HU184627B - Circuit arrangement for integrated amplifiers of two-wire technology - Google Patents

Abstract

The integrated amplifier is matched to the telephone network and has a wide drive range using few components. The amplifier's a.c. output impedance is increased compared to the differential impedance corresponding to the intermediate voltage output characteristics in the linear range. This increase is achieved by passing a positive feedback signal - obtained from a resistor - via a current mirror to the drive point of the output stage. A compensation signal is obtained from a point supplying the input stages and passed via two further current mirrors to the output stage's drive point in order to suppress the d.c. component of the positive feedback signal.

Description

(57) EXTRAS

BACKGROUND OF THE INVENTION The present invention relates to a circuit arrangement for integrated amplifiers of a two-wire technique using complementary mirror circuit units having a power amplifier output signal superimposed directly on a power supply connected to an internal point of the amplifier and a DC compensating voltage divider consists of two resistors, and a second capacitor is connected to a ground, parallel to the second resistor, and connected to a first price reflecting unit.

The object of the invention is that the voltage divider node is connected to a preamplifier, the output of the preamplifier is connected via a second mirror circuit unit, the input of which is connected to a power line through a coupling resistor, the terminal of the complementary mirror circuit unit is connected to the input circuit of the amplifier. it is connected to the output of the first mirror circuit unit and a resistor is connected between the input of the amplifier and the power line.

Figure 1

-1184,627

BACKGROUND OF THE INVENTION The present invention relates to a circuit arrangement for integrated amplifiers of a two-wire technique which can be used in connection with electroacoustic transducers in telecommunication technology, in particular in telephone technology.

Circuit arrangements for integrated amplifiers of two-wire technology are used to replace carbon microphones in new microphones built using better quality electroacoustic transducers such as piezoceramic, magnetic, or dynamic transducers. German Patent Publication No. 2,121,929 discloses a voltage-stabilized transistor amplifier consisting of a five-stage preamplifier and two parallel-connected end amplifiers. The transistor amplifier has no positive feedback and thus has too low an AC output resistance to connect to the mains.

German Patent Publication No. 1 762 924 discloses a telephone nicrophone amplifier consisting of a negative feedback differential amplifier or Darlington switched terminal and a positive feedback diode resistor network. This positive feedback reduces the current dependence of the gain.

. The AC output resistance of the circuit arrangement is barely improved with this solution compared to the carbon microphone. The low AC output resistance of the telephone coupling is disadvantageous due to the effect on the earpiece and microphone. In addition to this switching arrangement, on the one hand, the AC output resistance is less than desirable, but on the other hand, the differential resistance according to the output voltage characteristic of the current is so large that it limits the current range in which the circuit can be used. Accordingly, said circuits do not represent a technical advance in relation to the outgoing side connection to the telephone network with respect to use in modern telephone and telecommunication systems.

It is an object of the present invention to improve transmission quality and connectivity to the telephone network in dual wire technology, particularly in connection with amplifiers integrated with electroacoustic converters.

The object of the present invention is to provide a switching arrangement for integrated amplifiers of the dual-wire technique which can increase the AC output resistance than the differential resistance in the linear domain of the output voltage characteristic and the integrated amplifier in a high operating current range. it should be well controlled and easily connected to the telephone network.

The object of the present invention is solved by applying a coupling resistor to the power line which carries the output signal of the amplifier between the preamplifier output.

The coupling resistor produces a signal that contains an interfering DC component and the optional component of the coupler. In order to partially or completely eliminate the DC component, a compensation circuit is provided when a voltage divider, which is connected to the power line and consists of two resistors, with 2 capacitors connected to the ground in parallel with the second resistor, is mounted on a first mirror circuit unit. on.

The output of the first mirror circuit unit is connected to the input of a complementary mirror circuit unit, the emitter of which is connected to the power line, and the output of the complementary mirror circuit unit is connected to the control point of the amplifier. Through a second mirror circuit unit having an emitter grounded and coupled to an input transistor as a diode, to a coupling resistor and a preamp output, and to an output transistor collector to a terminal amplifier control point, the preamplifier output signal and the transformer , is connected to the control point of the power amplifier, which is connected to the power line through a resistor.

The voltage divider for producing the compensation signal provides a bias voltage to stabilize the preamplifier.

Thus, at the control point of the amplifier, the desired signal is formed which consists of the output of the preamplifier, the AC component of the coupler signal and a defined and adjustable residual portion of the DC signal which is generated by the coupler network.

The present invention provides an integrated amplifier having an AC output resistance greater than the differential resistance in the linear range of the current to voltage output characteristic. This provides, on the one hand, a better interface to the telephone network and, on the other hand, an integrated amplifier that operates over a wide power range. In addition, the defined gain control is independent of the AC output resistance, and can take advantage of the specific influence of the gain and AC output resistance and the output DC voltage, and thus the AC output resistance within the normal operating range. The entire amplifier is of a simple construction because only one external component is needed.

To ensure that the circuit layout parameters are independent of fluctuations in the individual power supply parameters across the entire power range, there is a resistor between the emitters of the transistors of the first and second mirror circuit units and ground, and of the transistors of the complementary mirror circuit unit the base collector short circuit of the input transistor of the complementary mirror circuit unit is replaced by a further transistor emitter base section, the transistor emitter of which is connected to the connected bases of the two mirror circuit transistors and its collector is grounded. To enable the gain adjustment of the whole arrangement by switching on a simple external short-circuit or resistor, the coupling resistor between the power cord and the preamplifier output is replaced by two series-resistor resistors, where the two resistor interconnection points are led.

By changing an external resistor between the power line and said connection point, the gain can be varied.

The invention will now be described in more detail with reference to an embodiment and drawings. In the drawings, Fig. 1 is a basic circuit of the proposed circuit arrangement, and Fig. 2 is an expanded circuit arrangement.

184,627

As shown in FIG. 1, the output signal of a preamplifier 1 having a current output is applied to the node 7.

The preamplifier 1 is connected via the connecting line 2 to the supply line 3 and through the connecting line 4 and the current generator 5 to ground 6. The resistor 5 of the coupler 8 is connected between the node 7 and the supply line 3. The npn transistor 9 is the reference element of the mirror circuit unit 10, and its collector 11 and base 12 are connected to node 7 and connected to ground 6 by its emitter 13. The emitter 14 of the npn transistor 10 of the mirror circuit unit 10 is coupled to ground 6, the base 16 of which is connected to the base 12 of the npn transistor 9 and is connected to the node 7 via a short-circuit. The collector 17 of the npn transistor 15 is connected to the control point 18 of the terminal amplifier 19, which is connected to the ground point 6 via the connecting line 20 15.

The output of the terminal amplifier 19 is connected to the supply line 3 via the connecting cable 21. The input of the amplifier 19 is connected to the control point 18 and via the resistor 22 which forms the working resistance of the preamplifier 1 to the power supply line 20.

. The resistor 23 is connected from the power line 3 to the node 24, which is connected via the resistor 25 to the node 26. The collector 27 and base 30 of the npn transistor 28, which is the reference element of the mirror circuit unit 29, is coupled to the node 26 and its emitter 31 is connected to the ground 6. The base 32 of the npn transistor 33 is connected to the base 30 of the npn transistor 28, the emitter 34 of the npn transistor 33 is connected to ground 6, and its collector 35 is connected to the node 36. The collector 37 and base 38 of the npn transistor 39, which is the reference element of the 3θ mirror circuit unit 40, are coupled to the node 36. The emitter 41 of the pnp transistor 39 is coupled to the power line 3 and the base 42 of the pnp transistor 43 of the mirror circuit assembly 40 is coupled to the base 38 of the pnp transistor 39. The emitter 44 of the pnp transistor 43 is connected to the supply line 3 and its collector 45 is connected to the control point 18 of the terminal amplifier 19.

Capacitor 46 is coupled between node 24 and ground 6. The node 24 is connected to the preamplifier 1 via the connecting line 47.

The connection terminals 48 and 49 serve to direct the input signal to the preamplifier 1. The connection point 50 of the power supply line 3 is led through the load resistor 51 to the node 52, from which the capacitor 53 and the current source 54 are connected in parallel to ground 6.

2, the emitter 13 is connected through resistor 55, emitter 14 through resistor 56, emitter 31 through resistor 57, and emitter 34 through resistor 58. 6, and emitter 41 is connected to resistor 59, and emitter 44 is connected to resistor 60 via power line 3. Between the node 36 and the common point of the bases 38 and 42, the base-emitter section of the pnp transistor 61 is replaced by a short-circuit, the base 62 of the pnp transistor 61 is connected to the node 36 and between the node 36 and the main point 6 The base collector section of the transistor is located. Instead of the coupling resistor 8, the supply line 3 is connected to the node 7 by a series of resistors 63 and 64, and a connection point 65 with a terminal 66 is provided between the resistors 63 and 64 so that an external short circuit or resistor can be provided. between terminals.

Claims (3)

PATENT CLAIMS 1. A circuit arrangement for integrated amplifiers of a dual-wire technique using complementary mirror circuit units, wherein an output signal of a power amplifier superimposed directly on a power supply is connected to an internal point of the amplifier, and a DC compensating voltage divider connected to the power line consisting of a resistor and a capacitor coupled to ground at the second resistor, connected to a first mirror circuit unit, characterized in that the node (24) of the voltage divider resistors (23, 25) is connected to a preamplifier (1); via a second mirror circuit unit (10) whose input is connected to a power line (3) via a coupling resistor (8), connected to the input of the power amplifier (19) by the output of the complementary mirror circuit unit (40), the complementary mirror circuit unit (40) input is connected to the first output of the mirror circuit unit (29), and a resistor is connected between the power amplifier (19) input to the supply line (3) (22). An embodiment of a circuit arrangement according to claim 1, characterized in that the emitters of the first and second mirror circuit units (29, 10) are connected via a resistor (57, 58; 55, 56) with the ground point (6) and the emitters of the complementary mirror circuit unit (40) are connected to the power line (3) via a resistor (59, 60) and are implemented by serially switching the resistor (8) with two resistors (63, 64) separately is led. An embodiment of a circuit arrangement according to claim 1, characterized in that the base emitter section of the transistor (61) coupled to the ground is parallel to the collector-base section of the input transistor (39) of the complementary circuit circuit (40), such that the output of the first mirror circuit assembly (29) being connected to the base (62) of the transistor (61) and the collector (37) of the input transistor (39). 2 drawings, 2 figures -3184 627 NSO ·,: Η 04 Μ 1/60