NO842239L - DEVICE FOR EXPATIBLE TRANSMISSION OF SOUND SIGNALS - Google Patents

Description

Device for dispatchable transmission of audio signals The invention relates to a device for dispatchable transmission of audio signals between several subscriber stations which are connected by a transmission line, while at the same time transmission of audio signals and control signals takes place by carrier frequency modulation.

Such a device is known from DE-PS 29 46 177. Ved

the known device is several participant stations connected in parallel with a transmission medium. The participating stations can connect with each other as they choose, i.e. dispatched. Control signals needed for the expedition are transmitted over separate control lines or over separate transmission channels on the same transmission medium as the audio signals. Such a device is relatively expensive due to the separate cables or transmission channels that are needed for the transmission of control signals. A separate wiring network is required for the mutual connection of the participating stations.

In the trade, there are exchange systems that do not need to

some separate connection line, as the audio signals are transmitted over the mains using a frequency-modulated carrier frequency. These exchange systems enable within their reach only

a single PBX connection. As the range mostly extends to several households, the power grid that serves for transmission is also covered in neighboring households, so

it is possible at all times<*>to eavesdrop on conversations. A remedy is possible by installing carrier frequency barriers at the feed into the network in each household. However, such carrier frequency barriers can only be installed by an authorized installer. But in doing so, one renounces a significant advantage of the devices without their own cable, namely the possibility of using them without any installation work whatsoever.

The task of the invention is therefore to design a device

of the kind mentioned at the outset so that an expedient transfer becomes possible without separate control channels.

According to the invention, this task is solved in that where transmission line is used by the mains, and that the audio signals are transmitted by frequency modulation of the carrier frequency and the control signals by amplitude modulation of the same carrier frequency.

Both the audio signals and the control signals are thus transmitted over the mains with the same carrier frequency. Thus, the cost is small, as it is only necessary to produce a single carrier frequency. Furthermore, it is advantageous that only one transmission channel is coated, as only a limited number of transmission channels can be realized in the power grid.

To set up a voice connection, a first participant station in a search operation sends a control signal with an address code for a desired other participant station, and the participant station that receives the address code that applies to it sends out an acknowledgment signal if the transmission line is not covered, and the connection is definitively established when a return call is triggered in the other subscriber station. With this setup sequence, a voice connection between two stations is only established by active actions on both participating stations, so it becomes impossible to eavesdrop on existing connections with corresponding devices.

In addition to a freely selectable address code, each control signal can also have an adjustable house code, which limits the possibility of connections to a group of participants with the same house code.

Advantageously, the meaning of each control signal can be determined by the combination of house code and address code as well as corresponding pauses. There is thus no need to select a separate control code. The meaning of each control signal can be determined as follows: (a) House code and address code are sent during the search operation and for receipt. (b) A pause (instead of the house code) and address code are sent to change voice authorization. (c) House code and a pause (instead of the address code) are sent to break the connection.

The control signals are advantageously sent at all times

in the area of zero crossings of the mains voltage. This results in an online synchronous transmission.

Advantageously, the frequency-modulated carrier wave is briefly interrupted during a voice connection, so that the participating station connected to reception can send control signals during the interruption. Thus, the participating station which is connected to reception, e.g. cause a change in direction of speech.

The interruption of the frequency-modulated carrier wave can i

that connection occurs when both the amplitude of the sound signal and its differential quotient with respect to time are small. The interruption of the frequency-modulated carrier wave thus occurs when a speech sound ends and the short-term disconnection of the carrier frequency does not cause any impulse noise.

In order to make it possible to determine whether the aforementioned condition for interruption of the frequency-modulated carrier wave is fulfilled, the audio signal and the differentiated audio signal are advantageously rectified, the rectified signals are added and the sum signal compared to a minimum value in a comparator, and the interruption of the frequency-modulated carrier occurs when the sum signal is below the minimum value.

The minimum value may depend on the setting of

a volume regulator on the participant station concerned. Thus, even in the case of strong environmental noise, a disconnection of the carrier frequency occurs, since in the case of strong environmental noise, a setting of an increased volume can also be assumed.

The minimum value can be increased time-dependently after each transmission of the frequency-modulated carrier wave, as the comparison input of the comparator is connected to a capacitor that can be charged up across a resistor. Thus, even in a loud environment, an interruption of the frequency-modulated carrier wave is forced at certain time intervals, and due to the nevertheless high noise level, the resulting impulse noise is unlikely to be disruptive.

Advantageously, the comparator is followed by a D-flip-flop whose set input is connected to the comparator, and whose control input is controlled in the time range when control signals are permitted, at the same time that the D-flip-flop's set input controls the interruption of the frequency-modulated carrier wave, as the flip-flop's reset input is connected to the capacitor via a diode.

Search operation or return calls from the participating stations can be triggered when the amplitude of the existing voice signal exceeds a pre-given value. Setting up connections and changing the direction of speech is thus voice-controlled, so free exchange of speech becomes possible without manual operation on the participating stations. Furthermore, with such a controlled participant station it is possible to monitor e.g. a children's room, since a connection is only set up when noise is to be transmitted.

Search operation or return calls can in this connection be triggered using the D-flip-flop's outputs and the interruption of the connection controlled using a timer.

Advantageously, each participant station has at least one voice key

and an end key, of which the voice key serves to set up a voice connection or trigger a return call and the end key to terminate an existing connection. With these keys, manual control of the set-up of connections or change of direction of speech.

In alternating speech operation, the right to speak is advantageously established by briefly touching the speech key on the participant station in question and then lasts until either the speech key is pressed on the associated participant station or the end key is pressed on one of the two stations. During speech, there is therefore no need for a permanent key press as with conventional PBX systems. As the participating stations automatically only allow one direction of speech, no collision can occur if both participants want to speak.

Before transmission, the audio signal can be passed through an amplifier with a logarithmic gain characteristic and, upon reception, passed through an amplifier with a mirror-image gain characteristic. Thus, weak signals are amplified over-proportionally before the transmission, so the noise-to-noise ratio is increased. Moreover, with a foreign device which does not exhibit a corresponding amplifier characteristic, one can only listen to the thus transmitted signal in a highly distorted form.

In connection terms, the logarithmic characteristic can simply be approximated with a broken characteristic curve.

A further increase in eavesdropping security is achieved if the audio signal during transmission is inverted in line with the mains, namely mains synchronously at times whose distance from the zero crossing of the mains voltage is determined by the house code, and the inversion is again reversed on reception. This makes it impossible to eavesdrop on an existing connection even with participant stations that have the same design, but have a different house code.

At all participating stations, the carrier frequencies can be derived from the grid frequency. This means that the carrier frequencies for all participating stations are synchronous, so that disturbing noise is avoided during the exchange of signals and when changing the direction of speech. In terms of connection, the derivation can be realized in a simple way with a PLL connection with a frequency divider in the feedback path.

The participant station can have two light signals, one of which lights up as long as the assigned participant station is entitled to speak, while the other light signal lights up as long as the corresponding participant station has a connection with another participant station, provided that this other participant station is entitled to speak, and both light signals lights up to form a blend light during the setup of a connection. Appropriately, the first light signal is green and the second red. Thus, the state of the connection is markedly signaled at all times.

An embodiment of the subject invention will

be elucidated in more detail with reference to the drawing.

Fig. 1 shows a block connection core for a participant station.

There must first be an account of the elements with regard to the direction of transmission. A microphone 13 is via a bi-directional amplifier 11, a scrambler 9 and an instantaneous value compander 14 connected to the input of a frequency modulator 18. The output of the frequency modulator 18 is via a further bi-directional amplifier 15 and a mains connection link 16 connected to the mains. The bidirectional amplifier 15

is also controlled by an amplitude modulator 17 at the input of which control signals from the control unit 1 appear.

Reception of signals takes place with the same elements,

being the amplification direction for the two bidirectionals

amplifiers 11 and 15 are switched, modulators 17 and 18 act as demodulators, instantaneous value compander 14 acts as instantaneous value expander, scrambler 9 acts as descrambler and microphone 13 acts as speaker.

In order to prescribe a carrier frequency for the frequency modulator 18, the participating station also contains a zero voltage detector 20 which is connected to the mains and controls a clock generator 19 to form mains synchronous clocks. The beats generated by the beat generator 19 are supplied to the frequency modulator 18 and the control unit 1.

Furthermore, the participant station shown contains a speech detection link 7 with which it is determined whether a speech signal occurs at the output of the amplifier 11 and which supplies a control signal for the control unit 1.

The scrambler 9 can be put out of operation with a switch 10. The speech detection link 7 can be connected via a switch 8 whose function will be explained in more detail to a further control input to the control unit 1. A switch group 3 is also connected to other inputs to the control link 1 for setting a house code, a switch group 4 for selecting an address code, a voice key 5 and an end key 6.

Furthermore, the control unit 1 has two outputs which are connected to an LED combination 2.

In fig. 1 are parts that are already found in conventional switching stations■ that do not have their own cable and cannot be dispatched, framed in dashed lines.

In what follows, the elements in the form in fig. will be explained in more detail. 1 provided that they are not generally known.

For setting up a voice connection, when changing the voice direction and for interrupting a connection, the control logic 1 sends control signals which are modulated with the amplitude modulator 17 on a carrier frequency and then sent out on the mains. The sequence of control signals required for setup

of a connection, is shown in table 1, specifically for the case that a participant A with its station a has set up a connection to a station b that is served by a participant B.

A detailed diagram of the control logic is shown in fig. 4. The receiving channel 14 is connected to a decoder 22 via an element 17 which acts as a demodulator in the receiving path, while the transmitting channel is connected to an encoder 21 via the element 17, which acts as a modulator in the transmitting channel, as well as an AND gate 44. Furthermore, encoders 21 and decoder 22 connected with code switches 3, 4 for house code and address code. The setup of connections is controlled with a voice key 5, interruption of the connection with an end key 6. A two-colour LED 2 shows the status of the connection at all times. As soon as the participant A presses the speech key 5, the flip-flop 25 is set. The command given with the voice key 5 is stored by the flip-flop 25 until it is executed in the device, so a short press on the key is enough to have the command executed. When the key is pressed, a signal is also delivered via an AND gate 26 to the encoder 21 if the flip-flop 27 which is connected to the other input to the AND gate 26, and which will be discussed later, has not yet been set. With this signal, the encoder 21 triggers a search operation. A search signal is sent via the AND gate 44 and the modulator 17 if the transmission path is not yet occupied. For this purpose, a detector 43 determines whether a carrier frequency signal is already present on the transmission path. In that case, the detector 43, which is connected to a negating input to the AND gate 44, blocks the signal delivery to the modulator 17. Otherwise, a search signal with a house code and an address code is sent. The house code, which will be explained in more detail in the following, serves in this connection to limit the possible connections to a specific transmission area, while with the selectable address code a specific participating station within this transmission area must be selected.

A station b, which is programmed to the relevant house code and address code, receives this search signal via the decoder 22 and sets the flip-flop 27 via an OR gate 29. Furthermore, via the OR gate 28 and an AND gate 30 as well as the encoder 21, a acknowledgment signal. The AND condition of the AND gate is satisfied, as the flip-flop 27 in front of its input was set.

When flip-flop 27 is set, the LEDs 2a and 2b are controlled via the 0G gates 31 and 32. The AND conditions for the AND gates 31 and 32

is fulfilled, as the flip-flop 33 is not yet set. Via the inverting output from the flip-flop 33 and the OR gates 34

and 35 are therefore supplied to the AND gates 31 and 32 one and one "one" signal. When both the green LED 2a and the red LED 2b light up, a mixed color yellow is obtained.

Station a receives the acknowledgment signal via the decoder 22

and sets the flip-flop 27 via an AND gate 36 and an OR gate 29 and likewise sets the flip-flop 37 directly via the AND gate

36. The AND condition for the AND gate 36 is fulfilled, as the flip-flop 25 connected to its second input is set due to the previous operation of the speech key 5. Via the OR gate 23, the flip-flop 25 is simultaneously set back. When flip-flop 37 is set, a voice authorization is stored for station A. With flip-flop 27 in the set state and flip-flop 33 not yet set, the two LEDs 2a and 2b in station b are activated, so that a mixed color yellow. Thus, it is signaled that the connection is possible,

but is not yet fully set up, as participant B has not yet signed up. Participant A can now . speak or by pressing their voice key 5 trigger a call tone via the AND gate 38. The AND condition for the AND gate 38 is fulfilled, as the flip-flop

37 which is connected to its second input is set.

When participant B presses his speech key 5, the flip-flop 25 in station b is also set. By means of the flip-flop 25 in this state, via the AND gate 39 and the encoder

21 sent a shift signal. The AND condition for the AND gate 29

is satisfied, since the flip-flop 27 connected to its second input was already set and the flip-flop 37 connected to its third input has not yet been set. With the shift signal, the flip-flop 33 is also set via the OR gate 40. Thus, the connection between participants A and B is now definitively set up, and participant B is authorized to speak. In station b, the green LED 2a is now controlled via the AND gate 31, as the first input to the AND gate 31 via the flip-flop 27 in set state and other

input to the AND gate 31 via the flip-flop 37 likewise in the set state as well as the OR gate 34 each receives a "one" signal. Thereby, the right to speak is signaled to participant B.

Station a receives the shift signal, as via AND gate 41

and OR gate 40 sets flip-flop 33. The AND condition of AND gate 41 is satisfied, since flip-flop 27 is still set. Via the AND gate 32, the red LED 2b in station a is controlled. Because at the first input to the AND gate 32, the "one" signal from the flip-flop 27 is in the set state, and at the second input via the OR gate 35, a signal from the inverted output of the flip-flop 37 which is not yet set. Participant A thus learns that the connection has been set up and that he is entitled to speak.

If participant A now wishes to speak again, he presses his speech key 5, so in the same way as described for station b, a shift signal is sent and the direction of speech is thus changed.

When a participant wants to disconnect, press

he on the end key 6, so a "end" signal is sent via the encoder 21. Via an OR gate 42, the flip-flops 33 and 27 in the own station are simultaneously reset. The counter station receives via the decoder 22 the "sultf" signal, which likewise via the OR gate 42 resets the flip-flops 33 and 27. Thus, the LEDs 2a and 2b turn off.

During the call, there is therefore no need to press keys permanently. To speak, you only need to press the talk key for a moment, and otherwise the operator's hands are free. As the participating stations automatically only allow one direction of speech, a disadvantage that occurs with traditional switching systems is avoided. Because with these, it is generally necessary to keep a speech key depressed as long as the person in question is speaking. If, however, both participants in the conversation press their voice keys at the same time, no transmission is possible. With these traditional facilities, a certain amount of practice is therefore required in order to be able to conduct an impeccable conversation.

The status of the connection at all times is clearly marked with the status indicator 2. Here "green" means authorization to speak, "red" means authorization to speak for the opposition and "yellow" means setting up a connection.

As already mentioned, the control signals contain a house code and an address code. The house code must be set the same for all devices to which a connection is to be established. Thus, the possibility of connection can be limited to a specific participant circuit, e.g. the members of a household. A connection between neighbors who use identical devices and do not know each other's house code or, by agreement, deliberately use different house codes, is thus excluded. This makes it possible to operate such facilities in neighboring households without carrier frequency barriers and thus without installation costs.

If a (malicious) neighbor finds out the other's house code, he cannot, with a uniform device, interrupt an existing connection in the neighboring household, as his participating station has not undergone the connection setup. When there is still no connection, he can choose a participating station at his neighbour's. But first, in the absence of an answer from the participant in the neighboring household, he only receives call and voice authorization. However, the neighbor now receives information about the unauthorized delaware and can break the connection again.

The address code makes it possible to set up different connections or dispatch participating stations in the same household. It corresponds to the subscriber number for normal telephones.

If another participant who is selected by a first participant with a specific address code/ already has a connection with a third participant, this can be reported optically to the first participant, e.g. when the status indicator flashes. However, in urgent cases, the first participant has the opportunity to break an existing connection by pressing the end key.

He can then set up a connection himself by pressing his voice key.

For the functions shown, four different control signals are needed, namely for the search operation, for the acknowledgment, for the change of voice authorization and for the termination of the connection. To convey these functions, the control signals can contain additional bits in addition to the house and address code. In order to keep the control signal short, however, a combination of house and address code with carrier frequency breaks can also be used to communicate the aforementioned functions. I saw

In this case, the following combinations can be assigned to the individual functions:

Search operation: House code and address code are sent.

Receipt: As search operation.

Change of voice authorization: Pause (instead of the house code)

and address code.

Break in connection: House code and pause (instead of the address).

In this connection, the fact that there is no longer a need for a house code and an address code for changing a voice connection and for interrupting a voice connection is used.

In the design example, the house code and address code show 4

bits each. However, it may be beneficial in individual cases not to utilize all of the respective possible 16 combinations. A redundancy that results from this allows the construction of conference connections and collective calls and enables connection-technical simplifications.

The control signals are transmitted synchronously at all times,

and preferably in the area around the zero crossings of the mains voltage. E.g. a time of 1.67 msec in the area around the mains voltage zero crossings can be defined as control time during which a telegram of 8 bitsy each with a width of 208 us can be transmitted. The necessary online synchronous transmission method is described in German patent application 32 15 081.

In order for a change of call authorization between two interconnected stations to be carried out, the

also the participating station which is just connected to "talk",

be able to receive a control signal from the other participating station. If the carrier frequency modulated with the voice signal is transmitted continuously, it becomes difficult to use the same carrier frequency. This problem is solved by inserting short pauses in the modulated carrier oscillation, which are detected by the station

which is connected to reception, and if necessary can be filled in with a control signal. Such breaks in the modulated carrier oscillation naturally also lead to an interruption in the speech signal and to a corresponding noise if the amplitude of the speech signal is not exactly very small or zero.

In the exemplary embodiment, therefore, each participating station has a device which only allows interruption of the modulated carrier oscillation when the amplitude of the speech signal in the interruption time period is at least very likely to be small.

An exact determination of the amplitude of the speech signal during the interruption time would only be possible with an electronic delay of the transmission signal and thus expensive. An interruption in the modulated carrier oscillation is permitted when the speech signal asymptotically approaches the zero line, i.e. when not only the speech signal, but also its slope (ie its differential quotient with respect to time) becomes small.

In fig. 3 two such cases are illustrated. With

the aforementioned criterion, it is determined that a speech sound is coming to an end. There is a high probability that a pause will follow, as a short-term disconnection of the modulated carrier frequency cannot cause any impulse noise if the carrier frequencies in the two participating states match exactly. This is achieved with a link which will be explained there.

The asymptotic approximation of the speech signal to the zero point can be ascertained with a speech detection circuit as shown in fig. 5. Hereby, the speech signal is supplied to a first and a second rectifier 7b, 7c, respectively directly and via a differentiation link 7a. With a summing amplifier 7d, the rectified speech signal and the differentiated rectified speech signal are added and supplied to an input of a comparator 7e. The comparator 7e compares the sum signal with a minimum value.

This minimum value must be adapted to the minimum sound level

the participant station which is connected to "speech", as the minimum value in case of strong environmental noise is otherwise not exceeded and there thus no signal exchange can take place. A signal exchange

however, it must be possible at least when the speaker takes a short break. The setting of the minimum value could be done with the help of the volume setting potentiometer which is still found on every participating station, as one would then supply the comparator's comparison input with a voltage taken from this potentiometer. It is assumed that the volume in the case of a noisy environment will also be set higher. In fig. 5, however, a connection option is shown where the minimum value is automatically shifted. The capacitor 7h is applied to positive voltage via a resistor 7g, and the connection point between capacitor 7h and resistor 7g is connected to the comparison input of the comparator 7e. The output of the comparator 7e is connected to the set input of a D-flip-flop 7f. At the clock input of the D-flip-flop, a signal appears in the area for the zero crossings of the mains voltage for the already mentioned control time in which the transmission of the control signals must take place synchronously with the mains.

At the set input Q from the D flip-flop 7f, a signal appears with which the interruption of the modulated carrier oscillation is carried out. The reset input Q of the D flip-flop 7f is via a diode 7i connected to the connection point between capacitor 7h and resistor 7g.

At a function as described so far, the set-up was

of the connection carried out using voice or end key. However, in many cases it is appropriate to set up a connection with a preselected participant station as soon as a voice signal is available at a participant station. This applies above all to an application for monitoring

of children's rooms where any noise or voice button operation must be communicated to a pre-selected participant station. In this case, the output Q from the D flip-flop 7f in the speech detection circuit 7 is connected to the control logic 1 via the switch 8 in fig. 1. The signal that appears there then fulfills the same function as the voice key. As soon as the microphone 13 emits a low-frequency signal higher than a minimum value, the intended second participant station is automatically selected, and the noise becomes

reproduced there. Interruption of the connection takes place via a time switch. The signal at output Q, which is delayed a few seconds, takes over the function of the stop button. Thus, the carrier frequency is only useful when noise is to be transmitted. After a few seconds of calm, the network is free again. Thus, disturbing noise caused by network disturbances becomes inaudible during the relatively long rest periods.

If both of the participant stations that connect to each other are voice controlled, i.e. that the switch 8 in both participant stations is operated, a free exchange of speech is possible without manual operation of the participant stations. Changing the direction of speech is then voice controlled.

As already mentioned, the carrier frequencies in all participating stations must match exactly. This can be done e.g. achieve with a mains synchronous clock shift coupling as shown in fig. 6. This link consists of two consecutive PLL links (phase locked loop links). The first PLL connection consists of a phase comparator which is supplied partly with the output signals from the zero crossing detector 20 and partly with the output signals from a frequency divider 19e. The output of the phase detector is connected via an RC link 19b, 19c to a controllable oscillator 19d which in turn controls the divider 19e on the output side. At the output of the frequency-controllable oscillator 19d, a voltage with a frequency equal to the mains frequency multiplied by the dividing factor for the divider 19e therefore appears there. This voltage has a fixed phase relationship with the mains voltage and is used as a reference voltage for another PLL link. For this purpose, it is supplied to a first input of a phase detector 19f whose second input is connected to the output of a divider 191. The output of the phase detector 19f is connected via a resistor 19g to the input of a further frequency controllable oscillator 19k whose output in turn is connected with the input to the divider 191. The input to the frequency controllable oscillator 19k also receives the output signal from the microphone 13 via an amplifier 19h and a capacitor 19i. A modulation of the carrier frequency is thus achieved.

With the connection shown, you get a midpoint frequency that is in a fixed relationship to the mains frequency and is therefore the same for all stations. With the first PLL connection, the mains frequency can e.g. is increased by a factor of 96 to 4.8 KHz and then in another PLL connection is again increased by a factor of 25 to 120 kHz.

The connection in fig. 1 also contains connecting elements to improve the noise distance and the eavesdropping protection, namely the instantaneous value compander 14 and the scrambler resp. the descrambler 9.

The speech signal passes through the instantaneous value compander

before sending an amplifier which in the ideal case has a logarithmic gain characteristic, i.e. large gain for small signals and small gain for large signals. Upon reception or reproduction, this intentional non-linear signal distortion is again reversed by a non-linear gain with exact mirror-symmetric gain characteristic. By means of the over-proportional attenuation of small signals that thus occur, noise signals that occur on the transmission path, e.g. unavoidable network disturbances, heavily suppressed. In the case of the previously known devices, such disturbances have had a considerable influence on the transmission quality, particularly when speaking at a low level and during breaks.

The logarithmic characteristic can be approximated with a broken line according to fig. 7 for the broadcast or fig.

8 for the reception. The broken characteristic according to fig.

7 can be realized with a correspondingly connected operational amplifier 14a according to fig. 9. The operational amplifier 14a has in series in a feedback branch two series-connected resistors 14c, 14d, of which the resistor 14d is shunted with an antiparallel connection of two diodes 14e and 14f. The input signal is supplied to the operational amplifier via a resistor 14b. As long as a voltage appearing on the anti-parallel connection of the diodes 14e and 14f does not exceed their threshold voltage, the series connection of the resistors 14c and 14d acts as feedback resistance. If the threshold voltage for the diodes is exceeded

14i and 14f, only resistor 14c is still active, so the gain is reduced from a breakpoint predetermined by the threshold voltage of diodes 14e and 14f.

The broken characteristic in fig. 8 can be realised

with a coupling according to fig. 10. Here, an operational amplifier 14g exhibits only a feedback resistor 14m.

In front of the input to the operational amplifier 14g is a parallel connection of a resistor 14k and two diodes 14i, 14h with anti-parallel connection. In series with this parallel device is a further resistor 141. With this device, the series connection of the resistors 141 and 14k acts as input resistance as long as the voltage on the anti-parallel connection of the diodes 14i and 14h does not exceed their threshold voltage. The gain is therefore small to begin with. If, on the other hand, the mentioned threshold voltage is exceeded, the resistor 14k is bypassed and the gain is increased due to the reduction in effective input resistance.

With the instantaneous value compander shown there is achieved

an improvement not only of the noise distance, but also of the eavesdropping security. Because with a foreign device that does not have a suitable compander, the compressed signal can only be listened to in a highly distorted form. A further improvement in eavesdropping security can be achieved with a so-called scrambler. The voice signal is then analogically inverted with a clock frequency of 50 Hz or a multiple thereof, and mains synchronously at times whose distance from the zero crossing of the mains voltage is determined by the house code. Such a signal can only be distortion corrected in the descrambler if it is set to the correct times. A distortion correction is therefore only possible with a participating station that has the same house code. A scrambler therefore not only improves security against eavesdropping with foreign devices, but also with identical devices with a different house code. The scrambler and descrambler are only in operation when the switch 10 in fig. 1 is finished.

Claims (22)

1. Device for dispatchable transmission of audio signals between several participating stations which are connected by a transmission line, at the same time that the transmission of audio signals and control signals takes place using carrier frequency modulation, characterized in that the power grid serves as a transmission line, and that the audio signals are transmitted by frequency modulation ion of the carrier frequency and the control signals by amplitude modulation of the same carrier frequency. 2. Device as stated in claim 1, characterized in that a first participating station in a search operation for setting up a voice connection sends a control signal with an address code for a desired other participating station, that the participating station that receives the correct address code sends an acknowledgment signal if the transmission line is not charged, and that the connection is definitively set up when a return call is triggered in the other subscriber's station. 3. Device as specified in claim 2, characterized in that each control signal, in addition to a freely selectable address code, also exhibits an adjustable house code which limits the possibility of connection to a group of participants with the same house code. 4. Device as stated in claim 3, characterized in that the meaning of each control signal is determined by the combination of house code and address code and corresponding pauses. 5. Device as specified in claim 4, characterized in that the meaning of each control signal is determined as follows: a) House code and address code are sent during the search operation and for receipt. b) A pause (instead of the house code) and address code are sent to change voice authorization. d) House code and a pause (instead of the address code) are sent to break the connection. 6. Device as stated in one of claims 1-5, characterized in that the control signals are sent at all times in the area around the zero crossings of the mains voltage. 7. Device as specified in one of claims 1-6, characterized in that the frequency-modulated carrier frequency during a voice connection is briefly interrupted and the participant station connected to reception can send control signals during the interruption time. 8. Device as specified in claim 7, characterized in that the interruption of the frequency-modulated carrier oscillation occurs when both the amplitude of the audio signal and its differential quotient with respect to time are small. 9. Device as stated in claim 8, characterized in that the audio signal and the differentiated audio signal are rectified, the rectified signals are added and the sum signal is compared with a minimum value in a comparator (7e), and that the interruption of the frequency-modulated carrier frequency occurs when the sum signal is below the minimum value. 10. Device as specified in claim 9, characterized in that the minimum value is dependent on the setting of a volume adjuster (12) on the participating station in question. 11. Device as stated in claim 9, characterized in that the minimum value after each interruption in the frequency-modulated carrier frequency is increased time-dependently, the comparison input of the comparator (7e) being connected to a capacitor (7h) which can be charged up via a resistor (7g). 12. Device as stated in claim 11, characterized in that the comparator (7e) is followed by a D flip-flop (7f) whose set input is connected to the comparator (7e) and whose control input is controlled in the time range when the control signals are permitted, that D- the flip-flop's (7f) set input controls the interruption of the frequency-modulated carrier frequency, and that the reset input of the D-flip-flop (7f) is connected to the capacitor (7h) via a diode (7i). 13. Device as specified in one of claims 2-12, characterized in that the search operation resp. the return call for the participating stations is triggered -when the occurring voice signal exceeds a predetermined amplitude. 14. Device as specified in claims 12 and 13, characterized in that the search operation resp. the return call is triggered by means of an output from the D flip-flop (7f) and that interruptions in the connection are controlled with a timer. 15. Device as specified in one of claims 1-14, characterized in that each participating station has at least one voice key (5) and an end key (6) and that the voice key (5) is used to set up a voice connection or a return call is triggered and an existing connection is terminated with the end key (6). 16. Device as specified in claim 15, characterized in that the authorization to speak in alternating speech operation is initiated by briefly pressing the speech key (5) on the relevant substation and continues until either the speech key (5) on the connected participant station is pressed or the end key (6 ) on one of the interconnected participant stations is pressed. 17. Device as set forth in one of claims 1-16, characterized in that the sound signal before transmission is passed over an amplifier (14) with logarithmic pre-tuning characteristics and during reception over an amplifier (14) with mirror-symmetric amplification characteristics. 18. Device as stated in claim 17, characterized in that the logarithmic characteristic is approximated by a broken line. 19. Device as specified in one of claims 3-18, characterized in that the audio signal is inverted during transmission in line with the mains, and mains synchronously at times whose distance from the zero crossing of the mains voltage is determined by house code^ and that the inversion is again reversed on reception. 20. Device as specified in one of claims 1-19, characterized in that the carrier frequencies in all participating stations are derived from the mains frequency. 21. Device as stated in claim 20, characterized in that the derivation takes place with a PLL link with a frequency divider (19c, 191) in the feedback branch. 22. Device as stated in one of the claims 1-21, characterized in that each participating station displays two light signals (2), the first of which lights up as long as the assigned participating station has the right to speak, and the other lights up as long as the participating station in question is connected to a other participating station; provided that this other participating station has voice authorization/ and that both light signals during the establishment of a connection light up to form a mixed light.