NO146077B - AA CLUTCH DEVICE AND LOCATE ERRORS IN A TRANSMISSION SYSTEM FOR HEAD CODE MODULATED SIGNALS - Google Patents

Abstract

1. Circuit arrangement for the determination and location of faults in a transmission system, which has two transmission directions for pulse-code-modulated signals with intermediate stations which are to be checked and which for each transmission direction respectively contain an automatic, active attenuation equalizer and a preliminary equalizing stage which is connected preceding the equalizer in the signal path, characterized in that the preliminary equalizing stage is designed as high-pass filter (F1), that in the signal path, the attenuation equalizer (D) is followed by an active compensation low-pass filter (F2) which is so contrived that the product of the transmission functions of the high-pass filter (F1) and of the compensation low-pass filter (F2) is a constant, and that during the fault-locating operation, in the locating signal path, the attenuation equalizer (D) is preceded, via a second input, by an auxiliary low-pass filter (F3) which is so contrived that together with the compensation low-pass filter (F2) an equivalent network corresponding to a medium length cable is formed.

Description

The invention relates to a coupling device for determining

and locating errors in a transmission system for pulse code modulated signals, where the system has two transmission directions and includes intermediate stations to be controlled, and each of which, for each transmission direction, has an automatic, active attenuation correction link and a pre-correction link which is connected before this in the signal path.

In connection with pulse code modulation, it is possible to build up information transmission systems that are very un- sensitive to noise, as the transmitted signal up to a certain signal-noise distance on the transmission path can be regenerated by almost 100% at intermediate stations as often as it should be. These intermediate stations as well as the end centers contain in the regenerators e.g. active correction links that balance the damping on the transmission line. These correction elements are composed of an input-side phase value correction element and a subsequent automatic correction

joints and is capable of correcting distortions over large regenerator field lengths.

In order to ensure operational readiness of such an information transfer system at all times, it is necessary to locate faults in intermediate stations or end centers with regenerators from at least one end station. This is particularly necessary at intermediate stations, which are generally located in the field with difficult access.

For locating faults in PCM wiring systems, according to DE-PS 23 58 272, the received pulse pattern of the fault location signal is blended into the input of an automatic damping correction link - e.g. as known from

DE-PS 23 18 246 - for the opposite direction, at the same time as

the received signal present at the input for the opposite direction is separated from (loop closing operation). In this connection, all active components must be included in the loop closure path. In addition, the fault location signal must be shaped with the help of wire copies in such a way that the automatic damping correction element during loop-closing operation sets itself approximately in the middle of its regulation range, which, especially in modern systems with long wire lengths, requires a considerable expense for the creation of wire copies.

The task of the invention is to develop a coupling device of the type mentioned at the outset so that it becomes possible to reduce the equipment for necessary wire copying in the fault location signal path.

Based on a switching device of the kind indicated at the outset, this task according to the invention is solved by the fact that the pre-correction stage is designed as a high-pass filter, that where the attenuation correction element is connected in the signal path, an active compensating low-pass filter is dimensioned so that the product of the correction element's and compensating the low-pass filter's transfer functions constitute a constant, and that where in the localization signal path, the attenuation correction link is connected to a complementary low-pass filter which is dimensioned so that together with the compensating low-pass filter, a line copy corresponding to the average cable length appears.

In this connection, it is particularly advantageous if the low-pass stage which is connected after the attenuation-correction element in the signal path, according to the invention, is dimensioned so that in loop-closing operation it already takes over a considerable part of the line copying, and in normal operation of the line attenuation-correction element can compensate the high-pass filter that is connected to the attenuation correction link in the signal path, with respect to attenuation and phase. The passive high-pass filter further prevents in a favorable way, especially with short cable lengths, an override of the damping correction element's input stage at the correction element's lower control limit, so that the damping step proportional to the root of the frequency in the transmission path for low-frequency signal components, which are more weakly damped and thus leads to to significant signal amplitudes, does not cause distortions in the input amplifier stage. Thanks to the double utilization of the aforementioned amplifier stage, it is thus possible to get by with little equipment for the processing of the fault location signals.

Further advantageous designs of the subject invention are indicated in the subclaims.

The invention will be explained in more detail below

in the case of design examples with reference to the drawing.

Fig. 1 shows a block connection for the damping correction link,

fig. 2 shows Bode diagrams for the high-pass filter Fl, the compensating low-pass filter F2, the complementary low-pass filter F3 and the resulting line copy obtained with the compensatory low-pass filter and the complementary low-pass filter,

fig. 3 illustrates the wire copying in the localization signal path,

fig. 4 shows a coupling device in an exemplary embodiment, and

fig. 5 illustrates further possibilities for realizing the compensation low-pass filter.

In fig. 1 shows a principle connection diagram for a connection device which is made in accordance with the invention and is contained in the intermediate stations. In front of the automatic damping-correction section D, a passive high-pass filter Fl is inserted in the signal path, while in the signal path behind the damping-correction section there is a compensation low-pass filter F2, whose output via an amplitude regulator AR is connected to a stage of the damping- the correction term. The automatic damping-correction link is further on the input side via a switch device S which is indicated schematically in the figure, connected to a localization signal path that comes from the output of the automatic damping-correction link in the opposite direction, and in which a supplementary low-pass f oxygen F3.

The passive high-pass filter Fl here prevents an oversteer of the input stage at the correction link's lower control limit, especially with short cable lengths, so

the low-frequency signal components which due to the attenuation step proportional to the root of the frequency in the transmission path is less attenuated, not with its considerable signal ampli-

honks cause distortions in the attenuation-correction link's first amplifier stage. Furthermore, the lightning protection of the device is improved by the passive pre-correction.

In order not to impair the signal-to-noise ratio of the attenuation-correction element, it is necessary that the pre-correction element has the least possible attenuation at the Nyquist frequency. The transfer function of the pre-correction link performed as high-pass filter Fl is again canceled by the compensating low-pass filter F2, which is designed as an active link. For that, it is necessary that the product of the transfer functions of the high-pass filter Fl and of the active compensation low-pass filter F2 becomes a constant.

In normal operation, the input signal comes via the high-pass filter Fl to the automatic damping-correction circuit D, which, with the help of the amplitude feedback circuit AR, adapts to the preceding line length. During fault location operation, where another input to the attenuation correction link via a switching device S is connected to the complementary low-pass filter F3 and thus to the localization signal path, the compensatory low-pass filter F2 is supplemented by the complementary low-pass filter F3 to a line copy corresponding to a average cable length.

In the design example, the high-pass filter Fl is reali-

shown as a shunted T-joint which is shown in detail in fig. 4,

and which has the transfer function shown in the Bode slide

aram on fiq. 2, nemlia

The upper corner frequency £2 is in the embodiment at 4.514Hz. The attenuation a^ at the Nyquist-f frequency of 12.88MHz then gets a value of 0.5dB^ which can be disregarded in practice. The lower corner frequency is chosen equal to 0.45MHz so that the signal amplitude at the input of the correction element, in the case of a cable length corresponding to an attenuation of a^ = 54dB, is reduced approximately by the factor 4, and the same corner frequency is suitable as a element in a wire copying.

For compensation of the pre-correction with the high-pass filter Fl, the compensatory low-pass filter F2 is designed as an active low-pass filter, whose frequency-independent gain forms part of the overall gain of the damping correction link. Its transfer function, which is shown in the Bode diagram of Fig.

2, is

The product of the transfer functions of the high-pass filter Fl and the compensating low-pass filter F2 thus amounts to

a constant K.

For during operation for fault location to do so

possible to supplement the compensating low-pass filter F2 with the complementary low-pass filter F3 to a line copy, the corner frequency f 2> which is not needed for this, must be compensated. This results from a corresponding dimensioning of the completion low-pass filter, where this gets the following transfer function

where V., denotes a constant gain, £ the degree of attenuation of a second-order delay term and f^ and f^ further corner frequencies, of which the corner frequency f^ lies between the corner frequencies f^ and f_ and f^ lies above the corner frequency f^- Bode- the diagram for such a complementary low-pass filter F^ is likewise shown in fig. 2.

The obtained line copy F^ now results from the product of the transfer functions of the compensating low-pass filter F2 and the complementary low-pass filter F3 to F^ = F2" F^ with

The Bode diagram for such a line replica provided with compensating and complementary low-pass filters is also shown in FIG. 2.

Fig. 3 shows the attenuation curve for the line copy in an exemplary embodiment with the corner frequencies f.^ = 0.4 5 MHz,

f3 = 3.3MHz and f^ = 6MHz. At the same time, fig. 3 also the attenuation of a wire with a length corresponding to the wire copy.

Fig. 4 shows a diagram for the coupling device in a realized embodiment with the automatic damping correction link D shown as a block and the further coupling components in detail.

The high-pass filter Fl is constructed here as a shunted T-connection, whose longitudinal branches contain the resistors Zf and whose shunt is constructed as a parallel connection of a resistor R^

and a capacity C,. The to the shunt branch dual transverse path2

at the T-joint, the series connection of a resistor Z_ contains and

<R>l

an inductance Z 2C-^. The high-pass filter Fl thus has the following transfer function

The active compensation low-pass filter F2 contains a transistor T1 with a collector resistor R2 and an emitter branch, which is constructed as a series connection of a resistor R^ directly connected to the emitter pole and a parallel connection of a resistor R 4 and an inductance. The collector connection of the transistor Tl can be connected directly via the amplitude regulator AR to the damping correction link D. In the design example, there is also a further transistor stage in the emitter connection inserted between the transistor Tl and the amplitude regulator AR. The following transfer function is thus obtained for the active compensation low-pass filter F2

R3' = R3 + Re" Re is here the internal emitter resistance of the transistor

Further possible connections for the active compensation low-pass filter and their transfer functions are shown in fig. 5.

The supplementary low-pass filter F3 contains in the embodiment in fig. 4 two transistor stages with transistors T2 and T3. At the same time, the completion low-pass filter's input is

via a series connection of the two resistors R,- connected to the base connection of the transistor T2, at the same time that this connection is also connected to good via a capacity C^.

A further capacity C- is arranged between the connection point for the two resistors R,, and the goods connection. In the emitter branch of the transistor T2 there is a series connection of a resistance R7 and an inductance L^, while the collector branch contains a parallel connection of a resistance Rg and a capacitance C^. The collector connection of the transistor T2 is further connected to the base connection of the transistor T3, whose collector connection is connected to good,

and whose emitter connection is directly connected to the connection to the attenuation-correction link D which is arranged for the localization signal path.

The following transfer function is thus obtained for the supplementary low-pass filter F3

Further possibilities for realizing the active compensation low-pass filter are shown in fig. 5. The first connection in this figure is constructed dually to the connection device in fig. 4 and as a transistor stage, whose collector stage contains a parallel connection of a resistance R and a series connection of a resistance Rg and a capacitance C. The second possibility according to fig. 5 lies in the application of an operational amplifier OP, whose inverting input follows a series connection of a resistor Rg and a parallel connection of an inductance L and a resistance R^. A resistor RT is also arranged between the output from and the inverting input to the operational amplifier. A realization possibility dual to this is shown as a third device in fig. 5, where a resistance R„ is inserted in front of the inverting input to the operational amplifier, and where in the branch between the inverting input to and the output from the operational amplifier a series connection of a capacity C and a resistance Rg as well as a resistance R P connected in parallel with this is inserted series connection.

Claims (3)

1. Coupling device for determining and locating faults in a transmission system for pulse code modulated stations, the system having two transmission directions and including intermediate stations to be tested, each of which, for each transmission direction, contains an automatic active attenuation correction link and a pre-correction element that is connected before this in the signal path, characterized in that the pre-correction stage is designed as a high-pass filter (Fl), that the attenuation correction element (D) in the signal path is followed by an active compensation low-pass filter (F2) which is dimensioned so that the product of the pre-correction stage's ( Fl) and the compensation low-pass filter's (F2) transfer functions form a constant, and that in front of the attenuation-correction link (D) in the localization signal path, a complementary low-pass filter (F3) is connected which is dimensioned so that together with the compensation low-pass filter ( F2) results in a cable copying corresponding to an average cable length. 2. Coupling device as stated in claim 1, characterized in that the high-pass filter (Fl) is designed as a passive, shunted T-joint which has the transmission function where f^ is the lower corner frequency and f2 the upper corner frequency in the Bode diagram. 3. Switching device as specified in claim 2, characterized in that the compensation low-pass filter (F2) has the transfer function where V2 is a constant gain and K a constant, and that the complementary low-pass filter (F3) has the transfer function where V is a constant gain, c the damping factor of a second-order delay term and f^ and f ^ additional corner frequencies in the Bode diagram .