CS273156B2 - Central communication equipment with district antenna array - Google Patents

Abstract

The solution lies in the fact that the reverse for reverse operation, connected via the local antenna system, with the operation frequency band that lies outside the band of the local antenna system, is created between the extension stations (2) and central station (1) and the outputs of the chain for reverse operation, which are connected to the extension stations via the directionally bound adding elements (7) and adding filters (3,6), are connected with the adding filter (14) of the main line (19) of the central station (1) when avoiding the units that take part in the signal transmission in the main direction, while the adding filter (14) of the main line (19) is equipped with an output that is assigned to the chain for reverse operation. The solution can be used for organization of information processing between the central station (1) and arbitrary extension station (2) and between two arbitrary stations (2).<IMAGE>

Description

(54)

Central communication equipment with a district antenna system

The solution consists in that between the sub-stations (2) and the main station (1) a reverse-link chain is provided via a precursor antenna system with an operating frequency band outside the precursor antenna band and the reverse-chain inputs of the sub-stations connected to the sub-stations via directionally coupled addition elements (7) and addition filters (3, 6) are coupled to an addition filter (14) of the main line (19) of the main station (1) bypassing units involved in the main signal transmission, the main addition filter (14) the line (19) is provided with an output assigned to the return chain.

The solution can be used to organize information processing between the head station (1) and any sub-station (2) and between two arbitrary sub-stations (2).

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a central communication apparatus with a district antenna system comprising a headend in which a television and / or FM receiver is provided, the output of which is connected to a first census input and subnetworks. a main amplifier, a first amplifier, the input of which is connected to the first output of the broadband amplifier and the outputs are subscriber outputs of the sub-station.

Precision antenna systems are used to provide television and FM broadcasts in cities, towns and villages. Precinct antenna systems are formed from one main station and several sub-stations connected to this via the main line. The slave stations may be connected to the main station in a star or chain arrangement. the main station antennas are connected via the television and VHF channel units to the broadband census stages, which in turn send signals to the main line. The slave stations are equipped with a broadband amplifier, the outputs of which are connected to the slave amplifier and, in associated systems, to the main line from the slave station.

Perimeter antenna systems connect buildings and apartments to each other in relatively densely populated areas.

Because in densely populated municipalities the creation of a connection network with lines requires considerable investment, attempts have also been made to use district antenna systems for other purposes, thus avoiding the need for new investments to expand connections. Since district antenna systems are originally intended to transmit radio channel signals, in particular television channels in the direction from the main station to the sub-station, this direction being referred to as the main direction, other uses are also based on the use of television channels.

This includes, for example, text-based systems operating on various principles and coin program systems introduced in the United States, where subscribers can choose from telephone exchange programs.

The disadvantages of all these solutions are, in particular, that the information can only be received through the district antenna system in the direction from the main station to the subscribers, i.e. in the main direction, and the signal transmission parameters are also limited by the program transmission system. Thus, there is no known communication system in which an additional information connection can be established between two arbitrary branches of the district antenna system without any restrictions, and also reverse operation via the existing district antenna system is not possible.

The above-mentioned disadvantages of the prior art are largely overcome by a district communication system with a district antenna system comprising a headend in which a television and / or VHF receiver is arranged, the output of which is connected to a first census subdivision and with sub-stations, connected by a coaxial cable to the headend output, and in each slave station there is a wideband amplifier, a first amplifier whose input is connected to the first wideband amplifier output, and the outputs are subscriber outputs of the slave station. system and extension of functional possibilities by connecting arbitrary participants to the main station is equipped with a pilot return signal generator, a third addition filter, a frequency converter, a mixer and a fourth amplifier wherein the third summation filter, frequency converter, mixer, and fourth amplifier are cascaded between the output of the second adder and the second input of the second adder; the third addition filter is the corresponding cable inlets and outlets of the main station, each subsidiary station being provided with a first addition filter, a second addition filter.

a second amplifier, a third amplifier, a first adder, a n modulator, and a demodulator, wherein the high frequency output of the first crosslink filter is connected to a broadband amplifier input whose second output is connected via a second additive filter to the first input of the first crosslinker the amplifier is connected to the interconnected inputs of the demodulators whose outputs are the information outputs of each slave station, and the first adder and the first amplifier are connected in series between the outputs of the n modulators whose inputs are the information inputs of each slave station and the low frequency input of the first crosslinker and the corresponding inputs; the outputs of the first crosslink filter and the second crosslink filter are the corresponding cable inputs and outputs of each slave station and are connected to the corresponding inputs and outputs of the main station and slaves h stations.

In particular, the advantages of the device according to the invention are that it allows the transmission of information from subscribers to the headend as well as the establishment of an information link between two arbitrary taps of the district antenna system.

The basic idea of the invention is that with the help of addition filters and addition members, a connecting network of district antenna systems is created to form the information chain not only in the main direction, i.e. from the main station to the secondary station, but also in the reverse direction, to the headend by circumventing certain system units involved in the main direction signal transmission, the band of operating frequencies of this information chain being outside the band of operating frequencies of the district antenna system.

The invention will now be described in more detail with reference to the accompanying drawing, in which a circuit structure of a central communication apparatus with a district antenna system according to the invention is schematically illustrated.

The central communication apparatus with a district antenna system consists of a head station 1 and sub-stations 2-1 to 2-n, each comprising a first addition filter 3, a broadband amplifier 4, a first amplifier 1, a second addition filter I, a adder T, the third amplifier 8, the second amplifier 11, the modulators 10 and the demodulators 11. The head station 1 comprises a television and / or a VHF signal receiver 12, an adder 13, an adder filter 14, a frequency converter 15, a mixer 16, an amplifier 17 and a pilot 18 the reverse signal.

The second sub-station 2-2 is connected to the main station 7 via the first sub-station 2-1. The sub-stations 2-1 to 2-n can be connected in a star or cascade manner to the head station JL. The main station 7 is connected to the sub-stations 2-1 to 2-n by main lines 19-1 to 19-n, for example by a coaxial cable.

In the headend 1, the input 21 of the television and / or VHF signal receiver is connected to the antenna 21, the output of which is connected to the first input of the second screening member 13. Cascading of the third screening filter 14, frequency converter 15 is connected to the output of the second screening member. a mixer 16 and a fourth amplifier 17, the output of which is connected to the second input of the second cross-linking member 13. The outputs of the pilot 18 reverse pilot generator are connected to the second inputs of the frequency converter 15 and the mixer 16. The other inputs and outputs of the third crosslink filter 14 are coupled to the respective inputs and outputs of the sub-stations 2-1 to 2-n. Each sub-station 2 is formed by a first summation filter 3, the first inputs and outputs of which form the inputs and outputs of the sub-station 1, and the second output of which is connected to the broadband amplifier input 4, connected further by its first output to the second amplifier input by its second cascade connection. the second summing filter 1, the first cross-linking member 7 and the first amplifier 5, the output of which is connected to the second input of the first summing filter 31. The third output of the broadband amplifier 4 is connected via the third amplifier 13 to the common input n of the demodulators 11, while the outputs n of the modulators 10 are connected to the second inputs of the first cross-linking element 7.

The central communication equipment with a district antenna system shall operate as follows:

In an exemplary embodiment, a computer is provided near the n-th sub-station 2-n, to whose outputs the first baseband signal inputs 20 are connected and to the inputs the second baseband signal inputs 21 are connected.

For example, a traffic light system to be used in alternation with a computer connected to the n-th sub-station 2-n is connected to the second sub-station 2-2. The following steps will be taken to establish the connection:

To the first baseband signal input 20, an information output of the traffic semaphore system is connected with baseband signals. These signals are applied to a corresponding modulator 10 where they modulate a carrier in a baseband from 4 to 25 MHz in a certain modulation manner. The modulated carrier goes through the first addition member T to the third amplifier 2 / where it is amplified to the corresponding level. The return signals are then fed via a first summing filter 2 to a second main line cable 19-2 which connects the second sub-station 2-2 with the first sub-station 2-1.

Via the main line cable 19, signals arrive at the second addition filter 2 of the first secondary station 2-1 and from there through the first addition member 2 »the third amplifier 2 ^{and the} first addition filter 2 to the first main line cable 19-1 connecting the first secondary station 2- 1 with a main station 2 · 19-1 cable through the first main line signals come reverse traffic to the main station 2 ^{»in Naz} via the third adder 14 of the filter 15 come to the transducer frequency. In the frequency converter 15, these signals are mixed with the pilot signal 18 of the reverse run pilot. Then the signals are converted to the frequency range from 295 to 320 MHz. This signal is applied to the mixer 16. Furthermore, the mixer 16 receives a signal from the reverse run pilot generator 18 with an amplitude such that at the output of the mixer 16 the amplitude of the reverse run pilot generator 18 is 11 dB higher than the amplitude of the reverse run signal. falling in the frequency range from 295 to 320 MHz. This generally applies to all reverse signals.

Such signal transmission of the reverse run pilot and information run back generator 18 is necessary for later demodulation.

From the output of the mixer 16, a signal passes through a fourth amplifier 17 to a second adder 13, to whose second input also a signal from a receiver 12 of TV and / or VHF signals comes.

Thus, at the output of the second adder 13, the TV and VHF signals, the signals of the pilot back signal generator 18, and the mixed return signals in the frequency band from 295 to 320 MHz appear. This summation frequency spectrum continues further through the third summation filter 14 to the n-th main line cable 19-n which connects the main station 2 to the n-th sub-station 2-n.

In the nth sub-station, the first summing filter 2 is designed to pass frequencies from 40 to 320 MHz only in the main direction to the broadband amplifier 6. At the output of the broadband amplifier 2 of the n-th sub-station 2-n, the signals are divided into three directions. In the main branch, they pass through the second summing filter 2K to the next sub-station 6.

The other two outputs of the broadband amplifier 8 of the nth sub-station 2-n are connected to the first amplifier 2 and the second amplifier 2, the first amplifier 2 transmitting to the subscribers the signals of the TV and FM channels and the second amplifier 2 serving to reverse the information traffic.

The signals from the second amplifier 2 come to the demodulators 12. The demodulators 11 are formed in two parts. The first part converts the frequency range from 295 to 320 MHz to the frequency range from 4 to 25 MHz with the help of the pilot run-back signal generator 11. This mixture with the pilot runback signal at the head station 2 allows greater variation in the frequency of the pilot runback generator 18 in the demodulator 11 and makes the oscillator in the first part of the demodulators 11 unnecessary. The second part of the demodulators 11 produces baseband signals corresponding to the modulation operation of the reverse run signal.

For example, if the second portion of the first demodulator 11 of the nth sub-station 2-n is configured to receive the signal of the first modulator 10, the corresponding second baseband signal input 21 will accurately display the information signal supplied through the first baseband signal input 20, between the two signals. there is only a difference in the delay caused by the passage of the said elements.

The information provided by the traffic light system connected to the second sub-station 2-2 is thus transmitted via the main station 6 to the input of a computer arranged at the sub-station 2.

The computer can evaluate this information according to its program. If it finds, on the basis of the information received, any irregularities in the operation of the traffic light system, it may issue instructions in the manner in which the notified signals are transmitted.

A possible signal path is, for example, from the first baseband signal input 20 of the n-th sub-station 2-n through the modulator 10, the first adder 5, the third amplifier 8, the first add-on filter 3 of the n-th sub-station 2-n, the nth cable. Main line 19-n, third adder filter 4, frequency converter 15, mixer £ 6, fourth amplifier 17, second adder member 3, third adder filter 14, first main line cable 19-1, first adder filter £ first minor station 2-1, wideband amplifier 4, second additive filter 8, second main line cable 19-2, first additive filter 8 of second slave station 2-2, broadband amplifier 4, second amplifier 8 for demodulators 11.

However, if the second demodulator 11 is ready to receive the signal of the second modulator 10, the information signal transmitted through the first baseband signal input 20 appears at the second baseband signal output 21.

This implies that in this district antenna communication system numerous other information can be transmitted in addition to the television and FM signals and that connections can be established between two arbitrary points of the district antenna system in both directions.

Claims (1)

SUBJECT OF THE INVENTION Central communications equipment with a district antenna system comprising a headend containing a television and / or VHF receiver, the output of which is connected to the first input of the adder and to the sub-stations, the first of which is connected by coaxial cable to the headend output; a broadband amplifier, a first amplifier whose input is connected to the first broadband amplifier output, and the outputs are subscriber outputs of the secondary station, characterized in that the main station (1) is provided with a pilot (18) pilot back signal generator, a third amplifier an adder filter (14), a frequency converter (15), a mixer (16) with a fourth amplifier (17), wherein the third adder filter (14), a frequency converter (15), a mixer (16) and a fourth amplifier (17) are connected cascaded between the output of the second adder about the member (13) and the second input of the second addition member (13), the reverse run pilot generator (18) is connected between the second inputs of the frequency converter (15) and the mixing member (16) and the corresponding inputs and outputs of the third addition filter (14) are corresponding cable inputs and outputs of the headend (1), each slave (2) being provided with a first addition filter (3), a second addition filter (6), a second amplifier (9), a third amplifier (8), a first addition member ( 7), n modulators (10) and demodulators (11), the high frequency output of the first summing filter (3) being connected to the input of a broadband amplifier (4), the second output of which is connected via the second summing filter (6) to the first input of the first summing the third output of which is connected via the second amplifier (9) to the interconnected inputs of the demodulators (11) whose Ί CS 273156 stup2 stages are the information outputs of each slave station (2), and the first adder (7) and the first amplifier (5) are connected in series between the outputs n of the modulators (10) whose inputs are the information inputs of each slave station (2), and the low frequency input of the first addition filter (3), and the corresponding inputs and outputs of the first addition filter (3) and the second addition filter (6) are the corresponding cable inputs and outputs of each slave station (2) and connected to the corresponding inputs and outputs of the headend (1) and substations (2).