FR2806571A1 - Multimedia distribution system has baluns can use Ethernet twisted pair allows simpler cheaper cabling - Google Patents

Abstract

The multimedia distribution system has baluns (3,5) connecting unbalanced signals from antenna (1) for distribution to TV receivers (7) by twisted pair lines (4) shared (400) with telephones (413) and computers (414). A preamplifier (404) can be included before the balun.

Description

"Multimedia system and method for distributing radio and cable channels in a cable network in twisted pairs" The present invention relates to a multimedia system for distributing radio channels in a cable network in twisted pairs. It also relates to a process implemented in this system. The present invention finds a particularly interesting application in the field of the distribution of television channels in places such as collective or public establishments (education, hospitals, hotels).

Television channels can be distributed either over the air using a reception antenna installed on the roof of a hotel, for example, or by cable network (fiber optic or coaxial cable). There are currently television channel distribution systems implementing broadband transmission techniques and using, for example, fiber optic cable or coaxial cable networks. Optical fibers and coaxial cables allow efficient transmission of high frequency signals such as signals from radio channels between 47 megahertz and 850 megahertz.

There are known, by the present applicant, video signal distribution systems in which a high frequency signal can be conveyed by a category 5 twisted pair from a central server to a plurality of television sets. The twisted pair is unique in that it costs less than fiber optics. In addition, networks of twisted pairs are generally pre-installed when the tertiary buildings are constructed. However, such systems require a demodulation of the high frequency signal into a baseband signal carried by the twisted pair and then a symmetrization of the baseband signal to supply the television set. This system is expensive due to the investment in devices such as a switching matrix.

The present invention aims to remedy the above drawbacks by providing an inexpensive system based on category 6 or 7 twisted pair technology which can carry signals of several hundred megahertz.

In the following, by balun is meant an impedance matching system enabling a symmetrical twisted pair cable (BALanced) to be connected to an asymmetrical coaxial cable (UNbalanced, with ground line); Category 7 cable, qualified for digital signals up to 700Mhz, means a shielded cable made up of four twisted pairs individually shielded to ISO SC25 / WG3. It will be recalled that category 5, qualified for digital signals up to 100 MHz, v relates to a shielded cable (STP) or unshielded cable (UTP), composed of four twisted pairs unshielded individually; Category 6, qualified for digital signals up to 250 MHz, concerns a screened cable made up of four screened twisted pairs in groups of two, or individually.

The above objective is achieved with a multimedia system for distributing high frequency signals in a cable network in twisted pairs. According to the invention, the system comprises - a first impedance matching means for receiving by means of a coaxial cable a high frequency (HF) signal and transmitting said twisted pair signal over a twisted pair; - a second impedance matching means for receiving the HF signal from the twisted pair and transmitting the HF signal to a given terminal by means of a coaxial cable.

In other words, a twisted pair connection is inserted between two coaxial cables. This technical solution is particularly advantageous insofar as the twisted pair is an inexpensive means of transport and generally located in collective or private premises for the construction of these premises. According to an advantageous characteristic of the invention, the twisted pair is of category 5, 6 or 7. Thanks to this twisted pair of category 5, 6 or 7, the system makes it possible to distribute high frequency signals which are signals of hertzian chains and wired between 47 megahertz and 850 megahertz, or any video signal modulated in this frequency band. According to a preferred embodiment, the first impedance matching means is a symmetrical balun comprising an amplifier and a balun. This balun is said to be symmetrical; it includes a means for making the HF signal symmetrical. According to one embodiment of the invention, the balun includes - impedance matching means so that the input impedance of the balanced balun is adapted to the impedance of the coaxial cable and the output impedance said symmetrical balun is adapted to the impedance of the twisted pair; - a means for carrying out galvanic isolation between the incoming coaxial cable and the output twisted pair; - means for achieving a phase shift of 90 between the input signals and the output signals of the symmetrical balun; and - noise rejection means.

Advantageously, the second impedance matching means can be an asymmetrical balun comprising impedance matching means so that the input and output impedances of said asymmetrical balun are respectively adapted to the impedance of the twisted pair and to the 'impedance of the second coaxial cable; and - an automatic gain control means to compensate for amplification weakening of the HF signal in the twisted pair.

Generally, the impedance of coaxial cables is 75 Ohms and that of twisted pairs of category 6 or 7 is 100 Ohms.

According to an advantageous variant of the invention, the symmetrical balun comprises eight identical outputs each on twisted pair as well as a ninth output for connecting in cascade, by means of a coaxial cable, a second symmetrical balun in order to multiply the number of outputs twisted pair.

The twisted pair connecting the first symmetrical balun and the asymmetrical balun can advantageously be part of a set of four twisted pairs forming an RJ45 type link.

According to an embodiment of the invention, twisted pair the RJ45 link is used for a telephone connection and two other twisted pairs of the RJ45 link are used for a network connection of Ethernet type.

The present invention also relates to a method of distributing high frequency signals in a cable network in twisted pairs. According to the invention, an impedance adaptation is made between a coaxial cable and a twisted pair so as to transmit a high frequency (HF) signal from the coaxial cable to the twisted pair. A second impedance matching is then carried out between the twisted pair and a second coaxial cable connected to a terminal. The second impedance adaptation involves an amplification linked to an automatic gain control in order to compensate for the weakening of the HF signal in the twisted pair.

Other advantages and characteristics of the invention will appear on examining the detailed description of a mode of implementation in no way limiting, and the appended drawings, in which - FIG. 1 is a simplified schematic view of the main elements included in the system according to the invention; - Figure 2 is a simplified electronic diagram first balun providing amplification and symmetrization of the high frequency signal picked up by an antenna; - Figure 3 is a simplified electronic diagram second balun performing an asymmetry and an automatic gain control of the high frequency signal transmitted to a television; - Figure 4 is a simplified schematic view of a distribution system for television channels to a plurality of televisions; - Figure 5 is a simplified electronic diagram of a symmetrical balun comprising a plurality of outputs; - Figure 6 is a simplified schematic view of a multimedia system according to the invention integrating telephony and Ethernet.

Figure 1 shows an antenna 1 for receiving radio channels capable of picking up a high frequency signal between 47 megahertz and 850 megahertz. The signal is transmitted to a balanced balun by means of a 75 Ohm coaxial cable 2. The symmetrical balun 3 is arranged so that the HF signal is correctly transmitted in a twisted pair cable 4 of category 7 and of impedance 100 Ohms. To do this, the symmetrical balun 3 amplifies the HF signal which arrives with a very weak amplitude level, then symmetrizes the amplified HF signal. Symmetrization consists in moving from an asymmetrical means of transport (unbalanced) composed of a conduction line and ground line (coaxial cable) to a symmetrical (balanced) means of transport composed of two conduction lines (twisted pair ). The twisted pair 4 is connected to an asymmetrical balun 5. The asymmetrical balun 5 makes it possible to transmit the HF signal coming from the twisted pair 4 (balanced) to a coaxial cable 6 (asymmetrical) with an automatic gain control to compensate for the attenuation amplitude in the twisted pair 4. The length of the twisted pair 4 is for example a maximum of one hundred meters, this makes it possible to have an asymmetrical HF signal at the input of the asymmetrical balun 5 whose amplitude is not weakened by irreversible. However, to increase the length of the twisted pair, two twisted pairs can be connected by means of a sub-distributor (not shown) providing amplification of the HF signal. The coaxial cable 6 is finally connected to the television set 7.

A simplified electronic diagram of the symmetrical balun 3 is shown in Figure 2 in which are also shown the coaxial cable 2 connected to the antenna 1 and the twisted pair 4 carrying the HF signal to the asymmetrical balun 5. The main functions of the balun symmetrical 3 are - an amplification of the incoming HF signal; an impedance adaptation, that is to say an input impedance of 75 Ohms and an output impedance of 100 Ohms for example, the impedance values being a function of the type of cables connected to the input and to the output; and - galvanic isolation between the coaxial cable 2 and the twisted pair 4. symmetrical balun 3 comprises at the input a high pass filter integrating a decoupling capacity and a resistor 302. The amplifier 303 makes it possible to amplify the incoming signal. The characteristics of the amplifier 303 are for example an amplification of 20 dB between megahertz and 850 megahertz. The amplifier 303 then supplies a transformer 304 ensuring the galvanic isolation. The primary of transformer 304 is connected to ground and has an impedance of 75 Ohms. The secondary of transformer 304 is connected in parallel to a resistor 305 with a value equal to 100 Ohms. The terminals of the resistor 305 represent the output of the symmetrical balun 3 to which the wires of the twisted pair 4 are connected.

The simplified electronic diagram of the symmetrical balun 3 differs significantly from that of the asymmetrical balun 5 represented in FIG. 3. The twisted pair 4 1st coaxial cable 6 connected to the television set 7 are also represented in FIG. 3. The main functions of the asymmetrical balun 5 are - an automatic gain control to amplify in a controlled manner the amplitude of the HF signal arriving at the twisted pair 4; an impedance adaptation, that is to say an input impedance of 100 Ohms and an output impedance of 75 Ohms for example, the impedance values being a function of the type of cables connected to the input and to the output; and - galvanic isolation between the twisted pair 4 and the coaxial cable 6.

two wires of the twisted pair 4 are connected to the primary of a transformer 501 ensuring galvanic isolation between the twisted pair 4 and the coaxial cable 6. The secondary of the transformer 501 is connected to an automatic gain control device represented by l variable gain amplifier 502, amplifier 503 the buffer amplifier. The impedance matching at the output is carried out by the resistor 505 with a value of 100 Ohms. Resistor 505 is connected in series to the coaxial cable. The present invention being for example intended for the distribution of television channels in hotels, we will now describe a system for a plurality of televisions. In such a system, in accordance with FIG. 4, the antenna 1 delivers an HF signal to a symmetrical balun 31 through the coaxial cable 2. The symmetrical balun 31 has eight identical outputs which are respectively connected to the eight twisted pairs 41-48 . Each twisted pair is then connected to an asymmetrical balun 51 ... or 58 followed by a coaxial cable 61 ... or 68 and a television set 71 ... or 78. The symmetrical balun 31, playing the role of a server, can be of a design identical to that of the balun 3 but with eight outputs obtained with eight secondary windings on the transformer 304. Each winding is provided in parallel with a resistance of 100 Ohms. The HF signal arriving via the coaxial cable 2 is thus dispatched on the eight twisted pairs 41-48 to the eight different televisions 71-78. The symmetrical balun 31 also has an additional output to which a second symmetrical balun 33 is connected by means of a coaxial cable 32. This additional output is for example the output of an amplifier connected upstream of the input capacity of the balun symmetrical 31. The symmetrical balun 33 is identical to the symmetrical balun 31 with eight outputs on eight twisted pairs 81-88 each connected in series to an asymmetrical balun 91 ... or 98, to a coaxial cable 101 ... or 108 and to a television set III or 118. The system thus described makes it possible to distribute the television channels on sixteen television sets. The number can be increased by connecting several other symmetrical baluns following symmetrical balun 33.

In Figure 5 we can see the simplified electronic diagram of the symmetrical balun 31. The identical elements with the symmetrical balun 3 are shown with the same references. The symmetrical balun 31 therefore comprises, in addition to the symmetrical balun 3, seven other outputs on twisted pairs from seven other secondary windings on the transformer 304. The symmetrical balun 31 also differs symmetrical balun 3 by said additional output produced upstream of the capacity 301 by means of an amplifier 313. One of the characteristics of the amplifier 313 can be an amplification gain of 8 dB for example to compensate for the losses of the branch on the coaxial cable 32.

Another advantage of such a device is the simplification of wiring both in collective or private premises as in the field of home automation. Referring to Figure 6, we see that the twisted pair 4 is part of a set of four twisted pairs 4, 401, 402 and 403 forming a cable 400 of category 5, 6 or 7 connected to distributors 405 and 406 The distributors 405 and 406 make it possible to separate the four twisted pairs 4, 401, 402 and 403. The twisted pair 401 is intended for telephony and the twisted pairs 402 and 403 are intended for connection to a network of Ethernet or Internet type. . The distributor 405, on the one hand directs the twisted pair 4 on a connector 404 of RJ45 type inserted in the symmetrical balun 3, and on the other hand directs the twisted pairs 401, 402 and 403 on a connector 407 of RJ45 type connected to the switched telephone network 408 for example, by means of a link 409. The distributor 406, on the one hand directs the twisted pair 401 on a connector 410 of RJ45 type inserted in the asymmetrical balun 5, and on the other hand directs the twisted pair 401 on a connector 411 of RJ45 type connected to a telephone 413 and the twisted pairs 402 and 403 on a connector 412 of RJ45 type connected to a microcomputer 414. The present invention therefore makes it possible to distribute television channels over a plurality televisions installed in a building such as a hotel in an inexpensive manner by using inexpensive electrical elements such as twisted pairs and active baluns.

We can advantageously use the four twisted pairs of category 5, 6 or RJ45 type to optimize the wiring in a collective or private room, or in a single house. Telephony, Ethernet and the distribution of radio channels are thus integrated into a cable with four twisted pairs.

Of course, the invention is not limited to the examples which have just been described and numerous modifications can be made to these examples without departing from the scope of the invention.

Claims (10)

1. Multimedia system for distributing high frequency signals in a cable network in twisted pairs characterized in that it comprises - a first impedance matching means for receiving by means of a coaxial cable a high frequency signal (HF) and transmitting on a twisted pair said signal; - a second impedance matching means for receiving the HF signal from the twisted pair and transmitting the HF signal to a given terminal by means of a coaxial cable. 2. Multimedia system according to claim 1, characterized in that twisted pair is of category 5, 6 or 7 3. Multimedia system according to one of claims 1 or 2, characterized in that the high frequency signals are signals of radio and cable channels between 47 megahertz and 850 megahertz. 4. Multimedia system according to any one of the preceding claims, characterized in that the first impedance matching means is a symmetrical balun comprising an amplifier and a balun. 5. Multimedia system according to claim 4, characterized in that the balun includes - an impedance matching means so that the input impedance of the balanced balun is adapted to the impedance of the coaxial cable and the impedance output of said symmetrical balun is adapted to the impedance of the twisted pair; - a means for carrying out galvanic isolation between the incoming coaxial cable and the output twisted pair; - a means for producing a phase shift of 90 between the input signals and the output signals of the symmetrical balun; and - a means of noise rejection. 6. Multimedia system according to any one of the preceding claims, characterized in that the second impedance matching means is an asymmetrical balun comprising - an impedance matching means so that the input and output impedances of said asymmetrical baluns are respectively adapted to the impedance of the twisted pair and to the impedance of the second coaxial cable; and - an automatic gain control means to compensate for the amplification weakening of the HF signal in the twisted pair. 7. Multimedia system according to any one of the preceding claims, characterized in that said symmetrical balun comprises eight identical outputs each on a twisted pair as well as a ninth output for connecting in cascade, by means of a coaxial cable, a second symmetrical balun in order to multiply number of outputs on twisted pair. 8. Multimedia system according to any one of the preceding claims, characterized in that the twisted pair connecting the first symmetrical balun and the asymmetrical balun is part of a set of four twisted pairs forming an RJ45 type link. 9. Multimedia system according to claim 8, characterized in that a twisted pair of the RJ45 link is used for a telephone connection and two other twisted pairs of the RJ45 link are used for a network connection of the Internet type. 10. A method of distributing high frequency signals in a cable network in twisted pairs, characterized in that an impedance adaptation is made between a coaxial cable and a twisted pair so as to transmit a high frequency signal (HF) from the cable coaxial to the twisted pair, a second impedance adaptation is then made between the twisted pair and a second coaxial cable connected to a terminal, the second impedance adaptation involving an amplification linked to an automatic gain control in order to compensate for the weakening of the HF signal in the twisted pair.