NO151525B - INSTALLATION FOR TRANSFER OF INFORMATION. - Google Patents

Abstract

1. A domestic system for information transmission, comprising a) a plurality of subscriber's sets (TL1, TL2;SP1-SP4) interconnected without central exchange, b) an electric power supply, c) the parallel connection of all subscriber's sets to the transmitting medium (10, 12), d) which system is designed such that each subscriber's set is provided with a substantially identically configured circuit (14, 15, 16) to which the individual desired functional blocks such as dial keys or technically equivalent dialling means are connected, e) wherein these circuits are connected to each other via a single transmission control medium (12) with coupling elements (17, 18) being interconnected therebetween, f) wherein the individual subscriber's sets are encoded in accordance with their functions by added electric encoding means (22), g) so that by means of the technical features c) to e) information may be processed, encoded, transmitted via the transmission medium to other subscriber's sets, received, decoded, evaluated, and the individual means of the system such as loudspeaker, bell, switches and the like may be controlled, characterized in that h) the identically configured circuit is designed as a large-scale integrated circuit arrangement (14, 15, 16) comprising the following circuits : I. a first circuit for determining the actuation of dial keys or the state of sensors or switching elements, for encoding the received information, for converting the same to a corresponding pulse sequence, and for supplying corresponding control data together with the received key information to the control channel of the transmission medium, II. a first circuit for receiving and evaluating pulse sequences containing control information from the control channel (12) and for generating corresponding control signals for a communication channel selection element or for signal devices, III. a third circuit for reading from the pulse sequences received from the control channel (12) the subscriber's addresses and for checking the same for coincidence with the own address, i) that the speechpath selection element (19) is disposed between the LSI-circuit (14, 15, 16) and the transmission medium (10), j) that two coupling elements (17, 18) for transmitting binary-encoded control signals are connected in antiparallel relationship between control line (12) and LSI-circuit of each subscriber's set, k) that a plurality of speechpath selection channels (10) is provided in addition to a single control channel (12), wherein, when the selected speechpath channel (10) is busy, each subscriber's set automatically effects transfer to the next free speechpath channel.

Description

The present invention relates to a house system for transmission

of information as stated in the introduction to claim 1.

Such facilities have long been known. They serve in particular as internal telephone systems, house telephone systems and intercoms.

With these devices, a large number of connection lines are required between the individual talking points. In addition, it is also generally necessary to have a connection centre, which enables the distribution of the calls to the individual call points. This distribution can be done manually with the help of an operator or automatically with the help of relays or semiconductor connections. Such a facility requires a large number of connecting lines. With such facilities, an expansion of the switchboard is only economically justifiable up to a certain number of subscribers.

The invention has the task of designing a plant according to the preamble to claim 1 so that the construction and installation is simple and so that the plant can later be simply and practically expanded to an arbitrary number and where there is no need for a switchboard.

According to the invention, the task is solved as indicated in

the characteristic part of claim 1. Further design of the invention is shown in the subclaims.

According to the invention, it is arranged at each subscriber location

an essentially identically structured highly integrated circuit,

in particular a microcomputer, to which the individual desired function blocks such as call button sets, state monitors etc.

These highly integrated circuits of each subscriber site are connected to each other over a single transmission medium such as an electrical wire by interconnecting connecting elements such as an RC link or a converter. They can be programmed from the outside corresponding to the individual functions of the respective subscriber locations by supplying electrical connection parts such as short-circuit bridges, diodes and coding links.

In this way, it is possible to process information, to encode it, to send it over the transmission medium to other subscriber locations and to receive and decode and evaluate and then control the individual devices such as door speakers, door openers, doorbells, switches and the like.

Appropriately, a single power supply line can be arranged in the single transmission medium for supplying power to the individual subscriber locations. In addition, a single common control line can be arranged in the same way, which can transmit the total information except for the actual voice transmission. Below are e.g. the activation of an SPS talking point in an apartment via a push button or a key field at the gate, which are affected by a visitor. The same also applies to the influence of the door opening by the subscriber or the indication that the door is open or closed.

For the actual voice transmission, at least one voice transmission line can be arranged. However, several voice transmission lines can also be arranged in addition to the single control line and/or a single power supply line.

Since, due to the connection structure, the total information is at each voice point, which is transmitted over this common line, the microcomputer can independently determine which subscriber and which voice transmission line is currently busy. Each subscriber can thus automatically switch to the next free voice transmission line.

In order, if necessary, to prevent the non-relevant subscriber from eavesdropping on a conversation, a blocking device can be arranged at each subscriber location, as this blocking device blocks the connection to some or all other subscriber locations when a communication connection is provided.

As further mentioned above, connecting elements are connected between the highly integrated circuit, generally a microcomputer, and the transmission line. These either receive from the microcomputer a pulse train with distances corresponding to the control information to be transmitted and emit a frequency train corresponding to the different impulse intervals on the control line, or it converts the frequency train received from the control line into a corresponding pulse train and transmits this to the microcomputer.

A speech path selection element may also be connected between the microcomputer and the speech transmission line, which has the task, due to the control pulses coming from the microcomputer, to select a free speech transmission line (in the event that several speech transmission lines are arranged) or to select a specific carrier frequency for the relevant voice transmission line. The latter device allows simultaneous transmission of several calls on a single wire.

In addition, a specific signaling device can be arranged which is also connected in terms of connection with the microcomputer and receives a series of impulses from it which denotes a specific functional state. Due to this series of impulses, the signaling device can trigger a corresponding signal indication, the signaling device as an acoustic or optical signal...

The system can also have a connection device for a peripheral device. This switching device can, due to a train of pulses coming from the microcomputer, trigger this peripheral device. Thereby, e.g. possible to trigger several alarm devices within a factory facility, or to trigger a larger number of work start, pause or end of work signals or the like. In a further embodiment of the invention, each subscriber location can be assigned a coding element connected to the microcomputer in a connection-wise manner. This coding element can initially be set so that it denotes the associated subscriber location. Secondly, by setting this coding element, it can be determined which function the subscriber location in question, which in basic structure is the same as all the other subscriber locations, will take over. For example thus, the different functions of a port call point and an apartment call point can be set. This setting or coding or programming generally follows electrical connection devices.

Furthermore, each subscriber location can have a connection block, which is connected to the individual functional elements of the specific talking location, such as keys, door condition sensors, etc., and which supplies to the microcomputer when the corresponding functional elements corresponding control and information signals are triggered.

When using the system, an internal tele-

phone system must be made with several loudspeakers and preferably at least one door loudspeaker. A further or further application of the system consists in an alarm being provided in cooperation with a sensor to influence centrally controlled several individual devices, e.g. to trigger a start-of-work, pause or end-of-work sign or the like.

The operation of the facility can take place independently of a central office. The facility can be expanded at any time, whereby only

a new standard connection with transmission medium, generally one or more electrical wires, must be connected. This makes the installation and especially the later installation very easy. In the case of previously known facilities, without a central office, an extension of the facility would require a large number of connection lines to connect the newly added subscribers with all other subscribers.

If a power supply line common to all subscribers is fed into a single transmission medium, there is no need for a separate power supply connection for each subscriber.

The separation of the voice transmission line from the control line enables all other functions to be triggered during a telephone conversation, e.g. the opening of a gate, the indication of an open gate, etc.

The plant according to the invention can be used for transmission

of arbitrarily coded information, e.g. also to trigger

ning of several control and switching functions in house technology,

e.g. switching on and off as well as switching on hotplates and stoves, refrigerators, air conditioning. A recording of information on printers, assessment devices or car LED screens is also possible.

The invention will now be described in more detail with the help of exemplary embodiments with the help of references to the drawings, where: Fig. 1 shows an overall diagram of a telephone system with several call points and door loudspeakers as well as a power supply unit.

Fig. 2a shows the flow diagram of an information dissemination.

Fig. 2b shows the flow diagram of an information reception.

Fig. 2c shows a typical sequence of impulses during information dissemination.

Fig. 3 shows the block diagram of a subscriber location.

Fig. 4a shows the connection circuit for a portal address.

Fig. 4b shows the connection device for an apartment call center.

In fig. 1 shows an internal telephone system with two so-called door loudspeakers TL1 and TL2 as well as four voice stations SPS1-

SPS4. Also shown is a power supply unit NG, which

is connected to each subscriber location via a common power supply line 11. In addition, a common voice transmission line 10 is arranged between all subscribers, which includes the voice location and the port speaker. In addition, a control line 12 is shown, which is also connected to all subscribers. All wires can suitably be ring wires.

The door loudspeaker generally consists of a push button in connection with a name plate or a set of buttons with space for the desired subscriber number whereby each subscriber is assigned an associated call number, such as is arranged on a list next to the key field, and also has a microphone and a speaker. When the push button is pressed or when a call number is pressed in the key field, a call sign rings in the usual way at the desired subscriber. When the call is received, which is displayed above a switching element in the switching circuit, the connection of the voice connection between the talking point and the door loudspeaker follows, e.g. TL1, since of course also the place of speech, e.g. SPS, has a microphone and a speaker. This voice connection is carried over the common voice connection line 10. If the subscriber at the voice point wants to let the visitor, who is waiting at the door speaker TL1, in, he presses the door opening button. Thereby, the integrated circuit, generally a microcomputer, provides a coded information which is conveyed over the control line to the gate speaker location and this causes the influence of the gate opening circuit.

With the system shown, it is also possible to conduct conversations over the voice transmission line 10 between two subscriber locations, e.g. SPS1 and SPS2, while the control path 12 for a contact between the port speaker 1 and a further speaking location is free. Fig. 2a and fig. 2b shows a flow chart for information or data transfer. Fig. 2a shows the individuals in the highly integrated or LSI circuit within the subscriber's place the progress of sending information, and Fig. 2b shows the corresponding procedures for receiving such information. Fig. 2c shows the time series of impulses during the information transmission. This concerns a single-series transmission (fig. 2a) and a serial reception of data words (fig. 2b). Fig. 3 shows a block circuit diagram of a subscriber station, which is generally denoted by 25. This speaking station SPS is connected respectively to a control line 12, a voice transmission line 10 and a power supply line 11. The center of the speaking station is the microcomputer 16. This microcomputer is connected to the control line 12 via a connecting element 17 (from the control line) and 18 (to the control line). In addition, the microcomputer 16 is connected to the voice transmission line 10 via a voice path selection element 19. This voice path selection element 19 is also connected to a carrier frequency generating device 26, in which a carrier frequency is provided for the simultaneous transmission of several calls on a single voice transmission line, which is appropriately selected by the voice path selection element.

The microcomputer 16 also controls, among other things, a switching device 21 over which peripheral devices such as several decentralized alarm devices etc. can be controlled.

A coding element 22, which is also connected to the microcomputer 16 in terms of connection, serves to encode the relevant voice location. Furthermore, a connection block 23 connected to the microcomputer is shown, which contains a key field, respectively a sensor field,

to enable activation of the keys and selection of the desired subscriber. In addition, the sensor field of the connection block enables the determination of the momentary state of the speech site, e.g. the indication of whether the gate is open or closed.

Furthermore, in fig. 3 shows a device 24 which has a voltage stabilization as well as a standard connection of the LSI circuit. A voltage stabilization is necessary to ensure the management of the individual complicated processes within the speech site. The standard circuit must include the functions that are common to each voice station. These standard circuits can of course also already be integrated into the microcomputer itself, but cannot then be changed further and be replaced by another standard circuit. In particular, the standard circuit contains a clock generator and a feedback circuit. In fig. 4a shows a preferred circuit for a door loudspeaker, the basic construction being the same as that shown in fig. 3. A microcomputer 14 is supplied with power via a fixed voltage regulation device via the power supply line 11. The individual functional units, such as the call selection button set, the microphone, the speaker, the door opener, etc., are connected to the microcomputer 14. A sensor is also provided, which indicates the open or closed the state of the port of the apartment telephone station connected to the portal telephone station, e.g. by means of a shining or flashing lamp.

A busy indication can, on the other hand, be arranged via an LED switching circuit for the gateway station. Thereby, the visitor can be given the information that the talking point in question is currently conducting a house phone call and that the action of the call-\alg keyboard must be repeated after a time.

In fig. 4b shows a suitable connection for a speech site. A comparison with the circuit of fig. 4a for a portal site shows a broad agreement of the structure. Here too, an LSI circuit forms the center point, with which a power supply line 11 is connected via a fixed voltage regulator. With the LSI circuit, on the other hand, all other devices, such as keyboard fields for selecting the individual subscribers, speaker connection, microphone, door status indicator, influence of the door opener, etc., are connected.

Those in fig. Circuits shown in 4a and 4b can be considerably changed according to the areas of application they are intended for. Thus, a large number of other devices can be connected to the central LSI circuit, such as a display screen, a data recording device, etc. The house system according to the invention can thus be extended to many different areas of application.

In the following, an embodiment according to the function of the present invention will be described with essentially references to fig. 4a and 4b.

Through the control program integrated in the LSI circuit, the key and switch field is cyclically (over A1/E1 , A2/E2 , A3/E3 , A4/E4) requested whether a switch or key influence exists. If there is an influence, the LSI circuit includes all information, such as is entered over the key and stores this information temporarily in an internal working memory. If no new keystrokes follow within the time period T, the information input is acknowledged at the end. In this example, this entered information is the call number of the called SPS, but can also be control information for connecting a device, such as e.g. is -connected to another SPS. Furthermore, there is e.g. possible by sensors to cause state changes in a switching element in the switching field and further detect this and convey this information to. a priority location. In the following, the term communication path corresponds to the speech transmission path. Since none of the communication paths can be occupied when the plant is started, at the beginning a storage location in the internal working warehouse is loaded with the information "free communication path" (e.g. a logical "0" for free path). The expansion step with the communication path is programmable in the function coding field (using corresponding connection of PD1, PD2 with diodes). As each subscriber location is continuously notified of the momentary busy state of the communication path, a free path can be selected with the help of the above-mentioned information (storage location—> communication path busy). Should no communication path be free, the signaling device above A7 is affected by means of a corresponding control program in the LSI switching circuit, to indicate to the user, the state of the busy communication path. If a path is free, the switching circuit produces a binary data word with the information about which communication path is to be used, the added call number, and with the requirement that a connection be set up from a port location. This binary data word is serially fed into the information path across the switching element by a pulse-pause modulation method. Incidentally, the procedure is also shown in fig. 2a and 2c.

In the present embodiment, this transfer is solved in a commonly known manner. A8 is connected alternately and correspondingly to the information of the data word from logic "1" to logic "0" by means of the control program. Thereby, a pulse pause corresponds to the time T, a logical "0" and the pulse pause to the time 2T, a logical "1". Each bit of the data words is thus entered in the manner indicated above into the information path, which here is the information ring wire^

In terms of switching, this happens with the help of the optical switching element K2 in the following way: If A8 is brought to logic "0", a current flows through R., and the diode of the switching element K2

in the order of the Vcc diode voltage. This current causes the Darlington stage to be switched to the switching element K2, and thereby the voltage between the two conductors of the information ring line drops almost to the saturation voltage of the conducting Darlington stage.

In the central power supply, the voltage is supplied

in the information ring line as well as the limitation of current flowing through the conductors and the Darlington switching stage. A series of impulses sent from the gate location is passed over the connection element Kl to the corresponding inputs E5 to all subscriber locations. In terms of switching technology, this happens in the following way: Through R1 and the diode of the optical switching element K1, a current flows depending on the voltage between the conductors of the information ring line. Analogous to this, the Darlington stage of the coupler K1 becomes conductive, and the pulse train transmitted from the gate location then arrives at E5.

The reception of the pulse train also takes place with the help of a control program integrated in an LSI circuit, the sequence of which can be seen in fig. 2b.

Received information, which is characterized by the temporally defined impulse pause T and 2T, is now decoded within each subscriber location (using the LSI switching circuit) into the original data word as it exists at the gateway location.

Each subscriber site now considers this data word and only that SPS, whose call number is given in the data word and whose number was determined in the function coding field by means of the diodes,

e.g. over PD^ - PD^, acknowledges the connection requirement in the form of an impulse, e.g. of the duration T. Due

of this acknowledgment impulse, all subscriber sites recognize the communication path previously specified in the data word as busy and only the called site, here the port site, connects via the switching element (using relay A) on the selected communication path (communication ring line). If the receipt is missing, e.g. because the selected location is already associated with another location, all subscriber locations register. the communication path (communication ring line) that is not busy.

The called location can show the user this condition by means of the signaling device or, as in this example with the gate location, indicate this via a large LED circuit (using programmed switching of A9).

If the called SPS is not busy, this (also program-controlled via A7) generates a call signal, which is shown to the user above the signaling device, e.g. an acoustic converter.

If the user accepts the call, which is shown to the LSI switching circuit by operating a key GA or another switch, the called SPS now switches its voice circuit using the corresponding switching element (here above the relay A) on the communication path (communication ring line) and a call is possible over both voice circuits and the communication path.

During the connection with the gate site, the user can by means of a key action (using the Tt) key) cause the actuation of a door opener relay (relay B) by means of programmed switching of A7, which is communicated to the gate site

also over a data word from SPS.

If the user does not receive the call within a defined period of time, the called SPS ends the generation of the call signal. In order for the already registered communication path (communication ring line) to be freed by all the subscriber sites, the called SPS sends a data word over the information path (information ring line) to all connected subscriber sites and thus causes the busy communication path to be released . The same process occurs when the connection from a location (here e.g. SPS) is interrupted,

which is indicated to the LSI switching circuit also by a key GA or other switch action.

Both participating subscriber locations return to their initial position and a new provision of a connection is possible. In the following, some terms in connection with fig. 4a and 4b are described in more detail.

It should first be mentioned that the standard link also, or especially, includes a key generator as well as a reset link device, which is necessary for the provision of the processing of the individual impulses and frequency ranges. As a transmission medium 10, 12, e.g. be arranged two conductors for the control line and also two conductors for the voice transmission line, which is arranged in the form of a ring line. As another possibility, however, a common ring line can also be arranged, e.g. a coaxial cable. Here, both the control "road" and the voice transmission "road" have an assigned frequency range with bandwidth B, since B-j. denotes the bandwidth for the control path and BKn denotes the bandwidth for the voice transmission path n. In this second case, the coupling element according to fig. 2a and fig. 2b as well as according to fig. 3, designed in the form of a modulator, respectively demodulator, which modulates, respectively demodulates, the information in a specific frequency range of these. Likewise, in the case of a common ring line, the coupling element of the speech transmission line is replaced by modulation and demodulation elements, respectively, which - controlled in pairs by means of the LSI switching circuit - allow access to the selected speech transmission path with the bandwidth BK^ for the entitled subscriber site.

UR denotes a fixed voltage regulator for generation

of a regulated supply voltage for the subscriber link (LSI switching circuit, switching stage, signaling device, etc.). C1 and C2 denote filter capacitors. D1, C3 and R5 form a switching network for resetting the switching circuit when the system is switched on. R4 and C4 form an RC circuit to generate the oscillator frequency with which the switching circuit operates. With A is designated a Reed relay. D2 denotes a

• free-wheeling diode, as R1 and R3 cause limitation of the flowing current through the diode to the couplers K1 and K2. R2 must limit it through the capacitor to the connecting element K2 liquid current. K1 and K2 constitute the high current transfer ratio optical switching element. The LED serves for optical signaling of the port state. PDq to PD^ serve for the function coding. This is provided by individual connection of the crossing points E1, E2, E3, E4/A5 and E1, E2, E3, E4/A6. The crossing points E1 - E4/A1 - A4 serve to influence the selector keyboard and to interrogate the sensors, respectively the switching elements. Above the output A7, an alarm or call signal is emitted in square form, which is provided by the LSI switching circuit or by means of a corresponding control program. The oscillator Osz serves in conjunction with R4, C4 for internal clock generation of the switching circuit. Vcc denotes the positive supply voltage. The reset serves, in connection with R5, C3, D1, a defined start-up of the control program sequence when the system is switched on. Through the input E5, the voltage level of the information ring line is sensed across the switching device K2. Output A8 serves for control

of the switching device K2 for control signal transmission. Output A9 is used to control the LED switching circuit. Outputs A10 and A11 are freely available, e.g. for connection of the centrally arranged alarm device. AK1 to AKn serve to control the voice transmission line selected therein,

and is f., e.g. in the form of relays. The numbers 0-9 denote a selection keyboard for entering the subscriber's call number. TO denotes a key for triggering the eri gate opener.

With GA, a key, or switch, for signaling call reception, or connection interruption, is designated. S1 to S4 are switches, respectively a sensor field, for alarm functions etc.

The above embodiment refers to that in fig. 4a showed apartment speech place. With the exception of the following exceptions, the same design applies to the gate location according to fig. 4b. In this case, output A7 serves to control the gate opener relay (relay B), output A9 serves to control the LED switching circuit (busy indication of the called voice station SPS). The door opener key TO and a key GA are missing here. The function coding field is connected corresponding to the function to a port location.

In addition to the embodiment described above, a number of further connection possibilities and application cases are of course conceivable. For example the transmission medium must in no way consist of an electric wire, but other transmission media are also conceivable, such as e.g. modulated light transmission over glass fiber cables.

Claims (10)

1. House system for the transmission of information, with a) several interconnected subscriber sites (TL1, TL2; SP1-SP4) without central transmission, b) an electrical power supply, c) parallel arrangement of all subscriber sites to the transmission medium (10, 12), d) where the system is designed so that at each subscriber location there is an essentially identically structured circuit (14, 15, 16), whereby the individual desired function blocks are connected to a selector keyboard or technically equivalent selector device, e) as these circuits are connected to each other over a single control transmission medium (12), such as an electrical wire, by interconnecting connection elements (17, 18), f) with the individual subscriber locations coded corresponding to their functions by means of connected electrical coding elements (22), g) in order to process and encode information using the technical features (c) to (e), send, receive, decode and evaluate information via the transmission medium to other subscriber locations and to control them easily e the equipment of the facility such as loudspeakers*, bells, switches etc., 'characterised 'by. h) design of identically structured circuits as high-integrated circuits (14, 15, 16) with the following circuits: I. a first circuit for recording the operation of the selector switch or the state of sensors or switch element, encoding the provided information in a corresponding pulse train and together with control data corresponding to the provided key information is delivered to the control channel for the transmission medium, II. a second control circuit for receiving, evaluating via the control channel (12) received pulse trains containing control information and providing a corresponding control signal for a communication channel selection element or for the signaling device, III. a third circuit for reading the subscriber address out of the pulse train provided from the control channel (12) and for verifying the conformity with the own address, i) arrangement of voice path selection elements (19) between highly integrated circuits (14, 15, 16) and overfo -ring medium (10), j) two coupling elements (17, 18) connected to each other between the control line (12) and the highly integrated circuit of each subscriber location to transmit binary-coded control signals, k) several speech path channels (10) in addition to a single control channel (12), as each subscriber site is automatically connected to the next free voice channel when the selected voice path channel (12) is occupied. 2. Installation according to claim 1, characterized by an integrated step program store in the highly integrated circuit (14, 15, 16) of each subscriber site. 3. Plant according to claim 1, characterized by a standard connection (24) for the highly integrated circuit (14, 15, 16) which has a timer and a reset circuit. 4. Installation according to claims 1-3, characterized by a device at each subscriber location for sensing, registering and storing the status of the control line, the selector keyboard and the sensor field. 5. Installation according to claims 1-4, characterized by a blocking device at each subscriber location (TL1, TL2; SP1-SP4), which blocks the connection to some or all other subscriber locations by providing a communication connection. 6. Installation according to claims 1-5, characterized in that the coupling elements (17, 18) from the highly integrated circuit (14, 15, 16), preferably a microcomputer (14) receive pulse trains with distances corresponding to the control information to be transmitted and transmit a keyed frequency corresponding to the different pulse intervals of the control channel (12) or in reverse order of the keyed frequency received from the control channel in a corresponding pulse train to the highly integrated circuit (14, 15, 16). 7. Installation according to claims 1-6, characterized by a speech path selection element (19), which is connected between the highly integrated circuit (14, 15, 16) and the speech path channels (10) and which, due to control pulses coming from the highly integrated circuit, selects a free voice line or carrier frequency. 8. Installation according to claims 1-7, characterized in that a signal device (20) is arranged, which receives a pulse train from the highly integrated circuit, which denotes a specific functional state, such as an open gate, and triggers a corresponding signal indication, such as an acoustic or optical signal in the signaling device (20). 9. Installation according to claims 1-8, characterized by a circuit device (21) for peripheral devices, which due to a pulse train coming from the highly integrated circuit (14, 15, 16) triggers these peripheral devices. 10. Installation according to claims 1-9, characterized by a feedback circuit between the transmitter coupling element (17) and the receiver coupling element (18) so that the binary coded control information delivered via the transmitter coupling element (17) to the control channel is delivered via the receiver coupling element (18) as a feedback signal also to the receiver of the highly integrated the circuit. 11- Installation according to claim 10, characterized by the following elements in the feedback circuit: a) a short-circuit connection between the transmitter coupling element (17) and the control line (12), b) an opto-electronic circuit connected to the control line (12), which delivers an optical signal corresponding to the short-circuit signal to a photosensitive element (K) in the receiver coupling element (18), which supplies a corresponding feedback signal to the receiver for the integrated circuit (14, 15, 16).