NO148239B - TELEPHONE SUBSCRIPTION BRANCH FOR CONNECTING TO A COVERED CABLE - Google Patents

Description

The invention relates to a telephone subscriber branch of

the type specified in the introduction to patent claim 1.

Such subscriber branches, known in the telephone remote dialing service, serve to keep the debiting pulses that occur over the central line during the call, away from the voice device and supply the pulses to a debiting pulse receiver connection over which a fee counter installed at the subscriber is affected. The blocking filter must here be of such a nature that the transmission of the speech frequencies in the so-called telephony band, which extends from approx. 300 to approx. 3,400 Hz, is not noticeably disturbed.

Blocking filters that are dimensioned for the two currently mainly used debiting transmission systems, namely the so-called high-frequency counting and the 50-Hz counting, do not pose any major problem as these debiting pulse frequencies are sufficiently far from the lower or upper limit.

However, both known counter systems have disadvantages. The high-frequency charging pulses, whose frequency in Switzerland is 12 kHz and in West Germany is 16 kHz, are exposed in ordinary telephone lines to a relatively strong attenuation which, in the nature of the matter, is all the more effective the greater the distance between the switchboard and the subscriber.

As is known, coiled or pupinized wires significantly reduce attenuation in the telephony band, but not at 12 or 16 kHz. Instead, the frequency range is over the telephone band, i.e. over approx. 4000 Hz, particularly strongly attenuated. Professionals in the field have therefore been looking for another suitable debit pulse frequency for some time. The 50-Hz counter system, on the other hand, has the disadvantage that it includes the earth as a transmission conductor and will therefore be less and less used in the future.

A debit pulse frequency of 4 kHz has therefore already been proposed, which admittedly has the advantage that it is not subject to any strong attenuation on coil-provided lines,

but which, however, creates significant problems with regard to the design and dimensioning of a suitable blocking filter. Such a blocking filter must, on the one hand, block the debiting pulse frequency as completely as possible, and on the other hand also ensure a perfect and frequency-independent transmission of the speech frequencies in the telephony band in both directions. Then fri-

the 4 kHz frequency to be blocked is very close to the upper end of the telephony band, previously this requirement could not be satisfactorily met economically.

In DE patent document no. 970 657, in the description of a coupling device for telephone extension systems, a blocking filter is mentioned which is arranged in the central line in front of the extension transmission unit and is designed for blocking debit pulse frequencies that lie in the upper third of the tone frequency band. However, the structure of this blocking filter, which is only indicated by means of an empty square, is not described. In the connection lines that connect the secondary device communication unit with each of the secondary devices, a respective locking link is also connected which keeps the tone frequency pulses, which are produced in a special generator when a debit pulse occurs, away from the respective secondary device. These locking links, which are also not described in more detail, but are only shown in the drawing, consist of simple, well-known parallel swing circuits. However, it has been shown that none of the conventionally constructed, simple filters, just like known, symmetrical chain circuits with real terminations, are suitable for passing through the speech frequencies in the majority of the speech frequency range odo to. an upper limit of

about. 4 kHz in a perfectly good way, i.e. practically undamped, and then, however, at approx. 4 kHz exhibit a steeply rising attenuation with an attenuation maximum. Both of the aforementioned requirements cannot therefore be fulfilled satisfactorily with the known blocking filters.

The purpose of the invention is to provide a blocking filter with the simplest possible structure which is suitable for blocking debit pulse frequencies near the upper voice band limit at approx. 4 kHz, and which keeps the debiting pulses away from the speech device and conversely keeps any noise signals produced in this away from the debiting pulse-receiver connection, and where the blocking filter enables an at least approximately frequency-independent transmission of the speech frequencies in both directions, and should also constitute is; good impedance converter which is matched to an average cable impedance for a normal, i.e. not coiled, telephone line.

The above-mentioned purpose is achieved according to the invention by means of the characterizing features stated in patent claim 1.

It has surprisingly turned out that one can dimension a relatively simply built cut-off filter with a symmetrical appearance with respect to its structure with a complex termination of the specified type located on the voice device side in such a way that it exhibits a wide passband, practically corresponding to the telephone band and one with this immediately connected, maximum attenuation for the debit pulses. In order to achieve an optimal wave transmission, such a blocking filter can simultaneously be given the properties of an optimal impedance converter in such a way that ordinary voice devices adapted to normal telephone lines can also be connected to coil-provided lines by front-connecting a subscriber branch according to the invention without disadvantages. In particular, it has been shown that a blocking filter according to the invention also produces good side tone or crosstalk attenuation.

Expedient embodiments of the telephone subscriber branch according to the invention are indicated in patent claims 2-5, while patent claims 6 and 7 indicate a preferred embodiment of the invention which enables the use of commercially available fee telephones or devices for call data registration which are arranged for receiving 12- or 16-kHz debit pulses and as a four-pole is intended for connection to the two voice wires. Such fee carriers or devices can then be simply connected between the subscriber branch according to the invention and the voice device in the usual way.

The invention shall be described in more detail below

in connection with design examples with reference to the drawings, where fig. 1 shows a block core of a central line with a central branch and a subscriber location which is provided with a subscriber branch and a fee counter, fig. 2 shows an equivalent diagram of the blocking filter termination in the case that the exchange transmits, fig. 3 shows an equivalent core of the blocking filter termination in the case that the speech device transmits, fig. 4 shows a typical attenuation curve that can be obtained with a blocking filter in a subscriber branch according to the invention, and which indicates the attenuation A as a function of the frequency (in Hz) when voltage is transferred from the subscriber to the exchange (according to fig. 3), fig. 5 and 6 show first and second examples of a blocking filter in its earth-unsymmetrical version, fig. 7 and 8 show the ground-symmetric versions of the blocking filters according to fig. 5 and 6, and fig. 9 shows a block diagram of a central line with a central branch and a subscriber location which is

provided with a subscriber branch, a frequency converter and a between the subscriber branch and the voice device to the voice wires connected

device for fee and possibly call data registration.

Fig. 1 shows a central line with the two speech wires

a and b between an exchange 1 in which a debit pulse transmitter 3 and a central branch 4 are installed, and a subscriber location with a voice device 2, a subscriber branch which exhibits a blocking filter 5 and a debit pulse receiver connection 6, and a debit pulse amplifier 7 and a fee counter 8 The central branch 4 prevents a transmission of the debiting pulses which are generated during a call from the debiting pulse generator 3 to the other central connection. The subscriber branch blocking filter 5 keeps the debiting pulses occurring over the voice wires a, b, which via the debiting pulse receiver connection 6 are fed to the amplifier 7 for influencing the fee counter 8, away from the speech device 2, and prevents noise signals with debiting pulse frequencies produced in the telephone set from arriving at the receiving connection 6 and thus possibly affecting the fee counter 8.

The blocking filter 5 is designed to block debit pulses with a frequency of approx. 4 kHz, and for terminations which according to fig. 2 and 3 are complex on the speech device side and ■ real on the exchange side. It has been shown that a complex termination in the form of a parallel connection of a resistor R2 of approx. 86 0 and a capacitor C2 of approx. 40 nF corresponds well to the input impedance that telephone cable lines have on average, and that a real termination using a resistor RI of approx. 1100 Q on the switchboard side is very well adapted to the impedance of a coil-provided line and the switchboard. When the exchange transmits, and a voltage transfer takes place from there to the subscriber's site, the source voltage UQ is active in the exchange and the voltage is active on the blocking filter's 5 output at the subscriber's site (fig. 2). When the speech device transmits, and thus a voltage transfer takes place from there to the switchboard, the speech device acts as a voltage source with the voltage UQ, whereby the parallel connection of R2 and C2 is in series with this voltage source (fig. 3), and the voltage U_ is present at the blocking filter's 5 output on the central side.

For sketching a blocking filter 5 with such terminations and with the characteristic that they tr. fully transmits the speech frequencies in the telephony band practically frequency-independently in both directions, the known technique hardly gives any impulses, as up to now mainly only the synthesis of filters for real terminations is known. It was therefore to be expected that a filter with different terminations, one of which is complex, would lead to a rather complicated connection.

However, it has surprisingly been shown that relatively simply constructed reactance filters which have the structure of an impedance symmetrical filter, fulfill the aforementioned requirements in an excellent manner. Fig. 5 shows a first design example of such a reactance filter 5 in its earth-unsymmetrical form. The following statements are limited to this form, as it is simpler than the earth-symmetric version with equal longitudinal voltages used in practice. The conversion to this earth-symmetric version, which is shown in fig. 7, any professional will be able to perform.

According to fig. 5 has the blocking filter 5 one in a speech wire

a located series connection of two parallel-oscillating circuits L3, C3 and other L4, C4 as well as a coil L5 on the central side, and further capacitors C6, C7 and C8 which connect the two speech wires a and b with each other between the two parallel-oscillating circuits and on both sides of the coil L5. A preferred dimensioning of the filter elements is the following: L3 = 14.5 mH L5 = 64.3 mH

C3 = 109.5 nF C6 = 51 nF

L4 = 43.6mH C7 = 41nF

C4 = 36.3 nF C8 = 17 nF

These values can of course vary by a few percent.

In the case of a voltage transfer from the subscriber to the exchange according to fig. 3 such a blocking filter 5 achieves attenuation

(since RI = 1100!,,; and R2 = 860 ^ in the considered example), and this damping is in fig. 4 shown as a function of the frequency in Hz. According to this curve, the attenuation within the telephony band is between

0 and approx. 3600 Hz very small, and rises strongly immediately above the telephony band, since at approx. At 4000 Hz, two narrow, adjacent damping peaks appear, as the blocking filter 5 exhibits two parallel oscillation circuits.

The corresponding curve for the attenuation during a voltage transfer from the exchange to the subscriber has in principle the same shape, but a frequency-dependent additional attenuation is superimposed on this in a known manner.

c

The blocking filter 5 described is not only a frequency filter that meets the desired requirements, but also constitutes a practically optimal impedance converter in the sense that a good match to the average cable impedance is achieved for a normal, i.e. non-coiled line . This means that the usual speech interferences determined for normal telephone lines at the subscriber location can in principle be used without further ado also for coil-provided lines that are equipped with a subscriber branch according to the invention, without any disturbances occurring with respect to the signal transmission or the crosstalk attenuation.

In fig. 6 shows a second embodiment of a cut-off filter 5' in which the starting point is a basic structure in which two series-connected parallel oscillating circuits are arranged on the filter side adjacent to the switchboard, and a single coil is arranged on the voice device side. By means of fig. 6 shall again be the ground-unsymmetrical form, whose ground-symmetrical version is shown in fig. 8, is discussed below.

When calculating such a filter which must meet the specified requirements, it turns out, however, that the last capacity located on the central side between the two voice wires a, b becomes negative, and therefore must be replaced by an equivalent coupling known in and of itself. This consists, according to fig. 6 of a parallel oscillating circuit L15, C15 located in one voice wire a whose coil L15

on the side facing away from the central side, by means of a series connection of a coil L18 and a capacitor C18, i.e. a series swing circuit, is connected to the other voice wire b. The coils Li5 and L18 are connected and in practice can consist of a single coil which has a to the speech thread a or to the capacitor C15 leading outlet.

In series with the parallel-oscillating circuit L15, C15, a further parallel-oscillating circuit L14, C14 and a coil L13 are located on the speech device side. On both sides of this coil L13, also in this case the speech wires a, b are connected to each other via capacitors C16

and C17. A preferred dimensioning of the filter elements in the filter 5' according to fig. 6 is the following: L13 = 70.5 mH C16 = 39.4 nF

L14 = 45.3 mH C17 = 47.4 nF

C14 = 35 nF L18 = 40.3 mH

L15 = 6.61 mH C18 = 18.3 nF

C15 = 82.8 nF

These values can vary, e.g. 5%.

In a further, not shown embodiment of a blocking filter, the centrally located parallel swing circuit in the filter according to fig. 6 is replaced with the coil L13 located on the voice device side, while a coupling which is equivalent to a coupling part with negative capacity is retained on the central side of the filter. Capacity or the inductance values of the individual filter elements are then changed. In principle, a blocking filter according to the invention can also have more than two parallel oscillation circuits, as the number of damping peaks located at 4 kHz generally increases accordingly. However, it has been shown that a cut-off filter which exhibits two parallel swing circuits completely meets the desired requirements, and that therefore for economic reasons no extended chain circuits with more links than what is indicated in the examples according to fig. 5 and 6.

In order to be able to use known subscriber fee counters in the male part or more expensive devices for call data registration including fee counting, which are designed for the usual high-frequency counting, i.e. for debit pulses of 12 or 16 kHz, one can preferably arrange one in fig. 9 shown subscriber branch. Also shown in this figure is the switchboard 1, the debiting pulse transmitter 3 installed there, the switchboard branch 4 and the voice wires a and b to which a subscriber branch comprising the blocking filter 5' is connected on the subscriber side, which can, for example, correspond to the blocking filter according to fig. 6 or 8, and the debit pulse receiver connection 6'. The output from the debit pulse receiver connection 6' is connected to a frequency converter 9 which converts the debit pulses of 4 kHz into pulses of 16 kHz. The output from this frequency converter 9 is, on the side of the blocking filter 5' facing the speech device 2, again supplied to the speech wires a, b, in which there is also connected a commercially available four-pole designed fee counter 8' for 16 kHz. In the considered example, the input of the 16-kHz pulses takes place by means of an inductive transmitter which comprises a coil 11 located in the output circuit of the frequency converter 9 and a coil 10 connected to this in series with the blocking filter's 5' capacitor C16. Of course, another type of input is also possible. In the case of 12-kHz counters, a 4 kHz/12 kHz converter must of course be used.

.With a subscriber branch according to fig. 9 can, then

■ without further ado, all commercially available fee counters designed for the known high-frequency counting or call data recording devices are used which are designed as four-pole and are intended for connection to the two voice wires a, b.

Claims (8)

1. Telephone subscriber branch for connection to a coiled line, comprising a blocking filter for separating the debiting pulses arriving over the central line from the speech device, the blocking filter (5; 5') having a passband in the speech frequency range, is arranged for blocking debiting pulse frequencies in the vicinity of the upper speech band limit, and consists of a reactance filter which exhibits a series connection of at least two parallel swing circuits and transverse capacitors arranged between them (C6; C18), characterized in that the last link at one end of the series connection consists of only one coil (L5; L13), that on both sides of this coil are also arranged transverse capacitors (Cl, C8; C16, C17), and that the reactance filter immediately after the pass area, at the end with the highest frequency, has a maximum attenuation at the occurring debit pulse frequency of approx. 4 kHz, on the speech device (2) side is dimensioned for a complex termination corresponding to a parallel connection of ohmic and capacitive resistors (R2, C2), and on the central side is dimensioned for a real closure. 2. Telephone subscriber branch according to claim 1, characterized in that the complex termination on the voice device side corresponds to an ohmic resistance (R2) of 800-1000 Q and a parallel-connected capacity (C2) of 30-50 nF with this, and the real termination on the exchange side corresponds to to an ohmic resistance (RI) of 1000-1200 fi. 3. Telephone subscriber branch according to claims 1 and 2, characterized in that for a terminating resistor (RI) on the exchange side Then approx. 1100 Q and for a termination on the speech device side with a resistance (R2) of approx. 860 Q and a capacity (C2) of approx. 40 nF, the cut-off filter in its earth-asymmetrical form comprises a coil (L5) of 64 mH located on the central side, a parallel oscillating circuit adjacent to this coil with a coil (L4) of 44 mH and rn capacitor (C4) of 36 nF, a second parallel swing circuit with a coil (L3) of 14 mH and a capacitor (C3) now 110 nF, and also capacitors (C8, C7, C6) which connect both tele-wires (a, b) and which, starting with the capacitor located on the central side, have capacities of respectively 17 nF, 41 nF and 51 nF, as all values can vary by approx. 5%. 4. Telephone subscriber branch according to claim 1 or 2, characterized in that the blocking filter (5<1>) in its -earth-unsymmetrical form at the central side end has a connection which is equivalent to a connection part with negative capacity and which consists of a in one of the speech wires (a) located parallel swing circuit (L15, C15) and a series swing circuit (L18, C18) which connects the parallel swing circuit's coil (L15) with the other voice wire (b), the coils (L15, L18) in these two swing circuits being coupled coils. 5. Telephone subscriber branch according to claim 4, characterized in that the coils (L15, L18) in the parallel-lell and series swing circuit in the said equivalent connection consist of a common coil with an outlet leading to the first-mentioned voice wire (a). 6. Telephone subscriber branch according to claims 4 and 5, characterized in that for a termination resistance (RI) on the exchange side of approx. 1100 9. and for a termination on the speech device side with a resistance (R2) of approx. 860 Q and a capacity (C2) of approx. 40 nF, the equivalent connection has a parallel swing circuit with a coil (L15) of 6.6 mH and a capacitor (C15) of 83 nF and a series swing circuit with a coil (L18) of 40 mH and a capacitor (C18) of 18 nF, a further parallel swing circuit is provided with a coil (L14) of 45 mH and a capacitor (C14) of 35 nF as well as a coil (L13) of 71 mH on the speech device side, and of the two capacitors (C16, C17) that connect the speech wires , the capacitor on the speech device side (C16) has a capacity of 39 nF and the other (C17) has a capacity of 47 nF, as all values can vary approx. h 5%. 7. Telephone subscriber branch according to one of the preceding claims, characterized in that a frequency converter (9) is connected after the debit pulse-receiver connection (6') which converts the frequency of the debit pulses arriving from the exchange (1) into a frequency suitable for the usual high-frequency counting ( 12 or 16 kHz.), and that the output from this f frequency converter (9) on the side of the blocking filter (5') facing the speech device (2) is connected to the speech wires. 8. Telephone subscriber branch according to claim 7, characterized in that it comprises an inductive transmitter (10, 11) which connects the frequency converter (9) with the end of the blocking filter (5') facing the speech device (2).