DE2925444C2 - Telephone booster circuit - Google Patents

Description

The invention relates to a telephone amplifier circuit according to the preamble of claim 1 the main patent 28 24 468.

With the telephone amplifier circuit according to the main patent, the problem is solved, this transformerless designed in such a way that common-mode interference voltages are suppressed and outgoing signals from the output line does not affect the two-core cable and incoming signals from the two-core cable the output line can be fed back.

The power supply for the two wires of the two-wire line must be supplied by a direct current source take place whose direct current is largely free of an alternating voltage ripple AC voltage ripple would appear as a hum in the unbalanced single-core output line. This requires a relatively complex and expensive smoothing circuit for the direct current source.

The object is to improve the telephone amplifier circuit according to the main patent so that the two wires of the two-wire line can also be fed from a direct current source, the direct current of which has an alternating voltage ripple.
This object is achieved by the characterizing features of claim 1. An advantageous embodiment can be found in the dependent claim.

An exemplary embodiment is explained in more detail below with reference to the drawings. It shows

Fig. 1 shows a block diagram according to the main patent and

Fig.2 for connection to the direct current source adapted Telefor.amplifier system.

As the fig. 1, the cores of a two-core symmetrical cable are connected to the same size Resistors 1 and 2 connected. These two resistors are connected to the two inputs of a first one Differential amplifier 3. The output connection of the differential amplifier 3 is connected to the input of a Isolation amplifier 4 connected. This output is also connected to an input of a second differential amplifier 5. The output of the differential amplifier 5 is connected to one of the wires and over a resistor 6 to one input of the differential amplifier 3. The unbalanced line output 7 is connected to the output of the isolation amplifier 4 and also to the other input of the second Differential amplifier 5. This input is the inverter input, while the output of the Differential amplifier 3 is applied to the non-inverter input of the differential amplifier "5

The telephone is connected between the two wires. Signals generated appear as a differential signal over the veins. The differential amplifier 3 converts this signal into one which is asymmetrical to the ground Signal between its output and earth. This signal is amplified by the isolation amplifier 4 and delivered to the unbalanced output line 7.

Common-mode interference voltages that occur in the cores are in phase with respect to ground in both cores and are connected to the with the same amplitude and phase Inputs of the differential amplifier 3 applied. Because between the signals at the inputs of the differential amplifier 3 there is no difference, these signals are not amplified and therefore do not appear at the output of the differential amplifier 3.

The amplifier circuit operates in two directions; H. also incoming signals from the unbalanced one Line 7 are converted into signals that appear in the balanced line.

The signals arriving in the output line 7 are used for amplification by the differential amplifier 5 fed. However, signals also occur in line 7, which are soft in the symmetrical two-wire line occur and were then amplified by the differential amplifier 3 and the isolation amplifier 4. Accordingly the signal from the output of the differential amplifier 3 is both inputs of the differential amplifier 5 supplied in such a way that an input with the

Output of amplifier 3 and the other is connected to the output of amplifier 4, whereby the Signals at the inputs of the amplifier 5 are deleted, d. H. they are not from the differential amplifier 5 re-amplified and fed to the veins. Accordingly, positive feedback is avoided. the The manner in which this suppression is effected is shown in detail with reference to FIGS. 2 described.

The signal fed to the two-wire line from the output line is also present as a differential signal at the input of the differential amplifier 3. Accordingly, the resistors 1 and 2, which are in series between the wires and the inputs of the differential amplifier 3 are connected, have a high resistance, each resistance should preferably be 100 times greater than the resistance of the connected telephone. This reduces the differential signal level at the input of the differential amplifier 3 of the signal from the output of the differential amplifier 5 by at least 200 times.

This signal, which has a low amplitude, is deleted by applying this signal from the output of the differential amplifier 5 via the resistor 6 at the other input of the differential amplifier 3. The resistance of the resistor 6 should therefore preferably be 200 times as great as the impedance of the telephone with the handset picked up. The resistor 6 should have a value that the one input of the Differential amplifier 3 applied signal is the same as that at the other input and also from the Output of the differential amplifier 5 originates and is fed through the resistor 1, whereby these signals cancel each other out in differential amplifier 3.

The F i g. 2 shows the circuit structure of the amplifier circuit according to FIG. 1. The two wires are connected to the corresponding inputs of the differential amplifier 10 via resistors 1 and 2. The amplifier has a feedback resistor 11 between the output and the inverter input of the amplifier is switched. As already mentioned in connection with FIG. 1, the resistance value of resistors 1 and 2 must each be about 100 times greater than the impedance of the telephone, which is connected to the connection and call lines. The output of the amplifier 10 is connected to a capacitor 14, which in turn is connected to the inverter input of the isolating amplifier J7, the latter the isolation amplifier 4 corresponds. The output of the amplifier 17 is via a resistor 18 with the Output terminal 19 connected.

A resistor 22 is connected between the output of the amplifier 17 and its inverter input. The non-inverter input of amplifier 17 is connected to V _c . The inverter input of the differential amplifier 16 is connected to the output of the amplifier 17 via the resistor 76, while the non-inverting input is connected to the output terminal 19 via the resistor 75. which in turn is connected to the output of the isolation amplifier 17 via the resistor 18.

The output of the second differential amplifier 16 is connected to the input of a power amplifier stage. The base of the NPN transistor 81 is connected to the output of the amplifier 16 and the collector of transistor 81 is at the positive pole of a DC voltage source, for example at +5 volts.

The emitter of transistor 81 is through a resistor 28 is connected to the inverter input of the differential amplifier 16. About the emitter of transistor 81 is connected to a wire via a resistor 30. The emitter of transistor 81 is still on a Resistor 32 connected to the non-inverter input of amplifier 10.

It is assumed that the handset of the telephone is lifted from the hook. Via the transistor 81 is Battery voltage across resistor 30 of the connection line fed.

The circuitry comprising the differential amplifier 10 should preferably have a gain of one Have tenths. If the value of the resistor is 1 100 000 ohms, then the value of the resistor should I / 10 000 ohms. Speech signals will be accordingly subjected to an amplitude reduction of one tenth. These signals get over the capacitor 14 and the resistor 76 to the inverter input of the differential amplifier 16. You arrive furthermore via the isolating amplifier 17, the resistor 18 and the resistor 75 to the other input of the differential amplifier 16.

Resistor 18 should have similar Ir, idanz, like the unbalanced line, wetcne is present in the output terminal 19 and the output signal is accordingly at connection 19 half as large as the speech signal in the balanced line.

The ^Λ 'amplifier 5 or 16 is designed so that it amplifies different signals to different degrees.

For signals at the inverter input of the amplifier 5, which originate from the output of the differential amplifier 10, for example, the gain of this stage is approximately 26. For signals coming from the line terminal 19 arrive, the gain of the stage is approximately 5, for example.

If a speech signal occurs in the wires and is present at the differential amplifier IC, a tenfold connection takes place, so that the output signal has an amplitude of one tenth of the input signal having. This signal is fed to the inverter input of the amplifier 16.

The signal is further amplified ten times by the circuit of the differential amplifier 17, whereby the original amplitude at the output of the latter Amplifier is obtained. As a result of the matching resistor 18 to match the line impedance At the output 19, the output signal amplitude is 50% of the original signal amplitude. This signal is applied to the non-inverter input of the differential amplifier 16.

As a result of the above-described difference in amplification by its amplifier circuit for signals, which are applied once to the non-inverter and to the inverter input, is reduced to a tenth original amplitude multiplied by about 26, resulting in an output amplitude of -2.6 times the original amplitude is obtained, while a signal mi *. + 5 multiplied resulting in an output amplitude of + V. or + 2.5. The differential amplifier 16 compares the two signals of -2.6 and +2.5, resulting in a resulting output signal, whose amplitude is 0.1 times the input signal, i.e. a signal amplitude which is negligible. This low signal amplitude of 0.1 of the original amplitude is desirable so that it does not give the impression a dead pipe arises.

If one now considers a line type connection 19 incoming signal, this signal arrives at the amplifier 16. The Auseansssienal at resistor 30 is

5 times half the original signal amplitude or 2.5 times the original signal amplitude. This signal is over the resistor 30 is fed to a wire. By dividing the voltage, it is brought to 1.25 times the original amplitude.

As mentioned before, the signal comes from the output 19, from the amplifier 5 or 16 via the Resistor 30 was supplied, also at the inverter input of the differential amplifier 10, but through the resistance 1 is reduced with respect to the amplitude. The signal from the amplifier or 16 continues to arrive via the resistor 6 or 32 to the non-inverter input of the amplifier 10. Since the value of the resistor 32 is at least twice the total value of resistors 1 and 2, the signal amplitudes at the the same for both entrances. This ensures that the signals present at the inputs of the differential amplifier 10 Output signals of the amplifier 5 are suppressed, creating a feedback and thus

gate 87 in series with a resistor 88 at the non-inverter input of the differential amplifier 16 is applied. The capacitor blocks the -24 volts DC voltage, but lets the AC hum through to the differential amplifier. The values of the capacitor 87 and the resistor 88 should be chosen so that the gain up to the connection 64 is equal to I, which means that the ripple voltage at terminal 65 is equal to the ripple voltage from the differential amplifier 16 cancels.

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Final 19 would be returned.

In the main patent, two transistors are used instead of transistor 81. Using a a single transistor 81 enables the collector of transistor 81 to be connected to a simplified supply voltage source. for example from + 5VoIt. The emitter of this transistor is through resistor 30 connected to the connecting line. A resistor 82 is between the base and emitter of the transistor 81 switched.

The in F i g. 2nd circuit enables connection to a low voltage supply voltage source. For example, it can be connected to 24 volts. In normal telephone systems, the supply voltage is 48 volts. The circuit can be connected are connected to a supply voltage source, which has a certain AC voltage ripple.

Since cheap supply voltage sources often have a high AC voltage ripple, the supply voltage connections are connected to the wires in a similar way to the output of the differential amplifier 16. The -24 volt connection is via resistor 84 with a wire and via resistor 85 with connected to the inverter input of the differential amplifier 10. The value of resistor 84 should be the same be like the value of resistor 30, for example half the line resistance (or about 300 ohms), while the value of resistor 85 should be similar to that of resistor 32, for example about 200,000 ohms. A resistor 86 connects the non-inverter input of the differential amplifier 10 with mass, w. “At its value, for example, about 10,000 ohms.

With the aforementioned values of the resistors 84 and 85, the main part of the ripple current comes from the -24 volt source via resistor 84 to one wire. This signal comes because of the resistor 2 with a significantly reduced amplitude at the non-inverter input of the differential amplifier 10.

The same signal reaches the inverter input with reduced amplitude via resistor 85, see above that a deletion of the AC voltage ripple is effected in the differential amplifier 10 and thus on Output of this amplifier 10 is no hum

The AC hum that occurs at terminals 64 and 65 can be eliminated by using the —24 volt supply voltage source via a condenser for this purpose 2 sheets of drawings

Claims (2)

Patent claims: 1. Telephone amplifier circuit between a symmetrical two-wire line to which a Telephone set is connected, and an unbalanced single-core output line, with a first differential amplifier, the two inputs of which are connected to the wires of the two-wire line and the output of which supplies the outgoing speech signal for the output line, as well as with a second differential amplifier, one input with the output line and one with the output line other input is connected to the output of the first differential amplifier and its output delivers the incoming speech signal for the two-wire line, with between the output of the first differential amplifier and the output line is a non-inverting isolation amplifier is connected, between the two wires of the two-wire line and the inputs of the first Differing strengths are two equally large cons Stands are switched, the resistance value of which is 10 times as large as the input impedance of the telephone set with the handset picked up, the output of the second differential amplifier with one of the wires of the two-wire line and via another resistor to that input of the first differential amplifier is connected to which the other via one of the same resistors The wire of this two-wire line is present and this additional resistance has a value at least equal to twice the resistance value of the resistors of the same size, according to patent 28 24 468, characterized in that a direct current supply voltage source with one of the wires the two-wire line and via a connection resistor (58) to that input of the first Differential amplifier (10) is connected to which one of the same resistors (1,2) the other Wire of the two-wire line is present and this connection resistance (85) has a value approximately equal that of the further resistance (32) aufwe'st. 2. Telephone amplifier circuit according to claim 1, characterized in that the direct current supply voltage source via a capacitor (87) and a resistor (88) connected in series with it an input of the second differential amplifier (16) and capacitor (87) and resistor (88) each have a value at which the gain up to the wire with which the output of the second differential amplifier (16) is equal to 1.