DE2140680B2 - RECEPTION POINT FOR VHF RADIO SIGNALS - Google Patents

Description

The increasing number of stereophonic VHF sound broadcasts requires community antenna systems a stereo-compatible signal processing. The previously common technique to follow the VHF FM signals Passing the receiving antenna on to the subscribers via a range amplifier has certain disadvantages with itself, as a conventional radio receiver for lack of sufficient selection properties mostly are not able to receive adjacent frequency transmitters with large level differences without interference. It has therefore already been proposed that the VHF received signal mixture in each case to a specific Channel frequency tuned frequency converters to convert into an intermediate frequency position, there make a level control and then put the intermediate frequency signal processed in this way back into to return to the original receive channel.

Another suggestion is to convert several channel signals into neighboring IF positions in order to get them after level adjustment has been carried out in groups by means of a single reconverter back into the VHF radio range traced back.

The invention specified in claim 1 is based on the object of improving the reception quality of VHF radio signals, in particular Stereophony signals to specify a solution that is as comprehensive as possible in the context of selective channel processing. The invention advantageously offers the option of using the same frequency converter either for the conversion back to the original To use the reception channel or for conversion back into any other free VHF channel, wherein the oscillator of the second mixer stage in the first case as an isolating amplifier of the oscillator of the first Mixing stage is used, while in the second case it is effective as a completely independent mixer oscillator.

Advantageous further developments of the invention are described in the subclaims. Details of the invention are explained in more detail in an exemplary embodiment with reference to a figure.

The block diagram of the frequency converter shown in the figure shows a VHF input stage in the left part 1, the received signal from the VHF radio frequency range between 87.5 MHz to 108 MHz either directly via input socket 2 or via input sockets 3, 4 of a directional coupler can be fed. When using the directional coupler input, it is possible to have several converters to be interconnected on the input side according to the loop-through principle. Due to the high back attenuation of the Directional coupler prevents the par all! switched converters interfere with each other. z. B. by the interference voltage of the oscillator of the first mixer. The direct input is from the directional coupling input can be separated by a switch 5.

In the VHF preamplifier 1, the input signal is transmitted using three adjustable VHF circuits are preselected and amplified by a low-cross-modulation field effect transistor. In the downstream of the VHF preamplifier 1 Mixer stage 6, which also uses a field effect transistor as an amplifying mixer element. the input signal with an oscillator frequency generated in a crystal-controlled oscillator 7 in an intermediate frequency position implemented. This oscillator frequency is around the IF frequency 10.7 MHz above the reception frequency of a certain VHF signal. A filter 8, which is subsequently switched on and tuned to the IF frequency of 10.7 MHz, provides together with a second filter 9, also tuned to 10.7 MHz, for the required selection. Both Filters 8, 9 are designed as ceramic filters and have the phase linearity required for stereo reception within the bandwidth of ± 100 kHz to achieve sufficient crosstalk attenuation on. The gain in the 10.7 MHz range is provided by an integrated filter connected between the two filters Amplifier circuit 10, which also acts as a symmetrical limiter at the same time. That has The advantage is that a constant signal level is available at the output of the IF section. Due to the exact symmetrical limitation also results in high amplitude modulation suppression achieved. The second filter is used for further selection of the receiving channel and for suppressing those caused by the limiter amplifier conditional harmonics of the intermediate frequency. Middle of a second mixer 11, in which a ring modulator is used, the conversion back into the VHF radio frequency position takes place, either into the original receiving channel or, if this is not due to direct radiation into the receiver it is possible to switch to another VHF channel that is free at the receiving station. When implementing in the same The second channel is the oscillator 12 of the second mixer stage 11 as an isolating amplifier of the oscillator 7 of the first mixer stage used. In this so-called co-channel conversion, the frequency constancy of the oscillator is important no high requirement is made, since the frequency error due to the inhibition and up-mixing grains

retires. If, on the other hand, it is converted back to another channel, the oscillator 12 works, Quartz-controlled like the oscillator 7, as an independent one Mixing oscillator at the required superimposed frequency. After the second mixing stage 11, a Danish plate 13 is arranged, which allows the output

Lower the output level by up to 2OdB. One on the output channel A matched band filter 14 ensures the level reduction of the level produced in the second mixer stage 11 unwanted mixing products and the oscillator signal.

1 sheet of drawings

Claims (5)

Patent claims: 1. Receiving station for VHF audio broadcast signals, using at least one on the receiving frequency each of a VHF audio broadcast; - signal tuned frequency converter that the received signal in a first mixer stage first in an intermediate frequency position and then converted from this in a second mixer stage into a free channel or into the original receiving channel in the VHF audio broadcasting range, thereby characterized in that the second mixer stage is both an amplifier and an oscillator usable active basic module is assigned, which when converted back into a free Channel as an independent mixer oscillator and when converted back into the original receiving channel acts as an isolating amplifier assigned to the oscillator of the first mixer stage. 2. Receiving station according to claim 1, characterized in that between the two mixing stages (6,11) a limiter amplifier is switched on. 3. Receiving point according to claim 2, characterized in that the limiter amplifier (10) as symmetrical limiter amplifier is formed. 4. Receiving station according to claim 2 or 3, characterized in that the limiter amplifier An intermediate frequency filter (8, 9) of high phase linearity is connected on the input and output sides is. 5. Receiving station according to claim 4, characterized in that the intermediate frequency filter as Ceramic or quartz filters are formed. 35