FR2487611A1 - Telephone voice frequency keyboard interface - has twin supply bridges, amplifier, line circuit, control circuit and impedance change circuit interconnecting amplifier and control circuit - Google Patents

Abstract

The appts. has a power supply circuit comprising two supply rectifier bridges having the same negative polarity, on amplifier, on impedance charge circuit, a transmitter control circuit and line circuit. The control circuit is connected to the positive and negative terminals of the first bridge and comprises a first adjustable voltage regulator and series resistance. The line circuit connected to the same bridge terminals comprises a second voltage regulator, line transitor and series line resistance. A negative terminal of the first regulator is connected to the line transistor base. The impedance change circuit comprises a transistor whose emitter-collector is connected between a control input of the first regulator and the first bridge negative terminal. The impedance charge circuit controls the charge in impedance of the interface circuit so that it presents a low impedance in conversation mode and high impedance in dialling mode.

Description

Voice frequency keyboard interface circuit
The invention is in the field of voice frequency keyboards and relates to an interface circuit connecting a subscriber line to such a keyboard.

 There are already known telephone sets with a voice frequency call keyboard, and in particular call keyboards comprising a multi-key dialing keyboard, a microprocessor and a voice frequency generator, the microprocessor acting as an interface between the keyboard. and the frequency generator. In such telephone sets, the microprocessor and the voice frequency generator must be supplied with power at a determined, stable voltage, and various conditions of current consumption and impedance of the set seen by the subscriber line must be fulfilled, in order to meet the conditions imposed by the Administration.

 The object of the invention is to provide an interface circuit between the subscriber line and the micropressor, dialing keypad and voice frequency generator assembly, which fulfills the operating conditions imposed.

 The subject of the invention is an interface circuit connected to accessible and standardized terminals of a subscriber station, to a microprocessor associated with a dial pad, to a voice frequency generator and to a signal filtering circuit. delivered by the generator, said interface circuit comprising in particular a supply circuit comprising two supply bridges, an amplification circuit, a line circuit, a line circuit control circuit, and a change circuit impedance connecting the amplification circuit to the control circuit.

 The interface circuit also includes a current limiting device, an overcurrent protection device and a calibrated breaking device.

Other characteristics and advantages of the invention will emerge from the description which follows of an exemplary embodiment illustrated by the appended figures in which
FIG. 1 schematically represents a subscriber station with the interface circuit of the invention,
FIG. 2 is a diagram showing how FIGS. 2A and 2B are assembled,
FIGS. 2A and 2B show in detail the interface circuit of the subscriber station of FIG. 1.

 In FIG. 1, the subscriber line consists of two wires L1 and L2 connected respectively, through the hooks CC of the station switch, to terminals I and IV; the wire L1 is connected, before the hook CC to a terminal III by a circuit comprising a resistor 4 and a capacitor C10; the wire L2 is connected, before the hook CC, to the terminal III by a buzzer S. The terminal IV is connected to a terminal II by a conversation circuit E of the subscriber station.

Terminals I, II, III, IV are station terminals accessible and standardized by the French Administration of Posts and Telecommunications.

The terminals I and IV are connected together by a resistor 1 in series with a protection device Z Z1; terminals IV and
III are connected by two zener diodes Z1 and Z2 in series and in opposition, which makes it possible to avoid ringing of the ringing in the dialing phase.

 In addition to the elements mentioned above, the subscriber station includes a microprocessor A, of the TMS 1000 NLC type from Texas Instruments for example, associated with a DI initialization device, a voice frequency generator B, of the MK 5091 type from MOSTEK. for example, and connected to the microprocessor by a multi-wire link L8, a CN dialing keyboard with several keys connected to the microprocessor, and a filtering circuit F connected to the output OAO of the voice frequency generator. An interface circuit CI, object of the invention, provides the interface between terminals I, II, III and IV and the microprocessor A, the voice frequency generator B and the filtering circuit F.

 The interface circuit CI comprises a supply circuit P, a shunting device SH, a calibrated breaking device H, a current limiting device N, an overcurrent protection device M, a line circuit CL, an impedance control circuit R, a control circuit T, and an amplification circuit G.

The supply circuit P has a terminal P1 connected to the wire L1, through the resistor 1, a terminal P2 connected to the wire L2, a positive terminal PII connected to a wire L4, another positive terminal P3, isolated from the terminal PII , connected by a wire L3 to a positive supply terminal
VDD of microprocessor A and to a positive supply terminal VDD of the voice frequency generator B, and to the initialization device DI, and a terminal P6 connected to a wire L6.

 Between the wires LII and L6 is connected a line circuit CL comprising, in series, a second voltage regulator TL2, a line transistor T16 and a line resistor 47. A terminal P7, common to the second voltage regulator and to the transistor line is connected to a L7 wire, the potential of which is lower than that of the LII wire; the wire L7 is connected to the initialization device DI, to a negative power supply terminal VSS of the microprocessor A, and to a negative power supply terminal VSS of the voice frequency generator B.

 The overcurrent protection device M is connected to the wires LII and L6, at a point common to the line transistor T16 and to the line resistor 47, and to the control circuit T.

 The control circuit T is connected to the wires LII, L6 and L7, to the base of the line transistor T16 and to the impedance control circuit R.

 The current limiting device N is connected to the wires L4 and L6, to the control circuit T and to a point common to the line resistor 47 and to the line transistor T16.

The H-rated breaking device is connected to the LII wires and
L7, to a terminal R8 of the microprocessor A by a wire L5, and to the control circuit T by a wire L11.

The impedance control circuit R is connected to the wire L6 and to the amplification circuit G
The amplification circuit G is connected to the output of the filtering circuit F by a wire L9, to an output AKD of the voice frequency generator B by a wire L10, and to the base of the line transistor T16.

 The shunting device SH is connected to the terminal P2 of the supply circuit P, to the terminal IV, to the wire L7 and to a terminal R7 of the microprocessor.

 In FIG. 2A, the supply circuit P comprises diodes D1, D2, D3, DII, D5 and D6 and a resistor 3. The terminal P1 is connected to a terminal P5 by the diode D1; resistor 3 is connected between terminals P3 and P5. Diode D2 is connected between terminals P2 and P5; diode D3 is connected between terminals P6 and î; the diode D4 is connected in the terminals P6 eb P2; diode D5 is connected between terminals P2 and prr, diode D6 is connected between terminals Pi and PII.

The shunting device SH comprises two transistors Tî and
T2, a diode D10, a capacitor Ci, a coil HL of a bistable relay, a contact rl of the relay and two resistors 2 and 5. The contact rl is in series with the resistor 22 the assembly being connected between the terminals Il and IV of the station, therefore in parallel on the conversation circuit E, FIG. 1. The transistor T1 has its collector connected to the wire L3, and its emitter connects to the emitter of the transistor T2 whose collector is connected to the wire L7; the capacitor C1 is in series with the coil RL, the assembly being connected between the emitter of the transistor T1 and the wire L7. The bases of the transistors T1 and T2 are joined together and connected on the one hand through the resistor 5 to the terminal R7 of the microprocessor and on the other hand to the terminal HALT of the microprocessor by the diode D10.

 A capacitor C2 is connected between the wires L3 and L7.

 The initialization device DI comprises a transistor TII, a transistor T5 for example of the type VN10, of Intersil, a diode D7, three resistors 6, 7, 8, and a capacitor C3. The transistor T4 has its base connected to the wire L4 by the resistor 6, its emitter connected to the wire L4 and its collector connected to an initialization terminal INIT of the microprocessor. A terminal K8 of the microprocessor is connected on the one hand to the base of the transistor TII by the resistor 7 and on the other hand to the wire L7 by the capacitor C3. The transistor T5 is connected by its drain and its source in parallel on the capacitor C3, its gate being connected to a terminal R9 of the microprocessor, said terminal R9 being also connected to the terminal HALT. The diode D7 and the resistor 8 are in series , the assembly being connected to the terminals R8 and K8 of the microprocessor.

 The microprocessor A has two terminals OSC1 and OSC2 connected by a resistor 9, the terminal 0SC2 being connected to the wire L7 by a capacitor CII. The microprocessor is linked by the link L8 to the voice frequency generator B, two terminals of which OSCO and OSC1 are connected to a quartz crystal Q.

 The filter circuit F comprises four resistors 10, 11, 12, 13, two capacitors C5 and C6 and an amplifier C. The resistors 10 and 12 are in series and connected between the OAO output of the voice frequency generator and the wire L7 Un point in common with resistors 10 and 12 is connected by resistors 11 and 13 in series to the positive input of amplifier C, the negative input of which is connected to the output; the capacitor C5 is connected between the negative input and a point common to the resistors 11 and 13; the capacitor C6 is connected between the positive input and the wire L7; the amplifier output is connected to wire L9. The power supply of the amplifier is connected to wires tll and L7.

 In FIG. 2B, the amplification circuit G comprises a differential amplifier D, three transistors T6, T7, T8, resistors 14, 15, 16, 18, 19, 20, 21, 22, 23, 48, 49, 50 , and two capacitors C7 and C11. The wire L9 is connected by the resistor 21 to the positive input of the differential amplifier D. The wire L10 is connected on the one hand to the wire L7 by the resistor 16 and on the other hand to the base of the transistor T6. The positive input is connected by the resistor 14 to the wire L7 and by the resistor 15 to the wire LII. The output of the differential amplifier is connected to the wire L7 by the resistor 49 and to the base of the transistor T7 by the resistor 18. The transistor T6 has its emitter connected to the wire LII and its collector connected to the base of the transistor T7. Resistor 50 is connected between wire LII and the base of transistor T7. The emitter of transistor T7 is connected by resistor 23 to wire L4 and by resistor 19 with negative input from the differential amplifier. The negative input is connected by the resistor 24 to the wire L7 and by the resistor 20 in series with the capacitor C7 to the collector of the transistor T8 whose emitter is connected by the resistor 22 to the wire L6. The collector of transistor T8 is connected by resistor 48, in parallel on capacitor C11, to wire LII.

- The line circuit includes the second voltage regulator TL2, the line transistor T16, the line resistance 47, resistors 42 and 43, and a resistor 45 connected between the base of the line transistor and the base of transistor T8 of amplification circuit G. The resistors 42 and 43 are in series, the assembly being connected between the wires L4 and L7; a point common to the resistors 42 and 43 is connected to a control input of the second voltage regulator TL2 whose voltage at the terminals is fixed by the resistors 42 and 43.

 The control circuit T comprises a transistor T17, a first voltage regulator TL1, adjustable, and resistors 31, 32 and 37. The emitter of the transistor T17 is connected to the wire LII, and the collector is connected by the first voltage regulator voltage at a point common to the base of the transistor T8 and to the resistor 45 of the line circuit CL.

The collector of transistor T17 is connected by resistor 32 to the control input of the first voltage regulator. The point common to the base of the transistor T8 and to the resistor 45 is connected to the wire L6 by the resistor 31. The base of the transistor T17 is connected to the wire L6 by the resistor 37.

 The calibrated breaking device H comprises a transistor T14, a diode D8, resistors 36, 38, 39. The emitter of transistor T14 is connected to wire L5, and the collector is connected to the base of transistor T17 of the control circuit T. The resistor 36 is connected between the emitter and the collector of the transistor T14. The wire LII is connected, by the diode D8 and the resistor 38 in series, to the base of the transistor T14, said base being connected by the resistor 39 to the wire L7.

 The overcurrent protection device M comprises two transistors T13 and T15, a capacitor C9, and resistors 25, 40 and 41. The transistor T15 has its emitter connected to the wire L4, its collector connected to the base of the transistor T17 of the circuit control T, and its base connected to the collector of transistor T13. The emitter and the base of transistor T1s are connected by resistor 41 in parallel with capacitor C9. The transistor T13 has its emitter connected by the resistor 25 to the wire L6 and its base connected by the resistor 40 to a point common to the line transistor T16 and to the line resistor 47.

 A zener diode Z3 is connected between the collector of transistor T17 and the base of transistor T13.

 The current limiting device N comprises two transistors T11 and T12, a diode D9, a capacitor C8 and resistors 30, 33, 34, 35, 46. The transistor T11 has its emitter connected to the wire L4 by the resistor 35, its collector connected to the collector of transistor T12, and its base connected to wire LII by resistor 33 and to wire L5 by resistor 34. The control input of the first voltage regulator TL1 is connected by diode D9 to the collector of transistor T12 the base of which is connected by the resistor 46 to a point common to the line transistor T16 and to the line resistor 47, and by the capacitor C8 to the wire L6.

 The impedance change circuit R includes a transistor T9 and resistors 27, 28 and 29. The transistor T9 has its collector connected by the resistor 29 to the control input of the first voltage regulator TL1, its emitter connected by the resistor 28 at wire L6, and by resistor 27 at its base, said base being connected to the collector of transistor T7 of amplification circuit G.

 The voltage regulators TL1 and TL2 are integrated circuits of the Tu431 type from Texas Instruments, for example.

 We will now describe the operation of the interface circuit.

In the supply circuit P the diodes D3, D4, D5, D6 constitute a first supply bridge, so that the terminals P4 and P6 are always at a positive polarity and at a negative polarity, respectively, whatever the direction of direct current in wires L1 and L2 of the subscriber line. Likewise the diodes D1, D2, D3, DII constitute a second power supply bridge whose terminals P5 and
P6 are respectively the positive and negative polarities whatever the direction of the current in the wires L1 and L2. The potentials of terminals PII and P5 are practically the same when current flows through the line; the potential of terminal P3 is slightly lower than that of terminal P5.

Dropout phase.

 When the telephone handset, which is part of the conversation circuit E, is lifted, the switch CC hooks close. The transistor T17 and the first voltage regulator TL1 are conductive, and control the line transistor T16, which allows the passage of line current through the second voltage regulator TL2, the line transistor T16 and the line resistor 47 ; the L7 wire is brought to a potential of the order of -3.6 volts compared to that of the LII wire, whence supply of the microprocessor A, the voice frequency generator B, the G amplifier and the Xamplifier differential D.

 The transistor T6 is saturated the tt-nnsistors T7 and T9 are non-conductive; if the line current is less than 35 milliamps the transistor T12 and nonconductive, the voltage across the terminals of the first voltage regulator TL1 is of the order of 2.6 volts and the line transistor T16 is saturated.

 If the line current is greater than 35 milliamps, the transistor T12 conducts, and unlocks linearly as a function of the line current; there is a current in the diode D9, which modifies the voltage on the control input of the first voltage regulator TL1 whose voltage at the terminals increases; This lowers the voltage of the base of the line transistor T16 which becomes less conductive, hence limiting the line current.

 The transistor Tii, in series with the transistor T12 only serves for the compensation of the thermal drift of the transistor T12.

 Still stalling, if the line current takes a value greater than 35 milliamps, the transistor T12, the base of which is connected by the capacitor C8 to the wire L6, is non-conductive and cannot therefore limit the line current as long as its voltage base has not reached a sufficient value. If the line current then takes a value greater than 80 milliamps, the transistor T13 becomes conductive and makes the transistor T15 conductive, which in turn gradually blocks the transistor T17, which modifies the potential of the base of the transistor down. line T16 which becomes less conductive; the line current is then of the order of 55 milliamps, which corresponds to a short subscriber line.

Then the transsitor T12 becomes conductive and the voltage across the first voltage regulator TL1 takes a new value which is limited to 44 volts by the zener diode Z3 which acts on the base of the transistor T13 making it more conductive; the transistor T13 makes the transistor T15 more conductive which in turn makes the transistor T17 less conductive. As soon as the line current is established, on stall, a voltage appears between the wires L3 and L7. In the initialization device DI, FIG. 2A, the capacitor C3 is charged and the transistor TII is conductive; terminal
INIT of microprocessor A is brought to level 1 and initializes the microprocessor, which cannot operate as long as the terminal INIT is at level 1. When the capacitor C3 is charged the transistor T4 is blocked, the terminal INIT goes to level "0" and the terminal K8 of the microprocessor goes to level 1; the microprocessor is then ready to operate.

 The terminal R7 of the microprocessor is at level ttO "as long as the microprocessor is not ready to operate; the transistor T2 is therefore conductive and the capacitor C1 discharges, if it was charged, which ensures the closing of the contact rl, or keeping it closed because it must be normally closed when the handset is hung up.

When the microprocessor is ready to operate, terminal R7 delivers a level 1 pulse with a duration of 20 milliseconds; the transistor T1 is conductive, the capacitor C1 charges through the coil RL of the relay and the contact rl opens. At the same time as the terminal R7 goes to level 1, the terminal R9 goes to level 1, which keeps the transistor T1 conductive and blocks the transistor T2, and makes the transistor T5 conductive, hence discharging the capacitor C3.

Conversation phase
This phase occurs after the dropout phase. The current coming from the conversation circuit passes through the wire LII, the second voltage regulator TL2, the line transistor T16, the line resistance 47 and the wire L6; the impedance of the interface circuit, seen from terminals I and II, is practically that of the line resistance 47, ie of the order of 25 ohms.

Dialing phase.

 This phase occurs after lifting the handset, therefore after the lifting phase. When the subscriber presses a key on the CL dial keypad, the microprocessor sends a signal corresponding to the voice frequency generator B which emits a dual-frequency signal on its OAO output; the voice frequency generator sends the level of the wire L3 to its terminal AKD, whence blocking of the transistor T6 and unblocking of the transistor T7 which is biased by the differential amplifier D. The dual-frequency signal emitted by the voice frequency generator is applied through the filtering circuit F at the positive input of the differential amplifier D which applies it to the base of the transistor T7. Resistor 19 constitutes a feedback circuit between the emitter of transistor T7 and the negative input of the differential amplifier D. The transistor T9 of the impedance change circuit R is saturated in static by the conduction of transistor T7 ; the control input of the first voltage regulator TL1 is then connected, through resistors 29 and 28, to wire L6; the voltage across the first voltage regulator TL1 takes a new value such that the line transistor T16 becomes less conductive and has an impedance of the order of 600 ohms.

The current of the collector of transistor T7 which crosses resistors 27 and 28 varies under the control of the dual-frequency signal applied to its base; the voltage across the resistor 28 varies like the current of the transistor T7, which also varies the voltage of the control input of the first voltage regulator TL1, therefore its voltage across the terminals, and therefore the voltage of the base line transistor T16; the line current flowing through the line transistor therefore varies with the frequency of the dual-frequency signal. The potential of the base of the transistor T8 also varies like that of the base of the line transistor, T16, which therefore varies its current; the transistor T8 therefore makes it possible to apply a feedback signal to the negative input of the differential amplifier D, from the signal applied to the base of the line transistor; this feedback signal makes it possible to adjust the total gain between the output of amplifier C and the base of line transistor T16, and to obtain a dynamic impedance of 600 ohms in the subscriber line.

Calibrated shutdown phase
The CN dialing keypad has a special key which, when pressed, acts via microprocessor A on the potential of wire L5 by bringing terminal R8 to the potential of terminal VDD, that is to say wire L3, terminal R8 is normally at the potential of wire L7, that is to say at the potential of terminal VSS.

The transistor T14 saturates and blocks the transistor T17, which causes the blocking of the line transistor T16; this state is controlled by microprocessor A and its duration is 270 milliseconds for example there is therefore cancellation of the line current during this same time at the end of this time, if the handset is not hung up, the off-hook phase proceeds normally, but without the microprocessor initialization phase.

 The various circuits described and shown have of course been given only by way of nonlimiting examples and some means may be replaced by equivalent means. On the other hand, depending on the characteristics of the line, or the specifications, certain devices may not be used; thus, the calibrated cut-off device may not exist in the interface circuit, or else this calibrated cut-off system can be used to make a decimal numbering system with the microprocessor A programmed for this function, or a mixed numbering system, i.e. decimal plus voice frequency.

Claims (8)

1 / Voice frequency keyboard interface circuit for telephone set, two terminals I and IV of the set being each connected to a wire (L1, L2) of a subscriber line through the hooks (CC) of a switch, a conversation circuit (E) of the set being connected between a terminal II of the set and terminal IV, a call device (S) being connected between a terminal III of the set and the wire (L2) connected to the terminal IV by a switch hook, terminals I, II, III, IV being terminals accessible from the station and standardized, said voice frequency keypad comprising a mechanical keyboard (CL), a microprocessor (A) a voice frequency generator (B) and a filtering circuit (F) comprising an amplifier (C) , characterized in that it comprises a supply circuit (P) connected to the terminals I and II, comprising a first supply bridge (D3, DII, D5, D6) and a second supply bridge (D1, D2, D3, Ten), the two bridges having the same negative polarity, an amplification circuit (G), an impedance change circuit (R), a control circuit (T) and a line circuit (CL) , the control circuit (T) connected to positive (piu) and negative (P6) terminals of the first supply bridge consisting of a transistor (T17), a first adjustable voltage regulator (TL1), and a resistor (37) in series, the line circuit (CL) connected to the positive (piu) and negative (P6) terminals of the first supply bridge consisting of a second voltage regulator (TL2), a line transistor (T16) and a line resistor (47) in series, a negative polarity terminal of the first voltage regulator (TL1) being connected to the base of the line transistor, the impedance change circuit (R) comprising a transistor (T9) whose emitter collector circuit is connected between a control input of the first voltage regulator (TL1) and the negative terminal (P6) of the first bridge power supply, said impedance change circuit controlling the change of the impedance of the interface circuit so that it has a low impedance in the conversation phase and a high impedance in the dialing phase. 2 / interface circuit according to claim 1, characterized in that the second supply bridge has a positive terminal (P3) connected to the positive supply terminals (VDD) of the microprocessor (A) and of the voice frequency generator (B), that a negative polarity terminal (P7) of the second voltage regulator (TL2) is connected to the negative power supply terminals (VSS) of the microprocessor and the voice frequency generator, that the amplifier (C) of the filter circuit (F) is supplied between a positive terminal (piu) of the first supply bridge and the negative terminal (P7) of the second voltage regulator (TL2), that the amplifier circuit (G) is connected to the output of the filtering circuit and comprises a differential amplifier (D) and a first transistor (T7), the differential amplifier (D) being supplied between the positive terminal (piu) of the first supply bridge and the negative terminal (P7) of the second voltage regulator (TL2) and the first transistor being connected from on the one hand to the positive terminal (piu) of the first supply bridge and on the other hand to the base of the transistor (T9) of the impedance change circuit (R), and that the transistor (T9) of the change circuit impedance has its collector connected by a first resistor (29) to the control input of the first voltage regulator (TL1), its transmitter connected by a second resistor (28) to the negative terminal (P6) of the first bridge d power supply and its base connected by a third resistor (27) to its transmitter. 3 / interface circuit according to claim 1, characterized in that it comprises a current limiting device (N) constituted by a transistor (T12) having its base connected on the one hand through a resistor (in6) at a point common to the line transistor (T16) and to the line resistance (il7) and on the other hand to the negative terminal (P6) of the first supply bridge by a capacitor (C8), its emitter connected by a other resistance (30) to the negative terminal (P6) of the first supply bridge, and its collector connected on the one hand to the control input of the first voltage regulator (TL1) by a diode (D9) and on the other hand to the positive terminal (P4) of the first supply bridge by a normally compensated thermal compensation transistor (T11) but blocked in calibrated cut-off phase, its base being connected to an output (R8) of the microprocessor brought to positive potential supplying said microprocessor in calibrated shutdown phase. 4 / interface circuit according to claim 1, characterized in that it comprises a device for protection against overcurrents (M) in the line, consisting of a first transistor (T13) and a second transistor (T15 ), the second transistor having its emitter connected to the positive terminal (piu) of the first supply bridge, its collector connected to the base of the transistor (T17) of the control circuit (T) and its base connected to its emitter by a resistor (here) and a capacitor (C9) in parallel, the first transistor (T13) having its emitter connected by a resistor (25) to the negative terminal (P6) of the first supply bridge, its collector connected to the base of the second transistor (T15) and its base connected by a resistor (in0) to a point common to the line transistor (T16) and to the line resistor (47). 5 / interface circuit according to claim 4, characterized in that a zener diode (Z3) of voltage limitation is connected between the base of the first transistor (T13) and a positive polarity of the first voltage regulator (TL1 ). 6 / interface circuit according to claim 1, characterized in that the amplifier circuit (G) comprises a second transistor (T6) having its emitter connected to the positive terminal (P4) of the first supply bridge, its collector connected at the base of the first transistor (T7) and its base connected on the one hand to a control output (AKD) of the voice frequency generator (B) and on the other hand to the negative terminal (P7) of the second voltage regulator (TL2) by a resistor (16). 7 / interface circuit according to claim 1, characterized in that it comprises a calibrated breaking device (H) of the subscriber line, device consisting of a transistor (T14) having its transmitter connected to a terminal ( R8) of the microprocessor (A) whose potential is brought to that of the positive power supply (VDD) of the microprocessor (A) by action on a particular key of the numbering keyboard (CN), its base connected on the one hand through a resistor (38) and a diode (D8) in series at the positive terminal (P4) of the first supply bridge and on the other hand at the negative terminal (P7) of the second voltage regulator (TL2) by another resistor (39), its emitter and its collector being connected by a resistor (36) and its collector being connected to the base of the transistor (T17) of the control circuit (T). 8 / interface circuit according to claim 1, characterized in that it comprises a shunting device (SH) of the conversation circuit on stall and during dialing, comprising a bistable relay whose coil (RL) is controlled by the microprocessor (A) via two transistors (T1, T2), a first transistor (T1) ensuring the charge of a capacitor (C1) in series with the coil of the relay and putting a contact (rl) of the relay in closed position, a second transistor (T2) discharging the capacitor (C1) in the coil to put the contact of the relay (r1) in the open position, said contact being connected in series with a resistor (2) in parallel on the conversation circuit (E).