DE3503616C2 - - Google Patents

Description

The invention relates to a multiplexing device for a Broadband connection in an integrated digital, preferably equipped with glass fibers network, whereby the individual participants with distribution-switched TV and sound signals, as well as a video telephone signal and several dialog-capable narrowband channels can be supplied.

With the introduction of glass fiber as a transmission medium also in the local network arise because of the available over bandwidth new possibilities. In addition to the introduction Glass fiber enables new services such as telephony also an increase in quality of service. Running in the area of DBP the BIGFON system test since mid-1981.

Six prototype systems were developed by six German telecommunications companies developed, u. a. described in the magazine NTZ, Volume 36 (1983) Issue 7, pages 428-433. Also in research DBP institute became a system concept under the name DOTAN implemented as a functional model (DE-OS 31 46 468). There are in a subscriber-specific distribution agency from the TV programs offered by the participant several pro selected and in the following individual participants len multiplex facilities with the sound, video and Narrowband signals summarized.

In the case of the digital multiplex used here The signals of the individual services are processed at bit rates assigned, which are then multiplexed independently of the bit sequence will.

So-called standard bit flows are formed, which it allow the bit flows of communication services to be lower Bit rate common with a high bit rate service (BiFe or TV) to transmit sam. To do this in conjunction with a distribution switching with 16 inputs each on a multiplexer  and to reach three exits selectable by the participant one of the selected standard bit flows a Demulti fed plexer and then in a new multiplexing process with low bit rate communication services before this bit flow together with the other two chosen is fed to a synchronous multiplexer. In the part slave connection unit is one for each of the three TV channels Demultiplexer in addition to a synchronous demultiplexer intended. Overall, this well-known concept requires a relatively large amount of individual participants len multiplexers or demultiplexers, the reduction of which represents general object of the invention.

The invention pursues a different concept for this purpose. It starts from the possibilities that ver relatively large vertical blanking gaps between the halves offers images of a digitized TV signal. Digitali As is well known, TV signals do without a horizon tale synchronization (DE-OS 33 47 114).

It is already part of the state of the art, digitized Accompanying sound of a TV program in its vertical blanking transfer gap. The vertical blanking gap of a digital TV programs also offer the option of Taktan fit from plesiochronic to a central clock TV signals by omitting or adding bit positions to the pulse frame if the clock tolerances are accordingly narrow are designed. This method has the advantage that the Clock adjustment at the participant cannot be undone got to.

The concept of the invention is also based on the use of this known options, but is also based on the following consideration:

With a known TV coding, as z. B. in the NTZ archive. Bd. 4 (1982) Issue 4, pages 103-107 is described in one Output bit rate of 68.750 Mbit / s in the vertical blanking  gap - called V-gap for short - a free one Transmission capacity of 5.39 Mbit / s. You reserve for the TV accompanying sound, teletext and data or test signals a capacity of 1.39 Mbit / s, so remains usable transmission channel of 4 Mbit / s. Another one known TV coding method with a bit rate of approx. 135 Mbit / s increases the free transmission capacity in the V gap to approx. 8 Mbit / s. The vertical blanking interval So the TV signals could depend on the transmission capacity forth for the transmission of distribution-mediated sound signals and narrowband communication services can be used.

This use is opposed by the fact that the vertical blanking gaps of different TV programs one Distribution mediation no defined temporal relationship to each other exhibit. Now a participant changes over the switching matrix of Distribution mediation his program, so this is through a clock adaptation unit is clock synchronized, but one interference-free reception of those housed in the blanking area Sound or narrowband channels are no longer possible.

The invention is therefore based on the special task of a Multiplex device for an integrated, digital, Optical broadband connection to indicate where the free Vertical blanking transmission capacity of digitized TV signals to transmit all narrow banded distribution and communication services is used, without those associated with distribution switching Problems with the changing location of the Blanking gaps of various programs occur. Next to the A return channel is also intended to be a transmission channel to the subscriber be placed in the vertical blanking interval of an image telephone signal also the narrowband communication services of the ISDN and the control signals of the distribution exchange transmits. The participant-specific facilities in the Central and the subscriber line unit should be especially with a view to cost-effective implementation be conceived.  

This object is achieved with a device according to the preamble of claim 1 by the in its characteristics given four characteristics solved. Further trainings are specified in the subclaims.

The essential features of the invention thus exist in short, that after the usual clock adjustment individual TV signals by adding or deleting Bit positions in the vertical blanking interval all TV signals via pulse frame synchronizers synchronized with each other with respect to the beginning of the frame and fed to the subscriber-specific distribution agencies will.

This ensures that regardless of any Pro Switching the gram of the subscriber in the distribution exchange the timing of the vertical blanking interval of the TV signals of all programs supplied to the distribution exchange always the is the same. In the downstream insertion device for after a special, e.g. B. dynamic, multiplexer drive combined sound and narrowband signals is at a program switch no phase jump of the pulse frame detectable, so that interference-free multiplexing in the V-gap is possible.

In the subscriber line unit are in a demulti plex device the sound and narrowband services from the TV Signals separated.

In the same way as for the transmission to the subscriber, the direction the video telephone coded like a TV signal signal as a base multiplex signal. Again, in the V gap the narrowband service transmission was carried out.

In principle, each subscriber-specific multiplexer to insert sound and narrowband signals first the frame of the TV signal present are synchronized. However, this effort can be done by a central control unit be significantly simplified. This unit creates the  Pulse frame of the TV signal and controls both the frame synchronization devices of all centrally available TV signal, as well as all participant-specific multi plexer to take advantage of the V-gap.

Since the TV signals are all transmitted frame-synchronously, in the subscriber line unit at the subscriber via a central control unit a synchronization and restore position of the multiplex frame only for a TV signal reali be settled. The remaining demultiplexing devices, both the removal of the sound and narrowband channels, as well as the Demultiplexing of the other TV channels are from this Control unit controlled. At a participant with remote images The encoding of the camera signal becomes an option if derived from this control unit.

The narrowband services is a video telephone suitability broadcasting TV channel is not required, so in the Broadband communication center just a clock adjustment of the outgoing BiFe signal required. An additional Frame synchronization of the BiFe signal enables the Be drive the BiFe service on all TV channels.

Achievable advantages:

By exploiting the vertical blanking gap of the TV Signals for the transmission of broadcasting and narrowband services on the one hand is an optimal use of the transmission capacity of the TV signal and on the other hand with the subscriber-specific multiplex facilities of the vermit a simple multiplex structure allows identical input bit rates. The TV signal provides represents a basic multiplex signal, the basic element of modular structure. By installing additional units in the subscriber unit, in the headquarters and in the network final unit at the participant can the number of TV, sound, Narrowband and data channels to meet the needs of the individual Participant can be customized.  

Another major advantage is the Taktan fit of the plesiochrones, prepared nationwide TV programs required only once per control center is (i.e. not individual to the subscriber) and in the end device of the participant does not have to be undone.

The participant does not have a TV program switchover Influence on the transmission of the sound and narrowband services, because all TV programs are frame synchronized. A half Image storage for frame synchronization provides one represents a certain effort, which is not significant, since the facility only once per TV program, so not participant-specific, is required.

In the case of a future synchronous network for TV signals can the clock adapter without changing the other device technology is eliminated. The frame synchronizer facilities can also serve as time equalizers serve.

The fact that the TV channels are frame-synchronized works very much in the subscriber line unit at the subscriber effort-saving because of a synchronization and frame generation unit once, even with multiple TV channels is required.

Description of an embodiment:

Fig. 1 and 2 show an embodiment of the invention. In Fig. 1, the exchange-end components are illustrated, while FIG. 2 shows the subscriber terminal unit.

In a broadband communication center according to FIG. 1, 15 TV channels and 32 stereo sound channels are received for the distribution services via a national distribution network. The sound signals are processed according to requirements in the unit T , z. B. received sound channel bundle, distributed via the digital hierarchy, broken down into individual channels. In the subsequent audio coupling field TON , up to 3 of the 32 audio channels are switched through to the narrowband audio multiplexer SB-T-MUX , controlled by the subscriber. This combines various narrow-band channels and audio signals into a time-division multiplex according to known dynamic multiplex methods, which can be transmitted in the vertical blanking interval of a TV channel.

The 15 TV channels will generally behave plesiochronously to each other, so that a clock adapter is required. This is done according to a known method by adding or deleting bit positions in the context of the TV signal within the vertical blanking gap. In the subsequent frame synchronization units RS , the 15 TV signals are frame-synchronized with respect to the field. The TV switching matrix TV switches up to 3 TV signals, controlled by the subscriber. The first TV channel has a special position. In an insertion device V-MUX , sound and narrowband signals are inserted into the V-gap of the TV signal. Based on a TV coding according to NTZ Archive Volume 4 (1982) Issue 4 Pages 103-107 with an output bit rate of 68.750 Mbit / s, a transmission capacity of 5.39 Mbit / s is available in the vertical blanking interval. If you subtract a capacity of 1.39 Mbit / s for the transmission of the TV accompanying sound and test or data characters, then 4 Mbit / s remain available for the transmission of three sound channels and flexibly assignable narrowband channels.

The three frame-synchronized TV channels are combined in a synchronous multiplex device Syn. MUX to form a bit stream with a bit rate of 206.25 Mbit / s. A LE + E / O line end device generates the line code required for optical transmission. Since the transmission takes place via a glass fiber, an optical diplexer DIPL separates the two transmission directions .

The transmission channel from the subscriber to the control center, which contains the narrowband services and the video telephone signal, has the capacity of one TV signal, ie 68.750 Mbit / s. The narrowband channels and the control signals for the two subscriber-specific switching matrixes are transmitted analogously to the opposite direction in the V-gap of the BiFe signal and are recovered in the broadband communication center in a de-multiplexing device SB-T-DEM . The actual video telephone signal is forwarded to a video telephone exchange.

The signal coming from the BiFe exchange is clock-matched and synchronized like a TV program in a subscriber-specific clock adaptation and frame synchronization device TA or RS . The signal is then fed into the TV switching matrix.

The central control unit ZS plays an important role. The pulse frame of the TV signals for the frame synchronization circuits and subscriber-specific insertion devices is generated here. Furthermore, the TV coupling field is supplied with an O channel signal by the central control unit ZS . This signal, which only contains the synchronization information of the TV signal, is sent on the channels not used by the subscriber to enable interference-free transmission of the sound and narrowband signals. The central control unit is supplied with clock by a PLL unit PLL from the synchronous 2.048 Mbit / s network. In the subscriber line unit at the subscriber ( Fig. 2), the two transmission directions are separated in an optical diplexer DIPL analog to the center and in line terminals LE + E / O the line coding for the optical transmission of the transmission signal, or in LE + E / O when the signal from the control center was canceled. The multiplex signal for the subscriber with a bit rate of 206.25 Mbit / s first arrives at a synchronous demultiplexer Syn DEM , which supplies the three TV channels as output signals. The first TV channel is fed to a demultiplexing device V-DEM , where the multiplex signal is taken from the V-gap. The following narrowband sound demultiplexer SB-T-DEM , a dynamic demultiplexer, delivers the selected sound channels and the occupied narrowband channels as output signals. The three TV signals go to the corresponding decoding devices. These decoders can, as indicated in Fig. 2 by dashed lines, be arranged in the TV set. These devices can be synchronized from the subscriber-side control unit TS , since all the TV signals are frame-synchronous. The BiFe camera and the BiFe coder are also synchronized by this subscriber-side control unit TS . If there is no BiFe connection, the BiFe coder sends an O- channel signal, which only contains the synchronization information, so that the subsequent insertion unit V-MUX inserts the data stream of the narrowband services from 4 Mbit / s into free bit positions in the V-gap can. In addition to the narrow-band communication services, the data for the control of the two switching switching sites for TV and sound programs are processed with a narrow-band sound multiplexer SB-T-MUX .

Claims (3)

1. Multiplexing device for a broadband connection in a service-integrated digital local network with distribution and communication services of different bandwidths, consisting of a broadband communication center with subscriber individual distribution exchanges for n digitized TV programs, the accompanying sound transmission and clock adaptation of which takes place in the vertical blanking interval and several, with subscriber connection devices each provided with a video telephone encoder, characterized in that

• a) that both the outgoing from the broadband communication center narrowband distribution and communication services (TON, ISDN) and the outgoing from the subscriber line unit narrowband communication services (ISDN) in each a special multiplexer (V-MUX) in the vertical blanking gap at least one the n distribution-switched TV programs or the outgoing video telephone signal (BiFe) are inserted,
• b) that the n Verteilvermittlungen supplied TV programs over-Pro n ge from a central controller (ZS) controlled clock adjustment means (TA) and the frame synchronizers (RS) to synchronize their pulse start of frame with respect to each center,
• c) that a generated by the central control system (ZS) , containing only the synchronization information, frame-synchronized O channel signal over the TV programs is sent to the outputs of the distribution switches (TV) not occupied by the participants and
• d) that in the subscriber line unit in the absence of a video telephone return signals from the Bi-Fe coder, an O- channel signal for transmission of the narrowband communication services (ISDN) of the direction of insertion is inserted (V-MUX) ( Fig. 1, 2nd ).

2. Multiplexing device according to claim 1, characterized in that the video telephone signal (BiFe) going from the broadband communication center to the subscriber via a centrally controlled frame synchronization device (RS) is synchronized with respect to its frame start with the other TV programs ( Fig. 1). 3. Multiplexing device according to claim 1, characterized in that the central controller (ZS) receives its clock via a phase locked loop (PLL) from the synchronous 2.048 MHz network ( Fig. 1).