HU183080B - Circuit arrangement to terminal equipment of a two-wire communication circuit for separating signals of transmitting and receiving path - Google Patents

Abstract

the circuit arrangement according to the invention provides, on the one hand, the non-reflective closure of the line by coupling a line section and a line imitation, then forming an output signal and an input signal of one of the amplifiers connected to the center of the line section and another amplifier connected at its two ends. The closing attenuation between the transmitter and receiver terminals ensures that both ends of the two-wire line have no reflection, so that regardless of the length of the line, only the symmetry defects of the line section can cause a fault signal in both terminals. In the invention, the line section and the line imitation are a distributed RC parameter. -1-

Description

(57) EXTRACT

The function indicated in the title is provided by the switching arrangement according to the invention, by providing, on the one hand, the non-reflective closure of the line by connecting a line section and a line imitation, then forming an output signal and a signal signal of the signal signal to the center of the line section and an amplifier connected to its two ends . The closing attenuation between the transmitter and receiver terminals ensures that both ends of the two-wire line have no reflection, so that regardless of the length of the line, only terminal symmetry errors in both terminals can cause a fault signal. In the invention, the line section and the line imitation are a distributed RC parameter.

-1183 080

It is known that the terminals of the two-wire wired communications circuit separate the path of the transmit and receive signals. Such circuitry is e.g. in the telephone, where the task is to direct the transmitter signal from the microphone to the two-wire line, the signal from the two-wire line to the listener, and to prevent the microphone signal from reaching the listener. For a similar purpose, the circuit is used in a two-wire bi-directional amplifier or where the two-wire circuit is to be connected to a four-wire circuit (eg carrier waveguide).

These transmit-to-receive signal separation circuits are generally balanced bridge connections, in which one bridge is impedance of the two-wire line, the other is a two-pole, so-called line imitation with a prescribed impedance. The other two branches of the bridge are optional impedance (eg ohmic, inductive, transformer, etc.). The diagonals of this hybrid switch form one-way signal terminals, the two-wire line is bidirectional messaging.

The characteristics of these circuits are optimal when their transmission attenuation from the two-wire bundle pair to the one-way receiver signal pair and the one-way transmitter pair to the two-wire bar pair is small and the one-way transmitter pair to the one-way receiver pair. In the art, low-damped paths are transmitted or receiving-permeability damping, the high-damped path is called damping.

Another important feature of these circuits is their impedance, which is connected to the two-wire terminal pair, which terminates the two-wire line.

For the above-mentioned known circuits, except for the so-called "T fork" circuit (155500 Hungarian, which is described later), their common disadvantage is that their two-wire input impedance is not the same as the wave impedance of the line connected to them. This fundamental error is due to the difficulties that accompany the operation of two-wire circuits. Such is e.g. the problem of the stability of the two-wire amplified transmission system, the annoyance of the phone, the reflection distortion, the sound of the phones, etc.

To illuminate the problem, consider the operation of a two-wire circuit, which consists of a unloaded local cable section and a terminal terminating its two ends, e.g. consists of a telephone. In this system, we examine the circuit of one of the terminals used to separate the transmit and receive signals. The closure of this circuit primarily occurs between the pair of transmitter signal terminals and the receiver pair. The closing attenuation will be large enough if the alignment of the above-described bridge circuit is sufficiently accurate. The fault signal of the bridge circuit is the undesirable signal that comes from the tax base to the customer base. The bridge circuit must therefore be as balanced as possible on all frequencies of the available transmission frequency band.

In the exemplary circuit, the tested terminal equipment e.g. The damping of the telephone set depends not only on the structure of this device, but also on the length of the two-wire line and the closing impedance of the far end, as they form a branch of said bridge.

This line length and span closure dependence is due to the fact that the impedance of the presently known end-to-end devices, as mentioned above, is not the same as the wave impedance of the cable and thus the reflection on the far end. Once the exemplary two-wire circuit is symmetrical, the bridge's unbalance is present at both terminals.

In the known circuits, this problem leads to the fact that in practice, instead of the desired 3.5 to 4 N closing attenuation, only 1-1.2 N can be achieved, even at some frequency of the transmission band.

The aforementioned "T-fork" is much more favorable than the general known circuits because the wire is shrunk down by a wave impedance as described in said patent and thus significantly reduces the reflections. However, in order to reduce the reflection, there is a high attenuation in the direction of the receiving signal, approx. Introduces 3 Nt. It follows from its principle that the better the reduction of reflection in the dimensioning, the greater the attenuation in the direction of the receiving signal.

As described above, the two-wire circuits whose terminal equipment could be provided at the same time with a low value of approx. 0.35 N permeation attenuations and a high capping attenuation of greater than 3.5 N. Particularly, the small 1 to 1.2 N value of the closing attenuation causes problems in practice. That's why the stability problems of two-wire amplified systems, the sound of the telephone handsets, the geo-functionality of the handsets, the reflection distortions, etc.

The present invention relates to a switching arrangement for terminating two-wire circuits, for separating the transmit and receive signals, which, when used at both ends of the two-wire circuit, simultaneously provides for line impedance sealing, optimum throughput and closing damping. Also, the size of the closure does not depend on the length of the line.

An exemplary embodiment of the circuit arrangement according to the invention is shown in Figure 1. In Fig. 1, between the terminals 1,2 and 3, there is the line 5 which is assembled from a series of R and C elements. The wave impedance of the line 5 is identical to the wavelength impedance of the two-wire line connected to terminals 1 and 2, also in the total receive frequency band, for absolute value and phase angle. The line imitation 8 is connected to terminals 3 and 4 of the line 5, which has an input impedance equal to the input impedance of a virtually endless section of the two-wire line connected to terminals 1 and 2.

If the two-wire line is terminated at both ends with the coil 5 and the associated line replica 8, the connection will be non-reflective. This is evidenced by the fact that the two-wire line section is cut anywhere, the impedance to the right and left of the incision is equal, so it can be reconnected without reflection. This reflection immunity extends to the entire reception frequency band.

1, a receiver 9 and a transmitter 12 are then connected to the line 5. The impedances of the amplifiers 9, 12 connected to the line 5 are so large - preferably 50 to 100 kOhm - that their shun effect is negligible. The freestanding terminals of the amplifiers 9, 12, the terminals 10-11 and the terminals 13-14 form the unidirectional reception or transmitter terminals.

The switching arrangement works as follows:

When the two-wire reception signal arrives, the signal passing through line 5 through line 5 produces a voltage difference between terminals 1 and 3 of the line 5, depending on the attenuation of the line 5. This voltage controls

183 080 shows the amplifier 9 and its output terminals 10-11 as a receive signal. The magnitude of the signal controlling the amplifier 9 depends on the damping of the line 5 and can be scaled appropriately.

The transmitter signal is connected from amplifier 12 to terminal 6-7 of the line 5. The transmitter signal arrives at the two ends of the line 5 with the same attenuation and phase rotation, so that no voltage is created between the terminals 1 and 3, the transmitter signal does not control the receiver 9. In this way, the transmitter signal is not transmitted from terminals 13 to 14 to terminals 10 to 11, and the closing attenuation of the switching arrangement - | θ is high.

It is understood that the closure attenuation of the terminal devices in the two-wire connection closed by the two above-mentioned structural units is not dependent on the length of the line section.

The practical embodiment of the two-wire circuit terminal according to the invention may be made in several versions.

The design of the line 5 and the line imitation 8 may differ

Figure 1 is a schematic representation of the principle circuit for understanding.

In order for the wave impedance of the line 5 and the line 20 to be truly accurate, the impedance of the two-wire line connected to the terminals 1 and 2 may also be an integral, distributed RC parameter structure. Such a structure is disclosed in U.S. Pat. Hungarian patent. 25

The conceptual drawing of the line + line imitation made on the basis of the above patent is shown in Figure 2, with the numbering according to Figure 1.

Fig. 2 shows a section of the line RC line of Fig. 2 with a split RC parameter between terminals 1-7-3, and in Fig. 1 the line 5 between the line 3-15 and the line replication 8 in Fig. 1. Figure 3 shows an example of a distributed RC parameter line + line imitation unit! Figure 1 shows a structural arrangement, also numbered according to Figure 1. 35

Fig. 4 shows a variant of a line of work for compensating for defects in manufacturing scattering. This variant connects the work line from a half piece A and B with an intermediate potentiometer 16 to compensate for the difference in dipping between the two A and B half pieces.

If this is done, the resistance of the potentiometer 16 should be as low as possible, which is still sufficient to compensate for the production standard deviation.

In this variant, the center line of the line is the slider contact of the potentiometer.

Claims (2)

Patent claims 1. A circuit arrangement for terminating a dual-wire communication circuit for separating transmit and receive signals from a line, imitation, transmitter, and receiver type amplifier, characterized by: a line imitation (8) having the same input impedance is connected thereto, and then connected to the line terminating part (5) and (8) thus formed, the transmitter and receiver amplifier (9, 12) having a middle lead at and one of the amplifiers (12) and the other amplifier (9) being connected to two points of the line (5) which are at the same attenuation distance from the center terminal. An embodiment of a circuit arrangement according to claim 1, characterized in that the line (5) is connected by two half-pieces (A, B) and a potentiometer (16) connected between them, which is connected to a central terminal of a potentiometer (16). 12). 4 pieces of figure