DE2705786B2 - Device for carrying out control measurements in a message transmission system - Google Patents

Description

The invention relates to a device as defined in the preamble of the main claim.

A device with the features of the preamble of the main claim is through the DE-OS 23 39 085 known In the control measuring method for PCM systems described there, from the LF side of such a system from linearity and phase errors determines the over the entire system, that is, the two end points and the transmission link in between occur. To this end, will a square wave alternating voltage is entered as measurement alternating voltage on the LF side of the system and removed. The measurement signal generator is thus connected to an analog signal input of the entire transmission system set where the measured values are also taken. The analog signal generator used supplies square-wave voltages of different amplitudes, the amplitudes correspondingly the quantization levels of the multiplex device can be selected. From the received square-wave voltage curve errors can then be determined by comparing them with a standard image. As a measuring device an oscilloscope or an oscilloscope is used for this.

Such an error determination in which the measurement is always over the entire transmission system extends is not always accurate because it extends mainly through the multiplexing device and the demultiplexing device Can reverse error sizes, which means that an exact error analysis is no longer possible. Both Previously known measurement methods can therefore certainly lead to the fact that no error is displayed, regardless

but there is no normal function of the transmission path because there are errors in the system can compensate the terminals.

The present invention has for its object to provide a measuring device with which

Measurements both over the entire transmission system and only over the area of one or the other terminal or over the area of the transmission path alone are possible.
According to the invention, this object is achieved by the features of the characterizing part of the main claim. Since measurements can occur in the analog signal range as well as in the digital signal range of the transmission system, the measuring device designed according to the invention has both analog signal inputs and outputs and digital signal inputs and outputs as well as switching devices that adapt the measuring device to the area to be checked

of the transmission system.

The measuring device designed according to the invention is constructed in such a way that it only has a single type of signal generator, in the present case a digital signal generator, has by the switching device can send the digital signals from the signal generator directly to a digital signal line of the transmission system or via a digital / analog converter to a Analog signal line of the transmission system are given. Another advantage of the invention is in the fact that only a single measuring device, namely a Measuring device for an analog display, is required. It can be an oscilloscope, a recording galvanometer or be a square meter. The measuring device is constructed in such a way that this measuring device is always an Analog signal either directly from an analog signal line of the transmission system to be checked or received from a digital signal line via a digital / analog converter

Further features relating to advantageous developments of the subject matter of the application, in particular their use in time multiplex systems are listed in the subclaims

An exemplary embodiment of the subject matter of the invention is described in greater detail below with reference to the drawings explained it show

Fig. 1, 2, 3 each have the same simplified scheme the measuring device designed according to the invention for three different applications with corresponding different position of the switching devices;

4, 5, 6 are schematic representations of a for Time division multiplex systems determined measuring device according to the invention in three different applications;

F i g. 7 shows a complete circuit diagram of the measuring device.

In the figures, all circuit parts that are of the same nature and play the same role are denoted by the same reference numerals. At the connections, the two letters A or N indicate whether they carry analog signals or digital signals.

In all figures, the connections in use are shown in solid lines designated. With thick broken lines those connections are denoted, which in each case not are used. Those circuit parts and connections are marked with thin solid lines, which are outside the actual measuring device.

First, the F i g. 1, 2 and 3 are considered. In this and the following figures, in order to maintain the clarity of the figures, the representation of a synchronization transmitter for the digital circuits and, with exceptions, the representation of the synchronization inputs of the circuits has also been dispensed with. The measuring device shown in FIGS. 1-3 is intended for measuring the signal level, that is to say the amplitude values of the signals, which occur on a PCM transmission link between two terminals. One terminal is designated with the letter E and the other with the letter R. In order to distinguish between the transmitting end E and the receiving end R during the respective measuring process, regardless of the fact that the transmission path is effective in both directions and thus both terminals and R can form both the receiving side and the transmitting side. The in F i g. 3 indicated transmission line C is to consist of a single digital transmission channel that can be operated in both "Richtunger and via a digital connection Central a loop circuit forms the terminal E has an analog / digital converter or an output code converter to which the signal received at its input analog signal , for example a voice signal or an information signal sent by a calling subscriber, is converted into a digital signal which is sent to the one transmission line of the transmission channel C leading from the terminal E to the terminal R. The terminal R has for this purpose a digital / analog converter or an input code converter that converts the digital signal received at its input into an analog signal that reaches the receiving subscriber via its output carried out

According to FIGS. 1, 2 and 3, the measuring device has a digital signal input 10, an analog signal input 20, a digital signal output 30, an analog signal output 40, a digital signal generator 50, a first digital / analog converter 60, a second digital / analog converter 70, an analog signal meter

80 - for example a square value measuring device - and manually operated switching devices 11, 12, 51 and

81 for two operating positions_aund_6auf each.

The output of the digital / analog converter 60 leads to an analog signal output 40. The switching device U connects the digital signal input 10 to the switching device 12 when it is in its position ajst In its position ^ the switching device 11 connects the switching device 12 to the contact ^ of the switching device 51. In its position a ^ the switching device 12 connects the switching device 11 to the input of the digital / analog converter 70, and in its position J> it connects the switching device 11 to the digital signal output 30. The switching device 51 connects the output of the digital signal generator 50 with the input of the digital / analog converter 60 when it is in its position a_ , and with the contact b of the switching device 11 when it is in its position ^. In its position j ^ the switching device 81 connects the output of the digital / analog converter 70 to the input of the analog signal measuring device 80, and in its position b it connects the analog signal input 20 to the analog signal measuring device 80.

The F i g. 1-3 show three different applications of the measuring device. Fig. 1 shows the measuring device in a setting to control the terminal E of the transmission system. F i g. 2 shows the measuring device in its setting for checking the terminal R of the transmission system. F i g. 3 finally shows the device in a setting to control the entire transmission system, which includes the two terminals and the intermediate transmission link C.

In the setting according to FIG. 1 are all four switching devices 11, '12, 51 and 81 in their position a ^ The digital signal generator 50 supplies its digital signals via the switching device 51 to the digital / analog converter 60, whose analog output signals are transmitted via the analog signal output 40, which with the terminal to be controlled £ is connected. The digital output signals of the terminal E are transmitted via the digital signal inputs 10

and the switching devices 11 and 12 are given to the input of the digital / analog converter 70, whose analog output signals reach the analog signal measuring device 80 via the switching device 81. The level of the digital signals of the digital signal generator 50 and the transfer factors of the digital / Analog converters 60 and 70 are known, so that the analog signal measuring device 80 the transmission factors for the terminal E for the from the digital / analog converter 70 correctly displays the analog signals supplied.

In Fig. 2 the four switching devices 11, 12, 51 and 81 are in their position. 6. The digital signal generator 50 supplies its signals via the switching devices 11 and 12 to the digital signal output 30. The digital signal output 30 is connected to the input of the terminal R to be controlled. Its output is with the input of the analog signal measuring device

80 connected via the analog signal input 20 and the switching device 81. The level of the signals supplied by the digital signal generator 50 is known, so that the analog signal measuring device 80 indicates the transfer factor of the terminal R for these signals. In the circuit of FIG. 2, the digital / analog converters 60 and 70 are not in use.

In the shift setting according to FIG. 3, the switching device 51 is in its working position a ^ and the switching device 81 is in its position J>. The position of the switching devices 11 and 12 is of no importance. The signals of the digital signal generator 50 are transmitted via the switchover device 51, the digital / analog converter 60 and the analog signal output 40 and applied to the input of the end parts E , which is connected to the end point R via the digital transmission link C. The analog output signals from the terminal R are sent to the analog signal input 20 and the switching device

81 given to the analog signal measuring device 80. In this way the global transfer factors of the both terminals E and Λ and the transmission link Get it.

The digital signal generator 50 will be described in more detail in connection with FIG. 7 in order to show how the determination of the transmission factor of the terminals E and R or the entirety of the transmission system E + C + R can be achieved with different measurements of the signal strengths by comparison.

The embodiment of the measuring device shown in FIGS. 4, 5 and 6 is intended to determine the signal level and thus the transmission factor of a multiplex transmission system, that is to say with a PCM time division multiplex transmission link C between two terminals. Each terminal is provided with several analog lines, for example subscriber lines and thus NF connections. The transmission-side terminal E allows a control of the analog signals received from the multiple subscriber connections, which are given in temporal quantization to the digital transmission channels occupying time slots of a pulse frame. The receiver-side terminal R has a demultiplexing device and channelized decodes the coded signals separated in time and converts them into LF signals that are given back to subscriber lines. With the second embodiment of the measuring device, the transmission factors of a digital transmission path are measured, namely between the LF input terminal of the transmitter-side terminal E and the LF output terminal of the receiver-side terminal R. In order to keep the figures clear, FIGS. 4, 5 and 6 aiii circuits of the terminal E the one determination de; LF signal arriving via a subscriber line <for example by means of an input code converter! allow, and the multiplex device is only represented by a switching block. The same are shown in FIGS. 4 5 and 6 also the demultiplexing device in dei

ίο terminal R on the receiving end and an output code converter present there not shown individually. The transmission link C is in turn a circuit loop that leads through a digital telephone exchange, and the terminals fund R form a single block, which has both a multiplex and a demultiplex device.The inputs of the multiplex device and the outputs of the demultiplex device are in both directions operable analog subscriber lines in the Niederfre frequency range connected via input and output code converters. The output of the multiplex device and the input of the demultiplex device are connected to the digital transmission path, which has a transmission branch for the one transmission direction and a transmission branch for the other transmission direction.

So in a transmission system constructed in this way, the circuit parts of the terminal A reference

Control on a single digital transmission channel zi, so with respect to a single subscriber line, the measuring device must have a removal circuit 13, with the help of this channel from the multiplex output connection of the transmitting end E can be picked out. If you want to control the circuit parts of the receiving end station R ir with reference to a single transmission channel, the measuring device must have an insert circuit 31, with the aid of which a digital test signal, which is supplied by the digital signal generator 50, can be entered into the time slots which this transmission channel in Multiplex system are assigned and from which it is given to the input of the receiving-side terminal R.

The F i g. Figures 4, 5 and 6 show more detail than Figures. 1 to 3, but affect the same three Use cases such as FIG. 1 to 3. The different line thicknesses etc. of the circuit parts and dei Connections has the same meaning as in the

so F i g. 1 to 3, but are shown in FIGS. 4 to 6 the zi controlling terminals E, R no longer shown. The circuits according to FIGS. 4, 5 and ί

differ from the circuits according to FIG. 1, 2 and 3 through the following circuit parts:

the two digital / analog converters 60 and 70 are replaced by a single digital / analog converter 90 , which works time-division multiplexing, which is much more economical; In the digital signal input 10 and the Digitalsignalaus output 30, a removal circuit 13 and a plug-in circuit 31 are inserted; a digital attenuation line 99 and two analog attenuation lines 41 and 82 have been added. About the digital / analog converter 90, the removal circuit 13 and the plug-in circuit 31 is said in more detail in connection with Figure 7 The digital; Analog converter 90 has one electronically switched input and one electronically switched

Outputs, which are optionally opened or closed via connections 95 and%, which supply synchronization signals that come from an internal timer of the measuring device. As already mentioned, this timer is not shown. The digital signals which are supplied via the switching device 51 to the first input 91 of the digital / analog converter 90 are thus decoded in a repetitive manner and sent to a first output 92 of the digital / analog converter 90. Then the digital signals given via the switching device 12 to a second input 93 of the digital / analog converter 90 are decoded and passed via a second output 94 of the digital / analog converter 90 to the contact a of the input device 81.

The digital attenuation line 99, which will be explained in connection with FIG. 7, is inserted between the switching devices 11 and 12.

The analog attenuation lines 81 and 82 consist of known circuits, the operational amplifiers with negative feedback loops or single resistance attenuators. In the Fig. 4. 5 and 6 is not shown that the controller the gain of the digital attenuation line 99 and the analog attenuation lines 41 and 82 so: j is coupled so that the compensation of the gains is achieved, which is necessary for the digital / analog converter 90 works at a constant level.

In addition to the switching devices 11, 12, 51 and 81 which have already been described in connection with FIGS. 1, 2 jo and 3 have been mentioned, the formations according to FIGS. 4, 5 and 6 the following circuit parts on:

1. a manually operated switching device 42, with which the input of the damping line 41 ^s> in its position j? the analog signals of the output 92 j> be given of the digital / analog converter 90 and in its position that may on the analog signal input 20 via a gnale occurring switching device 83 to be described Analogsi- ^"0;

2. a manually operable switching device 43 which connects the output of the damping line 41 in its position_a to the analog signal output 40 and in its position J? .To the contact b of a three-position switch 85 still to be considered;

3. a manually operated switching device 83 with three positions, which the analog signals that arrive via the switching device 81 from the digital / analog converter 90 or the analog signal input 20, in a position J ^ on the contact a of the switching device 85 via a connection 84, in their position _b_ on the contact b of the switching device 42 and in their Steliung_c. on the input of the damping line 82;

4. A manually operated switching device 85 with three positions, which in its position ^ the contact a of the switching device 83 connected via the connection 84, in its position _b_ the contact Ader switchover device43, and in its position c_ the output of the damping line 82 with the input of the Analog signal measuring device 80 connects.

So the following applies:

1.) When all switching devices are in their position jj_ (circuit according to Figure 4), the measuring device can use the analog signal output 40 on the

50

55

60 LF input of the terminal E from the digital signal generator 50 deliver signals which are converted over the path 91-92 of the digital / analog converter 90 and whose levels are influenced by the attenuation line 41, and the measuring device can determine the level of the digital output signals of the Measure terminal E , which are transmitted via the digital signal input 10 and taken from the multiplex connection by the extraction circuit 13 , influenced in their level by the digital attenuation line 99 , converted on the path 93-94 of the digital / analog converter 30 and transferred to the analog signal measuring device 80 given are.

2.) When all switching devices assume their working position (circuit according to FIG. 5), the measuring device can deliver signals formed by the digital signal generator 50 via the digital signal output 30 to the digital multiplex input of the terminal R , the level of which is transmitted by the digital attenuation line 99 is influenced and which are inserted into the multiplex transmission path by the plug-in circuit 31, and the measuring device can measure the level of the analog output signals of the N F output of the receiver-side terminal R , which are supplied via the analog signal input 20, the level of which through the analog attenuation line 41 is influenced and which are given to the analog signal measuring device 80.

3.) If the Umschaltvorrichlung 42,43 and 51 in the position a ^ the switching device 81 in the position b_ and the Umschahvorrichtungen 83 and 85 are both in the position χ, the measuring device can via the analog signal output 40 to the analog LF input of the transmit-side terminal E transmit a signal formed by the digital signal generator 50, which is converted on the path 91-92 of the digital / analog converter 90 and regulated in its level by the analog attenuation line 41, and the measuring device can determine the level of the LF output of the Measure the analog signals occurring on the receiving end R , which are input via the analog signal input 20, are leveled in their level by the attenuation line 82 and sent to the analog signal measuring device 80.

So it should be noted:

1. Analogously to the circuit according to FIGS. 1, 2 and 3, it is possible to combine all switching devices, with the exception of the switching device 81, into a single switching device with several paths and with two operating positions. The switching devices 83 and 85 can be combined into a single switching device with two paths and three directions, whereby the control of the measuring device is simplified;

2. If the application shown in FIG. 6 is excluded, the damping lines 82 and the switching devices 83 and 85 dispensable, and the switching device 81 can with the other switching devices to one single switching device are combined;

3. The use of the digital attenuation line 99 and the analog attenuation line 41 is permitted in the application according to Fig. 4 the digital / analog

log converter 90 on a practically constant Operate at levels and close to values that guarantee a minimum of distortion.

FIG. 7 shows the main circuit parts of the measuring device of FIG. 4, 5 and 6 in more detail. Below essentially only those parts of the circuit are described that are not already in context with the F i g. 4-6 have been mentioned.

The extraction circuit 13 has, in a known manner, a demultiplexing circuit 131 and, in the event that the signals have been subjected to time compression in accordance with a law χ (for example law A of the international recommendation), a code converter 132 to restore linearity. In the same way, the plug-in circuit 31 has a code converter 311 in front of a multiplex circuit 312 which restores the correct temporal position. The synchronization circuits are not shown because they do not pose any particular problems.

The extraction circuit 13, which allows access to a digital channel of the multiplex transmission link C at the output of a terminal E (FIG. 4), plays a role as the extraction organs in a digital channel and on the corresponding analog LF output line in a receiving-side terminal E play. The insert sound 31, with which a digital signal can be entered in time slots of a digital channel at the input of a receiving end point R (Fig. 5), plays the same role as insert elements on an analog LF input line and on a corresponding digital channel in a receiving end point R. As has already been mentioned in connection with FIGS. 4 to 6, the two terminals actually form a single terminal of a telephone exchange that can be operated in both directions and that serves several analog subscriber lines that are multiplexed on a transmission path that can be operated in two directions that forms a circuit loop inside the switchboard.

The digital signal generator 50 consists of:

a) a digital multi-frequency signal generator 52 for generating sinusoidal signals. This circuit can advantageously be formed by an address generator and a read-only memory. The read-only memory can have a structure described in DE-PS 25 43 356. It forms several frequencies by multiplying a frequency of 25 Hz. The upper limit is around 3600 Hz;

b) a digital noise generator 53 for a frequency band-limited white noise, more precisely for pseudoalleatoric frequencies with Gaussian distribution, for example in accordance with the CCITT recommendations for experiments on PCM time division multiplex links;

c) a switch 54 with three positions, which is connected to the switching device 51 in FIG its position_a the multi-frequency signal generator 52, in its positionJ> the noise generator 53 and in its position j ^ connects a ground connection. The last-mentioned position j allows measurements of the noise at a terminal that is at rest, i.e. when there is no signal transmission takes place

The digital attenuation line 99 can be formed, for example, by a multiplier 991 , the multiplication coefficients of which are supplied from a read-only memory 992 , the reading of which is controlled by a circuit 993 which sets up the required addresses. As already mentioned, the attenuation lines 99, 41 and 92 are coupled in such a way that in the application according to FIGS. 4 and 5 the product of the damping coefficients of the damping lines 99 and 41 remains constant and that in the application of FIG. 6 the damping coefficients of the damping lines 41 and 42 remain the same. The digital / analog converter 90 for linear decoding contains a converter 901 of known design and a digital switch 902 and an analog switch 903, each controlled by the timer of the measuring device via connections 95 and 96 to ensure the time division multiplex function. The digital signals that may arrive from the digital signal generator 50 via the digital signal input 10 in the application shown in FIG. The switching frequency is somewhat lower than the minimum frequency of the signals formed by the circuit 52. It is, for example, of the order of magnitude of 5 Hz. The analog signal measuring device 80 includes a circuit (not shown) with a time constant.

The circuit according to FIG. 7 also has a low-pass filter 97 inserted between output 92 and switchover device 42 for filtering out harmonics, and a switchable measuring filter 86 is inserted between switchover device 81 and switchover device 83, neither of which are essential to the invention.

Another measurement example is described below: The analog signal measuring device 80 allows a comparison measurement of multifrequency sinusoidal signals that are triggered by the multifrequency generator 52 or of noise signals that are triggered by the noise generator 53, which are limited in frequency by the pass frequency band of the digital transmission link C. The transmission factor of a terminal or the entirety of the transmission system is consequently measured with the aid of digital signal generators, regardless of the type of input the area to be checked or the place of the transmission system to be checked has. The measuring device can be connected to an analog signal input as well as to a digital signal input of the transmission system by means of the switching devices and the digital / analog converters contained in it. The measurements can also be measured via a digital signal channel and on the corresponding analog LF line of the transmission system if the individual signals are quantized in terms of time and amplitude in a multiplexing device of the PCM system , because the measuring device has appropriate multiplexing and demultiplexing May have devices in 13 and 31.

The transmission factor, i.e. the residual attenuation of a monitored area of the transmission input direction, so either the terminal £ or R or the entirety E + C + R, so including the transmission path Q can with the help of the multi-frequency signal generator 52 and the analog signal measuring device 80

measured either as a function of the frequency and a constant amplitude or as a function of the amplitude and a constant frequency. In both cases, the analog signal measuring device 80 is designed for a setpoint frequency input signal / o and a setpoint amplitude which can be set with the aid of attenuators, and it receives a reference amplitude or a reference level Po. In the first case, a signal with the nominal amplitude and with a measuring frequency f is applied to the input of the part or area of the transmission system to be monitored, and the analog signal measuring device 80 receives a signal with the amplitude P. The difference between the amplitudes P and Po shows the attenuation distortion at the frequency / "in ¹ ^ comparison to the setpoint frequency k . In the second case, a signal with a setpoint frequency / o and with an amplitude that differs from the setpoint amplitude is transmitted to the input of a part of the to be monitored during the measuring process Transmission system given, and the analog signal measuring device 80 receives a signal with the amplitude P '. The difference between the amplitudes P' and Po shows the attenuation distortion in the measurement amplitude in relation to the nominal amplitude at the nominal frequency / ö-

When measurements are made with the noise generator 53 at the end point £ on the transmission side (measurement example according to FIG. 4), the noise signal delivers a certain limited frequency band with a certain number of individual frequencies of the selected frequency spectrum distributed according to a Gaussian curve. The analog signal measuring device 80 permits the measurement of the ratio between the power of that part of the noise signal obtained in the given frequency band and the power of the other complementary part of the noise signal received within the given frequency band. When taking measurements at terminal R on the receiver side (measurement example according to FIGS. 2 and 5), the noise generator delivers a certain number of PVM test words directly to the digital line, which represent the previous noise signal and which are converted into analog test signals in terminal R. The analog signal measuring device allows to determine the noise factor between the power of the usable signal and the power of the interfering signal, as in the previous case. These last-mentioned measurements thus allow the quantization distortion to be determined both on the transmission side and on the reception side of a PCM system.

Comments on the type of coding and the multiplexing of the digital signals to the Controlling PCM transmission links are unnecessary since they are not essential to the invention.

For this purpose 3 sheets of drawings

Claims (8)

Patent claims: 1. Device for performing control measurements in a message transmission system which has two terminals and an intermediate transmission link and in which analog input signals are transmitted in digital form and converted back into analog output signals; with a signal generator and a measuring device for analog signals, characterized in that for the optional measurement of analog or digital signals in the message transmission system, the control measuring device has both an analog signal input (20) and a digital signal input (10) and, accordingly, an analog signal output (40) and a digital signal output (30); that the signal generator (50) is designed as a digital signal generator that two digital / analog converters (60, 70) are provided, the first (60) being connected to the analog signal output (40) and its input optionally to the digital signal generator (50) or to the input of the second digital / analog converter (70) and the second (70) with its input optionally to the digital signal input (10) or the signal generator (50) and with its output to the analog signal measuring device (80) can be, and that several changeover switches (11,12,51,81) are provided for the selection circuits. 2. Measuring device according to claim 1 for a multiplex communication system, characterized characterized in that the digital signal input (10) is followed by a demultiplex stage (13) and the A multiplex stage (31) is connected upstream of the digital signal output (30). 3. Measuring device according to claim 1 and / or 2, characterized in that instead of the two Digital / analog converter, a single digital / analog converter (90) is provided, the input side and changeover switches (902, 903) are assigned on the output side, with which an input (91) of the converter (90) with the output of the signal generator (50) and an output (92) of the converter (90) with the Analog signal output (40) or an input (93) of the converter (90) with the digital signal input (10) and an output (94) of the converter (90) can be connected to the input of the measuring device (80). 4. Measuring device according to one of claims 1 to 3, characterized in that it also has a has digital attenuation path, which can be selected between the output of the signal generator (50) and the digital signal output (30) or between the digital signal input (10) and a digital / analog converter (90) is switchable. 5. Measuring device according to claim 4, characterized in that the digital attenuation path (99) has a multiplier (9911) which is connected to the output of an address-controlled digital memory (992) 6. Measuring device according to one of claims 1 to 5, characterized in that it also has a analog damping path (41), which by means of switches (42, 43) selectively between the Output of the digital / analog converter (90) and the analog signal output (40) or between the analog signal input (20) and the input of the measuring räts (80) is switchable 7. Measuring device according to claim 6, characterized in that it has a second analog damping path (82) which can be switched between the analog signals input (20) and the input of the measuring device (80) by means of switches (83, 85) 8. Measuring device according to one of claims 1 to 6, characterized in that the signal generator ίο (50) two optional single generators (52, 53), namely a generator for digital signals corresponding to a sinusoidal analog signal and a generator (53) for noise signals