DE3707244C2 - - Google Patents

Description

The invention relates to a method for digital transmission of radio broadcast signals via broadband channels.

The supply of radio broadcast subscribers is increasing the measure over broadband distribution networks. In radio reception centers the received radio broadcast signals are initially signal-based processed before going through fiber optic or coaxial cables a broadband distribution point and from here to the participants reach. The transmission between broadcasting station and Broadband distribution point can in principle with demodulated ana radio signals. Such a transfer would be however, extremely complex and associated with loss of quality. The demodulated broadcast signals can also be digitized, to then be transmitted over a multiplex channel. Through demodulation, digitization and digital-analog conversion setting with subsequent modulation would, however quality losses also occur. The effort for the over Carrier would be less, the effort for the De However, he continues to use modulation and modulation devices considerable.

A method is described in the published patent application DE 32 08 308 A1 for transmitting frequency-modulated radio broadcast signals via described a digital broadband network. With this procedure there is a closed sampling of the frequency-modulated Radio broadcast signals. The scanning signals are transmitted. Is there a harmonic on the receiving side? the sampling frequency filtered out.

This method can be implemented with little effort in addition to restrictions on the choice of sampling frequency there is also a high attenuation of the received signal.

The object of the invention is an inexpensive transmission procedure for radio broadcast signals over broadband connections to specify the network.

The object is achieved by the note specified in claim 1 times solved.

In addition, a further can be realized with less effort education indicated.

Advantageous developments of the invention are the subclaims refer to.  

It is particularly advantageous that the processed reception signals into the sound baseband signals with the desired sound carrier distance to be implemented, then closed to be groped and digitized. Here can be different antennas for optimal reception of radio signals be set and the received signals processed individually will. The closed sampling of all received signals Sound baseband requires only a small amount of circuitry.

The implementation in standard bit rates is advantageous because it is already the best existing transmission facilities can be used. Emp on the upstream side, the conversion into analog signals takes place generally again in a higher frequency range, for example se the FM radio band are implemented. Demodulation and renewed modulation is not necessary with this method.

A quantization with 9 or 10 bits per sample results in be has an excellent signal-to-noise ratio. But also with 8 bits of resolution per sample and synchronous operation already a signal-to-noise ratio according to CCIR Rec. 468 of more than 60 dB. In addition to today's VHF satisfactory quality standards Radio stations can of course also amplitude mod gated signals are transmitted. For reasons of interference immunity however, it is useful to demo the AM broadcast signals beforehand dulate and convert into FM radio signals before transmission Zen.

Instead of converting individual radio broadcast signals into audio The baseband range is theoretically also the closed implementation of the entire FM range into the sound baseband range. The scanning devices required for digitization as well as analog-digital converters are, however, at the current state of technology cannot yet be realized. That is why the FM-Be richly divided into several subbands, each in one Tone baseband range between about 0 and 7 MHz can be implemented. By intermediate implementation of the FM sub-bands in the video intermediate existing frequency converter and Si Signal processing devices are used.  

Embodiments of the invention are based on figures explained in more detail. It shows

Fig. 1 is a basic circuit diagram for realization of the invention with single channel implementation,

Fig. 2 shows a frequency plan,

Fig. 3 is a frequency plan for the implementation of amplitudenmodulier th received signals,

Fig. 4 is a schematic circuit diagram for the implementation of FM sub-bands,

Fig. 5 shows a frequency plan for this purpose,

Fig. 6 is a block diagram for single channel conversion and

Fig. 7 is a block diagram for FM subband conversion.

The basic circuit diagram shown in FIG. 1 contains up to 15 receive intermediate frequency converters EZU 1 to EZU 15 . At the antenna inputs - only two antenna inputs EA 1 and EA 3 are shown in Fig. 1 - different receiving antennas can be connected. The outputs of the receive intermediate frequency converters are brought together and connected to the input of a first analog-to-digital converter AD 1 . Whose output is connected to the first input EM 1 of a multiplexing device MUX , via whose link output AS a multiplex signal is transmitted over a broadband channel to the link input ES of a demultiplexing device DMUX . At the first output AM 1 of the demultiplexing device, a first digital-to-analog converter DA 1 is switched on, the output of which is connected to the inputs of baseband frequency converters FUB 1 to FUB 15 . The outputs of the baseband frequency converters are also brought together so that the broadcast signals, for example in the original VHF range, are emitted at the common distributor output AV .

The frequency plan for the basic circuit diagram according to FIG. 1 is shown in FIG. 2.

The task of the receiving intermediate frequency converter EZU is the processing of individual received signals US . To achieve good results, different directional antennas can be used first. A single received signal - here, for example, an FM radio broadcast signal US 1 is first - as shown in FIG. 2 - converted to the intermediate frequency position (f _IF = 10.7 MHz), regulated and limited. The intermediate frequency signal processed in this way is converted into the baseband position, assigned to a first baseband BB 1 and referred to here as the tone baseband signal BS 11 . The receive intermediate frequency converter can be designed so that the distances between the carrier frequencies between the converted receive signals BS 11 , BS 12 are at least 400 kHz. The first baseband BB 1 comprises, for example, a frequency range between 200 kHz and 6.2 MHz, the carrier frequencies between 0.4 MHz and 6.0 MHz. The sum of the received signals BS 11 , BS 12 ,. . . form the base band signal BS 1 . The baseband signal BS 1 is sampled closed and digitized by a first analog-digital converter AD 1 . The quantization is carried out with 9 or 10 bits per sample, with a first digital signal DS 1 with a standard bit rate of 139 264 kbit / s according to CCITT-Rec. 703 is generated. In plesio-chronic operation, signal-to-noise ratios of more than 60 dB are achieved. In synchronous operation, the signal-to-noise ratio increases by another 6 dB due to the lack of stuffing jitter. The first Digitalsi signal can be transmitted directly or previously combined with other digital signals DS 2 to DS 4 to form a multiplex signal MS , as is shown in the schematic diagram of FIG. 1 Darge.

At the receiving end, the first digital signal DS 1 is converted back into the first baseband signal BS 1 . Via the baseband frequency converter FUB 1 to FUB 15 , the FM radio broadcast signals can be converted into partial signals VS , which are, for example, transmitted again in the FM radio band. Up to 15 FM radio broadcast signals can be transmitted with a frequency spacing of the carrier frequencies of 400 kHz at a standard bit rate of 139 264 kbit / s. Of course, other radio broadcast signals can also be converted and transmitted into further basebands BB 2 , BB 3 and digital signals DS 2 , DS 3 . The other digital signals DS 2 to DS 4 can also include television programs, for example.

Of course, not only FM radio broadcast signals can be transmitted. The transmission of short, medium and long wave radio broadcast signals is also possible ( Fig. 3). The amplitude-modulated short, long and medium wave received signals are first implemented in the AM intermediate frequency position (F _ZA = 460 kHz) and demodulated, for. B. the received signal MS 13th The FM intermediate frequency carrier (f _IF = 10.7 MHz) is then frequency-modulated and the frequency-modulated signal is inserted into the first baseband BB 1 after a further frequency conversion as a tone baseband signal BS 13 . Of course, it is also possible to insert a converted radio broadcast signal into the distribution signals at a broadband distribution point.

The digitized radio broadcast signals of a baseband can as a digital signal over all suitable digital channels and between different facilities. The Use of the invention is useful wherever a larger Number of radio broadcast signals to be transmitted. You own net is therefore, for example, for transmission between different those broadcaster receiving stations and distribution points band network. Of course it is also possible to use the digital transmit signals directly to the subscriber, who then transfers the order must set in analog signals.

In order to avoid the so-called stuffing jitter, synchronous transmission of the digital signals should take place in multiplex operation . A variant of the invention is shown in FIG . In this, there is no implementation of individual VHF reception signals, but the implementation of entire frequency subbands ( FIG. 5). In order to implement a frequency sub-band, in this embodiment the series connection of a first receive frequency converter EU 1 , a first intermediate frequency converter ZFU 1 and a first analog-digital converter AD 1 is provided. The digital signal DS 11 output by the first analog-digital converter AD 1 is transmitted via the multiplexing devices MUX and DMUX . The conversion back to the VHF range takes place via the series connection of a first digital-to-analog converter DA 1 , a first baseband converter BBU 1 and a first intermediate-frequency converter ZRU 1 .

The entire FM range is divided into 3 frequency sub-bands FT 1 , FT 2 and FT 3 ( Fig. 5), which are digitized and transmitted separately. At the distributor output AV , the three converted frequency subbands are combined to form the original FM range. In the specified exemplary embodiment, an intermediate conversion of each frequency subband FT 1 , FT 2 , FT 3 of the FM frequency range f _u into intermediate frequency signals ZFS 1 ,. . . of the video intermediate frequency range f _V , since the necessary bandpasses are already available here. The Fre quenz subbands FT 1 to FT 3 and the intermediate frequency signals are each implemented in baseband signals BS 1 , BS 2 , BS 3 of the basebands BB 1 , BB 2 , BB 3 , which are here between about 0 Hz and 7 MHz. This frequency range is selected so that a color television signal can also be converted into the baseband range, the image carrier frequency being 1.25 MHz. Each base band signal BS 1 , BS 2 , BS 3 is sampled closed and digitized. An 8-bit or 9-bit resolution is possible. The sampling frequency is chosen so that the standard bit rate of 139 264 kbit / s is generated again. Four digital signals DS 1 to DS 4 can be combined and transmitted to form a multiplex signal MS . At the receiving end, each digital signal is first converted back into a baseband signal and then converted into the FM range. Here, the conversion can also be carried out again over the video intermediate frequency range, the intermediate frequency signal ZFS 1 corresponding to the baseband signal BS 1 . The three frequency subbands are again combined to form the FM range.

A disadvantage of the implementation of frequency subbands is that the FM reception signals cannot be processed individually nen.

In Fig. 6 block diagrams of the receive intermediate frequency converter are shown. The first receive intermediate frequency converter EZU 1 is suitable for converting VHF receive signals. In addition, a receiving intermediate frequency converter EZA 1 is shown for on the modulus-modulated signals, which first demodulates the received signal and then generates a frequency-modulated signal which is converted from the intermediate frequency range to the baseband range.

In Fig. 7, a receive converter is shown, as it is used in the circuit diagram of Fig. 4. It contains an input part ET , which first converts an FM sub-range into the Vi deo intermediate frequency range f _V. The intermediate frequency signal is band-limited, amplitude-limited and regulated in an intermediate frequency section ZFT . The intermediate frequency signal ZFS 1 is converted into the baseband range in a converter part UT . The baseband signal BS 1 is fed to the first analog-to-digital converter AD 1 in accordance with FIG. 5. Apart from the implementation of the signals received on the amplitude modulation, demodulation and renewed modulation of the signals is not necessary. Losses in quality are avoided here.

Claims (10)

1. A method for digital transmission of Hörrundfunkksigna len over broadband channels, in which a frequency conversion of an individual radio broadcast signals into a frequency band, which is sampled closed, converted into a digital signal ( DS 1 ,...) And converted and at the receiving end a Um the digital signal ( DS 1 ,...) is converted into analog signals, characterized in that
that FM radio broadcast signals (US 1 , US 2 ,...) individually from the intermediate frequency position (f _IF ) in sound baseband signals (BS 11 , BS 12 ,...) with different carrier frequencies of basebands ( BB 1 , BB 2 ,...) with a lower frequency range (0.2 MHz to 6.2 MHz),
that all sound baseband signals (BS 11 , BS 12 ,...) each of a baseband ( BB 1 ) are sampled and converted into a digital signal (DS 1 )
and that on the receiving side the digital signal (DS 1 ,...) is converted back into sound baseband signals ( BS 11 , BS 12 ,...). 2. The method according to claim 1, characterized in that amplitude-modulated short, medium and long-wave radio broadcast radio signals (KML) are first converted into frequency-modulated signals and then also converted into sound baseband signals ( BS 13 ). 3. The method according to claim 1 or claim 2, characterized featured, that everyone received when sampling the sound baseband signals Sample is quantized with 9 or 10 bits. 4. The method according to any one of the preceding claims, characterized in that a channel spacing of the sound baseband signals ( BS 11 , BS 12 ,...) Of 400 kHz is provided. 5. The method according to any one of the preceding claims, characterized in that a plurality of digital signals ( DS 1 , DS 2 , DS 3 , DS 4 ) are combined to form a multi-plex signal. 6. A method for the digital transmission of radio broadcast signals via broadband channels, in which a frequency conversion of the radio broadcast signals into a frequency band is carried out, which is sampled closed, converted into a digital signal ( DS 1 ,...) And transmitted and in which a reception conversion of the Digital signal ( DS 1 ,...) In analog signals, characterized in that
that the FM range is divided into at least three frequency subbands ( FT 1 , FT 2 , FT 3 ),
that FM radio broadcast signals ( US 11 , US 12 ,...) of each frequency sub-band ( FT 1 , FT 2 , FT 3 ) in sound baseband signals ( BS 11 , BS 12 ,...) of a baseband ( BB 1 ) with low frequency range are implemented
that the sound baseband signals ( BS 11 , BS 12 ,...) of each baseband ( BB 1 , BB 2 , BB 3 ) are sampled and converted into digital signals ( DS 1 , DS 2 , DS 3 ),
that the digital signals ( DS 1 , DS 2 , DS 3 ) are combined and transmitted to form a multiplex signal ( MS) and
that the multiplex signal at the receiving end is divided into the digital signals ( DS 1 , DS 2 , DS 3 ), the baseband signals ( BS 11 , BS 12 ,...) containing analog baseband signals ( BS 1 , BS 2 , BS 3 ) are converted back and implemented in the FM range. 7. The method according to claim 6, characterized in that the sampled tone baseband signals (BS 11 , BS 12 ,...) Are encoded with 8 or 9 bits. 8. The method according to claim 6 or claim 7, characterized in that the VHF radio broadcast signals ( US 1 , US 2 ,...) In frequency bands first in the video intermediate frequency range ( f _V ) are converted and then in the baseband position ( BB 1 , ... ) Are implemented. 9. The method according to claim 8, characterized in that the base band signals ( BS 1 , BS 2 , BS 3 ) are converted back into FM radio broadcast signals over the video intermediate frequency range ( f _V ). 10. The method according to claim 5 or one of claims 6 to 9, characterized in that the digital signals ( DS 1 , DS 2 , DS 3 ) are transmitted synchronously.