FR2616607A1 - System for transmitting a signal from a microphone for telephone set - Google Patents

Abstract

The invention relates to a system for transmitting a signal over a transmission line from a microphone 1, comprising a preamplifier 2 receiving the signal S emanating from the microphone 1 and delivering the signal transmitted over the line; in which the preamplifier 2 includes a control input for adjusting the gain, the system furthermore comprising means 5, 6, 7 for adjusting the gain of the preamplifier 2 receiving at a first input the signal emanating from the microphone and at a second input a threshold, comparing the signal with this threshold and delivering a signal applied to the control input for adjusting the gain of the preamplifier in such a way as to reduce the gain of the transmission system when the signal is below the threshold. Application to telephone sets.

Description

SIGNAL EMISSION CHAIN
FROM A MICROPHONE
FOR TELEPHONE SET
The invention relates to channels for transmitting a signal from a microphone, in particular for telephone sets.

 The transmission chain of a telephone set mainly comprises a microphone which transforms the speech of a subscriber into an electrical signal, this signal then being amplified in a preamplifier and then amplified by an output amplifier of the station. The signal thus amplified is transmitted on the telephone line.

 The microphones used today are more and more sensitive which is an advantage for using the handset hands-free. In fact, when a microphone has a high sensitivity, it is possible to put this handset on and talk to a caller while staying relatively far from this microphone.

 Such microphones are also extremely sensitive to noise - which is particularly annoying for the caller. In fact, during the silences which take place between the words during a conversation, the noises are picked up by the microphone, transmitted on the line and heard by the subscriber at the other end of the line.

 The present invention makes it possible to remedy this problem by proposing a chain for transmitting a signal from a microphone, which includes a threshold comparator making it possible to reduce the gain of the transmission chain when the online signal is below of the threshold, that is to say when the online signal is considered to be noise.

 the present invention relates to a chain for transmitting a signal on a transmission line from a microphone, comprising a preamplifier receiving the signal from the microphone and delivering the signal transmitted on the line; characterized in that the preamplifier has a gain adjustment control input and in that the chain comprises means for adjusting the gain of the preamplifier, receiving at a first input the signal from the microphone and at a second input a threshold, comparing the signal to this threshold and delivering a signal applied to the preamplifier gain adjustment control input so as to reduce the gain of the transmission chain when the signal is below the threshold.

 The present invention will be better understood using the description given below by way of nonlimiting example and illustrated by the drawings.

- Figure 1 shows a diagram of an emission chain according to the invention
- Figure 2 shows a detailed diagram of the preamplifier according to Figure 1
- Figure 3 shows a detailed diagram of the peak detector according to Figure 1
- Figure 4 shows a detailed diagram of the comparator according to Figure 1
- Figure 5 shows a detailed diagram of the microphone preamplifier according to Figure 1.

FIG. 1 represents the general diagram of a chain for transmitting a signal on a transmission line 4. The chain comprises a microphone 1 either of electret or electrodynamic type which transforms speech into an electrical signal
S. This signal is transmitted both to a variable gain preamplifier 2 and to a gain adjustment circuit 11 of this preamplifier 2. The output signal of the preamplifier is transmitted by a line 4 after being amplified by an amplifier of output 3 of the telephone station emission chain to have the required level on the telephone line. The gain adjustment circuit 11 preferably comprises a preamplifier 6 which receives the signal S directly, a peak detector 7, a threshold comparator 5 and a time constant circuit 10. The comparator output signal makes it possible to adjust gain of microphone preamplifier 2.

 One of the aims of the invention consists in reducing the noise emitted online outside of the speech periods, a line level is chosen for this, below which any signal is considered to be noise. When the online signal drops below this level, the gain of the broadcast channel is reduced. the gain reduction is done on the microphone preamplifier 2 from information on the dynamics of the signal transmitted, this information being provided by the peak detector.

 Another object of the invention consists in avoiding untimely variations in the transmission gain when the signal transmitted is - in the vicinity of the threshold, a hysteresis is introduced for this on the comparator.

 Another object of the invention consists in avoiding unpleasant noises due to sudden variations in gain, for this, these variations are integrated by a circuit 10 having a predetermined time constant.

 Another object of the invention consists in eliminating the parasitic components of the sector which are important. at the level of the signal taken at the output of the preamplifier 6, a connection capacitor 8 is connected for this between the output S6 of the preamplifier 6 and the input D7 of the detector 7.

 According to the particular example which will be described below, the online noise level below which the signal is considered to be noise is -35dBm. The gain of the transmission chain having been chosen of 50dB, the noise threshold at the microphone is therefore -86dBm or 40 pV effective. As according to this particular example, the threshold is particularly low, so a preamplifier is provided before the peak detector.

 A particular example of embodiment of each of these circuits is described in the following. These particular examples are designed to allow integration. The examples of the values which are given, are given as an indication and correspond to the threshold which was fixed in this application.

FIG. 2 represents a particular embodiment of the preamplifier 6 according to the invention. The gain of 48dB is fixed by a network of four resistors R9, R10,
R11, R12 easier to integrate than two resistors with higher values. The transistors T12, T13, T14, T31, T32 make it possible to limit the output dynamics so as not to saturate the next stage. The signal from the microphone is applied to the input
A6 which is constituted by the base of a transistor T5 which forms with a transistor T6 a differential amplifier whose bias current is supplied by a current source J1.

The preamplifier 6 is supplied by a voltage source Va - Vb. The potential Va is approximately equal to 5V, the potential
Vb is equal to OV.

The differential amplifier T5, T6, J1, is part of an input stage constituted by the transistors T1 to T9 and the polarization resistors R1 to R4, R15 and R16. Two series resistors R8, R9 are connected between the base of the transistor T6 and a reference voltage Vr. Resistances
R10 and R12 are connected in series between the common point A7 of the resistors R8 and R9 and the output terminal S6 of circuit 6.

An output stage comprises a darlington circuit T10, T11 with resistors R13 and R14 and a dynamic limiter comprising a current mirror T12, T13, J2, the resistor R7 and the transistor T14 and a current source J3. This output stage makes it possible to limit the consumption of the current symmetrically during a negative and positive alternation of the input signal.

The current I12 of 5 PA supplied by the source J2 is
copied by transistor T12. The transistor T13 which is of geometry 4 delivers a current I13 of 20 p A
During a positive alternation, the transistors of the darlington circuit are blocked, the current 113 passes through the diode T24, half of this current is absorbed for the resistor R11, the other half compensates for the current source J3.

 During a negative half-wave, the transistors T10 and T11 are conducting, the current I13 is absorbed by the transistor T11. The diode T24 prevents the current from the source J3 from also being absorbed by the transistor TI1, this current I13 passes through the resistance network.

 In Figure 3, there is shown a particular embodiment of the peak detector 7 according to the invention.

This detector is a mono-alternating rectifier which comprises an input stage comprising the transistors T25 to
T28, the current sources J4, J5, with an input terminal D7 and an output stage comprising the transistors T12 to T23, the current source J6 and an output terminal S7. The detector is supplied by the potential terminals Va, Vb When during a positive current alternation, the signal increases, the transistor T29 which receives on its base the signal copied by the transistor T19, the current I6 from the source J6 passes through diodes T21, T22, T23 and allows to charge the capacitor
C of the circuit RC 9 at the same time as the threshold voltage of the diode T23. This circuit 9 is a circuit external to the integrated circuit and one terminal of which is connected to the output terminal S7 and the other terminal to the potential terminal Vb . The rise time is equal to the charging time of the capacitor and the discharge takes place through the resistor R, the current being unable to pass through the transistor T29 because of the non-return diodes T21 and T22. This arrangement allows thanks to the current source J6 to have a constant consumption and thanks to the RC circuit to have a discharge speed slower than the charge speed.

The peak detector does not introduce a variation in the current consumed on the line in the presence of the signal corresponding to speech; the load of the capacity being done at constant current by the source J6. Diodes T20 to
T22 avoid saturating the transistor T29 in the absence of speech, when the capacitor C of the detector is charged. The descent time of the peak detection is set by the external resistance R.

 The threshold function is inhibited by grounding the S7 output. In the case of the handset used hands-free, it may be useful to keep all the sensitivity of the microphone, and therefore to remove the threshold introduced by the device according to the invention.

 In Figure 4, there is shown an embodiment of the comparator 5 according to the invention.

 The comparator 5 has a first input E2 which receives the signal from the common terminal S7, from the output of the detector 7 and of the circuit 9.

The input E2 is formed by the base of a transistor
T51. The comparator 8 has a second input El which receives the threshold voltage VS equal to iOmV in this example.

This input is formed by the base of a substrate PNP transistor, T50 which consequently has a large gain and a very low base current.

 The threshold of iOmV applied to the input El corresponds to a signal of 40> 1V of amplitude applied to the input of the preamplifier A6 whose gain is 250.

Comparator 5 has two Darlington circuits, a first circuit consisting of transistors T46 to T50 for an input, a second circuit consisting of transistors
T47 to T51 for a second entry E2. The collector currents of transistors T46 and T47 (mounted on a diode) are each fixed by a current source J7 for T46 and J8 for
T47. Comparator 5 therefore has two Darlington inputs to reduce the effect of the base current of transistors T50 and T51.

 The output of this stage is produced by means of the transistors T45, T58, T59, a current mirror T61, T62, diodes T53 to T57, T60, current sources J9 and J10.

When the signal at the input E2 is less than the threshold applied to the input El, the transistors T45, T59, T58 are conducting so that the current from the source J9 is absorbed for the transistor T58. T61 transistors (diode mounted) and
T62 are blocked, the output current I1 supplied by this comparator 8 is then fixed by the current source J10.

When the signal at input E2 is greater than the threshold applied to the input El, the transistors T45, T59, T58 are blocked. The current of the source. J9 goes through the diodes T55,
T60 and T61. The 1/4 mirror formed by the transistors T61 and T62 (of geometry 4) generates a current at the collector of T62 equal to four times J9. The collector current of transistor T62 is added to the current of source J10 at the common point S5 of output of comparator 8.

 So when the detected signal is below the threshold VS which has been predetermined, a current Il corresponding to the current of the current source J10 is applied to the control of the preamplifier 2, this current I1 is higher (three times higher in this particular application ) when the detected signal is above the threshold VS. The current I1 is equal to 10 uA given by J10 when the signal in E2 is less than VS. The current I1 is equal to 5gA x 4 + 10pA or 30> iA when the signal in E2 is greater than VS. The ratio between these two current values defines the gain factor applied to the preamplifier 2. The transition from 30pA to lOpA corresponds to a reduction in the gain of lOdb. The. comparator 8 a constant current consumption whatever the signal that this signal is greater or less than the threshold VS. Indeed, the current consumed in the two cases corresponds to the current supplied by the source J9, multiplied by the geometry factor four of T59 in one case or of T62 in the other case.

 On the other hand, a hysteresis phenomenon is introduced into the comparator so as not to cause untimely tilting when the signal is in the vicinity of the threshold. For this, the comparator comprises a stage which makes it possible to reduce the current supplied by a current source fixing the threshold VS by means of a resistor R20. This stage includes a current source J11, the transistors T37 to 40 and T52, the diode T41.

Resistors R20 and R21. When the signal at the input E2 is above the threshold given by the voltage across the resistor R20, the transistor T61 conducts, the transistor T52 becomes conductive (their base being rellated) and absorbs the current supplied by the transistor T38 which copies the current of transistor T37, this transistor being biased by the source J11.

The current I38 of the transistor T38 is therefore absorbed by the transistor T52. Transistor T39 copies the current from the transistor
T37 by increasing its amplitude in a ratio three, its geometry being three. The current I39 supplied by the transistor T39 passes through the resistor R20 and then defines a threshold VS equal to R20 x I39 either: Jll being equal to 10JuA, and R20 to 1k A, then VS = 30mV instead of 40mV when the transistor
T52 does not drive.

 When the signal at the input E2 is below the threshold, the transistor T61 is blocked, the transistor T52 is blocked, the threshold is then fixed by the current I38 added to the current I39 passing through the resistor R20.

 The comparator 5 also includes an integrator produced by the capacitor 10 connected between the bases of the transistors T61 and T62 and the ground to integrate the polarization variations of the input A2 of the preamplifier 2.

 In Figure 5, there is shown an embodiment of a microphone 2 preamplifier according to the invention.

The preamplifier 2 has a high input impedance and therefore allows the use of electret type microphones. The signal from microphone 1 is applied to the bases of a differential amplifier T70, T71. The bases are also connected to the reference potential Vr by a resistor R24, R25. The transmitter bias current I1 is supplied by the comparator output S5. The collector of transistor T70 is connected to a current mirror T75, T74, R20,
R21. The collector of transistor T71 is connected to a current mirror T76, T77, R22, R23.

 A second differential amplifier T72, T73 with a fixed bias current I12 given by a current source J12 is connected to the first differential.

The base of transistor T72 is connected to potential Vr by a resistor R26, the base of transistor T73 is connected to this potential Vr by resistor R30. The collectors of these transistors T72, T73 are connected to the collectors of the transistors
T70 and T71 and consequently respectively to the current mirrors T74, T75 on the one hand, T76, T77 on the other hand. The current at point N1 corresponds to the sum of the collector currents is mirrored by the transistor T74, copied by the transistor T79 and copied inverted by the transistor T80. In the same way the current at point N2 results from the sum of the collector currents, this current is mirrored by the transistor T77. At point N3 the currents from transistor T80 and T77 are cut off and the corresponding current is applied to the base of a transistor T81. The preamplifier includes a dynamic limiter at its output. This limiter includes the transistors T83 to T85, the current sources J13 and J14, the resistor R34 and the diode T86.

 The current at the output of the collector of transistor T84 is four times greater than the source J13 due to the geometry of T84 and is equal to 2qpA. The limitation on the positive alternation of the signal is made when the transistors T81 and T82 are not conductive: J14 absorbs 10 A and pass through the resistor (R30 + R31). The limitation on the negative half-wave is done when the transistors T81 and T82 absorb all the current of the transistor T84. The lOjuA of the source J14 are taken from the resistance (R30 + R31) thus limiting the amplitude on the negative half-wave of the signal.

 The gain control is done by depolarization of the microphone preamplifier. This gain is fixed at all times by the formula.

It R30 + R31 G = -
A variation of the current I1 on the output S5 of the comparator therefore introduces a variation of the gain of the preamplifier - when the signal amplitude is less than the threshold: I1 decreases and the gain decreases - when the signal amplitude is greater than the threshold: I1 has its maximum value and therefore the gain of the preamplifier also has its maximum value.

 The gain control is therefore done by depolarization of the microphone preamplifier when the signal transmitted is below the noise threshold, the current source I1 polarizing the differential (T70, T71X being reduced compared to the current source I2 polarizing the differential (T72 , T73).

Claims (9)

 1. Chain for transmitting a signal on a transmission line from a microphone (1), comprising a preamplifier (2) receiving the signal (S) from the microphone (1) and delivering the signal transmitted on the line ; characterized in that the preamplifier (2) has a gain adjustment control input and in that the chain comprises means for adjusting the gain (5, 6, 7) of the preamplifier (Z), receiving a first input the signal from the microphone and on a second input a threshold, comparing the signal to this threshold and delivering a signal applied to the preamplifier gain adjustment control input so as to reduce the gain of the transmission chain when the signal is below the threshold.  2. Transmission chain according to claim 1, characterized in that the adjustment means comprise  - a threshold comparator having a first (El) and a second (E2) input, receiving on the first input the threshold (VS)  - a peak detector (7) comprising an input and an output, the output being connected to the second (E2) input of the comparator (5)  - a preamplifier (6) comprising an input (A6) receiving the signal from the microphone (1) and delivering a signal applied to the input of the peak detector  3. Transmission chain according to claim 2, characterized in that it further comprises a coupling capacity (8) between the output (S6) of the preamplifier (6) and the input of the peak detector (D7) to remove the offset voltage and the parasitic components due to the mains frequency.  4. Transmission chain according to claim 2, characterized in that it also comprises an integrator (9) (RC), one common terminal of which is connected to the second input (E2) of the comparator (5) and the other of which common terminal is connected to an electrical ground.  5. Transmission chain according to any one of claims 1 to 4, characterized in that it comprises an integrator (10) connected by a terminal to the output (S5) of the comparator (5) and to the input of the gain adjustment (G2) of the variable gain preamplifier (2) and connected by the other terminal to an electrical ground, to integrate the variations in polarlsation of the input (A2) of the variable gain preamplifier signal (2).  6. Transmission chain according to any one of claims 1 to 5, characterized in that the preamplifier (6) comprises -an input stage (T1 to T9) comprising a differential current amplifier (T5, T6, I1 ) one input of which corresponds to the input (A6) of the stage signal; a resistor network (R9 - R12) between the signal output (S6) and an input (A7) of the differential amplifier (T5, T6, Il) to fix the gain at a predetermined value; an output stage comprising a darlington circuit (T10, T11) and a dynamic limiter (T12, T13, -T14, J2, J3) to limit the current consumption symmetrically during a negative and a positive alternation of the input signal .  7. Transmission chain according to any one of claims i to 6, characterized in that the peak detector (7) consists of a full-wave rectifier comprising an input stage (J4, J5, T27, T28, T25, T26) with a signal input (D7); an output stage (T19, T29, T20 - T23, J6) comprising a charge control circuit with constant current or discharge of the integrator circuit (9) connected to the output (S7) of this stage.  8. Transmission chain according to any one of claims 1 to 7, characterized in that the threshold comparator (8) comprises a differential stage (T46 to T51) having a first input (El) for the threshold signal, a second input (E2) for the output signal of the peak detector, a circuit for adjusting the polarization of the preamplifier (T55 to T62 and J9, J10), a hysteresis circuit (Jll, T37 to T40 and T52).  9. Transmission chain according to any one of claims 1 to 8, characterized in that the microphone preamplifier comprises a first (T70, T71) and a second (T72, T73), differential amplifier whose bias current (I1 ) of the first is given by the output of the comparator (8) the bias current (I2) of the second being fixed by a current source (J12), a gain circuit - (R30, R31), a dynamic limiter at the output (T38 to T85, J13, J14).