DE4013885A1 - Complex impedance model for 2-wire 4-wire interface - Google Patents

Abstract

The complex impedance model has a measuring device (M) providing a voltage proportional to the output signal of the model, using an output amplifier (VS2) supplying an output current fed to an output resistance (RM) to provide the model output current (S). A second circuit path contains a complex impedance (Z) connected between the output of the measuring device (M) and the input of the output amplifier (VS2). Pref. a feedback operational amplifier (VS1) input of the output amplifier (VS2) has a feedback path provided by a complex partial impedance.

Description

The invention relates to a simulation of a complex Impedance, especially the simulation of the impedance of a Telephone subscriber line, as well as a Two-wire four-wire interface with one Replica.

Two-wire four-wire interfaces or also Hybrid circuits are in the telephone and Transmission technology has been known for a long time. Fork circuits are three gates with the task of a receiver (e.g. the Earpiece of a telephone) from a transmitter (e.g. to decouple the capsule of a telephone) and yet couple both with a two-wire line. To achieve this, there is an additional one Line replication required. Cf. for this z. B. K. Steinbuch, W. Rupprecht, communications engineering, Springer publishing house Berlin u. a. 1973, pp. 235-241. The German Bundespost is currently demanding the replication of a line, their impedance as a series connection of a resistor 220 ohms with the parallel connection from a resistor too 820 ohms and a capacitance of 115 nF is formed. Other postal administrations give the same order similar values.  

Especially for those facilities that are for everyone individual participants must be present is one Reduction of effort and costs is urgently required. That is why these institutions, including the Two-wire four-wire interfaces with those in it included replicas, if possible as integrated circuits executed. Particularly annoying are the capacities. A minimum requirement is now that that instead of a given capacity value any other can be used and that anyway the required property is achieved. A Two-wire four-wire interface has different To meet demands simultaneously. With many known versions are therefore often several Impedances with a capacitive component included in one specified relationship to each other. The Tolerances of the components must then be chosen very closely because deviations in the absolute value are often less make out as deviations from each other. The aim is therefore, with as few impedances as possible, if possible with an impedance to get along. In the present case the replica should also be independent of of the impedance to be simulated, freely definable ohmic Have series share as measuring resistor, that of the measurement of the current on the line can serve.

The invention has for its object with little Feasible replicas and thus equipped two-wire four-wire interfaces specify a predetermined ohmic series component have as a measuring resistor, the measurement of the current can serve on the line.  

The task is solved by a replica according to the Teaching of claim 1 and an interface according to the Teaching of claim 5. Advantageous embodiments of the Invention can be found in the subclaims.

The basic idea is the outcome of a Amplifier over the measuring resistor and a complex Feedback network so on the input of the Coupling the amplifier back at the end remote from the amplifier of the measuring resistor is the one required for the simulation Phase relationship between voltage and current occurs. A additional, purely ohmic feedback branch allowed it to specify the measuring resistor as desired.

The two-wire four-wire interface according to the invention makes advantageously of the invention Replica use. By appropriate dimensioning of the ohmic feedback path can be achieved that the interface just a single complex impedance which is equal to a real multiple of is to be simulated impedance. Both earth symmetrical as also asymmetrical replicas and interfaces are equally easy to implement.

In the following the invention with the aid of accompanying drawings further explained.

Fig. 1 shows an embodiment of a replica of the invention.

Fig. 2 shows an embodiment of an interface according to the invention with a replica of the invention contained therein.

The replica N of Fig. 1 includes a measuring device M, and an amplifier V.

The measuring arrangement M consists of a measuring resistor RM and a measuring amplifier, for the sake of simplicity and because no additional degree of freedom is needed Gain factor equal to 1 is selected. The Measuring resistor RM connects the output of amplifier V with a connection a, the replica N. The other Connection is earthed. The measuring resistor RM is from the flows through the replica N flowing current i. Between the connections of the replica N is the Voltage u. The output of the measuring arrangement is also located the tension u.

The amplifier V is constructed in two stages with a first amplifier stage VS1 and a second amplifier stage VS2, each with an operational amplifier. The inverting input of the operational amplifier of the first amplifier stage is connected via a feedback resistor RS to its output and by a complex impedance Z to the output of the measuring arrangement. The inverting input of the operational amplifier of the second amplifier stage is connected via a feedback resistor R 4 to the output thereof, via a resistor R 2 to the output of the first amplifier stage and via a resistor R 3 to the output of the measuring arrangement M.

As can be easily shown, current i and voltage u behave like at the terminals of the replica N
i / u = 1 / Zin = (1 / Z) (RS / R 2 ) (R 4 / RM) + (1 / RM) (1-R 4 / R 3 ).

It is readily apparent that the Impedance Zin uses a different impedance Z can be. In particular, instead of one in the impedance contained capacity of z. B. 115 nF a smaller capacity with standardized size, e.g. B. 1 nF be used. Such capacities are also easier to get with tighter tolerance. Both at the mechanical size as well as the price can be a Achieve reduction to about 1/10.

In the event that the feedback branch with the resistor R 3 is missing, that is to say for R 4 / R 3 = 0, the simulated impedance has an ohmic series component which is at least as large as the measuring resistor RM. By inserting the resistor R 3 , the measuring resistor can be chosen to be of any size.

Based on two particularly advantageous dimensions be pointed out:

• - For R 2 = R 3 = R 4 , Zin is equal to a real multiple of Z, namely Zin = (RM / RS) Z.
• - If Zin contains an ohmic series component, it can can be achieved that Z contains no such.

Fig. 2 is now a two-wire-four-wire interface according to the invention shows a therein invention replica N. This interface circuit of connecting a unidirectionally operated receive line E and a unidirectionally operated transmit line S is on the one hand with a bidirectionally operated two-wire line a, b on the other hand.

The two-wire line a, b is completed with the replica N. This contains a measuring arrangement M, a two-stage amplifier with the amplifier stages VS 1 and VS 2 and an inverter I.

In contrast to the example according to FIG. 1, the replica N is constructed here in earth symmetry. This is achieved by the inverter I and the division of the measuring resistor into the measuring resistors RS 1 and RS 2 .

The consequence of the earth-symmetrical structure is that the measuring arrangement M is constructed as a differential amplifier. For the sake of simplicity, the measuring arrangement M is dimensioned such that, in the absence of voltage on the receiving line E, the voltage u present on the two-wire line a, b on the measuring arrangement M causes the output voltage u 1 = -u. It would also be possible to set up and measure the measuring arrangement so that u 1 = -i (RS 1 + RS 2 ).

The branch from the reception line E to the two-wire line a, b is coupled into the measuring arrangement M in the example according to FIG. 2 via a resistor R 9 . It thus leads primarily via the complex impedance Z to the amplifier stage VS 2 and from there via the inverter I and the measuring resistors RS 1 and RS 2 to the two-wire line a, b. The effect of this signal routing is the same as that of the circuit protected by European Patent 01 71 692. To understand this, reference is made to the associated patent specification. In the present case, however, the purely real-acting branch has a disturbing effect via the resistor R 3 . This is compensated for by an additional purely real branch via a resistor R 1 from the reception line E directly to the inverting input of the amplifier stage VS 2 . The dimensioning is simple, it results in R 1 / R 3 = R 9 / R 7 .

In the dual case described above, in which the voltage measurement is replaced by a current measurement and the gain factor of the amplifier stage VS 1 is replaced by the reciprocal value, the signal coming from the reception line E could be coupled in via an ohmic resistor at the inverting input of VS 2 .

To the transmission line S, the interface has a transmission amplifier SV, which on the one hand evaluates the output voltage of the measuring arrangement M and on the other hand adds a signal proportional to the voltage on the receiving line E via a resistor R 10 in order to compensate for its share in the output voltage of the measuring arrangement M. In the case of the dual circuit, the transmitter amplifier SV would also have to take over the measurement of the voltage on the two-wire line.

Such an interface is usually part of it a subscriber line circuit. The remaining functions are not shown here.

Claims (7)

1. Simulation of a complex impedance, in particular simulation of the impedance of a telephone subscriber line, with a measuring arrangement (M) which outputs a voltage (u 1 ) proportional to the output signal (u, i) of the simulation, with an output amplifier (VS 2 ), the output current of which flows through an output resistor (RM, RS 1 , RS 2 ) and the output current (i) is the simulation, with a branch containing a second complex impedance (Z) from the output of the measuring arrangement (M) to the input of the output amplifier (VS 2 ), and with a second purely real-acting branch (R 3 ) from the output of the measuring arrangement (M) to the input of the output amplifier (VS 2 ). 2. Replica according to claim 1, characterized in that the real-acting branch is dimensioned so that the simulated complex impedance (Zin) equal to one is a real multiple of the second complex impedance (Z). 3. Replica according to claim 1, characterized in that the real branch is dimensioned such that despite a Ohmic series share of the complex to be simulated  Impedance (Zin) the second complex impedance (Z) none ohmic series component contains. 4. Replica according to claim 1, characterized in that an inverter (I) is present, which inverts the output voltage of the output amplifier (VS 2 ), that a resistor (RS 2 ) is present, which is the same size as the output resistor (RS 1 ) that this resistance is traversed by the output current of the inverter and that the output current of the inverter as well as the output current of the output amplifier is the current (i) flowing through the simulation. 5. Interface between a bidirectionally operated two-wire line (a, b), in particular a telephone subscriber line, a unidirectionally operated receive line (E) and a unidirectionally operated transmit line (S), with a first branch from the receive line to the two-wire line, with a second branch from the Two-wire line to the transmission line, with a third branch from the receiving line to the transmission line, and with a simulation (N) of a complex impedance terminating the two-wire line, which has a measuring arrangement (M) which matches the output signal (u, i) of the simulation (N) outputs proportional voltage (u 1 ), at which the simulation further comprises an output amplifier (VS 2 ), the output current of which flows through an output resistor (RS 1 , RS 2 ) and the output current (i) of the simulation (N), with a second branch containing complex impedance (Z) from the output of the measuring arrangement (M) to the input of the output amplifier ( VS 2 ), and with a second, purely real-acting branch (R 3 ) from the output of the measuring arrangement (M) to the input of the output amplifier (VS 2 ). 6. Interface according to claim 5, characterized in that the measuring arrangement (M) is designed as a summing amplifier, that the first branch of the interface is coupled to the measuring arrangement in the replica (N) and thus the second complex impedance (Z) and the pure contains real-acting branch (R 3 ) and that a second purely real-acting branch (R 1 ) leads directly from the receiving line (E) to the output amplifier (VS 2 ) and the effect of the (first) purely real-acting branch (R 3 ) overrides the first branch of the interface. 7. Interface according to claim 5, characterized in that an inverter (I) is present which inverts the output voltage of the output amplifier (VS 2 ), that a resistor (RS 2 ) is present, which is the same size as the output resistor (RS 1 ) that this resistance is traversed by the output current of the inverter and that the output current of the inverter as well as the output current of the output amplifier is the current (i) flowing through the simulation.