NO155029B - SYSTEM FOR TRANSMISSION OF MESSAGES TO A PHONE DEVICE OVER THE SUBSCRIPTION LINE IN A PHONE SYSTEM. - Google Patents

Description

The invention relates to a system for transmitting messages to a telephone device via the telephone line belonging to the device in a telephone system or a telephone system, comprising a device for generating service signals regarding the establishment of a telephone connection between this device and another telephone device.

These service signals, such as rnawer signals, idle or buzzer or ring tone signals, callback signals, routing or busy signals, are sent to any user of a telephone set who has taken off or lifted the handset and wishes to send a call to another telephone set or is in the process of with doing this. This telephone line requesting user must take such service signals into account as they inform him of the state of the telephone network or telephone system, determining the course of the call procedure and indicating whether his call has been successful or not. This means that the user listens during essentially the entire period for establishing the connection, except during the number transmission or keyboard operation times.

The purpose of the invention is to provide a system for the transmission of messages, for example audio messages, such as advertising texts or of any other character, or music, during the periods of presence of such service signals or at least some of such signals.

To achieve the above-mentioned purpose, the message transmitting system according to the invention comprises a mixer with two inputs which are connected respectively to the service signal generating device and to a message generating device, the output of the mixer being connected to the telephone line.

According to an advantageous feature of the invention, the system comprises a service signal and message sending synchronizer.

According to another advantageous feature of the invention, the mixer consists of a transformer with two primary windings and one secondary winding, and the free terminals of the windings form the inputs of the mixer, the common terminal of the windings being grounded.

A further object of the invention is to provide a system for transmitting messages to a telephone set which is completed with a display or viewing screen, and if necessary with further message receiving devices, such as a printing device. This telephone set, which has thus rather become a subscriber terminal,

is therefore designed to be connected to a telematics network designed for data transmission. This terminal could, for example, be connected to a videophone network or to a data bank consultation network.

To achieve this purpose, the data transmission system according to the invention is characterized in that the message generator consists of a device for sending out signals, such as data signals, which are suitable for being reproduced in the telephone set of the subscriber who requests the establishment of the telephone connection, on an auxiliary device, such as a viewing and/or writing screen, this sending device being connected to the input of a mixer with another input which receives the service signals, the output of the mixer being arranged to be connected to the calling subscriber's line.

According to an advantageous feature of the invention, the transmission system comprises a separator for separating the service signals from the signals to be reproduced on an auxiliary device, in the subscriber telephone set or the subscriber station.

According to yet another advantageous feature, the transmission system comprises a service signal presence detector and possibly a detector for sensing the moment of response from the called subscriber's device or station, both detectors being connected to a control circuit for respectively switching on and off the message generator.

According to a further, advantageous feature of the invention, the subscriber's device or station is equipped with a storage device or memory for storing the information received from the message generator during the time period for establishing the connection with the called subscriber's device or station, and for reproducing this information at any desired, convenient time on the auxiliary device, such as the viewing screen.

The invention will be better understood, and further purposes, features, details and advantages thereof will appear more clearly from the subsequent detailed description with reference to the schematic drawings showing two examples of the invention, and where fig. 1 shows a block diagram of the principle of the message transmission system according to the invention, fig. 2 shows the arrangement of the synchronizer in the block diagram according to fig. 1, and fig. 3 shows another embodiment of the invention for the visual presentation of messages.

As shown in fig. 1, a telephone system or telephone arrangement to which the present invention is applicable comprises a device GS for generating special electrical signals and which is arranged for sending out a number of service signals, such as maneuver signals, call-back signals, routing signals, busy signals, call signals, etc. These signals are sent to each subscriber apparatus whose handset has been removed for the purpose of providing a telephone connection by this apparatus or station to another subscriber apparatus or station. According to fig. 1, the service signals are forwarded to the connection requesting telephone apparatus successively through telephone line sections A and B and a telephone network section SR. Each of the different sections SR (of which only two are shown as an example) is connected to the line section or line section B by means of a transformer TRS.

As can be seen from fig. 1, the direct connection between telephone line sections A and B can be interrupted by means of an inverter switch or reverse INI for switching on the message transmission system according to the invention between both line sections.

This system comprises a mixer TRM with two inputs El, E2 and an output S. In the example shown, the mixer consists of a transformer with two primary windings which are connected in series and whose common point is grounded. Each primary-winding free terminal forms one of the mixer's two inputs El, E2. The input El is connected to the output of a differential amplifier device AM whose control or drive input is connected to the input line section A via the inverter INI. The transformer mixer's TRM input E2 is arranged to be connected to a device GM for generating a message, e.g. an audio message, via an attenuator AT, a switch IN2, a synchronization circuit CS, a switch IN3 and a suitable transformer TRG. A switch IN4 makes it possible to remove the synchronizer CS from the circuit connecting the mixer TRM and the message generator GM. The synchronization circuit CS's input and output for the messages to be transmitted are denoted by the reference designations El and S. The synchronization circuit CS includes a second input E2 on which it receives the service signals from the line section A. The arrangement of the synchronization circuit CS will be described in more detail later.

As regards the arrangement of the amplifier AM, it appears that its control input is connected to the sliding contact of a potentiometer Pl, which with one terminal is connected to the line section A. The other terminal is grounded. The amplifier's AM output is connected via a capacitor Cl to the transformer mixer's TRM input El. A series circuit consisting of a capacitor C2 and a resistor Ri is connected between this input and ground. The amplifier's AM output is further connected via two series-connected resistors R2, R3 to ground. The amplifier's second input E2 is connected via a capacitor C3 to the common point of the resistors R2, R3. It also appears that a capacitor C4 is connected between the amplifier's AM input El and ground.

It should be pointed out that the message-generating device GM could comprise one or more (e.g. two, as in fig.

1) cassette or disc recorder devices or reading devices and auxiliary generators or auxiliary devices of any other type. It is advantageous that a generator which in principle works continuously without stopping is a disc generator, while a cassette generator is more suitable for the transmission of special messages due to the fact that it offers the advantage of a quick cassette change. In addition to the message generator GM, the system according to the invention can include an external modulation source SME for the transmission of special and random messages. This source could be connected to the mixer TRM instead of the generator device GM, either directly via the inverter IN2 or via the synchronization circuit CS by setting the inverter IN3 in the position not shown.

The arrangement of the synchronization circuit CS shall be described in the following with reference to fig. 2.

The synchronization circuit comprises two parts, more specifically a first part I for on/off control of the message generating device GM, and a second part II which is designed to terminate or break the connection between the generating device GM and the mixer TRM. The effect of part I on the generating device GM is in fig. 1 illustrated by the arrowed line F.

Part I is connected to the service signal receiving input E2. The part comprises a flip-flop BAI consisting of two NOR gates Pl, P2, each of which has two inputs. As is known per se, the output from one port is connected to the input of the other port. The free input to each gate forms one input to the flip-flop. The free input of the gate Pl is connected to the synchronizing circuit CS input E2 which is arranged to receive the service signals, via a circuit which essentially comprises an input transformer TRC, a low-pass filter PB, a Schmitt trigger circuit BSl, a pole-reversing or pole-reversing switch IVl and a differential circuit CDl . The latter comprises a capacitor C6 which is connected between the inverter IV1 and the input of the gate Pl, and a parallel connection of a resistor R5 and a diode D1 which connects this input to earth. It is the anode of the diode that is grounded. A series connection of two inverters IV2, IV3 is used as a Schmitt trigger circuit, each of which consists of a NAND gate whose inputs are interconnected.

A resistor R6 is connected in parallel with the inverters. The low-pass filter PB comprises a capacitor C5 which is connected in parallel with the secondary winding of the transformer TRC, and a series connection of a variable resistor R7 and a resistor R8 which is connected between the secondary winding of the transformer and the Schmitt trigger circuit BS1. The common point between the two resistors R8 and R7 is connected to the cathode of a diode D2 whose anode is grounded. This common point is further connected to the stationary contact in a switch button Bl. The switch's movable contact is connected to a positive voltage via a resistor R9. At rest, the switch is in its open position.

Portéji's Pl output, which forms an output from the flip-flop BAI, is connected via a resistor RIO to the base of a switching transistor Tl. In the emitter circuit of this transistor, a series connection of a resistor Ril and a light-emitting diode DEI is connected. This diode emits light of, for example, red colour. The emitter of the transistor Tl forms an output from the control circuit for the message generating device

GM.

The gate's P2 free input, which forms the flip-flop's BAI second input, is connected to a voltage divider consisting of a resistor R12 which is connected to a positive voltage,

and a variable resistor R13 which is grounded, via a resistor R14, a Schmitt trigger circuit BS2 and a differential circuit CD2. The Schmitt trigger circuit BS2 and the differential circuit CD2 have the same construction as the Schmitt trigger circuit BS1 and the differential circuit CD1, respectively. Inverters IV4, IV5 and resistor R15 correspond to inverters IV2, IV3 respectively

and the resistor R6. Correspondingly, the differential circuit CD2 comprises a capacitor C8, a resistor RI7 and a diode D4 which correspond respectively to the capacitor C6, the resistor R5 and the diode D1.

As regards the voltage divider, it appears that a resistor R16 can be connected in parallel with the resistor R12 via a switch button B2 which is open in its rest position.

The gate's P2 output, which forms a second output from the flip-flop BAI, is connected via a resistor R18 to a switching transistor T2. This transistor's emitter forms a second control output for the generator device GM and is grounded via a resistor R19 and a light-emitting diode DE2 suitable for emitting light of green color.

Part II of the synchronizing circuit CS, for establishing the connection between the transformer mixer TRM and the generating device GM, comprises a relay contact ri which is connected between the input El of the synchronizing circuit CS and its output S. In the rest state, the contact ri is open and connects the output S to ground via a resistor R20 . This contact ri is operated by a relay R which is connected to the emitter circuit of a transistor T3. A connection consisting of a resistor R2 and a light-emitting diode DE3 which is designed to emit light of green color is connected in parallel with the relay R. Furthermore, a diode D5 is connected across both terminals of the relay. The anode of the diode is grounded. The transistor T3 is controlled by means of a flip-flop BA2. For this purpose, an output from this flip-flop is connected to the base of the transistor T3 via a resistor R22. A second output from the flip-flop is connected by a series connection of a resistor R23 and a light-emitting diode DE4. This diode emits red light. Like the flip-flop BAI, the flip-flop BA2 consists of two NOR gates P3, P4 with two inputs, one input to each gate being connected to the output of the other gate. The free input to each gate forms a control input to the flip-flop.

The control circuit for the flip-flop BA2 comprises a potentiometer P2 which is connected between the synchronizing circuit CS input El and ground, a Schmitt trigger circuit BS3 which with its input is connected to the sliding contact of the potentiometer P2 and with its output is connected to two parallel-connected input circuits which are each connected to the free entrance to a port P3, P4. The input circuit to gate P3 comprises a differential circuit CD3, while the input circuit to gate P4 comprises a differential circuit CD4 in front of which an inverter IV6 is connected. Differential circuits CD3 and CD4

has the same construction as the differential circuit CDl. The differential circuit CD3 thus comprises a capacitor CIO, a resistor R24 and a diode D6. The differential circuit's CD4 elements are denoted by the reference designations C11, R25 and D7. The Schmitt trigger circuit BS3 comprises two inverters or reversing switches IV7 and IV8. A resistor R26 is connected in parallel

sorry with the inverters. A resistor R2 7 is connected between the potentiometer's P2 sliding contact and the Schmitt trigger's BS3 input. It also appears that a diode D8 is connected between the sliding contact and ground. It is the anode of the diode that is grounded.

The synchronizing circuit CS parts I and II are interconnected by means of a diode D9 to enable part II to act on part I.

Whereas on Aytt reference is made to fig. 1, it appears that the system according to the invention also comprises a loudspeaker HP and a head receiver or earphone CE which can be connected to the system according to the invention by means of two rotary switches IN6 and IN7. In accordance with the position of the inverter IN7, the speaker or head receiver can be connected in parallel with the line section B or connected instead of it.

The previously described message transmission system according to the invention works in the following way: The sending of a message via the telephone network can take place as soon as the switches INI - IN5 are in the positions shown in fig. 1. The start of the transmission of a message is determined by the synchronization circuit CS in synchronism with the arrival of a service signal.

Before the arrival of such a signal from the generator GS and before the closing of the switch button Bl, the synchronizing circuit CS flip-flop BAI is biased so that the output of the gate Pl exhibits a positive potential representing the logic value 1. The output of the gate P2 is therefore in the zero state of which it follows that this input to port Pl, which is connected to the mentioned output, is also in the O state.. Due to the location of capacitor C6, the free input of port Pl automatically shows the value 0. As for port P2, its free input is at due to the capacitor C8 in the O state, while the other input shows the value 1. Under these conditions, the transistor T1 is conductive or on, and the diode DEI emits red light, indicating that the message generating device GM is off or inactive. Transistor T2 is off. In the case of the flip-flop or multivibrator BA2, it is the output of the gate P3 that exhibits the state 1. Both inputs to the gate are therefore in the 0 state as a result of the 0 value of the output of the gate P4 and the location of the capacitor Cll. The port's P4 inputs are in the states 0 or 1. Under these conditions, the diode DE4 is energized. The transistor T3 is off and the relay R is not energized. The relay's contact ri is open.

By closing the switch button Bl, the flip-flop or multivibratro BAI is made sensitive to the service signals coming from the synchronizing circuit CS input E2. These signals cause the gate Pl's free input to transition from state 0 to state 1 and thus cause the flip-flop or multivibrator BAI to flip over or change its state. The output of the gate P2 assumes the value 1 so that the transistor T2 is made conductive and on the emitter produces a positive signal which is transferred to the generating device GM and switches it on. The generator then starts sending out signals that represent the message to be sent out. These message signals cause the free input to the flip-flop's or multivibrator's BA2 port P3 to assume the state 1, thereby causing tilting of the multivibrator or flip-flop BA2, conduction of the transistor T3, energization of the relay R and closing of the contact ri. As soon as this contact is closed, the message signals from the generator GM reach the input E2 of the mixer TRM which receives the service signals on its other input El. At its output S, the mixer produces a mixture of both types of signals. The signals can be measured using the amplifier device AM which acts as a clipping amplifier, and using the attenuator AT. The messages from the generator GM can be of any suitable nature, such as e.g. music or advertising messages. It should be pointed out that the multivibrator's or flip-flops' BAI and BA2 ports P2 and P4 show the potential 0 on their two inputs and the value 1 on their outputs during the transmission of the messages.

At the end of the transmission of a message, the free input of the gate P4 returns to level 1 and thus causes the switching or state change of the multivibrator or flip-flop BA2, the blocking of the transistor T3, the de-energization of the relay R and the opening of the contact ri and thus interruption of the connection between the mixer TRM and the message generating device GM. Through the intervention of diode D9, the switching or state change of flip-flop or multivibrator BA2 results in switching or tilting of flip-flop or multivibrator BAI. The output of the gate Pl becomes positive again, and this causes the transistor Tl to become conductive or switch on. The positive signal produced on the emitter of the transistor will switch off the generating device GM.

If one wishes to stop the generator GM before the end of a message, it is sufficient to close the button switch B2 so that the free input of the gate B2 is caused to pass from state 0 to state 1. The flip-flop or Raulti vibrator BAI changes its state. As just indicated, this results in the generator GM being stopped or disconnected.

It is obvious that the system according to fig. 1 and 2, as described and shown, can be modified in various ways within the framework of the invention. For example, the mixer may be of any suitable type. The synchronizing circuit CS may comprise means for bringing the generator GM to a stop or cut-off at the end of a service signal. The generating device GM may comprise an arbitrary number of generators, each of which is arranged to be connected to the transformer TRG by means of a switch, as shown in fig. 1.

Fig. 3 shows an embodiment of the invention which is adapted to a telematics system.

As can be seen from fig. 3, a subscriber terminal A in such a system is connected via a subscriber telephone line LT to a central station B. The subscriber terminal A comprises a telephone set AT and a data processing device TD which is adapted to reproduce or reproduce the information or the data that can be transmitted to the terminal A using the subscriber line LT, on a suitable auxiliary device. According to the figure, the inputs of the telephone set AT and the data processing device TD are connected to a respective output from a signal separator SP whose input is connected to the subscriber telephone line LT. The task of this separator is to separate the acoustic signals which are adapted to be read out or picked up by the telephone set's AT receiver, from the data, e.g. digit signals, to be processed in the device TD.

In the example shown, this data processing device TD mainly comprises a viewing screen EV, such as e.g. a cathodic screen, a printing device IM, such as a printer, and a storage or memory device ME. These various devices are connected to a modulator-demodulator unit (MODEM) MDI which performs the function of a converter as is known in the art. The storage device ME is designed to receive serial information and to transmit the information in parallel or in series, but possibly with a higher transmission speed. The arrows show the effect of the storage device on the display device EV and on the writing device IM.

In the case of central station B, a mixer M is provided, both inputs of which are adapted to be connected to a service signal generator GS and to a message generator GM. The mixer's output is connected to the subscriber line LT.

In accordance with the invention, the message generator consists of a device for sending signals, such as data signals, which are adapted to be processed in a data processing device, such as the device TD in the subscriber terminal A, i.e. messages which are adapted to be reproduced on an auxiliary device, such as viewing or the display screen EV, and/or on a writing device (the printer IM). Possibly with the assistance of a modem device MD2, the information to be sent to terminal A can be processed so that, with regard to transmission speed and frequency bandwidth or frequency range, it corresponds to the data signals that are normally transmitted with the help of the network.

The message generator GM is operated by means of a control circuit C, according to the example shown, under the action of two detectors D1, D2 which are connected to the telephone line between the service signal generator GS and the mixer. The detector D1 can optionally perform the function of sensing the presence on the subscriber line of a service signal, for example of a signal requesting the subscriber using the terminal A, after he has lifted the handset of his telephone set AT, to dial the call number of that telephone set or the station or terminal with which he wishes to communicate. The detector D2 may optionally be sensitive to the end of the step of establishing the telephone connection, and in particular to the moment in which the called subscriber answers, e.g. by lifting his handset.

The signal produced by the detector D1 can possibly cause the control circuit C to switch on or start the message generator, while a signal from the detector D2 can possibly cause the generator GM to be stopped or switched off via the control circuit C. In such a case, the generator GM would issuing messages during the entire stage of establishing the telephone connection until the moment of a positive response from the called subscriber's telephone apparatus.

The detectors could of course, while possibly being supplemented with other detectors, be adapted to perform more complex functions, and for example to work in such a way that the generator GM transmits only during periods of absence of service signals, or only during certain periods of the line connection establishment step. It could also be ensured that the service signal generator GS controls the message generator directly or indirectly, in accordance with the type of service signals that it emits, as symbolized by the arrow-provided, dashed line.

These various simple or even complex functions for controlling the message generator GM can be performed in any known suitable manner.

It should be noted that the service signals consist of periods of the presence of oscillations with frequencies of several hundred Hertz, e.g. between 400 and 500 Hz. These signals can therefore be easily detected or sensed.

It is easily realized that the separation of the service signals from the data signals under such circumstances can easily be carried out by means of the subscriber terminal A separator SP if the modem MD2 which forms a converter which is connected to the message generator GM, uses carrier frequencies which are sufficiently separated from the service frequencies.

To complete the description of the shown message transmission system, this system comprises a reversing switch CMI for short-circuiting the mixer M, and a reversing switch CM2 which is adapted to connect the telephone apparatus AT and the data processing device TD alternately and directly to the telephone line LT without forcing the signals to pass through the separator SP. As symbolized by the arrowed lines, the reversing switch CMI can possibly be influenced by the control device C in synchronizing relation with the operation of the message generator GM.

The way the message transmission system works is self-explanatory from the description of the system's construction and of the functions that the various elements and devices must perform.

When an owner subscriber of terminal A wishes to be connected via the telephone or data transmission network with another subscriber's device, station or terminal, which may be a data bank or e.g. a bank transaction center or any other information-issuing institution, he picks up the microphone on his telephone set AT. After this step, the central station sends several signals to the subscriber requesting the subscriber to perform the necessary steps for establishing the telephone connection. In accordance with the functions assigned to the detectors D1, D2 described above, the message generator GM will emit messages of a nature suitable for reproduction in the subscriber terminal A from which the call for establishing a telephone connection originates. Before these signals reach the mixer M and before they are fed into the subscriber's telephone line LT, where they will possibly be superimposed on the service signals, they will be processed by the modem MD2 in order to be adapted to the characteristics and capabilities of the network. This treatment is of course different depending on whether the telephone lines are normal lines or special lines, i.e. consist of e.g. fiber optic or coaxial cables. It is well known that in the latter case the output of binary digits or bits, i.e. the transmission rate or the modulation rate, can be much higher and also enable the transmission of television signals. The modems MDI and MD2 must therefore be designed in accordance with the permissible modulation speed for the network.

The system according to the invention enables data transmission from the message generator GM during the entire period for establishing the telephone connection.

In the subscriber terminal A, the data signals, after being passed through the separator SP, can be viewed or displayed visually directly and immediately on the screen EV, or printed using the printer device IM. If the network allows a sufficient transmission speed, the calling subscriber can see, for example, a television image or text that appears on the subscriber's screen. If the telephone line does not allow a sufficiently high transmission speed, i.e. a binary digit or bit output that is sufficient for a direct display as an image on the screen, the information can possibly be stored in the storage or memory ME and later transmitted, e.g. at a given time with a sufficient output speed to the screen or to the printer.

It will be realized that the message transmission system according to the invention enables a large number of applications without deviating from the principle that has been stated above.

In the system according to fig. 3, a synchronizing circuit of the type described in connection with the embodiment shown in fig. 1 and 2.

Conversely, a control circuit for a detection device, as shown and described in connection with the system in fig. 3, is used in the embodiment according to fig. 1 to replace the synchronizer. Thus, for the first embodiment, a transmission of messages during the period of silence between two successive service signals could be provided. As a general rule, the devices used in one embodiment can be built into the other embodiment, at least in a suitable, practical and possibly equivalent version.

Claims (20)

1. System for transmitting messages to a telephone device over the telephone line belonging to the device in a telephone system, comprising a device for generating service signals regarding the establishment of a telephone connection between this device and another subscriber device, characterized in that it comprises a mixer with two inputs which are respectively connected to the service signal generating device and to a message generating device, the output of the mixer being connected to the telephone line. 2. System according to claim 1, characterized in that it comprises a circuit for synchronizing transmissions of service signals and messages. 3. System according to claim 1, characterized in that the mixer consists of a transformer with two primary windings and one secondary winding, and that the free terminals of the primary windings form inputs to the mixer, the common terminal of the windings being grounded. 4. System according to claim 1, characterized in that it comprises a switch which ensures connection of the system in the service signal routing telephone line. 5. System according to claim 1, characterized in that the circuit connected to one input of the mixer comprises an amplifier, while the circuit connected to the other input of the mixer comprises an attenuator. 6. System according to claim 2, characterized in that the synchronization circuit comprises a first circuit arrangement for on/off control of the message generating device, and which is connected to the incoming service signal section of the telephone line and is sensitive to these service signals. 7. System according to claim 6, characterized in that the synchronization circuit comprises a second circuit arrangement for controlling the conclusion and breaking of a connection between the mixer and the message generating device in accordance with the presence of, absence of and/or end of a message from the generating device on an input to the synchronization circuit. 8. System according to claim 7, characterized in that the synchronizing circuit comprises a device for connecting the first and second circuit arrangements and which is arranged to cause the generation of a control signal for switching off the generating device by means of the first circuit arrangement upon detection of the end of a message using the second circuit arrangement. 9. System according to claim 8, characterized in that the synchronization circuit's first circuit arrangement comprises a control device for stopping the generation device before the end of a message. 10. System according to claim 7, characterized in that the synchronization circuit comprises a reversing switch which is connected between its message receiving input and its output, and a control circuit for the reversing switch which is sensitive to the presence of a message on its message receiving input. 11. System according to claim 7, characterized in that the first circuit arrangement comprises a bistable multivibrator with two inputs and two outputs, one input being connected to a detector circuit for sensing a service signal to cause the generation of a signal to connect the generating device on, while the other input forms the control input for stopping or disconnecting the generating device. 12. System according to claim 11, characterized in that the synchronization circuit's second circuit arrangement comprises a bistable multivibrator, one input being sensitive to the presence of a message on the message receiving input, while the other input is sensitive to the end of a message. 13. System according to claim 12, characterized in that one input of the bistable multivibrator is connected to a control circuit for a relay, the changeover switch being a contact operated by a relay. 14. System according to claim 12, characterized in that each bistable multivibrator consists of two NOR gates, the output of one gate being connected to the input of the other gate. 15. System according to claim 1, characterized in that it comprises one message generator consisting of a device for sending out signals, such as data signals, which are adapted to be reproduced in the telephone device that requires the establishment of the telephone line connection, on an auxiliary device, such as a viewing screen or a writing device, this sending device being connected to an input of the mixer whose other input receives the service signals from the service signal generator, the output of the mixer being arranged to be connected to the line of the calling subscriber. 16. System according to claim 15, characterized in that it comprises a separator for separating the service signals from the signals to be reproduced on the aforementioned auxiliary device in the subscriber's telephone set. 17. System according to claim 15, characterized in that it comprises a detector that senses the presence of service signals, and possibly another detector that senses the moment of an answer from the called subscriber's telephone device, these detectors being connected to a control circuit for switching on and disconnection of the message generator. 18. System according to claim 15, characterized in that the subscriber's telephone device is equipped with a storage device for storing the information received from the message generator during the period for establishing the connection with the called subscriber's telephone device, and for reproducing this information at any the desired, appropriate time on the auxiliary device, such as the viewing screen or writing device. 19. System according to claim 15, characterized in that a modem device is connected between the message generator and the mixer. 20. System according to claim 1, characterized in that it comprises a toggle switch for switching the mixer on or off, this toggle switch being operated in synchronized relation to the control of the message generator.