EP1436992A1

EP1436992A1 - Audio/video signal distribution system

Info

Publication number: EP1436992A1
Application number: EP02783204A
Authority: EP
Inventors: Henri Lee
Original assignee: Lee Henri
Current assignee: CASANOVA
Priority date: 2001-09-25
Filing date: 2002-09-24
Publication date: 2004-07-14
Also published as: DE60239625D1; US20060139489A1; US20060143663A1; US7685623B2; ATE504163T1; EP1436991B1; WO2003028370A1; FR2830156A1; US7784075B2; EP1436991A1; FR2830156B1; ES2361300T3; WO2003028369A1

Abstract

The invention concerns an audio/video signal distribution system, comprising audio/video signal sources (MGT, DVD, C, HIFI) and audio/video signal receivers (TV1, TV2, TV3, TV4), and a central processing and multiplexing unit (MDS, MDS'). The invention is characterized in that it comprises a twisted pair service network (PS) for routing said audio/video signals from the sources to the processing and multiplexing unit and a twisted pair distribution network (P, D) for routing the processed multiplexed audio/video signals from the processing and multiplexing unit to the receivers.

Description

AUDIO VIDEO SIGNAL DISTRIBUTION SYSTEM

The present invention relates to a distribution or transmission system for audio / video and / or TV signals intended for the production of images or sounds on a TV, audio and / or video receiver.

Today there are many sources of audio / video signals that can be classified into two categories, namely internal sources, such as VCRs, DVD players, cameras, HIFI, etc. and external sources, such as radio or satellite dishes, satellite terminals, etc. The present invention will firstly be concerned with the distribution of video signals from internal sources, and then with video signals from external sources.

Today, the user has numerous signal sources which are currently dedicated to a single receiver, while it is more and more frequent to have several receivers inside the same house. It is no longer surprising that the same family has up to four to six TV receivers. However, since the signal sources are generally dedicated to a single receiver, the other receivers cannot benefit from these various sources. It has already been known for a long time to use a splitter and an amplifier to multiplex the TV signals coming from a hertzian antenna or a parabolic antenna. The wiring between the antenna and the TV receivers is then reduced in length and is done using coaxial cables. However, in addition to these external sources, there are still other external sources in the form of satellite terminals as well as internal sources like those previously cited. For these other sources, it is not easy to route them in a simple way to the various TV receivers. So far, if a person wants to use the family VCR on his own TV receiver, he disconnects it from the receiver where it was originally installed to connect it to his own TV receiver. The same is true for other internal sources such as the DVD player or cameras.

On the other hand, in the field of connectors and home automation, it is very common to use for wiring or pre-wiring of building or dwelling cables of twisted pairs of wires. This cable is used for transmission of very low voltage signals for the most diverse uses: telephony, IT, automation, alarm, sound system, etc. It is also increasingly common to pre-wire homes for domestic use with a pre-wired low current network using this type of twisted pair wire cables. Thereafter, we will often speak of networks of twisted pairs.

The purpose of the transmission system of the present invention is to use a preexisting twisted pair network for the transmission of audio and / or video signals from internal sources, but also from external sources. To achieve this aim by overcoming the aforementioned drawbacks of the prior art, the present invention provides an audio / video signal distribution system, comprising audio / video signal sources and audio / video signal receivers, and a central unit. processing and multiplexing system, characterized in that it comprises a twisted pair service network for routing audio / video signals from the sources to the central processing and multiplexing unit and a twisted pair distribution network for routing the multiplexed audio / video signals from the processing and multiplexing unit to the receivers. Two distinct twisted pair networks are therefore used to on the one hand make the signals from the sources go up to the central processing and multiplexing unit on a network and on the other hand to bring the processed multiplex signals back down to the receivers on the other network.

Advantageously, the system comprises means for inputting control signals which can be routed over the network of control signals.

Advantageously, the system comprises socket means on which the signal sources can be connected to send audio / video signals and to receive control signals over the service network.

Advantageously, the system comprises input modulators respectively associated with the socket means for modulating the signals to be routed over the service network. Advantageously, the system comprises coaxial cable sockets on which a coaxial cable for connection to a TV receiver is connectable. Advantageously, the system includes adapters respectively associated with the coaxial sockets to adapt a processed signal from the distribution network to be routed over a coaxial cable.

Advantageously, the central unit comprises multiplexing means for multiplexing the control signals on the service network and for multiplexing the audio / video signals modulated on the distribution network.

Advantageously, the central unit comprises a processing unit for processing the multiplexed modulated signals from the service network so as to route them over the distribution network. With this system, it is possible to control any source by sending a control signal to it from the control signal input means. The control signal thus entered into the system is routed through the service twisted pair network to the central processing and multiplexing unit which multiplexes it over the entire service network. The control signal does not need to be specially processed before it is multiplexed. As soon as the source sought has received and recognized the control signal, it transmits in response an audio / video signal which is processed at its associated input modulator so that it can be sent over the twisted pair network for service up to '' to the central processing and multiplexing unit which, after multiplexing and processing, sends it over the entire distribution network and to the output modulator with which the coaxial socket of the selected TV receiver is associated, which is connected by means of a coaxial cable. The chain is thus closed. The advantage of this distribution or transmission system lies in the use of two preexisting twisted pair networks, the twisted pairs of which are used to carry the control signals and the modulated video signals over a network and to return the processed multiplexed signals over the network. other network. Thus, the central processing and multiplexing unit forms a network node connected to a pre-existing cable network of pairs of twisted wires. Advantageously, the system comprises processing means for individually processing the modulated signals originating from the service network before routing them to the multiplexing means.

Advantageously, the multiplexing means multiplex the control signals from the service network to reinject them onto the service network.

Advantageously, the control signal input means comprise a wave receiver associated with a remote control.

According to a practical embodiment, the system includes boxes integrating the input modulators respectively associated with the socket means for modulating signals from the sources, the output adapters respectively associated with the coaxial sockets for adapting the signal from the distribution network , the input means of control signals routable on the service network, the socket means on which the signal sources can be connected to send audio / video signals and receive control signals on the service network, the sockets coaxial cable on which a coaxial cable connecting to a receiver is connectable, and means for connection to the distribution network and to the service network. Advantageously, the distribution network and the service network are formed by a single pre-existing network of cables of twisted pairs of wires. This audio / video signal transmission system can thus be summarized as a set of boxes and a central unit integrating processing and multiplexing means. Each box is associated with a specific receiver while the central unit is common to all the boxes. Each box is connected to an outlet on the network of cables of pairs of pre-existing or pre-wired twisted wires, as is the central unit at the other end of the network in the technical room. Each box is thus connected to the pre-existing twisted pair network using a cable for twisted pair wire connection, but it is also connected to the receiver using a conventional connection cable and to the source of signals using a specific cable which can, among other things, be of the SCART / RJ45 or also RJ45 / RJ45 type. However, the audio / video signal transmission system of the invention can also accept external signal sources. For example, the multiplexing means can also be connected to external sources of audio / video signals subsequently processed in the processing unit to be routable over the distribution network. Advantageously, the external sources include antennas and / or satellite terminals. Thus, quite similarly, a control signal can be entered into the service network up to the multiplexing means which will multiplex the control signal over the entire service network. In return, the external source delivers a video or audio signal which is first multiplexed and then processed in the processing unit so that it can then be routed over the distribution network to the output adapter with which the socket is associated. coaxial cable which is connected to the receiver using a conventional coaxial connection cable. In practice, the system can thus be summarized as a set of boxes as defined above and a central multicast unit.

The central unit is thus connected to the network of pre-existing twisted pairs which serves as a branch to reach the boxes which are installed near a weak current outlet installed in the room where the dedicated receiver is located.

The invention will now be described more fully with reference to the accompanying drawings giving by way of non-limiting examples two embodiments of the invention.

In the figures:

FIG. 1 is a diagram illustrating the implementation of a transmission system according to the invention in a room or a house composed of four rooms each equipped with a TV receiver,

FIG. 2 is a diagram of the housing used in the present invention,

- Figure 3 is another diagram illustrating the transmission system according to the invention in an application involving external sources of video signals, and - Figure 4 is a diagram showing the structure of the central multicast unit. Reference will first be made to FIG. 1 which illustrates an application of the transmission system of the invention in a residential or office space composed of four rooms referenced PI to P4. In the present case, it is rather a dwelling for domestic use, in which the room PI can be the living room, and the rooms P2, P3 and P4 of the bedrooms for example. This house has a network of cables of twisted wire pairs PT which extends into each room PI to P4. In FIG. 1, this pre-wired or pre-existing network is constituted by the cables of pairs of twisted wires PT located outside the rooms PI to P4 and reaching inside the rooms at the level of sockets RI to R4 , which can for example be in the form of RJ45 type sockets. At the other end of the sockets RI to R4, the cables of twisted pairs PT arrive for example in a technical room (not shown).

Conventionally, a cable of pairs of twisted wires consists of four pairs of twisted wires. In the present invention, two pairs of wires will be used, namely a so-called “service” pair for routing control signals and upstream audio / video signals, and another so-called “distribution” pair for routing downlink audio / video signals.

We will now describe the content of parts PI to P4. Each room is equipped with a TV receiver referenced TV1 to TV4 with which is associated a remote control TC1 to TC4, which may for example be of the infrared emission type. One can also imagine audio receivers such as HIFI channels.

Each part is also equipped with a housing B1 to B4, the details of which are shown in FIG. 2.

The boxes Bl to B4 can be identical. Each box comprises on the front a weak current socket of the RJ45 type, a coaxial socket F and a RIR wave receiver for example of the infrared type. On the rear face, for example, the box includes connection or connection means CPT for connecting a cable of pairs of twisted wires PT. The RJ socket is connected to the CPT connection means via an MDL modulator. The coaxial socket F is connected to the CPT connector by means of an adapter / balun which can for example be a balun. As for the RIR receiver, it is connected to the CPT connector via a PIR wave processing unit. The MDL modulator is furthermore provided with RC adjustment means making it possible to adjust the channel of the signal injected at the level of the RJ socket. On the other hand, the RJ socket is directly connected to the CPT terminals by a twisted pair.

The CPT terminals of the boxes Bl to B4 are connected to the respective socket RI to R4 by means of a twisted pair cord PT. Thus, the various boxes Bl to B4 are connected to the network of twisted pairs pre-wired or preexisting. It should be noted that the control signal received by the RIR receiver is connected to a terminal of the CPT which is connected to the service network. The BL balun is connected to the PD distribution network, while the modulator and the direct line from the RJ socket are connected to the PS service network.

On the other hand, each receiver TVl to TV4 is connected to its respective box Bl to B4 by means of a coaxial cable CX which is connected at the level of the socket.

F.

The PI room is also equipped with an MGT video recorder which is connected to the TVl receiver using a scart cable. The MGT video recorder is also connected to the Bl box at the RJ socket by means of a SCART-RJ45 connection cord.

Room P2 is equipped with a DVD player connected to the TV2 receiver using a SCART cable. The DVD player is also connected to the B2 box using a SCART-RJ45 connection cable.

The room P3 is equipped with a camera C which is connected to the box B3 at the level of the RJ socket by means of a connection cord made up of pairs of twisted wires.

Room P4 includes only the TV4 receiver and the B4 box

Although the present application mode implements three internal sources of audio / video signals, it is of course feared to provide even more sources, the number of which is limited only by the ranges available on the map. frequency. The source channels can be adjusted using the adjustment means associated with the MDL modulator.

Preferably, the remote controls TC1 to TC4 are universal remote controls capable of controlling both the receivers TV1 to TV4 as the video recorder, the DVD player and the camera C.

The receivers TV1 to TV4 as well as the video recorder, the DVD player and the camera C are thus connected via the respective boxes Bl to B4 and the connection cables PT to the sockets RI to R4 of the network of cables of twisted pairs of wires. PT which is here divided into a service subnet PS and a distribution subnet PD. This preexisting network extends outside the rooms PI to P4 as far as a technical room (not shown). In this technical room, the various network PT cables coming from rooms PI to P4 are connected or connected using a connection cable to a central multicast unit. This MDS unit integrates MX multiplexing means, which constitute network nodes which interconnect all the PS cables of the existing service network.

This central broadcasting unit MDS integrates, in addition to the multiplexing means MX, several levels of signal processing which make it possible on the one hand to process the uplink signals coming from the service network and on the other hand the downlink signals coming from the central unit broadcast and fed back into the distribution network. A complete architecture of this central television broadcasting unit will be given below with reference to FIG. 4.

This is the architecture of the video signal transmission system according to the invention in this application case. The only sources of video signals are internal sources, as they are the MGT VCR, the player

DVD and camera C.

A person in the room PI can of course operate the video recorder MGT using the remote control TC1 so that video signals will be transmitted to the receiver TV1 via the cord P. Likewise, a person in the room P2 can operate the DVD player using the TC2 remote control to send out video signals to the TV2 receiver via the P cord. This is entirely conventional.

However, thanks to the invention, a person in, for example, room P4 can use the universal remote control TC4 to send a control signal, for example a read signal, to the RIR receiver in box B4 to activate the MGT video recorder. found in the PI room. After processing this control signal at the PIR processing unit, the processed control signal is sent to the connector CPT of the housing B4. From there, the control signal is sent over the service network in the connection cable PT to reach the connector R4 of the pre-existing network. From there, the control signal will go up the network, on a specially dedicated pair which is called “service pair”, to the central unit MDS where it arrives in specific multiplexing means mxs. From there, the control signal is multiplexed on all the service pairs of the service network connecting the MDS box to the RI to R4 sockets. Arrived at the RI socket, the signal goes up by the connection cable PT to the housing Bl. After having reassembled the direct line in the housing Bl, the control signal goes up to the video recorder MGT by the connection cable PPT. The MGT VCR thus receives a playback command signal, and in response, the VCR begins playback. A video signal is thus emitted by the video recorder. Conventionally, this video signal is transmitted with a frequency called "baseband" of 12 MHz, which is not compatible with a transmission over a cable of twisted pairs of wires. This is why the unit Bl integrates the MDL modulator whose function is to modulate the baseband video signal into a video signal capable of being transmitted without loss of characteristics of the original signal. Once processed, the modulated video signal can be transmitted by the connection cord PT which connects the housing Bl to the socket RI. From there, the modulated video signal enters the twisted pair service network PS and goes up to the central unit MDS which integrates multiplexing means MX. From there, the modulated video signal is processed in an individual processing unit ut, then multiplexed with the other inputs from the service network, to then be sent to another central processing unit Ul which processes the signal in a substantially inverse manner compared to the unit ut. From the R4 socket, the video signal goes back to the B4 box at the level of the BL balun whose function is to adapt the signal impedance so that it can transmit it this time through the coaxial cable CX which connects the box

B4 to the TV4 receiver. A main function of the BL balun is to transform the impedance of the signal from 75 to 100/120 ohms. Thus, a person in room P4 can use his T4 TV receiver to view a cassette played by the MGT VCR in room PI. Likewise, a person in room P2 can use the VCR in room PI. Conversely, a person in room PI can use the DVD player in room P2. All combinations are possible.

The spirit of the present invention is to use a network of preexisting twisted pair wire cables to route a control signal and modulated video signals over a service subnetwork and multiplexed modulated signals processed on a sub -distribution network.

Reference will now be made to FIG. 3 which illustrates an alternative application also involving external sources of audio / video signals. We can immediately notice that the diagram of Figure 3 takes in its entirety the diagram of Figure 1. Therefore, we will no longer describe again the structure and operation of this part. Only the differences with Figure 1 will now be explained and commented on. The central multicast unit MDS 'of FIG. 3 also integrates a processing stage UT composed of several individual processing units ut intended for the processing of signals going up the service network. Given that the service network is also used for raising control signals, the central unit MDS ′ also comprises means for multiplexing mxs of the control signals. Since the control signals do not need specific processing, they are simply multiplexes at the level of the mxs multiplexing stage and reinjected directly into the service network PS to descend over the entire service network, and more particularly to the source concerned which will recognize the control signal. Beyond the UT processing unit stage, the processed uplink signals are injected into multiplexing means MX. In FIG. 4, it can be noted that the four lines of the preexisting twisted pair network which connect the four pieces PI to P4 use four individual processing units ut. The two other remaining individual processing units, namely the two on the left in FIG. 4, receive signals from an external source constituted by satellite terminals TS1 and TS2 visible in FIG. 3. The parabolic antenna PRB visible in Figure 3 is connected to the central multicast unit MDS 'which will re-inject the video signal received by the antenna PRB to the satellite terminals TS1 and TS2. This is visible in FIG. 4 where it is clearly seen that the antenna connected to the MDS 'unit is directly oriented along the service lines which connect to the two satellite terminals TS1 and TS2. The signals processed at the level of the satellite terminals TS1 and TS2 are then routed via the service line to the individual processing units ut which then send the processed signals to the multiplexing means MX. From there, all the signals previously processed and modulated are sent to the processing unit Ul whose function is substantially the opposite of that of the processing stage UT. In the processing unit, the signals are amplified, pre-sloping, symmetrized, adapted in impedance so as to be able to reinject them without significant loss of transmission characteristics on the distribution network PD. The conventional rake antenna is directly connected to the processing unit Ul, together with the multiplex signals. The ANT antenna signal will simply be processed (amplified, pre-sloped, balanced, adapted in impedance, etc.) so that it can be routed without loss of transmission characteristics on the distribution network. At the output at the BL balun, the signal will be processed again to be able to route it over a coaxial cable connected to the receiver. Thus, at the input of Ul is injected a bouquet of signals each corresponding to a predetermined channel. The number of channels is only limited by the frequency plan.

We can clearly see with this last application that the external sources are treated in the same way as the internal sources by using the two service and distribution sub-networks which are actually formed by the preexisting network of twisted pairs.

The present invention can thus materialize in a set of boxes B1 to B4 and an MDS or MDS 'box. The boxes are each connected to a socket on a pre-existing twisted pair network and the dedicated TV or audio receiver and any internal video or audio source are connected to each box. As for the MDS or MDS 'box, it is connected to all the cables of the preexisting network, and integrates processing and multiplexing units to reinject the signals processed on the distribution network to the dedicated receivers.

Claims

claims

1.- Audio / video signal distribution system, comprising audio / video signal sources (MGT, DVD, C, HIFI) and audio / video signal receivers (TVl, TV2, TV3, TV4), and a unit central processing and multiplexing (MDS, MDS '), characterized in that it comprises a twisted pair (PS) service network for routing audio / video signals from the sources to the processing and multiplexing unit and a twisted pair (PD) distribution network for routing the multiplexed audio / video signals from the processing and multiplexing unit to the receivers.

2.- The system of claim 1, further comprising input means (RIR) of control signals routable over the network of control signals.

3.- System according to claim 1 or 2, further comprising connection means (RJ) on which the signal sources are connectable to send signals and receive control signals on the service network.

4.- System according to claim 1, 2 or 3, further comprising input modulators (MDL) respectively associated with the socket means (RJ) to modulate the signals to be routed on the service network.

5.- System according to any one of the preceding claims, further comprising coaxial cable sockets (F) on which a coaxial connecting cable (CX) to a TV receiver (TVl, TV2, TV3, TV4) is connectable.

6.- System according to any one of the preceding claims, further comprising adapters (BL) respectively associated with the coaxial sockets (F) to adapt a processed signal from the distribution network to be routed on a coaxial cable.

7.- System according to any one of the preceding claims, further comprising multiplexing means (MX, mxs) for multiplexing the control signals on the service network and for multiplexing the modulated TV signals on the distribution network.

8.- System according to any one of the preceding claims, further comprising a processing unit (Ul) for processing the multiplexed modulated signals from the service network so as to route them over the distribution network.

9.- System according to any one of the preceding claims, further comprising processing means (ut) for individually processing the modulated signals coming from the service network before routing them to the multiplexing means (MX).

10.- The system of claim 7, wherein the multiplexing means (mxs) multiplex the control signals from the service network to reinject them on the service network.

11.- System according to any one of the preceding claims, wherein the control signal input means comprise a wave receiver (RIR) associated with a remote control (TC1, TC2, TC3, TC4).

12.- System according to any one of the preceding claims, comprising a housing integrating: a- the input modulators (MDL) associated respectively with the socket means (RJ) for modulating signals from the sources, b- the adapters of output (BL) associated respectively with the coaxial sockets (F) to adapt the signal from the distribution network, c- the input means (RIR) of control signals routable on the service network, d- the socket means ( RJ) on which the signal sources can be connected to send video signals and receive control signals on the service network, e- the coaxial cable sockets (F) on which a coaxial connecting cable (CX) to a receiver TV is connectable, and f- means of connection (CPT) to the distribution network and to the service network.

13.- System according to any one of the preceding claims, in which the distribution network and the service network are formed by a single pre-existing network of cables of pairs of twisted wires (PT).

14.- System according to any one of the preceding claims, in which the multiplexing means (MX, mxs) are also connected to external sources of video signals (ANT, PRB, TSl, TS2) subsequently processed in the unit. processing (Ul) to be routable on the distribution network.

15.- The system of claim 14, wherein the external sources include antennas (ANT, PRB) and / or satellite terminals (TSl, TS2).