NL1024800C2 - Home communication system with two-wire subscriber connection. - Google Patents

Description

Short indication: Home communication system with two-wire subscriber connection.

DESCRIPTION

The present invention relates to a home communication system with at least one door station and at least one home station, wherein at least the / each home station is connected or connectable via a two-wire line for transmission of control and / or communication signals as well as a supply voltage.

Furthermore, the invention also relates essentially to so-called "1 + n installations", wherein the door station acts as a switching center. Each home station is connected via its own line to the door station as well as to a common ground line. The "1" in "1 + n" stands for the mass conductor, the "n" for the number of home stations and therefore the individual conductors. The supply voltage from a mains supply is then fed to the door station and from there via two conductors to the individual home stations. In both cases, therefore, at least every home station is connected via a two-wire line for transmitting communication (audio) signals and supply voltage.

Home communication installations such as, for example, intercom systems according to the two-wire bus system are described, for example, in the publications DE 195 48 744 C2, DE 197 16 598 C1, DE 197 16 599 C2 and DE 30 23 988 A1. In these known installations, the door and home stations present consist of different devices for inside and outside, wherein each device is furthermore specially adapted for the application, in each case predetermined, for example as a door station or as a home station. Usually, these are universal devices with a device housing to be installed on a mounting surface (for example a wall), also called "superstructure (0B)". An installation for "built-in (IB)" is only possible in a particularly expensive way 1024800 2 by means of fairly large IB cabinets. In the case of an installation in a building after completion, expensive breaking work is therefore necessary. These known devices therefore lead to higher costs for the manufacture of the individual devices, stock (keeping different devices available) and also assembly.

In the older, non-prepublished German patent application 10160813 of applicant, a modular structure of the stations is proposed, wherein certain modules are connected via an internal bus. However, nothing is disclosed in the patent application mentioned about the technical realization of the internal bus connection.

The present invention is therefore based on the object of designing a home communication system of the type mentioned in the preamble such that with a lower manufacturing, stock and assembly costs a high installation diversity, in particular also with regard to future compatibility. that is, the possibility of later connecting possibly further developed components is achieved.

According to the invention, this is achieved by the fact that at least a part of the door and / or home stations present is modular, each modularly constructed station consisting of at least two modules that are connected or connectable to each other via an internal bus wherein one of the modules forms a bus connector as a connecting member between the external two-wire line and the internal bus and wherein the internal bus consists of at least three conductors, namely a ground line, a common system bus line leading with the ground line and the external two-wire line, and a common data line serving with the ground line for communication between microcontrollers of the individual modules, wherein the module connected to the bus connector does not have to be controlled by the bus connector via 3 separate signal conductors due to the microcontroller present as intelligence in the modules, I wondered.

According to the invention, therefore, the bus connector forms as a two-wire / multi-wire converter a relay stage between the external two-wire line, in particular the external two-wire system bus, and the multi-wire (at least three-wire) internal bus. The bus connector transmits data from the internal data line to the system bus if necessary and if desired under a protocol and level conversion, respectively transmits received data after reverse conversion from the system bus to the internal data line. This means that each module can not only send data to the other module of the associated station, but can also send it independently on the system bus. Consequently, the bus connector is not an "all-controlling instance", but rather a bus connector switch, level converter and processor for address-15 telegrams. This makes the system according to the invention advantageously "future-compatible", because further developed modules do not have to be taken into account in terms of software in existing bus connectors. New modules can control themselves and only use the bus connector for sending and receiving data as well as for power supply, signaling and two / multi-wire conversion.

In a further embodiment of the invention, the internal bus has as its fourth conductor an audio signal line also related to the ground line.

In the preferred embodiment with audio signal line 25, speech signals from all modules are generated on this, which enable speech communication. The bus connector forwards the signals from the audio signal line on the system bus if necessary (for a voice connection). The bus connector herein acts as a two-wire / four-wire converter, which divides speech signals present on the system bus into speech signals received and to be sent.

Further advantageous embodiments of the invention are included in the dependent claims as well as the following description.

The invention will now be further explained by way of example with reference to the drawing. Herein: figure 1 shows a schematic, block diagram-shaped representation of a home communication system in the preferred embodiment as a bus system and in an example of an extension form, figure 2 shows different modules that can be used in the context of the system according to the invention, each in a strong schematic side view, figure 3 an example of a door station in a front view (operating side), figure 4 a schematic side view with exploded parts of the components of the door station in the arrow direction IV according to figure 3, figure 5 a block diagram of a bus connector module Figure 6 shows a block diagram of an audio module, Figure 7 shows a block diagram of a key module, and Figure 8 shows a block diagram of a power supply and bus driver, respectively.

Figure 1 shows an exemplary structure of a home communication system (door intercom system) in an embodiment as a bus system. Conventionally there is provided (at least) one door station 2, which is installed externally of a house door. 25 and a home station 4, which is usually installed internally next to a dwelling entrance door. In the example shown in Figure 1, four home stations 4 are provided. However, the system can be expanded arbitrarily. The stations 2, 4 are all connected via a common two-wire system bus 6. All signals and commands required for communication and connection setup are transmitted via this system bus 30. Moreover, the system bus 6 also serves to supply power to the individual stations 2, 4. For this purpose a central control device 8, also connected to the system bus 6, is provided, which in particular has a mains supply (see also Figure 8). Hereby the control device 8 generates from a supply voltage V5, usually the mains voltage of 230 V, a supply voltage for all stations 2, 4. At least the door station 2 contains a certain number of call buttons 10. When a call button 10 is operated, a digital address code is sent via the system bus 6. This calls up a specific home station 4, which has been programmed in advance to this address code during installation. The home station 4 with corresponding address code generates a ringing tone after receipt. A speech connection with the door station 2 can hereby be established. Speech signals are preferably transmitted analogously via the system bus 6. Moreover, each station 2, 4 can have at least one command key 11 for specific switching or control functions. When a door opening button is operated at the relevant home station 4, a digital telegram is transmitted as a command signal via the system bus 6, whereby a door opener 12 is activated via the control device 8. The data (address codes) are preferably modulated in an inaudible frequency range (for example 50 kHz). Optionally, a video signal can also be transmitted between a camera and a monitor via the system bus 6. In order not to disturb the frequency bands of speech and data, this is then modulated on a high-frequency carrier (e.g. 10 MHz).

In the embodiment shown in Figure 1, furthermore, preferably, a light-activating member 14 is provided for controlling a lighting, for example a stairwell lighting in larger residential houses. The light activator 14 for this purpose receives an individual digital telegram transmitted by a light button from one of the stations 2, 4 as a command signal for activating the lighting. Moreover, the light activating member 14 can also be activated via separate light buttons 6 installed, for example, in a stairwell. The illumination to be controlled is shown in Figure 1 by way of example only by one lamp 16. Furthermore, each home station 14 is assigned, in the usual manner, a storey call button 18 installed for a dwelling entrance door.

According to the invention, the stations 2, 4 are at least partially modular in structure. All stations, the door station 2 and each home station 4 preferably each consist of at least two modules M (see also Figures 2 to 4 for this), which are connected to each other or connectable via a special internal bus 20. For each station 2, 4, one of the modules M forms a bus connector 22 as a connection between the external system bus 6 and the internal bus 20, i.e. the bus connector 20 converts the system bus 6 or its signals into the internal bus 20 respectively. the internal signals transmitted over it between the individual modules M. Here, the internal bus 20 according to the invention consists of at least three conductors.

To this end, reference is made in the first instance to the block diagram of the bus connector 22 shown in FIG. Accordingly, the bus connector 22 has a first interface CN1 for the system bus 6 (BUS-A, BUS-B). The internal bus 20 consists at least of a ground line GND ("Ground"), a system bus line EXTBUS related to the ground line and a data line CMMBUS also related to the ground line. The system bus 6 is routed to all modules via the EXTBUS system bus line. The data line C0MBUS serves for communication between microcontrollers pC of the individual modules M.

The internal bus 20 preferably has as its fourth conductor an audio signal line AUDIOBUS, also connected to the ground line GND.

In a further advantageous embodiment, the internal bus 20 can have two additional conductors ZV + and ZV- for an additional 7 voltage supply. In addition, two additional conductors VIDEO-A and VIDEO-B can be provided in the internal bus 20 for transmitting video signals.

Figure 2 shows, by way of example, different types of modules M, which can be provided within the home communication system according to the invention in virtually random combinations for forming door and home stations 2, 4. A first module M is formed by the bus connector 22. Furthermore, a key base module 24 is shown, which can be electrically and mechanically connected to a key module 26. The key modules 26 are preferably formed as surface-mounted modules, which can be plugged into the basic module 24 designed quickly and easily. In addition, however, a key module 26 can preferably also be plugged onto the bus connector module 22, the latter taking over the function of a key base module. According to FIG. 2, an audio module 28 with a free speech function and / or a listening module 30 for connecting a telephone receiver 32 (see FIG. 1) may be provided. Moreover, still further modules, not shown in Figure 2, may be provided, for example a video module with a camera and / or a display (monitor) and / or a voice recorder module for audio recording and / or an image recorder module for image recording.

In terms of hardware, the said modules can preferably be designed partly as built-in elements for installation in conventional electrical installation boxes and partly as build-up elements for mounting them on one of the insert modules. Details of this are contained in the aforementioned German patent application 10160813.6, to which reference is made in full herein.

According to the invention, each module M has at least one interface 34 for the internal bus 20 in the form of a suitable plug connector. The interfaces are connected directly by stitches between each component and the associated component. For connecting the internal bus between the built-in modules, suitable connecting lines 36 with the necessary conductors are provided, at least three, preferably six or eight. These connection lines 36 have suitable plug connectors 38 for connection to the interfaces 34. The bus connector module 22 also has connection elements 40 for the external system bus 6 and connection elements 42 for one of the storey call buttons 18 and preferably connection elements 44 for an additional supply line 46.

In the following, further details concerning the special embodiment of the internal bus 20 will be explained more precisely.

In order to obtain a simple construction of the modular stations 2, 4 and to keep the number of signal wires in the internal bus 20 low, the following signals 15 for the internal bus 20 are generated in the simplest embodiment:

The system bus 6 is passed on to all modules via the line (EXTBUS). They derive the DC voltage for their own power supply from this line and receive voice and, if necessary, data signals depending on the device specification. The second conductor 20 of the system bus 20 is realized by the ground line GND ("Ground").

The speech signals to be transmitted, which is generated in the device by speaking into a microphone of a horn 32, for example, are collected on the line 25 designated as AUDIOBUS. These signals do not necessarily have to be sent over the system bus 20, but can also be exchanged between the modules of a station, for example the delivery of voice messages from a voice recorder to the audio module 28. This line is ground-related to the ground line GND.

30 All modules M with a higher degree of complexity contain a microcontroller μθ. Data exchange between the 9 microcontrollers is carried out via the additional COMBUS communication line. This pipe is also massage related on GND.

The EXTBUS and GND cables are implemented in the bus connector 22 in terms of hardware.

5 The signals for the COMBUS line are generated in all modules by microcontrollers. This is a serial bus with a dominant and a recessive level (so-called I2C bus). Recessive levels can thereby be exceeded by the dominant levels. Consequently, the transmission stages of two simultaneously transmitting modules 10 cannot be disturbed. The recessive level is thereby generated by a pull-up resistor in the bus connector 22.

The speech signals on the AUDIOBUS are generated by all modules that enable speech transmission (listening module, audio module, voice recorder). The bus connector 22 switches the signals from the AUDIOBUS to the system bus 6 if necessary (voice connection). The bus connector 22 acts as a two-wire / four-wire converter, which distributes the voice signals present on the system bus and transmits voice signals to individual wires received from the AUDIOBUS.

The bus connector 22 transmits, if necessary and under protocol and level conversion, data from the COMBUS to the system bus 6, or receives received data after reverse conversion from the system bus 6 to the COMBUS. Thus, each module can not only send data to the other modules of a device, but can also send it independently on the system bus 6. The bus connector 22 is therefore not the all-controlling body, but rather a bus connector switch, level converter and switching stage (processing of address telegrams). This ensures that the system is "future-compatible", because new software developments do not yet have to be taken into account in the existing bus connectors by software. The new modules, on the other hand, will control themselves and use the bus connector 22 for sending and receiving data as well as for power supply, signaling and two / four-wire conversion.

The individual components and the way in which they generate and use signals are described below.

5 Bus connector (Figure 5)

The bus connector 22 is present as a basic module in each subscriber station 2, 4. The bus connector 22 is connected to the system bus 6 via the connections 40 (BUS-A and BUS-B). This carries direct voltage (for example 28V). A rectifier 48 makes a polar neutral connection possible.

If video signals are also transmitted over the system bus 6, an optional video filter 50 (RF chokes) prevents the video signals from penetrating into the bus connector 22. These would otherwise be disturbed by the input resistance of the bus connector 22, which is low in the high-frequency range. .

A voltage regulator 52 connected behind the rectifier 48 generates from the positive connection of the relatively high DC voltage of the system bus 6 the lower operating voltages (e.g. 10 V, 5 V) necessary for the bus connector 22 for the microcontroller and the amplifier circuits. The negative connection of the system bus 6 provides the ground potential 6ND.

Between the rectifier 48 and the voltage regulator 52 there is preferably still an electronic inductance 54 (gyrator). This provides a high input resistance in the voltage regulator 52 and decouples load fluctuations from the system bus 6 caused by the voltage regulator 52. The high input resistance avoids a load or level reduction of the speech and data signals. Load fluctuations are generated, for example, by switching operations or in the amplifier stages and would be mixed with the speech signals on the system bus 6 without gyrator 54 as clicks or distortion. These would then be heard during a conversation. The 11 output of the rectifier 48 can be switched via a switch ENBUS to the signal EXTBUS, i.e. the signal EXTBUS then corresponds to the positive line of the system bus purified from the video signal. The EXTBUS signal is routed to three further plug connectors from the bus connector with GND to other modules.

The ENBUS switch is only closed in the active state of the bus subscriber (voice connection, eavesdropping of voice recording), in which it absorbs a high load and must receive and output the transmitted voice signals from the other call participants by the system bus 6. In this state, the input impedance in the subscriber also decreases, because the gyrator 54 is bypassed for all loads hanging on the EXTBUS.

The switch is open in the inactive state. In this case the EXTBUS receives a smaller voltage with a lower power output via a disconnection diode 56 from the output of the gyrator 54. This voltage then only serves to supply the further microcontroller 57 internally in the module (necessary for, for example, processing of a key operation). The input impedance in the subscriber corresponds to that of the local gyrator. Voice signals are not transmitted by the system bus 6. Received data signals from the system bus 6 bypass the video filter 50 and the rectifier 48, if necessary, and arrive via a data processing 58 (filter, amplifier, level adjustment) for processing at the microcontroller 57 (DATAIN). Data signals are, for example, a call request from a door station with subscriber address present. The bus connector 22 processes these addresses and, in accordance with a pre-programmed address, causes a ring tone via the COMBUS. The COMBUS is also routed to plug-in connectors to further modules.

Via the COMBUS, the microcontroller of the bus connector 22, for example, receives a request from a key module to activate the 12 door opener. This request passes this on under level and protocol conversion via a transmit stage 60 (amplifier, filter, level converter), the rectifier 48 and, if present, the video filter 50 to the system bus 6. In advance, it must actively activate the transmitter stage 60 via a signal ENOUT. As a result of this switch-off, the output of the transmission stage becomes high-impeded, so that the signal levels on the system bus 6 are not loaded in the inactive state of the subscriber.

In an active voice connection with a further bus subscriber station, the AUDIOBUS is switched by the microcontroller 57 via a switch 10 ENAUDIO to the transmission stage 60. The transmit stage 60 is active and transmits the speech signals from the receiver or the audio module from the AUDIOBUS to the system bus 6 after a level adjustment. If the speech signals are transmitted only within one subscriber, for example from a voice recorder to the audio module, the switch ENAUDIO is opened and the AUDIOBUS is separated from the transmit stage 60. Consequently, also during an internal speech signal transmission, data signals without speech signals can be sent via the transmission stage 60 to the system bus 6.

In series with the output of the transmission stage 60, a local operating resistance (corresponding to a telephone loop) which allows simultaneous transmission from the low-ohm transmission stages 60 of two subscribers to the bus 6. Half the level is then achieved on the system bus 6 on account of the voltage divider forming the operating resistances.

According to the above description, a preferably four-core cable is sufficient for connecting the modular components of a bus subscriber station. To this end, the bus connector 22 has three interfaces (CN3, CN4, CN5 according to the number 34 in figures 2 and 4), to which further modules can be connected.

In the case that the individual modules have a higher current consumption, which can no longer be obtained from the 13 system bus 6 in large installations, the connection of an additional power supply (ZV-A, ZV-B) is possible. The higher current consumption is necessary for a call button illumination, for example. To this end, the bus connector 22 has a terminal CN2 with ZV-A and ZV-B, to which a direct voltage with arbitrary polarity is connected. In the case of smaller installations, however, it is possible to obtain the additional power supply from system bus 6 if the bus line is connected (additionally) to terminals CN1 and CN2 simultaneously. A second rectifier 62 again enables a pole neutral connection. A second video filter 64 disconnects the video signals from the input. The bus connector 22 does not need additional power. The output lines ZV + and ZV- of the rectifier 62 go directly from the interfaces of the bus connector to the further connected modules. In this case, the four current cores of the internal bus 20 are expanded by two cores to six cores.

An additional interface CN6 is available if video signals are also transmitted via the system bus. The system bus 6 in the bus connector 22 is directly routed to this interface. In addition to the six-pole interface, an additional cable is routed to this interface to a video module (camera or display module). The interface does not necessarily have to be carried out separately. The two cores of these can also be integrated in the interface CN3, CN4 and CN5, so that an eight-pole interface is created here. This is not implemented in the exemplary embodiment shown, because the contribution of door intercom installations with video transmission is very small, there is only one video transmitter / receiver per subscriber and the general application of an eight-pole cable would be too expensive.

Audio module (listening / speaking module; figure 6)

To build up a voice subscriber, a voice processing module 28 or 30 is connected to the internal bus 30. This module is either a listening built-in element 30 with horn 32 with speech microphone, horn style and call loudspeaker or a speech input element 28, to which a speech building element 33 (see Figure 4) with microphone and loudspeaker must be connected. The block diagram shows how the signals from the internal bus 20 are used.

The EXTBUS goes directly to a first voltage regulator 66, which controls the supply voltage for the microcontroller 67. The power delivered to the microcontroller is very low and can be taken from the gyrator 54 in the bus connector 22 (switch ENBUS opened). The voltage regulator 66 has a special construction which has a high-resistance input for alternating signals. This is necessary for the active state 10 (switch ENBUS in the bus connector 22 closed), because the controller 66 lies almost directly on the system bus 6.

The microcontroller 67 is connected via the COMBUS to the microcontrollers in the bus connector 22 and in the further modules. For example, as mentioned above, the microcontroller of the bus connector 22 receives the request to generate a ring tone. For this purpose, the microcontroller 67 switches on the local gyrator 68 via POWERON with a second voltage regulator 70 that is downstream. This controller 70 supplies the high current required for the call flow and a subsequent voice output. To this end, the bus connector 22 switches the system bus 6 on the EXTBUS to supply the required power to the controller 70 via the switch ENBUS.

The local gyrator 68 ensures that precisely the gyrator 54 is bridged in the bus connector 22, so that switching and supply currents from the local amplifier circuits are not directly transferred to the bus 6, but are smoothed out in advance (weakened).

A speaker and microphone amplifier 72 is supplied by the second voltage controller 70. The microcontroller 67 sets the call or speech volume necessary or set by the user via VOLCON and causes a personal ring tone melody via RUFT0N 30. This is applied to a summation point 74 located in front of the loudspeaker amplifier 72, amplified via the loudspeaker amplifier 72 and delivered via a call loudspeaker in the listening or speaking module.

If the receiver 32 is picked up in the case of the listening module, this is then communicated to the microcontroller 67 via a so-called fork switch not shown here. This then switches off the call loudspeaker and reduces the volume of the amplifier. The EXTBUS for switch signal and at the summation point 74 is switched via the ENEXTBUS switch. The speech signals sent from the other side to the system bus 6 are therefore adjusted in the loudspeaker amplifier 72 to the desired delivery loudness and transmitted to the currently active listening capsule in the receiver or to the loudspeaker in the speaking module.

The own speech signals are transformed by the microphone into the horn 32 or the speech component 33 and supplied to the microphone-amplifier 72, which transmits it via the AUDIOBUS with the DISAUDIO switch closed to the bus connector 22, which in turn passes it over the system bus 6 on the other side. In order to reduce the volume of the self-generated speech signals in the own loudspeaker, which are fed back via the EXTBUS to the loudspeaker amplifier 72, the AUDIOBUS is inverted connected to the summation point 74 (back-listening suppression). This ideally leads to the extinguishing or at least suppressing of returned speech signals in the loudspeaker.

When it concerns a speech module (speech integration element), which makes it possible to speak freely without a toggle key, the block of loudspeaker and microphone amplifiers 72 additionally comprises a special speech-free switching circuit (IC). This prevents local feedback from the "microphone -> AUDIOBUS -> system bus -> EXTBUS -> loudspeaker" chain and provides for a voice-controlled forward and reverse switching of the direction of speech (voice balance, return calls).

The AUDIOBUS itself can also be switched at the summation point 74. This is necessary if, for example, a local voice recorder has to be listened to via the loudspeaker of the horn or speech module. To do this, the ENAUDIO switch is closed and the DISAUDIO switch is opened.

5 A voice recorder has essentially the same structure as the listening / speaking module. However, this includes a magnetic tape or a digital voice recorder medium (IC). Because the voice recorder only transmits or receives from the AUDIOBUS, the ENEXTBUS switch is not necessary. A listen-in suppression also lapses, because either 10 is only sent (eavesdropping) or received (spoken). Only the DISAUDIO switch is closed when transmitting, only the ENAUDIO switch is closed when received.

Key module (key structure element; figure 7)

The key module 26 allows the sending of a ringing tone from the door station 2 or an internal call from one home station 4 to another or the operation of certain functions of the door or home station (call acceptance, door opener key, light, volume, etc.). This module 26 also comprises a voltage regulator 76 for the local microcontroller 77 with a high-resistance input 20 for alternating signals, which is fed from EXTBUS via the gyrator 54 into the bus connector 22.

The microcontroller 77 processes the operation of the local keys 10, 11 and after a key operation sends a telegram via the COMBUS to the microcontroller in the bus connector 22 or another module 25 (for example, volume adjustment to the listening module 30). However, the microcontroller 77 also switches on or off any status LEDs 79 present (for example, operating, call input or quitting displays).

A call button illumination 78, further shown in Figure 7, is optional and is supplied via the additional power supply (ZV +, ZV-).

A pre-connected current source 80 generates a constant direct current independent of the bus voltage 17, with which the LEDs 79 are supplied. The brightness of the LEDs 79 therefore does not change with bus voltage changes (for example voltage reduction with ring tone generation).

Key-base module (key module): 5 The key-base module 24 (see figures 2 and 4) does not include electronics, but only the transmission of the signals from the internal bus 20 to three plug connectors (2x for the flush-mounted module, lx for the surface-mounted module).

Video module: 10 The video module (camera and display module) not shown here also uses the signals EXTBUS, 6ND and COMBUS. AUDI0BU5 is not applied. Instead, the VIDEO-A and VIDEO-B core pair are present (corresponds to system bus line). The video built-in element can also use its supply voltage for this. 15 It mainly receives or sends its video signals on it. These are in particular transmitted as a symmetrical signal (counter clock signal) on both bus line conductors. This makes the video signals more insensitive to disturbances with respect to the system mass, because it concerns both signals and disturbances in the signal abstraction in the receiver are erased.

Steering:

Figure 8 shows the block diagram of the control device and the net part respectively. The DC bus voltage (preferably approx. 26V) is generated by a transformer 82 from the 230V mains voltage with the rectifier 84 switched off and voltage regulator 86. A gyrator 88 between the regulator 86 and the system bus 6 increases the output impedance of the regulator 86 for alternating signals , such as speech and data. The levels of this would otherwise be greatly reduced due to the low output impedance of the voltage regulator 86. However, the output impedance for direct current remains small.

18

With a video filter not shown here at the output, any RF video signals on the bus line 6 can be disconnected from the output of the gyrator 88 which is low-ohmic in this frequency range.

Optionally, the control device 8 or the network part receives a microcontroller 87 with data processing and transmission stages, not shown here, in accordance with the bus connector 22. The microcontroller 87 sends a relay 90 for a door opener upon receipt of a special telegram from the home stations (door open button). The door opener is fed from a further secondary winding of the net transformer.

Furthermore, the control device 8 optionally receives further direct voltage sources for providing an additional power supply. These are obtained from a third secondary winding with the rectifier 92 and controller 94 connected behind. Alternatively, however, a possibly required additional power supply 15 can also be withdrawn from a separate, non-shown net part (without gyrator) (for example, a simple DC "rail net part").

Advantages of the preferred structure:

Arbitrary extension of a subscriber station with a key module (call keys) (only limited by the power output of the bus connector). Each call button accessory has its own intelligence and does not have to be controlled or interrogated by the bus connector via separate signal wires. Failure of a call key builder does not result in failure of the subscriber station as a whole; 25 - Random expansion of a subscriber station with further modules with or without processing of voice signals (voice recorder) or fingerprint switch); only limited by the power output of the bus connector;

Only one transmit stage on the system bus in the bus connector is required; 2/4-wire conversion in the bus connector generates two speech signal paths for speech signals to be received and transmitted and enables the simple switching on of further modules, such as, for example, voice recorders with separate speech inputs and outputs.

Mechanical: arbitrary construction of home / door stations through different concatenation of modules above or below each other, also in connection with other components of the electrical installation (switch, PIR detectors, ...)

Alternative structure:

The AUDIOBUS will also be canceled if the structure is also possible. In this case, transmitted speech signals are sent directly over the system bus 6 by the listening / speaking module on the EXTBUS and with a speech connection (switch ENBUS in the bus connector closed). The advantage is the reduction of the internal bus 20 with one conductor. However, in this case each speech-processing module, such as the bus connector, must have its own interruptible transmit stage with operating resistance to the EXTBUS. The two-wire / four-wire conversion of the speech signal path then takes place in the listening / speaking module.

Furthermore, it is again noted that in the case of the home communication system, contrary to the current concrete description, this can also be a so-called "+ ln installation".

Here, the bus connector 22 serves in each home station 4 as a connecting member between the internal bus 20 according to the invention and the external two-wire line, wherein the door station 2 accordingly has a multi-core connection (for each connected home station 4 a separate wire plus a common ground wire).

The invention is not limited to the exemplary embodiments shown and described, but on the other hand also encompasses all embodiments operating in the same way within the meaning of the invention. Furthermore, the invention has hitherto not been limited to the combination of features defined in claim 1, but can also be defined by any other combination of particular features of all the individual features disclosed in totality. This means that substantially any individual feature of claim 1 can be omitted or replaced by at least one individual feature disclosed at another location in the application. In this respect, claim 1 is to be understood solely as a first formulation attempt for an invention.

10 1024800

Claims (7)

Home communication system with at least one door station (2) and at least one home station (4) wherein at least the home station (4) is connected via a two-wire line (6) for transfer of control and / or communication signals and a supply voltage or can be connected, characterized in that at least a part of the door and / or home stations (2, 4) present is modular, each modular station (2, 4) consisting of at least 10 two modules (M) which are connected or connectable to each other via an internal bus (20), one of the modules (M) forming a bus connector (22) as a connecting member between the external two-wire line (6) and the internal bus (20) and wherein the internal bus (20) consists of at least three conductors, namely a ground line 15 (GND), a system bus line (EXTBUS) continuing with the ground line (GND), the external two-wire line (6) and a common line with the ground line line (GND) for communication between microcontrollers (pC) of the individual modules (M), data line (COMBUS), the module (M) connected to the bus connector (22) resulting from the intelligence in the modules ( M) microcontroller (pC) present does not have to be controlled or interrogated via separate signal conductors through the bus connector (22). System according to claim 1, characterized in that the internal bus (20) has as its fourth conductor an audio signal line (AUDIO bus) related to the ground line (GND). System according to claim 1 or 2, characterized in that the internal bus (20) has two additional conductors (ZV + / ·) for an additional voltage supply. System according to one of claims 1 to 3, characterized in that the internal bus (20) has two additional conductors (VIDE0-A / B) for transmitting video signals. 1024800 System according to one of Claims 1 to 4, characterized in that the module for each station (2; 4) is a bus connector module (22) and at least one key module (26) with at least one electrical switch button (10/11) and / or at least one button base module 5 (24) and / or at least one audio module (28) with a free-talk function and / or at least one listening module (30) for connecting a telephone receiver (32) and / or at least one video module with a camera, and / or a display and / or at least one voice recorder module for audio recording and / or at least one image recorder module for image recording has been provided. System according to one of claims 1 to 5, characterized by an embodiment as a two-wire bus system, wherein all stations (2, 4) are connected via a common two-wire line forming a system bus (6). System according to one of claims 1 to 6, characterized by an embodiment as a so-called "1 + n installation", wherein all stations (2, 4) via a common ground line and each home station (4) via a separate line are connected to the door station (4). 20 i 024800