitter. 2. Transmission system according to claim i, characterized in that that the subcarrier is also frequency modulated. 3. Transmission system according to Claim i and 2, characterized in that the low frequency part of the receiver branched subcarriers for interference reduction and channel separation is limited. 4. Transmission system according to claims i and 2, characterized in that the demodulation of the subcarrier by rectifying the mean value of the charging current of a capacitor at constant Voltage or the induction voltage at a constant current flowing through it Inductance takes place.