NL7807961A - IMPEDANCE NETWORK AND MONITORING CHAIN FOR A TELECOMMUNICATION LYUS USING THIS NETWORK. - Google Patents

Description

J. Venken et al 2-1 ^ BELL TELEPHONE MANUFACTURING COMPANY S.A., Antwerp, Belgium IMPEDANCE NETWORK AND MONITORING CHAIN FOR A TELECOMMUNICATION LINE LOOP USING THIS NETWORK.

The invention relates to an impedance network having a source with a DC component and an AC component, a variable resistor, a DC detection circuit to determine changes in the value of this resistor, terminals of all three of which are coupled to different ports of a multi-port network and a filter circuit associated with the equal current detection circuit to substantially prevent the alternating current component from affecting the operation of the direct current detecting circuit having at least one further point on a fixed DC voltage potential.

Such a network is already known from Belgian patent no. 688,760. This known network is a wake-up switch circuit arranged in a telephone exchange and comprises a multi-port network, which contains a bridge chain with a first port, which can be connected via a telephone line to a telephone subscriber station, to a second port, which is connected to a source with a direct current component and an alternating current or wake-up current component and with a third port, the terminals of which are connected to the base and emitter of a normally non-conductive transistor DC detector with a 20 collector or a further terminal at a fixed potential. The base and the emitter of this transistor DC detector are coupled to ground through respective (shunt) capacitors, which together with (series) resistors of the bridge circuit for the alternating current or quenching current component form a filter circuit.

After a call initiated by a subscriber is detected in the telephone exchange and the dialed telephone number of a called subscriber is obtained, the above-mentioned source is connected via the bridge chain to a telephone line leading to the called subscriber station and a call is made therein. alarm device activated by means of the alternating current or alarm current component supplied thereto.

7807961 * 2 r

Then, when the called subscriber records his micro-telephone, a line loop containing the called subscriber station and the telephone line is closed for direct current, so that the resistance connected to the first port of the transistor DC detector is greatly reduced. As a result, the transistor DC detector becomes conductive, indicating that the wake-up can be ended. In principle, the filter circuit operates in such a way that the wake-up current component has no influence on the state of the detector transistor. However, it has been found that due to the tolerances in the values of the capacitors and the resistors, the filtered AC signals applied to the base and emitter electrodes of the transistor DC detector can have such phase shift and amplitude that the transistor can only influence of these alternating current signals can be switched on and off instantly. This is, of course, a drawback, since the operation of the detector circuit should depend only on DC variations at its input port.

The object of the invention is therefore to provide an impedance network of the above type, which does not however have this drawback.

According to the invention, this object is achieved by the fact that the further terminal is coupled to the source in such a way that its potential also has an alternating current component, which influences any alternating current signal on the terminals of an input port of the gate of the multi-port network 25 nulls coupled DC detection circuitry.

In this manner, it is possible to modify the AC component on the further terminal so that the DC detector circuit responds only to DC variations at its input port.

Other features of the impedance network according to the invention are that the DC detector is a differential amplifier, this amplifier includes two tripod amplifier circuits with individual input terminals constituting the input port and with interconnected first and interconnected second output terminals which form the output port. and each of the three pole amplifier circuits includes a transistor, the base of which forms different from the individual input terminals and whose emitter and collector electrodes form the 7807961 3 first and second output terminals.

It should be noted that an impedance network containing a DC current detector with a two transistor differential amplifier is already known from U.S. Pat. Nos. 3,524,816 and 5,748,395.

Still other features of the impedance network of the invention are that the DC detector circuit is coupled to the multi-port network through the filter chain, which is a low-pass filter chain, the higher cutoff frequency band of which contains the frequency of the AC component of the source and that the low-pass filter chain contains a parallel T network, over which a parallel RC chain is connected.

According to a preferred embodiment of the invention, the impedance network comprises a bridge chain with two opposite first branches, each containing a potentiometer chain and with two opposite second branches, each containing a resistor, the bridge chain having a first gate, which is formed by a pair of first bridge terminals and which can be coupled via a telephone line to a telephone station, while this bridge chain has a second gate 20, which is formed by a pair of second bridge terminals and which is coupled to the non-interconnected first poles of a direct current source, which series is connected to a wake-up current source and that the bridge circuit has a third gate, which is formed by tap points of the potentiometer chains and is coupled via a parallel T-25 filter network over the output of which a parallel RC circuit is connected, to the bases of two PNP transistors connected according to the configuration of a differential amplifier, wherein the common emitters and the common collectors of these transistors are connected to the node of a first pair and a second pair of diodes, the cathodes and the anodes of which are respectively connected to each other. The anodes of the diodes of the first pair are connected to the first poles of the DC and AC sources respectively, while the cathodes of the diodes of the second pair are connected to the second pole of the DC source and to the tap point of potentiometer which bridges the wake-up power source.

By a suitable choice of components, the thus 7807961 are 4.

pre-voltage signals applied to the emitters and collectors of both transistors such that the state of these transistors is not affected by the wake-up current signals applied to their bases.

The invention also relates to a monitoring circuit 5 for a telecommunication loop. This circuit is characterized in that it contains an impedance network as described above and that the variable resistor is formed by a telecommunication line which couples the multi-port network to a subscriber station, the above AC component being generated by a wake-up power source.

The invention will now be further elucidated for an embodiment on the basis of the drawing. In the drawing: Fig. 1 shows an impedance network according to the invention, and Fig. 2 signal waveforms which occur at the terminals A, B, F and G of Fig. 1.

This impedance network includes a multi-port network, either a bridge circuit BC, a filter circuit FC, a DC detector circuit DC, and a level lock circuit CC.

The bridge circuit BC has two opposite first branches, which respectively contain a potentiometer T1, T2 with the resistors R1, R2 and R3, R4 and two opposite second branches each. contain a so-called supply resistance R. The bridge circuit BC further has a first gate PQ formed by two first bridge terminals P and Q, a second gate SU formed by two second bridge terminals S and ü and a third gate MN formed by the tap points M and N of the potentiometers 25 T1, T2 respectively. .

The terminals Q and P of the first port PQ can be connected to a telephone station TS via switching means SMI, SM2 and a telephone line with a pair of wires L1, L2. This telephone station TS contains, in addition to other circuits (not shown), a parallel circuit with a first 30 branch, which contains a series-connected capacitor CS and an alarm clock RI and a second branch with a series-connected hook contact HS for a micro telephone (not shown) and a resistor RS.

The terminal S of the second gate SU is connected to the grounded positive pole of DC source E, the negative pole of which is connected to a pole of a wake-up signal source RSS, so that both these sources are connected in series and in fact a single source with 7807961 5 Η provide a DC component E and an AC component RSS and provide a DC voltage E and an effective wake-up signal V, respectively (Fig. 2). The terminal U of the second gate is connected to the pole of the wake-up signal source RSS which is not connected to the negative pole of the DC source E.

The terminals M and N of the third gate MN are connected on the one hand to the terminals E and D of the filter chain FC and on the other hand via the resistors R5 and R6 to the positive and negative pole of the direct current source E.

As stated in the above-mentioned Belgian patent, the special advantage of this bridge chain is that it compensates for longitudinal stresses induced in the telephone line L1, L2.

The filter circuit FC has the input terminals D and Ef which are respectively connected to the output terminals N and M of the gate MN of the bridge circuit and the output terminals F and G which are connected to the DC detector circuit DC. This filter circuit FC contains a known parallel T-network, which contains the resistors R7, R8, R9 and the capacitors C1, C2, C3 and also an RC network, which is depicted over the output of the parallel T-network and a resistor R10 contains 20 which is connected in parallel with the capacitor C4.

The values of the components are chosen such that R7 = R8; C1 = C2 and R7.C3 = 4R9.C1 = 2T, so that the transfer function of the filter chain FC can be written as: VVG 1 + pS2 Rl ° VVM, A T0 2 2 ®7 + R8 + R10 1 + p + ρτο

O

. . 2 + 2 <V.

25 where TQ = -

Tj2 = T.Oj.Ej l / (R3 + 2R1). {Cj + 2C3) T.R ^ Q _ * 2T (R1 + R3) + 2R1R3 (Cj + C3) ^ 3 * ^ 7 T = 2crRg = - p * j U2 f where Ca? the angular frequency is.

7807961 6

Due to the presence of the parallel chain R10,

C1, the filter circuit FC is a low-pass filter, which attenuates the attenuation current signal containing a frequency f and relatively high amplitude peak values, as well as interference signals of higher frequencies, the highest attenuation being produced at a frequency f ^ = -.

Since the value of this frequency fl is. can change with changes of the values due to the tolerance of the different components, the frequency fl is chosen such that under all circumstances it remains close to the frequency f of the wake-up current signal. This ensures that the latter signal is attenuated almost completely, independent of the changes in the values of the components due to tolerances. This means that the AC voltage waveform at the output terminal F has substantially the same amplitude and phase as the AC voltage waveform at the output terminal G.

Due to the presence of the parallel circuit R10, C4, the filter circuit FC processes a phase inversion which does not occur at the frequency f1, as was normally the case with a parallel T network, but at the frequency f0 =. Again because the value of this frequency f0 can change with the variations of the values of the components due to the tolerance, the frequency f0 is calculated such that under all circumstances it remains considerably smaller than the frequency f of the wake-up current signal. Thus, it is ensured that the phase-reversal does not occur at the wake-up current frequency or at higher frequencies.

From the above it follows that the higher reverse frequency band of the low-pass filter chain FC contains the frequency f of the wake-up signal and is different from the frequency f0 at which the filter chain processes a 180 ° phase rotation between the signal V V-V „. that input D, E is applied to N rl and the signal V_ - V_ appearing at its output FG.

F G

The DC detector circuit TC is formed by a differential amplifier having two PNP transistors TR1 and TR2, the bases of which are connected to corresponding output terminals F and G of the filter circuit. The emitters of these transistors TRI and TR2 are connected to the 7807961 7 ν '-Λ output terminal A of the level locking circuit CC through a relatively large common resistor Ril and the output terminal H, while the collectors of these transistors connect through the output terminal J and through the resistor R12 and this output terminal J are connected to the output terminal B of this level lock circuit CC. The collector of the transistor TR2 is the output terminal 0 of the circuit. A differential amplifier is used because it has a high input impedance, so that the base current of neither transistor TRI, or TR2 adversely affects the bridge circuit BC or the filter circuit FC 10 to any degree. On the other hand, this base current is almost constant, since one of the two transistors TRI or TR2 is always conductive.

The purpose of the detector circuit DC is to detect a DC voltage inversion between the output terminals M and N of the bridge-15 circuit BC as soon as a called subscriber picks up his micro telephone, thereby closing the hook contact HS, that is, as soon as the one connected to the gate QP connected resistance of the chain is changed.

The level locking circuit CC includes two pairs of diodes D1, D2 and D3, D4. The interconnected cathodes of the diodes D1, D2 are connected to the output terminal A of the level locking circuit CC, while their anodes are respectively connected to ground and to the pole of the wake-up signal source RSS, which is not connected to the equal current source. The DC voltage on the anode vein the diode D2 is equal to Ξ Volt, while the effective AC voltage at this point is equal to 25 V Volt so that the latched voltage VA (Fig. 2) available at the output terminal A is supplied to the emitters of the transistors TR1, TR2 are formed by positive going half-wave sections, which change between a minimum of 0 volts and a maximum E + V V2 Volts (fig. 2). The interconnected anodes of the diodes D3, D4 are connected to the output terminal B of the level locking circuit CC, while their cathodes are respectively connected to the negative pole of the DC voltage source E and to a tap point W of the series connected resistors R13 and R14- These resistors R13, R14 are connected to the wake-up brine RSS and have equal value. The DC voltage at their node W equals 0 Volts, while the effective AC voltage at this point equals 7807961

F

8 ττ Volt, so that supplied to the output terminal B and to the collectors

level locking voltage VB supplied to the transistors TR1, TR2

is formed by negative-going half-wave portions, which are located

V

change between a maximum of E Volt and a minimum of E - (fig. 2). 5 From the above it follows that as shown in fig. 2:

- during the positive going half waves of the wake-up current signal V.

the voltage VB at the collectors of the transistors TRI, TR2 is equal to E Volt, while it follows that negative going half

V

10 waves change between E Volts and E - Volts during the negative going half waves of this wake-up signal V; and - during the upper parts of the positive going half waves of the wake-up current signal, the voltage VA on the emitters of the transistors TR1 and TR2 follows these parts, while during the remaining 15 parts of these positive going half waves and during the negative going half waves waves of the wake-up signal V these emitters are at potential 0 Volt.

Preferred values of the components of the above chain are as follows: 20 R = 0.2 kObm;

R1 = 27 kOhm; R2 = R3 = R4 = 30 kOhm; R5 = R6 = 300 kOhm; R7 = R8 = 16.2 kOhm; R9 = 8.9 kOhm; R10, R11 - 100 kOhm; R12, R13 - R14 = 10 kOhm;

Cl = C2 = 0.68 micro-Farad; C3 = 1.5 micro-Farad; C4 = 1 micro-Farad; f = 16 Hz; V = 90 volts; E = -48 Volts.

The operation of the above-described chain is as follows: In the quiescent state of the chain, that is, when the hook contact HS in the subscriber station TS is open, the difference between the DC voltage is 7807961 9; At the output terminals F and G of the filter chain different from O and equal to a predetermined bias value. With the above given values of the components, this bias value is such that the DC voltage signal at the terminal F connected to the base of the transistor TR1 is smaller than that at the terminal G connected to the base of the transistor TR2. The wake-up signal source RSS becomes supposed to be in the working state and therefore supplies the wake-up signal C with a frequency f and effective voltage value V between the terminals S and ü of the bridge chain BC in series with the DC-10 voltage E. This wake-up current signal V also appears attenuated at the output port MN of the bridge and is supplied from this gate via the filter chain FC to the bases G and F of the detector transistors TR1, TR2. Due to the fact that the total voltage v at the terminal F is less than the total voltage V_ at the terminal G, and the emitters 15 and collectors of these transistors TR1, TR2 change between 0 and Ξ + V V2 Volt and between E and E - ^ Volt, the transistor TRI becomes conductive, while the transistor TR2 is turned off, so that the output 0 of the circuit is deactivated.

Although in Fig. 2 both signals V_ and V_ are both equal

E G

Ξ Q

2 "+ - are indicated, when the impedance connected to the gate QP is infinite, they differ slightly, which difference is sufficient to make the transistor TR1 conductive and keep the transistor TR2 in the blocked state.

It should be noted that a filter circuit such as FC which provides a high attenuation of the ringing current signal and of higher frequency signals is used, since the ringing current signal has a relatively high amplitude and interference signals of such higher frequencies can be applied thereto.

When a call initiated by a subscriber is detected in the telephone exchange and the dialed telephone number of a called subscriber station such as TS is obtained and this station is found, the switching means SM1 and SM2 are actuated in order to bridge the bridge port QP via the telephone line L1. , L2 to this subscriber station TS. As a result, the transistors TR1, TR2 remain in the conductive and non-conductive states, respectively.

The latter states of the transistors TR1, TR2 78 0 7 9 6 f

F

10 are not affected by the AC voltage signals V and V applied to their bases, respectively.

F G

Namely, the following is the case (fig. 2): - during the positive going half-waves of the voltage signal 5 V, which is applied to the base of the conductive PNP transistor TRI and which tries to block this transistor, the collector thereof is on E Volt while its emitter is either 0 Volt or varies along with this base voltage. The emitter voltage V, however, always remains greater than the latter base voltage νρ, so that TRI remains leading; - during the negative going half waves of the voltage signal

V_ which becomes G at the base of the uncalled PNO transistor TR2

and which tries to make this transistor conductive, its emitter is at 0 Volts while its collector varies along with this base voltage but remains smaller than the latter so that TR2 remains nonconductive.

It is noted that the AC voltage signal on the collectors is reduced by using the resistors R13, R14, so that the transistors TR1, TR2 are not exposed to an excessively high emitter-20 collector voltage.

Since the influence of the AC signals on the bases of transistors TR1 and TR2 is eliminated by appropriate compensation of the AC signals applied to their emitters and collectors as shown in Figure 2, it is clear that it is necessary that no phase reversal occurs in the wake-up signal f. applied to the bases of these transistors. This is the reason why the frequency f of the wake-up current signal is well above the above-mentioned frequency fg, producing such phase inversion in the filter circuit FC.

When the called subscriber receives his micro-telephone upon receipt of the wake-up signal, the DC line is closed, because the hook contact HS is then closed. As a result of this and due to the fact that the impedance of the line loop then decreases below a predetermined value, the voltage V falls below

G

35 the voltage V with such a value that the transistor TRI is blocked

F

is turned.

7807961

Claims (18)

1. Impedance network with a source having a DC component and an AC component, a variable resistor, a DC detection circuit to detect changes in the value of this resistor, with terminals of all three means coupled to different ports of a network with multiple gates and a filter circuit associated with the DC sensing circuit to substantially prevent the AC component from affecting the operation of the DC sensing circuit having at least one further terminal to a fixed DC potential, characterized in that the further k (H , J) is coupled to the source (E, RSS) in such a way that its potential also has an alternating current component, which has the influence of an alternating current signal 25 on the terminals (F, G) of an input port (FG) of the port of the network with multiple ports coupled direct current detection. nullifies the chain (DC). Impedance network according to claim 1, characterized in that the AC voltage component is derived from the AC voltage component (RSS) of the source (E, RSS). Impedance network according to claim 2, characterized in that the alternating voltage component is derived from the alternating current component (RSS) of the source (E / RSS) by level-locking a signal (V, -) proportional to the alternating voltage ^ -35 component (V) at a value (O, E) that is derived from the DC voltage component 7807961 (E). Impedance network according to claim 1, characterized in that the DC voltage detection circuit (DC) is a difference amplifier (TRI, TR2). Impedance network according to claim 1, characterized in that the DC detection circuit (DC) has the input port (FG) and an output port (HJ), which contains two (H, J) of the further terminals to which the AC voltage component is applied. Although not absolutely necessary, diodes can be inserted between the resistor R11 and the emitters of the transistors TRI and TR2 in order to protect these transistors when, for example, the level lock circuit CC fails. The invention has been described for embodiments which are only exemplary and do not limit the scope of the inventive idea. Impedance network according to claims 4 and 5, characterized in that the differential amplifier (TRI, TR2) comprises two three pole amplifier circuits (TRI, TR2) with individual input terminals (FG), which form the input port (FG) and with interconnected first (H) and interconnected second (J) output terminals 15 which form the output port (HJ). Impedance network according to claim 6, characterized in that each of the three pole amplifier circuits comprises a transistor (TRI, TR2), the base of which forms a different one of the individual input terminals (F, G) and whose emitter and collector electrodes are the first (H) and second (J) output terminals. Impedance network according to claim 1, characterized in that the DC detection circuit (DC) is coupled to the multi-port network (BC) via the filter chain, which is a low-pass filter chain (FC) whose higher blocking frequency band is the frequency (f) of the AC voltage component (RSS) of the source. Impedance network according to claim 8, characterized in that the low-pass filter chain (FC) is a reverse filter with an attenuation above a certain minimum at an infinitely high frequency. Impedance network according to claim 8, characterized in that the low-pass filter chain (FC) contains only resistors and capacitors. Impedance network according to claim 8, characterized in that the low-pass filter chain (FC) consists of a parallel T-network (R7-R9, C1-C3J, via the output of which a 78 0 7 9 6 1 * / * parallel RC chain (R10, C4) is connected. Impedance network according to claim 11, characterized in that the frequency of the AC voltage component is different from the frequency (f0) at which the filter circuit (PC) processes a 180 ° phase inversion between the signal (V applied to its input port (DE) ^ -V ^ and the signal that appears at its output port (FG). Impedance network according to claim 1, characterized in that the multi-port network is a bridge circuit (BC) with two opposing first branches, each containing a resistance potentiometer (T1, T2) and with two opposing second branches, each include a resistor (R), the bridge circuit (BC) having a first gate (PG), which is formed by a pair of first bridge terminals (P, Q) and is coupled to the variable-resistor (L1, L2, TS ), has a second gate (SU) which is formed by a pair of second bridge terminals (S, U) and which is coupled to the source (E, RSS) and has a third gate (MN), which is formed by tap points (Μ , N) of the potentioraeter circuits and which is coupled to the DC detection circuit (DC). Impedance network according to claim 13, characterized in that the source (E, RSS) comprises a direct current source (E) and an alternating current source (RSS), one pole of which is connected in series and the other poles are connected to the second port (SU). Impedance network according to claims 7 and 14, characterized in that the bases (F, G) of the transistors (TRI, TR2) are coupled to one and the other poles of the DC source via further resistors (R6, R7) significantly larger than those that make up the bridge chain. Impedance network according to claims 8 and 14, characterized in that the first (H) and second (J) output terminals of the tri-pole amplifier circuits (TRI, TR2) are respectively coupled to the node of the first electrodes of the diodes of a first (D1, D2) and a second (D3, D4) pair of diodes, the second electrodes of one (D1, D3) of the diodes of the first (D1, D2) and second pair (D3, D4) pair being connected to one and the other poles of the DC source and that the second electrodes of the other 7807961 (D2, D4) of the diodes of the first (D1, D2) and second (D3, D4) pair are coupled to the other poles of the AC source (RSS). Impedance network according to claim 16, characterized in that the second electrodes of the other 5 (D2, D4) of the diodes of the first (D1, D2) and second (D3, D4) pair respectively are directly coupled to the other pole of the alternating current source (RSS) and through one (R14) of the resistors (R13, R14) of a potentiometer (R13, R14) bridging the alternating current source (RSS). 18. Telecommunication line loop supervision circuit, characterized in that it comprises an impedance network according to one or more of claims 1-17 and in that the variable resistance is formed by a telecommunication line (L1, L2), which couples the multi-port network (BC) with a subscriber station (TS), wherein the above AC power component is generated by a wake-up power source 15 (R55). 7807961