CZ2015381A3 - Device for group reception and distribution of television and broadcast programs - Google Patents

Abstract

The device (13) for receiving and distributing television and radio programs and data signals (52) includes a satellite multiswitch (1) provided with at least two satellite inputs (2) for receiving satellite intermediate signals I and at least two subscriber outputs (5) for connection the subscriber terminal device (17). The apparatus (13) further comprises an output (28) and an input (10) for connecting an external decoder (8) to which the signal modulator (21) is connected. The multiswitch (1) is provided with a terrestrial signal input (7) to which the combiner output (20) is connected to merge the signal from the modulator (21) and the terrestrial antenna (12). In a preferred embodiment, the device (13) is provided with an Ethernet switch (55) which is coupled to a plurality of data signal combiners (48), wherein the combiners (48) are connected in individual subscriber lines. The device (13) for group reception and distribution of television and radio programs allows the use of existing coaxial star-type distributions for data communication (52) and distribution of television and radio programs.

Description

Field of technology

The invention relates to a device which enables the reception and distribution of television and radio programs for a group of subscribers, with the possibility of transmitting data communication.

Prior art

At present, television and radio programs are broadcast by terrestrial broadcasting from a group of transmitters located in specific places in the area, or by cable lines, which are, however, largely the prerogative of intensive urban development, or by satellite broadcasting from geostationary satellites in Earth orbit. . With the growing supply of programs, the popularity of receiving satellite broadcasts is increasing among users, as this broadcast is available over a large area and provides a wide range of broadcast programs.

Signals transmitted from a satellite can be received on Earth using satellite dishes, and the intensity of the received signal is different at different places on the earth's surface. The visualization of the covered part of the earth's surface by a satellite signal is the so-called reception diagram. Satellite-based satellite transmission is strongest at the center of the reception diagram and weakest at its edge. The receiving satellite antennas used at the outer edge of the reception diagram must naturally be larger than the antennas used at the center of the reception diagram.

For the transmission of satellite signals, mostly centimeter waves are used, ie a frequency band from approximately 3 GHz to 30 GHz. One of the reasons for using such short radio waves is the negative effect of cosmic noise for frequencies of 1 GHz and lower. At high frequencies above 15 GHz, the signals are in turn greatly attenuated by water vapor in the atmosphere and oxygen molecules. Signals, aka oscillations of electromagnetic radiation, transmitted from satellites in orbit have a certain permanent orientation in space. Usually, this radiation is linearly polarized, either vertically or horizontally.

However, some satellites also emit circularly polarized radiation, where the orientation of the oscillations of electromagnetic radiation rotates around the direction of radiation propagation, either clockwise or vice versa.

A typical satellite receiving system consists of a parabolic antenna that reflects the incoming satellite signal and concentrates it in focus in front of the parabolic surface of the antenna. At the focus of the satellite dish is a feedhorn that picks up the signals reflected by the antenna and transfers them to another part of the satellite receiver system, the low-noise amplifier (LNA). In a low-noise amplifier, the signals are amplified and fed to a converter, where the frequency of the input signals is converted to an output frequency, the so-called first satellite intermediate frequency. The value of the first satellite intermediate frequency is given by the difference between the frequencies of the local oscillator of the converter and the input signals of the antenna.

The output intermediate frequency signals are propagated from the converter via a line, eg a coaxial cable, to the satellite receiver. The parts described above, i.e. the feedhorn, the LNA and the converter, are usually integrated into one block called the LNB. For currently manufactured LNBs, the frequencies of the local oscillator are determined according to the universal standard: 9.75 GHz for reception in the lower band and 10.60 GHz for the upper band. Inside the LNB there is either one oscillator with a frequency of 9750 MHz, with such an LNB it is then possible to receive only signals in the lower frequency band, or there are two oscillators in the LNB, the first with a frequency of 9750 MHz and the second with a frequency of 10600 MHz. universal LNB, which allows reception in both the upper and lower band. It is then possible to select (switch) the desired polarization and frequency band from the satellite receiver.

A standard receiving satellite system, which has a so-called single LNB in the focus of the antenna, can be used to receive television programs with one satellite receiver, ie usually also with one television receiver. To connect two or more satellite receivers to one LNB, i.e. to one satellite antenna, it is necessary to use another type of LNB, whereby a device called a multiswitch must be connected between the LNB and the satellite receivers.

A multiswitch is a device that is inserted between a converter and a satellite receiver. From the receiver's point of view, the multiswitch behaves as a universal switchable LNB, ie it provides exactly the satellite intermediate frequency, ie the required polarization or frequency band, which the receiver requests with the appropriate control commands. Each receiver connected in a multiswitch system has access to all broadcast programs of the satellite, and this is the main advantage of the multiswitch solution. In the case of multi-satellite transmission, the multiswitch behaves as a set of several LNBs switched by the switch relative to the receiver, with standard commands having access to all programs transmitted by the satellites whose transmission is routed to the multiswitch.

The disadvantage of installations (distributions) with multiswitches is a relatively large consumption of coaxial cable or similar transmission line, because each output of the multiswitch has one cable or line. Another disadvantage is the need to use a satellite receiver at the end of the line for each output of the multiswitch. In addition, if the satellite receiver is not equipped with a command generator compatible with the command receiver in the multiswitch, the user cannot automatically receive satellite programs on his receiver from at least some inputs of the multiswitch, ie from some satellite positions, or also from the corresponding outputs of the satellite receiver. antennas.

Satellite converters (LNBs) with eight to sixteen outputs are known, enabling direct connection of satellite receivers to the LNB. In this case, the satellite multiswitch is directly part of the LNB. However, if a larger number of participants in a given installation (distribution) is to be connected to the satellite antenna or antennas, eg several tens to hundreds, it is necessary to use a separate multiswitch connected to the LNB, or use STA distribution (so-called headend).

Also known are satellite converters (LNBs) with a single output, which allow to connect to a single output with the help of a single coaxial cable or similar RF transmission line up to 24 or even 32 satellite receivers. Similarly, satellite multiswitches or similar devices with a single output are known, which make it possible to connect up to 24 or even 32 satellite receivers to it with the aid of a single coaxial cable or similar RF transmission line (e.g. patent application US 2011/0296470 A1).

The disadvantages of the above solutions are that these solutions allow to receive in a given installation (distribution) and at a given time only a limited number of satellite transmission channels, maximum 32, and also the number of received satellite positions or connected LNBs is limited. Another disadvantage, similar to standard multiswitches, is the need to use a satellite receiver for each distribution party, which must also be specially adapted satellite receivers capable of being connected to a single line with other satellite receivers of the other participants.

In the case of STA (headend) distribution for a larger number of subscribers - tens or hundreds, usually satellite broadcast channels received from a satellite antenna or antennas are first amplified and converted by LNB to the first satellite intermediate frequency, which is usually in the band from 950 MHz to 2150 MHz. Furthermore, the individual satellite broadcast channels are demodulated and possibly also decoded and subsequently modulated again and converted into a terrestrial television band ranging from 5 MHz to 862 MHz. Originally digitally modulated satellite programs are thus converted in the terrestrial television band to a digital DVB-T format signal, or even converted to a classic analog signal in PAL, NTSC, etc. Subsequently, the signals in the terrestrial television band are split or branched to individual participants in the installation ( divorce). Both the DVB-T signal and the analogue television signal can then be processed directly in the television into video and audio, as most current televisions available on the market can process both analogue and digital DVB-T signals. If the television cannot do this, it must be equipped with a set-top box.

Recently, STA distributions have been increasingly used, where after demodulation and eventual decoding of satellite signals and their conversion into a data stream, this data is disseminated over a computer network of the Ethernet type. This is IPTV or television via the Internet protocol. In this case, video and audio reception is possible either via a personal computer or a special set-top box (receiver) connected to the TV, or video and audio can be received directly on the "smart TV". If you use a Wi-Fi router connected to an Ethernet network, it is possible to broadcast TV image and sound wirelessly and receive it with the help of tablets, mobile phones and similar devices.

The disadvantages of the STA distribution solution are that with the conversion of satellite broadcast channels into the terrestrial television band, or with the help of IPTV, it is possible, unlike a satellite multiswitch, to distribute only a limited number of programs to individual participants in the installation or distribution. the whole spectrum received by satellite antenna or antennas. This is due to the limitation of the bandwidth of the terrestrial television band, which is in the range from 5 MHz to 862 MHz, as well as the limitation of the data rate that can be transmitted in the computer network in the case of STA distribution over the computer network. Although there are STA connections, where a satellite multiswitch is used, subsequently only one or a maximum of several satellite broadcast channels are processed from each output of the multiswitch, which are then transferred to the terrestrial television band and split or branched to individual participants in the installation (distribution), or are converted to a data stream transmitted over a computer network using IPTV.

From the point of view of Internet distribution in houses with many residential units, it is known that in earlier times coaxial cables were used for the construction of local computer networks of the Ethernet type created according to the 10BASE5 and 10BASE2 standard. The networks constructed in this way reached transmission speeds of 10 Mbit / s.

In the following years, well-known data transmission standards were replaced by new data transmission standards 10BASE-T, 100BASE-TX - Fast Ethernet, which use twisted metallic pairs for data transmission, the so-called UTP cable (Unshielded Twisted Pair). Coaxial cables continued to be used to mediate the reception of television broadcasts.

In new apartment buildings, both television and data distribution systems are currently being built in a star topology, so it is possible to use a common physical medium for both technologies. A well-known solution is the conversion of television broadcasting into data packets (IPTV - Internet Protocol Television), which are then transmitted over common UTP cables.

The disadvantages of the above solution are that the existing buildings have built coaxial distribution lines for television broadcasting and UTP lines must be laboriously completed. Residents of buildings do not want to pay high acquisition costs and do not want to limit their comfort by renovating lines. Another disadvantage of IPTV-based solutions is the limited program offer.

There are adapters - modems that modulate digital data into a dedicated high frequency band, which can then be shared with other services transmitted by coaxial cable. This technology is known as Ethernet-over-Coax (EoC). The disadvantage of this solution is that the modulation procedures used in the existing devices of the EoC system are relatively complex and the resulting high purchase price of adapters - modems prevents a more massive spread of this technology.

In order to be able to transmit a data signal over a single coaxial cable, it is necessary to provide two-way data communication. The 10BASE-T and 100BASE-TX standards assume two metallic two-wire pairs for data transmission - one pair for transmission and the other pair for reception, while the coaxial cable consists of only one pair of wires - the middle wire and the shield.

Bidirectional data communication is possible if the transmitting and receiving pair is connected to the coaxial cable via a special circuit, the so-called duplexer. The connection used is based on the so-called telephone switch, which was used in analog telephone sets to connect a microphone and speaker to a two-wire subscriber line. The duplexer allowed you to speak and listen at the same time, while ensuring the electrical separation of the microphone from the speaker, so that there was no unwanted connection between them.

In order to enable the mutual coexistence of the data channel and other necessary signals (television broadcasting) transmitted by coaxial lines, a so-called diplexer is used, which allows the simultaneous existence of multiple signals in one line. The analog radio signal ranges from 88 MHz to 108 MHz, and the 100BASE-TX data signal has a spectrum ranging from 125 MHz, which means that it is not possible to transmit analog radio and data signals simultaneously.

The television signal ranges from 470 MHz to 860 MHz, so they can be transmitted over a coaxial cable at the same time. Furthermore, satellite television broadcasting, which uses the frequency band above 950 MHz and which needs to transmit both direct current and a signaling frequency of 22 kHz by cable, can be transmitted via coaxial cable. It follows that the data input of the diplexer must be provided with a bandpass, while the television input of the diplexer must be provided with a bandpass.

The disadvantages of the distribution of television programs and the Internet according to the above are that if in the case of a house inhabited by a larger population each resident receives TV programs / Internet using their own satellite system / Wi-Fi, the appearance of the house is distorted by individually mounted antennas of different sizes. . Another disadvantage is that each user has to purchase their own receivers and decoders, which must be wired to the antennas, although in many cases the original star distribution of analogue transmission is made in houses using coaxial cables. According to the requirements of the newly used technology, the original wiring in the houses must be reworked, which leads to costs and inconvenience, or the original wiring is not used at all.

The object of the invention is to provide a device for group reception and distribution of television and radio programs with the possibility of data communication, which would allow the use of existing star wiring in houses with many residential units for transmission of television programs from a single receiving device and data transmission for Internet communication according to 10BASE standards. -T and 100BASE-TX.

The essence of the invention

The stated object is solved by means of a device for group reception and distribution of television and radio programs by means of the present invention.

The device for group reception and distribution of television and radio programs comprises at least one satellite multiswitch. The multiswitch is equipped with at least two satellite inputs for receiving I. intermediate IF signals and at least two subscriber outputs for connecting at least one terminal device from the group TV receiver, satellite receiver, DVB-C cable TV receiver, DVB-T or DVB-T2 terrestrial TV receiver .

The essence of the invention is that the device further comprises at least one terrestrial reverse link output and at least one terrestrial reverse link input for connecting a terrestrial reverse link decoder. It further comprises at least one signal modulator and at the same time the multiswitch is provided with at least one terrestrial signal input. An input of a terrestrial reverse link decoder is connected to the terrestrial reverse link output of the multiswitch, and a modulator is connected to the terrestrial reverse link decoder output via a terrestrial reverse link input. The output of the signal modulator is further connected to the input of the terrestrial transmission signal of the multiswitch.

Alternatively, the apparatus further comprises at least one terrestrial reverse link output and at least one terrestrial reverse link input for connecting a terrestrial reverse link decoder. It further comprises at least one signal modulator, at least one terrestrial signal splitter and at least one terrestrial frequency band combiner and an I. satellite intermediate frequency connected to the subscriber output of the multiswitch. The combiner is equipped with an output for connecting a terminal device. At the same time, the input of the terrestrial return decoder is connected to the output of the multiswitch reverse link decoder and a modulator is connected to the output of the terrestrial reverse link decoder via the terrestrial reverse link input. The output of the modulator is connected to the input of the splitter and the output of the splitter is connected to the input of the combiner. The output of the combiner is connected to the subscriber's terminal equipment.

The device allows the simultaneous distribution of programs broadcast by satellite broadcasts among the connected subscribers, without the subscribers necessarily having to be equipped with satellite receivers. The original star-shaped distribution of the coaxial line in a residential building can be used, while a limited number of antennas is sufficient to receive the transmission.

In another preferred embodiment of the device according to the invention, the device comprises at least one signal combiner for combining the signal from the modulator and the signal from the terrestrial antenna, the signal combiner inputs being connected to the signal modulator and the terrestrial antenna and the combiner output connected to the multiswitch terrestrial input; the output of the combiner is connected to the input of the hub.

If subscribers want to receive terrestrial broadcasts at the same time as the satellite broadcast, a combiner is added to the device. It combines a satellite broadcast signal from a modulator with terrestrial broadcasts, and subscribers connected to the device can watch programs with almost no restrictions. The minimum restriction occurs if one of the DVB-T terrestrial reverse link decoders is a decoder. Subsequently, the device sends an analog signal in the format of eg PAL to the subscribers' televisions, which decodes any recent television.

In another preferred embodiment, the device according to the invention comprises at least one signal-passing multiswitch control command generator which is connected between the multiswitch groundband feedback output and the terrestrial reverseband decoder input. The signal generator controls the multiswitch function, in particular the satellite polarization signal reception.

In the most common embodiment, the reception setting allows either horizontal or vertical polarization of the transmission.

In another preferred embodiment of the device according to the invention, the connection between the output of the signal combiner and the input of the terrestrial signal of the multiswitch is disconnectable, or the connection between the output of the signal combiner and the input of the signal splitter is disconnectable. Disconnecting the combiner limits the device's function to a known multiswitch in situations that require this condition.

In another preferred embodiment of the device according to the invention, the terrestrial reverse link decoder is an integrated part of the device, or an external device. If the decoder is an integrated part, the function of the device is reliable, no stranger has access to the decoder settings, and the device is compact. External decoders are available devices that can be used individually, but can be used in a device loopback.

In another preferred embodiment of the device according to the invention, the terrestrial feedback output is provided with a high-frequency connector or a high-frequency terminal, and the terrestrial feedback input is provided with at least one connector of at least one type from the group RCA, CINCH, USB, HDMI, 8P8C. Connectors built into the housing of the device, for example, enable user-friendly connection of external decoders.

In another preferred embodiment of the device according to the invention, the device is provided with at least one modified Ethernet switch, which comprises at least one transceiver of PHY circuit for data communication according to 10BASE-T or 100BASE-TX standard with at least one duplexer for transmission of unmodulated data signals in baseband by coaxial line connected to the PHY circuit.

The duplexer enables data transmission via a coaxial cable, so it is possible to simultaneously use the star-shaped distribution of coaxial lines in the house not only for the distribution of programs, but also for the data connection.

The invention includes a duplexer for transmitting unmodulated data signals in the baseband by a coaxial line connected to a PHY circuit for data communication according to the 10BASE-T or 100BASE-TX standard. The duplexer includes two transformers with three terminals at each winding, and at least one balancing dipole.

The invention consists in that the primary winding of both transformers is connected via at least four terminals to the input and output interface MDI of the PHY circuit, the secondary winding of the first transformer is grounded with one terminal and connected to the middle terminal of the secondary winding of the second transformer; the secondary winding of the second transformer is connected to the middle conductor of the coaxial line and the second end terminal is grounded via a balancing dipole whose impedance equals the impedance of the connected coaxial line, or the end terminals of at least one of the secondary windings of the transformers are reversed.

The duplexer allows the transmission of data connection signals using a coaxial cable. It eliminates the need to replace cables and makes it easier to establish a data connection to subscribers in homes with existing star-shaped television broadcasting. The purchase price of the duplexer is low while maintaining the guarantee of transmission quality.

The advantages of the device according to the invention are that it does not require the installation of a large number of antennas on subscribers' houses, it distributes programs to a large group of subscribers at once, it does not require laborious reworking of existing coaxial wiring in houses, subscribers can connect TVs without the broadcast is decoded in the device and transmitted to the subscribers' televisions in an acceptable format. The current possibility of providing a data connection through existing coaxial cable distribution systems is a huge financial saving.

Explanation of drawings

The present invention will be further elucidated in the following figures, where:

Fig. 1 shows a schematic illustration of a classic set for individual reception of satellite broadcasting, Fig. 2 shows a schematic illustration of a device with a combiner connection to the input of a multiswitch, Fig. 3 shows a schematic connection of a device with a combiner connection to the output of a multiswitch via a hub and secondary combiner; shows a schematic connection of a device for receiving transmissions from one satellite, Fig. 5 shows a schematic connection of a device for receiving transmissions from several satellites simultaneously, Fig. 6 shows a schematic connection of a duplexer, Fig. 7 shows a block diagram of the duplexer function.

Example of an embodiment of the invention

It is to be understood that the specific embodiments of the invention described and illustrated below are presented by way of illustration and not by way of limitation. Those skilled in the art will find, or be able to ascertain using routine experimentation, more or less equivalents to the specific embodiments of the invention described herein. These equivalents will also be included within the scope of the following claims.

Fig. 1 shows a standard set for receiving a satellite broadcast. The set consists of a parabolic antenna 4 with a converter 3 and a satellite receiver 14 with a television 17.

Fig. 2 shows a variant of connection of the device 13 with a built-in signal combiner 20 connected via a special output 11 to the input 7 of the terrestrial signals of the multiswitch 1. The device 13 is provided with a group of diplexers 48 and a modified Ethernet switch 55 connected to the data source 52. The data source 52 may be, for example, an optical cable terminated by an ISP's modem. Via coaxial cables, the connection for Internet transmission is routed via socket 16 to computer 53 or to Wi-Fi router 54. A detailed description of the modified Ethernet switch 55 will be described below.

Fig. 3 shows a second possible variant of the device 13, where a terrestrial combiner 20 with a modulated signal from a decoder 8 and a modulator 21 is connected to a signal splitter 26. The outputs of the signal splitter 26 are connected to individual lines passing between the subscriber output 5 of the multiswitch 1 and the subscriber socket 16 for connecting at least one terminal device (satellite receiver 14, cable television receiver 56, television receiver 17). A combiner 27 is connected to the line, which combines the terrestrial frequency band with the I. satellite frequency.

Fig. 4 shows a device 13 intended for the distribution of satellite channels from one satellite position, i.e. from one satellite. The device 13 is shown including connected external satellite antennas 4 and terrestrial antennas 12, television receivers 17, and satellite receivers 14, DVB-T terrestrial television receivers 15, subscriber sockets 16, power supply and the like.

By means of a converter 3 located in the focus of the satellite receiving antenna 4, the signals coming from the satellite are first amplified and then converted to frequency band I. satellite intermediate frequency, which is usually in the frequency range 95050 to 2150 MHz or narrower, but sometimes also 950x up to 2300 MHz or even in the range 900 MHz to 2400 MHz, etc. A given satellite transmits signals with two polarizations, in this particular case vertically polarized and horizontally polarized signals. Both polarizations, or polarities, are conducted by means of two coaxial cables and connecting high-frequency connectors 28 of type F with an impedance of 75 ohms to the satellite inputs 2 of the multiswitch 1, each coaxial cable transmitting signals of only one polarization.

Further, terrestrial signals are received from the terrestrial reception antenna 12. Via the 75 ohm impedance input connector 28 and via the combiner 20, the signals are fed to the multiswitch 1 terrestrial input 7. In the multiswitch 1, the terrestrial television signals are connected to the satellite signals and routed together via the 75 ohm coaxial cables to the satellite signals. receivers 14 from the subscriber outputs 5 of the multiswitch 1. From the terrestrial reverse link outputs 6 of the multiswitch 1, satellite television signals are fed to the terrestrial reverse satellite decoders 8, these satellite receivers = decoders 8 are not a fixed part of the device 13 and are connected to it by interconnecting coaxial cables terminated with high-frequency connectors 28 of type F with an impedance of 75 ohms and by means of interconnecting cables terminated each by three connectors 10 of type RCA (or CINCH) at the output point 9 of the terrestrial reverse link. Two of these CINCH type connectors 10 are for transmitting analog stereo audio signals from the satellite receiver 8 to the analog TV modulator 21 for the left and right audio channels, the third CINCH connector 10 is for transmitting an analog composite video signal from the satellite receiver 8. to the TV modulator

21. The external satellite receivers = decoders 8 used are those which process at the input signals I. satellite intermediate frequencies and equipped at their output with three connectors 10 of the CINCH type for the transmission of analog stereo audio signals and a composite video signal. Connectors 28 and 10 are an integral part of device 13.

The multiswitch 1 can also pass terrestrial signals to its terrestrial feedback outputs 6, but this is not necessary for the functionality of the device 13. Command generators 18 for controlling the multiswitch 1 are arranged between the terrestrial reverse link outputs 6 and the satellite receiver 8. These generators 18 are pass-through for satellite television signals and are each connected to a corresponding satellite receiver 8 by a coaxial cable connected at one end to the input of the satellite receiver 8. and the other end to the RF connector 28 or coupler. Each generator 18 is equipped with a manual two-position toggle switch, the position of this toggle switch determines whether the multiswitch 1 transmits vertical or horizontal polarization satellite signals to its terrestrial feedback outputs 6, i.e. determines which of the satellite inputs 2 of the multiswitch 1 is with the generator 18. interconnected output 6 of the ground connection of the multiswitch 1 is switched. Each of these toggle switches is permanently set to one of the positions, thus also the respective terrestrial reverse link satellite receiver 8 is firmly tuned to one program channel in the selected polarization.

Generator 18 is actually a DiSEqC command generator which communicates with the circuit at the output 6 of the multiswitch 1 ground link by means of DiSEqC commands sent from generator 18 to multiswitch 1 on a carrier frequency of 22 kHz. An AC signal with a carrier frequency of 22 kHz and an amplitude of approximately 0.7 Volt is superimposed on a DC voltage of 13 or 18 Volt supplied from the satellite receiver 8 to its input and further connected by a coaxial cable to the generator 18. DiSEqC command to switch the given output 6 band of the multiswitch to vertical or horizontal polarization is automatically sent from the generator 18 to the multiswitch 1 every time the position of the toggle switch on the generator 18 changes and also after each disconnection and subsequent connection of the satellite receiver 8 to the power supply, more precisely after each disconnection and subsequent connection with a 13 or 18 Volt supply supplied to the generator 18 via a coaxial cable from the satellite receiver 8. When the toggle switch is set to one fixed position and the satellite receiver 8 is permanently connected to the mains, a command for the given polarization is sent from the generator 18 to the multiswitch 1 only once, after the introductory setting the position of the switch during the initial installation of the device 13.

Each of the analog modulators 21 is equipped at its input with three CINCH type connectors and is connected to the respective satellite receiver 8 by means of them and three connecting cables. Each of the connecting cables is two-wire, the first of the connecting cables has one wire reserved for grounding and the second wire for composite video signal transmission, the second and third of the connecting cables have one conductor again reserved for ground connection and the other conductor reserved for transmitting the stereo audio signal of the left channel or the right channel. The modulator 21 receives, via connecting cables from the satellite receiver 8, one PAL baseband television channel and converts the received audio and video signals at its output into one PAL analog television signal transmitted on one fixed-tuned UHF television channel. This signal is sent from the modulator 21 via a high-frequency line with an impedance of 75 ohms and at a fixed frequency in the UHF band to the combiner 20, e.g. from one modulator 21 it is transmitted on channel 30 and from the other modulator 21 on channel 40. The combiner 20 functions as a frequency switch. and combines the two analogue television channels received from the modulators 21 together with the DVB-T channels received from the terrestrial television antenna 12 to the output 11 and further to the input 7 of the multiswitch 1. The two television channels originally received by the satellite antenna 4 and fed therefrom to the multiswitch 1. , are then transmitted together with DVB-T transponders in the terrestrial television frequency band again via a multiswitch 1 to its outputs 5 and from there further to the subscriber television sockets 16 and to the televisions 17. Simultaneously from the satellite antenna 4 and via the multiswitch 1 towards the television the satellite channels received from the antenna 4 are also transmitted to the receivers 17.

The use of external satellite receivers = decoders 8 carries the risk that some of them may enter a fault condition, for example due to a satellite signal decoding error or another software error in the satellite receiver 8 and this error will have to be rectified. In order to eliminate this fault, it is necessary to reset the satellite receiver 8, this can be achieved by disconnecting the satellite receiver 8 from the mains for a certain time and then reconnecting it to the power supply. For this purpose, the device 13 is equipped with an automatic circuit which detects whether a software fault of the satellite receiver 8 has occurred and, when a fault is detected, this automatic circuit subsequently resets the satellite receiver 8 by disconnecting it and reconnecting it to the mains. The external satellite receiver 8 is connected to the mains by means of a mains socket 23, which is a fixed part of the device 13, this socket 23 itself being connected to the mains via a plug 25. The plug 25 thus serves to supply electricity not only to the whole device 13. but also for external satellite receivers 8. The power supply from the plug 25 to the socket 23 can be interrupted by a switch or relay 24 which is controlled by a detector 22. The detector 22 detects the presence of an audio signal on cables transmitting the audio signal between the satellite receiver 8 and the modulator 21. the audio signal is not present for more than 1 minute, i.e. it is most likely that the satellite receiver 8 has failed and is temporarily disconnected from the power supply by means of the switch 24 and is then reconnected to the power supply. This resets the satellite receiver 8 and puts it back into operation.

In the example of a practical embodiment of the device according to FIG. 4, two users are connected to the device 13 via subscriber sockets 16. In addition to the television receiver 17, one of the users is also equipped with a satellite receiver 14, so this user can watch the two originally satellite channels directly on the television receiver 17 as analogue and in the frequency band of terrestrial television. Furthermore, it can monitor all the satellite channels transmitted via the multiswitch 1 with the aid of the satellite receiver 14. A user cannot watch DVB-T channels received from antenna 12 unless his television 17 is equipped with a DVB-T tuner.

The second user can watch the two originally satellite channels directly on the television 17 as well as the DVB-T channels received from the antenna 12. Since his television 17 is not equipped with a satellite tuner or receiver, he is not able to receive any satellite programs broadcast via multiswitch 1 except two already originally mentioned satellite channels.

Fig. 5 shows a device 13 according to the present invention, intended for the distribution of satellite channels from four satellites, or from four satellite positions. Device 13 is again shown including connected external antennas 4 and 12, television and satellite receivers 17 and 14, subscriber sockets 16, power supply, etc. The connection is similar to Fig. 4, but the differences are as follows:

- It is possible to receive 4 satellite positions instead of one, while so-called 4 polarities can be received from each position. The multifocal satellite antenna 4 is equipped in its foci with Quatro type converters 3, which are each equipped with four outputs for the transmission of channels I. of the satellite intermediate frequency, both of the upper and lower frequency band, of both vertical and horizontal polarization.

- To the multiswitch 1, which is part of the device 13, three terrestrial reverse satellite receivers 8 are connected to the terrestrial reverse link outputs 6 instead of two, so the connected subscribers can watch three originally satellite channels converted to terrestrial television channels instead of two, in terrestrial television frequency band. One of the satellite receivers 8 is permanently integrated in the device 13, the other two satellite receivers 8 are external and are connected to the device 13 by connecting coaxial cables terminated with high frequency connectors 28 type F with impedance 75 ohm and by connecting cables terminated by connectors 10. Connectors 28 and 10 are an integral part of the device 13.

- Receivers processing satellite IF intermediate signals at the input are used as external satellite receivers 8 of the terrestrial reverse link. The first of the external satellite receivers 8 is equipped with an interface (connector 10) HDMI (High-Definition Multimedia Interface) according to the standard EIA / CEA-861, which allows transmission of audio and video signals of one satellite HDTV (Highdefinition television) channel in the form of data and the modulator 21 connected to it is connected to the respective satellite receiver 8 at its input via an HDMI connection connector, at its output the modulator 21 provides a DVB-T signal which transmits the original satellite HDTV channel.

- The second of the external satellite receivers 8 is equipped with an interface (connector 10) according to the USB (Universal Serial Bus) standard, this satellite receiver 8 sends audio and video signals of one satellite HDTV channel via data via the USB connection connector 10 to the corresponding digital modulator 21. The given modulator 21 then provides at its output a DVB-T signal transmitting just that originally satellite HDTV channel. Similar to external satellite receivers 8 with USB or HDMI interface in this practical example, a satellite receiver with 8P8C (RJ45) interface according to the IEEE 802 standard could also be used, these interfaces are quite often seen in mass-produced satellite receivers. , as well as the already mentioned HDMI and USB interfaces.

- The third satellite receiver 8, which is a fixed part of the device 13, is equipped with HDMI and is firmly connected to the respective digital modulator 21. The outputs of all three modulators 21 are combined by a combiner 20, which is a frequency switch, into the output 11 together with the signals received. from the terrestrial antenna 12. Thus, both the three originally satellite digital channels transmitted here from the satellite receivers 8 and the terrestrial television channels received from the antenna 12 are present at the output 11. The output 11 is provided with a high-frequency connector type F with an impedance of 75 ohm and is intended for frequencies in the VHF and UHF bands, as well as the connector 28 connected to the input 7 of the multiswitch 1 is designed for this frequency band and is of type F. The connector 28 corresponding to the input 7 of the multiswitch 1 is interconnected with the output 11, which is also equipped with a type F connector. a section of coaxial cable with an impedance of 75 ohms and terminated with interconnecting cable F connectors.

A total of 5 users, i.e. 5 televisions 17, are connected to the device 13 according to Fig. 5 via coaxial cables coming from connectors 28 corresponding to the outputs 5 of the multiswitch 1 and further via user sockets 16. Satellite receivers are connected to some of these televisions 17. 14, or DVB-T terrestrial television receivers 15, some of these television receivers 17 already have a built-in DVB-T or DVB-T2 receiver, some even a DVB-S or DVB-S2 receiver.

Each user can watch on his television 17 three HDTV originally satellite programs from satellite receivers 8 of the terrestrial reverse link, which are programs received by the satellite antenna 4, can also watch DVBT programs from the connected antenna 12, users equipped with satellite receivers 14 can also watch satellite programs received from the satellite antenna 4 and transmitted to the subscriber outputs 5 via a multiswitch 1 ..

To implement data transmission via coaxial line 44, the device 13 includes at least one duplexer 47. A similar duplexer 47 is then located at the subscriber and is connected behind or in front of the subscriber socket 16. The duplexer 47 converts data communication into a high frequency signal (outside the frequency band of television and radio distribution - the function of the diplexer 48), which can be propagated by the coaxial line 44. For more subscribers, the duplexers 47 are incorporated in a modified Ethernet switch 55.

Fig. 6 shows the connection of two isolating transformers 35, 36 with central terminals 30, 33, 38, 41 of the primary and secondary windings. The primary winding of the transformer 35 is connected via terminals 29 and 31 to the transmitting terminals of the MDI interface of the PHY circuit 46 intended for data communication according to the 10BASE-T or 100BASE-TX standard. The primary winding of the transformer 36 is connected via terminals 32 and 34 to the receiving terminals of the MDI interface of the same PHY circuit 46. The center terminals 30, 33 of the primary windings are connected according to the specifications of the manufacturer of the PHY circuit 46.

The secondary winding of transformer 35 is connected so that terminal 37 is grounded, center terminal 38 is not connected and terminal 39 is connected to terminal 41 of secondary winding of transformer 36. Terminal 40 is connected to center conductor 51 of coaxial line 44 and terminal 42 is grounded via double pole balancer 43 , the impedance of which corresponds to the impedance of the middle conductor 51 of the coaxial line 44. The coaxial line 44 has a middle conductor 51 and a shield 45 which is grounded. In an alternative arrangement, the connections of terminals 37 and 39 of the first transformer 35 and terminals 40 and 42 of the second transformer 36 may be interchanged.

The circuit in question according to FIG. 7 operates as follows. The signals transmitted by the PHY circuit 46 arrive at the duplexer 47 on the primary winding of the transformer 35 and are transmitted to its secondary winding. Because one of the end terminals of this winding is grounded, the transformer 35 acts simultaneously as a balun.

In the duplexer, the signals from terminal 39 are fed to the center terminal 41 of the secondary winding of transformer 36. Since both end terminals 40 and 42 of this winding have the same impedance to ground, the current coming through terminal 41 is divided equally into two currents, one passing through terminal 40 to the middle conductor 51 of the coaxial line 44 and the other proceeds through the terminal 42 to the balancing dipole 43.

Because the currents between terminals 41 and 40 and between terminals 41 and 42 are the same, but oppositely oriented, they are not transmitted to the primary winding of transformer 36 and to the receiver of PHY circuit 46. This suppresses the feedback between the transmitter and receiver of the PHY circuit 46.

The signal currents that come from the opposite communication station through the coaxial line 44 flow through terminal 40 and terminal 42 through the secondary winding of transformer 36 to ground, are transmitted to the primary winding of transformer 36 and thus to the receiver of circuit PHY 46. It follows from the circuit that the received signal is simultaneously partially transmitted by the transformer 35 i to the transmitter of the PHY circuit 46.

In order not to interfere with the signals, the center conductor 51 of the coaxial line 44 is introduced into the diplexer 48, which allows the simultaneous transmission of TV band signals 49, data and power supply 50 via the coaxial line 44.

Industrial applicability

The device according to the invention can be used as a device for group reception of satellite and terrestrial television and radio broadcasting, including a data connection. The solution is especially economically advantageous where the number of connected participants or users of the installation distribution reaches from two to hundreds.

Overview of reference numerals satellite multiswitch satellite inputs multiswitches converter external satellite antennas external satellite antenna subscriber output multiswitches terrestrial feedback connection multiswitches for connecting a satellite receiver / terrestrial reverse link decoder multiswitch input for connecting terrestrial television signals satellite receiver / terrestrial reverse link decoder terrestrial feedback input connecting connector / connectors or terminal / terminals for connecting the audio and video outputs of the satellite receiver to the device, HDMI port / output or USB port / output or 8P8C port / output of the satellite receiver special output antenna for terrestrial reception receiving equipment and distribution of television broadcasting according to the application satellite receiver terrestrial television receiver DVB-T or DVB-T2 subscriber television socket television receiver command generator for controlling the output of a multiswitch which is pass-through for sig nal I. satellite intermediate frequency detachable section of coaxial cable signal combiner from terrestrial television antenna and from modulator outputs digital or analog modulator detector presence of audio signal from satellite receiver output mains socket for connection of external satellite receiver terrestrial reverse link switch (relay) for power supply to mains socket plug for power supply for devices according to the application terrestrial frequency band signal splitter terrestrial television frequency band combiner and I. satellite intermediate frequency connecting high frequency connector or terminal primary winding terminal of the first transformer for connection to the transmitter connector primary terminal of the first transformer primary transformer terminal of the first transformer for connection to the transmitting connector of the terminal of the primary winding of the second transformer for connection to the transmitting connector of the central terminal of the primary winding of the second transformer primary transformer terminal of the second transformer for connection to the transmitter connector first transformer second transformer secondary force terminal of the first transformer central secondary winding terminal of the first transformer secondary force terminal of the first transformer secondary transformer terminal of the second transformer secondary terminal of the second transformer secondary terminal of the second transformer balancing dipole coaxial coaxial line shielding line

PHY circuit duplexer diplexer

TV band power supply center conductor coaxial line data source computer

Wi-Fi router modified Ethernet switch cable TV receiver DVB-C

Claims (10)

PATENT CLAIMS Device (13) for group reception and distribution of television and radio programs comprising at least one satellite multiswitch (1), provided with at least two satellite inputs (2) for receiving I. intermediate intermediate frequency signals and at least two subscriber outputs (5) for connecting at least one terminal device from the group of television receiver (17), satellite receiver (14), DVB-C cable television receiver (56), DVB-T or DVB-T2 terrestrial television receiver (15), characterized in that the device (13) it further comprises at least one terrestrial reverse link output (6) and at least one terrestrial reverse link input (9) for connecting a terrestrial reverse link decoder (8), at least one signal modulator (21), and the multiswitch (1) is provided at least one terrestrial signal input (7), wherein the input of the terrestrial reverse link decoder (8) is connected to the terrestrial reverse link output (6), to the decoder output (8) the terrestrial reverse link is connected to the terrestrial reverse link input (9) by a modulator (21), the output of the signal modulator (21) is connected to the terrestrial signal input (7) of the multiswitch (1), or comprises at least one output ( 6) terrestrial reverse link and at least one terrestrial reverse link input (9) for connecting a terrestrial reverse link decoder (8), at least one signal modulator (21), at least one terrestrial signal splitter (26), at least one combiner ( 27) a terrestrial frequency band and an I. satellite intermediate frequency connected to the subscriber output (5) and having an output for connecting a terminal device, the input of the terrestrial reverse link decoder (1) being connected to the terrestrial reverse link output (6). The modulator (21) is connected to the output of the terrestrial reverse link decoder (8) via the terrestrial reverse link input (9), the modulator output (2). 1) is connected to the input of the hub (26), the output of the hub (26) is connected to the input of the combiner (27) and the output of the combiner (27) is connected to the terminal device. Device according to claim 1, characterized in that the device (13) comprises at least one signal combiner (20) for combining the signal from the modulator (21) and the signal from the terrestrial antenna (12), wherein the inputs of the signal combiner (20) are connected to the signal modulator (21) and to the terrestrial antenna (12) and the output of the combiner (20) is connected to the terrestrial input (7) of the multiswitch (1), or the output of the combiner (20) is connected to hub input (26). Device according to Claim 1 or 2, characterized in that it comprises at least one signal-passing command generator (18) for controlling the multiswitch (1), which is connected between the terrestrial feedback output (6) of the multiswitch (1) and the decoder input. (8) ground band feedback. Device according to Claim 2 or 3, characterized in that the connection between the output (11) of the signal combiner (20) and the terrestrial signal input (7) of the multiswitch (1) is disconnectable, or the connection between the output (11) of the combiner (20). ) of the signal and the input of the signal splitter (26) is disconnectable. Device according to one of Claims 1 to 4, characterized in that the terrestrial reverse link decoder (8) is an integral part of the device (13). Device according to one of Claims 1 to 4, characterized in that the terrestrial reverse link decoder (8) is an external device. Device according to one of Claims 1 to 6, characterized in that the output (6) of the terrestrial reverse link is provided with a high-frequency connection connector (28) or a high-frequency connection terminal. Device according to one of Claims 1 to 7, characterized in that the terrestrial reverse link input (9) is provided with at least one connector (10) of at least one type from the group RCA, CINCH, USB, HDMI, 8P8C. Device according to one of Claims 1 to 8, characterized in that the device (13) is provided with at least one modified Ethernet switch (55) which comprises at least one transceiver of a PHY circuit (46) for data communication according to the 10BASE-T standard or 100BASE-TX with at least one duplexer (47) for transmitting unmodulated data signals in the baseband via a coaxial line (44) connected to the PHY circuit (46). A duplexer (47) for transmitting unmodulated data signals in the baseband band by a coaxial line (44) connected to a PHY circuit (46) for data communication according to the 10BASE-T or 100BASE-TX standard comprising two three-pin transformers (35, 36) (29, 30, 31, 32, 33, 34, 37, 38, 39, 40, 41, 42) for each winding, at least one balancing dipole (43), characterized in that the primary winding of both transformers (35, 36) ) is connected via at least four terminals (29, 31, 32, 34) to the input and output interface of the MDI circuit (46) of the PHY, the secondary winding of the first transformer (35) is grounded by one terminal (37) and connected to the other terminal (39) by a middle terminal (41) of the secondary winding of the second transformer (36), wherein one end terminal (40) of the secondary winding of the second transformer (36) is connected to the middle conductor (51) of the coaxial line (44) and the other end terminal (42) is grounded via balancing dipole (43), the impedance of which is equal to the impedance of the connected coaxial line (44), or the connection of the end terminals (37, 39, 40, 42) of at least one of the secondary windings of the transformers (35, 36) is reversed.