DE3316950A1 - Multi-channel transmission system in time-division multiplex technique with delay compensation devices - Google Patents

Abstract

Using double-current pulses with exchanged phase angle for forward and return channel in the transmission system, and detectors, responding to the phase angle of the double-current pulses, in the delay compensation devices of the transmission system makes it possible to provide in each case only one delay section inserted into the transmission path for each forward and return channel, blocking elements controlled by the detector blocking the access to the delay section for pulses of the opposite direction.

Description

Multi-channel transmission system in time multiplex @ e @@@ ik

with transit time compensation devices The invention relates to a multi-channel Transmission system in time division multiplex technology with delay time compensation devices for pulse duration modulated signals, using at least one delay element, especially for conference systems or discussion systems with more than one remote Subscriber station for bidirectional traffic on a transmission link, in particular an infrared transmission path, with signal feed to several pulse generator devices from a control center as resp.

of several simultaneously responding impulse receiving devices to a central control unit via a common coaxial line, with the signal transmission in the form of pulse trains when a Synchronisierimou @ -es pro is transmitted Pulse sequence is carried out from the control center.

In order to ensure a shadow-free transmission of information by means of light or to ensure infrared radiation it is necessary to distribute several in the room or to install a variety of transmitters. In particular n @ scner, lodges or for Part of the furniture make a corresponding geometric transmitter arrangement necessary, Due to runtime effects, it is necessary on the recipient side to unambiguously Take appropriate measures to identify information. This is the only way to one.

or to transmit several channels via IR emitters in free space and to prevent impermissibly high channel noise.

For conference, discussion, voting and two-way talk facilities, that work in bidirectional traffic is a transmission in time division multiplex technology of the impulses necessary in which at any point in time only one impulse in only one Direction on the transmission path is on the way. This is especially true with the Infrared pulse transmission in the room. Special runtime facilities are available for this necessary.

In the AT-PS 362 424 is a centrally controlled simultaneous transmission device for a pulse duration modulated multi-channel system, especially for a light or infrared radiation taking place time division multiplexed signal transmission, for emission formed from the leading or trailing edges of the individual pulses of pulse trains Short pulses are described in which the short pulses are emitted as flashes of light of about 200 ns duration by means of extensive or spatially distributed, from a central one Pulse generator fed via branch-shaped branched coaxial lines, as a transmitter serving light or infrared radiator takes place, and at the outputs of the central Pulse generator to the coaxial lines gradually adjustable delay elements upstream and the inputs to the transmitters further adjustable in steps Delay elements are connected downstream, in order to achieve the transmitter synchronization the lower delay stage is to be switched on to the respective distant transmitters, so that the different transit times of the impulses due to the different Lengths of the coaxial cables are compensated. The disadvantage here is that the runtime compensation only unidirectional, i.e. only when sending in one direction.

The invention is based on the object of a transmission system create that is suitable for two-way traffic in time division multiplex operation, whereby via a transmission link, in particular an infrared transmission link, from a pulse generator pulse receiver device strong to subscriber receivers outgoing impulses and weak impulses arriving from subscriber transmitters are selected in this way that mutual interference is prevented and unambiguous transmission is secured, and in terms of duration unambiguous relationships for one or more Coaxial line routes between a control center for incoming and outgoing Traffic and differently distant pulse generator-pulse receiver facilities are given, and a simple reconciliation of the maturity lending facilities should be possible on site.

This object is achieved in that in itself known way for the transmission between the center and to a coaxial line Runtime compensation devices connected via one signal distribution node each DC voltage-free double current pulses are provided, the phase position for the Transmission from the control center to the transit time compensation device opposite the is phase reversed from the transit time compensation devices to the center that for the Selekr.nm tion of the DoppJe4YUS'pulse is connected to the signal distribution node Detector is provided that has a receptor @ for outgoing signals from the control center and controls a driver for signals to be output to the control center, the input of the receptor and the output of the driver are connected to the signal distribution node are that the output of the receptor is connected to a delay element via an OR element whose output is both to the input of the driver and via a pulse blocking element dn a pulse generator is connected that a pulse receiver via the pulse blocking element to a second one gang of the OR gate is connected, and that the pulse blocking member is designed so that it pulses on outgoing signal incoming signal impulses and incoming signal impulses outgoing signal impulses locks.

This advantageously means that only one transit time compensation device for the impulse transmission in two-way traffic that is required by several Pulse generator-pulse receiver devices each only a single multiple received impulse reaches the control center and that is prevented, impulses from a pulse generator from other pulse generator-pulse receiver devices.

In a further embodiment of the invention it is provided that the detector from a first monostable timing stage at its normal output a first input a ResDtor AND element for the selection of outgoing signal pulses and others inverting output a first input of a driver AND element for the selection incoming signal pulses is connected that the second input of the receptor AND Eq iedes to the output of the Rezeators and the output of the receptor AND element to the -first input of the OR gate is connected, and that the output of the driver AND gate with the driver and the second input of the driver AND gate with the output of the Term member is connected.

This makes the simple execution of a pulse selection advantageous made possible by corresponding edges of double current pulses.

According to a further advantageous embodiment of the invention is provided that the output of the delay element to the first in the pulse blocking element Input of an encoder AND element is connected, the output of which is connected to the Input of the pulse generator as well as the inverting output of a second monostable timing stage connected to one input of a receiver AND element is that another input of the receiver AND gate with the output of the pulse receiver is connected, and that the output of the receiver AND gate to the second input of the OR gate, as well as via the inverting output of a third monostable Timer is led to the second input of the encoder AND element.

This results in a simple implementation of a mutual time impulse block for outgoing resp.

incoming impulses.

Finally, it can also be provided within the scope of the invention that for optical coupling each one designed as an infrared transmitter or receiver Pulse generator pulse receiver device, a device consisting of a subscriber receiver and subscriber transmitter device with an intermediate delay element it is provided that the running time of a pulse emitted by the control center is up to when the pulse is re-encountered in the control center it is determined with quartz accuracy, and that this runtime by appropriate adjustment of the runtime compensation device The same size for all pulse generator / pulse receiver devices in a room is made.

This makes the possibility of an uncomplicated match an advantage of the entire counter-centering system on site with only one adjustment Jr air time compensation devices created for both traffic directions.

An exemplary embodiment of the invention is described below with reference to FIG Drawing described in more detail. 1 schematically shows a coaxial line branch of the transmission system with transit time compensation devices according to the invention and Pulse generator pulse receiver devices FIG. 2 shows a transit time compensation device according to the invention In Fig. 1, a coaxial line branch K is shown, in which two transit time compensation devices LZEl, LZE2 two pulse generator pulse receiver devices IE / IGz. IE / IG2 looped in are, and which is led at one end to a control center Z, and at the second end adjusted is completed. Impulses come from and also become the headquarters. Z transferred. In the case of outgoing pulses from the center Z, the transit time compensation devices LZEl, LZE2 ensure that the transit times in each 1 (oaxial line branch K and are balanced with one another in the coaxial line branches K so that all Pulses simultaneously from the pulse generators of the pulse generator-pulse receiver devices IE / IG1, IEAIG2 are passed on. Incoming impulses in the control center Z must even if they are received and forwarded by different pulse receivers IE would be coincident. Since the transmission is on the infrared transmission path practically going at the speed of light is a simple time-of-flight comparison thereby possible that with the help of an electro-optical short-circuit device together a delay element between a pulse generator IG and a pulse receiver IE of a pulse generator pulse receiver device IE / IG1, IE / IG2, the transit time is accurate to the quartz an outgoing pulse from the control center Z and arriving there again is detected This running time is then for all pulse generator / pulse receiver devices connected to the control center IE / IG1, IE / IG2 must be the same.

In Fig. 2 the inventive Laufzelvgleichereinrictung LZE, consisting of a pulse selection device element ISE, a transit time compensation element L and a pulse blocking element ISP.

A coaxial line socket K with loop-through option forms the central-side connection of the pulse selection device member ISE and is with connected to a signal distribution node SV, from which via a detector DET with rising edge controlled, a first monostable timing stage M is connected, whose normal output Q is led to one input of a receptor AND element UR is, and its inverting output 4 to one input of a driver AND gate UT is performed, with the signal distribution node SV via a receptor R the second input of the receptor AND gate UR is connected, and the output of the driver AND element UT via a driver T to the signal distribution node SV connected.

The transit time compensation glled L consists of an OR gate 0 with a on the output side connected delay element LZ, whose output with the second Input of the driver AND element UT in the pulse selection device element ISE and is connected to an input of a transmitter AND element UG in the pulse blocking element ISP. One input of the OR element 0 is connected to the output of the receptor AND element UR connected in the pulse selection device ISE and the second input of the OR gate 0 is at the output of a receiver AND gate UE in the pulse blocking element iSP connected.

In the pulse blocking element ISP, the output of the encoder AND element UG is over the transmitter output of the air time compensation device LZE to a pulse transmitter IG and via the inverting output 4 of a second monostable time stage S i the one input of the receiver AND element UE connected, sen, its second input via the receiver input of the transit time compensation device LZE is connected to the pulse pmpfänge IE, and its output via the inverting Output 4 of a third monostable time stage 51 to the second input of the transmitter AND element UG is connected.

The heart of the delay time compensation device LZE is the detector DET in the pulse selection device element ISE.

The detector DET responds to such pulses from the signal distribution node SV get off to the input of the detector DET, and that at the beginning of the pulse is a rising one Flank ke have. Since K double current pulses are transmitted on the coaxial line , whereby the impulses emanating from the central unit Z begin with a rising edge, and the impulses going to the center Z start with a falling edge, becomes the Detector DET is excited by the former and controls the first with a rising edge monostable timing stage M, via its normal output Q in the receptor AND element UR a release option for the forwarding of outgoing impulses and via their inverting output 4 in the driver AND gate UT a block for the transmission of incoming impulses. Conversely with regard to the possibility of approval and lock are given when the monostable time stage M is not excited.

Functionally, there are three cases to be distinguished, namely: From the control center Z emitted pulses that are emitted by the pulse generator IG.

In the center Z incoming pulses, which are received by the pulse receiver LE will.

Located on the coaxial line K via any Impulse receiver LE received impulses.

Pulses emitted by the central unit Z come via the coaxial line K via the signal distribution point SV to the detector DET and via the receptor R and via the receptor AND element UR released by the detector DET to one input of the 00ER element 0, the second input of the OR element O at this point in time No incoming pulses from the pulse receiver IE due to the time division multiplex and the ISP pulse blocking element.

The pulses come from the OOER element 0 via the delay element LZ delayed via the pulse blocking element ISP to the pulse generator IG and from there broadcast, while at the same time in the pulse blocking element ISP the second monostable Time stage S2 via the receiver AND element UE the signal reception from the pulse receiver IE locks.

Incoming pulses in the center Z come when the receiver AND element is not blocked UE via the OR element O to the delay element LZ, while at the same time via the third monostable timer S1 and the encoder AND element UG the output to the pulse generator IG is locked. Delayed by the delay element LZ, the pulses come via the from Detector DET from enabled driver AND element UT via driver stage T to the signal distribution node SV and to the center Z. The detector DET speaks to the phase position of these pulses not on and the receptor AND element UR remains blocked.

If any pulses received from any pulse receiver IE on the Coaxial line path K are, then these pulses in the detector DET as pulses to the center Z and detected by the receptor AND element UR for the false emission blocked via the pulse generator IG. It is essential here that the first monostable Time stage M only each Weil locks or releases for a certain period of time gives.

The delay element LZ is an important component, the difficult one being and exact comparison must be carried out on site.

The running time itself must be finely stepped or continuously adjustable be for a precise, meaningful runtime compensation. In an advantageous manner In the invention, only one delay element LZ is used for both transmission directions and the adjustment itself takes place in each pulse generator-pulse receiver device IE / IG with a balancing device that is optically coupled to a subscriber receiver-like and a subscriber transmitter-like circuit, these two circuits are connected to one another by a delay element, the duration of which is the processing times simulated in the subscriber circuit, which is essentially through the modulation and Demodulation are intended. The comparison is carried out by sending an impulse from the control center Z is delivered, and via the optically short-circuited by the balancing device Pulse generator / pulse receiver device IE / IG comes back to control center Z. In the Central Z, measured with quartz accuracy and possibly displayed on site, must be the running time between impulse emission and impulse return for all pulse generator-pulse receiver devices IE / IG be the same size in a room.

For the transit time compensation device LZE according to the invention it is essential that that emanate strong pulses from the pulse generators IG and from the pulse receivers IE weak pulses are received, assuming that only one Participants with the center Z can connect. It is also essential that when emitting strong pulses by the pulse generator IG at the associated pulse receiver IE the pulse generator pulse receiver input direction IE / IGl, 1E / IG2, reception by others and oneself is prevented. For this purpose, ISPs are in the pulse blocking element the monostable time stages S1 'S2 to be dimensioned accordingly, which still has to be taken into account is that an operating point stabilization must have taken place in the pulse receiver IE.

4 claims 2 figures

Claims (4)

Claims Multi-channel transmission system in time division multiplex technology with transit time compensation devices, for pulse-modulated signals, using at least one delay element, in particular for conference systems or discussion systems with more than one remote subscriber station for bidirectional traffic on one Transmission path, in particular an infrared transmission path, with signal feed to several pulse generator devices from one central station or from several simultaneously responsive impulse receiver devices to a central office via a common Coaxial line, the signal transmission in the form of continuous Pulse sequences when sending one synchronization pulse per pulse sequence takes place from the control center, that is, that in in a manner known per se for the transmission between the center and to a Koa.xialleitungsabschnitt (K) connected via a signal distribution node (SV) each Runtime compensation devices (LZE) provided double-current impulses free of DC voltage are whose phase position for the transmission from the control center to the transit time compensation devices (LZE) - compared to the one from the transit time compensation facilities (LZE) to the control center (Z) is out of phase that for the selection of the double current pulses one to the signal distribution node (see above) connected detector (DET) is provided, which has a receptor (R) for signals coming from the control center (Z) and a driver (T) for the control center (Z) controls signals to be emitted, the input of the receptor (R) and the output of the driver (T) are connected to the S signal distribution node (SV) that the The output of the receptor (R) is connected to a delay element (LZ) via an OR element (O) whose output is to both the input of the driver (T) and via a Pulse blocking element (ISP) is connected to a pulse generator (IG) that a pulse receiver (IE) via the pulse blocking element (ISP) to a second input of the OR element (0) is connected, and that the pulse blocking element (ISP) is designed so that it with outgoing signal pulses incoming signal and with incoming signal pulses impulses blocks outgoing signal impulses. 2. Transmission system according to claim 1 d a d u r c h g e k e n n z e i c h n e t that from the detector (DET) via a first monostable time stage (M) at their normal output (Q) a first input of a receptor AND element (UR) for the selection of outgoing signal pulses and their inverting output (4) a first input of a driver AND element (UT) for the selection of incoming ones Signal impulses is connected that the second input of the receptor AND gate (U) to the output of the receptor (R) and the output of the receptor AND element (UR) is connected to the first input of the OR gate (0), and that the output of the driver AND element (UT) with the driver (T) and the second input of the driver AND element (UT) is delayed with the output of the delay element (LZ). 3. Transmission system according to claim 1 and 2, d a d u r c h g e k e n n z e i c h n e t that in the pulse blocking element (ISP) the output of the delay element (LZ) is connected to the first input of an encoder AND element (UG) whose Output both to the input of the pulse generator (IG) and to the inverting one Output (Q) of a second monostable timing stage (S2) to one input of a Receiver-AND element (UE) is connected that another input of the receiver-AND element is connected to the output of the pulse receiver (IE), and that the output of the Receiver AND element to the second input of the OR gate (0) as well as via the inverting output (4) of a third monostable time stage (S1) ) is led to the second input of the encoder AND element (UG). 4. Transmission system according to one of claims 1 to 3, d a d u r c h g e k e n n n e i c h n e t that a facility consisting of a subscriber receiver and subscriber transmitter device with an intermediate delay element is provided, one each as an infrared transmitter for optical coupling or receiver trained pulse generator-pulse receiver device (IE / IGl, IE / IG2), that the running time of a pulse emitted by the control center (Z) until it arrives again of the pulse in the center (Z) is determined with quartz accuracy, and that this transit time through appropriate adjustment of the transit time compensation devices (LZE) for all Pulse generator / pulse receiver devices (IE / IG1, IE / IG2) of the same size in one room is made.