DE10059174A1 - Process for the qualification of lines and subscriber connection facilities with high bit rate data transmission - Google Patents

Abstract

The invention relates to a method for quantitative analysis of the properties of line (2) and/or subscriber connection devices (24) and for testing switching centre devices (1) on the exchange side for hardware errors and functional defects. To this end, a test signal is generated by a digital signal processor (21) on the basis of a loaded test code. This test signal is sent via the transmission path to be qualified. The reflected test signal is then evaluated in order to quantitatively determine the transmission properties of the transmission path taken by the test signal.

Description

The present invention relates to a method for Qualification of lines and subscriber line equipment tions, so-called remote terminal modems (RT modems) high bit rate data transmission. The invention relates also on a test procedure for public switching len facilities, so-called line cards or central office Modems (CO modems), for hardware errors and malfunctions to check.

Numerous methods and methods exist in the prior art drive to test the line properties, especially to Testing the line cards when transmitting speech. The Methods are currently used in both the production test as well tested in field trials (in China). You work in Voice frequency range (0 to 4 kHz) and are under the Be drawing "ILTF" (integrated line test functions) and "ITFP" (Integrated Test Functions for Production) be known. These procedures qualify the properties ordinary lines regarding the portability of Language. These tests show that it is unusable ner line for voice transmission, so it is in general not usable for data transmission either. It turns out however, as a result of the tests, the line found itself suitable for the transmission of speech, it does not mean that yet, that it can also be used for data transmission.

For the qualification of lines and subscriber lines facilities or office-side switching facility So far there have been developments in high bit rate data transmission No integrated test procedures yet, as line cards for the Until now, these applications have only existed as development patterns.  

Fig. 1 shows the general structure of such a line card for voice and data transmission.

The qualification of lines in the range of higher frequencies is currently only possible by means of an externally connected test facility possible. For example, there are test devices that are physically connect to the line and an RT modem emu in order to establish an xDSL connection to the maximum achievable Da to test ten rates. Other test methods require one test ter on the CO modem side and a counterpart on the RT modem te to establish a data connection and thus the lei testing properties.

The object of the invention is therefore a less complex Procedures to provide accurate analysis anyway the management and not only qualitative but also provides quantitative information. Line, RT modem and line card should be a system that is flexible to change can adapt to the requirements and the environment.

This object is achieved according to the invention in that from a memory on the line card to one digital signal processes on the line card or a test code is loaded. The digital processor generates from this a test signal and sends this to the to qualifi ornamental system. The reflected test signal becomes the quanti tative determination of the transmission properties of the evaluated the test signal through the transmission path.

The test signal can, for example, consist of a multi-tone signal exist, that is, a signal that is in the usable Fre quenzband each at a defined distance signal compo features.

A multi-tone signal can also be used, in which a individual signal components are suppressed. This so-called  "Missing Tone Signal" provides information about the level control properties and intermodulations of neighboring carriers.

The multi-tone signal is in the time domain by the test code specified and by means of the digital signal processor Inverter Fast Fourier transformation generated.

For echo compensation, there is a switch on the official exchange B-filter is activated.

From the difference between the sent and the received the damping is discrete spectral lines of the test signal characteristic of the B filter determined.

The attenuation characteristic of the B filter becomes the he targetable reflection loss determined.

In the event of a deviation from an error-free transmission path characteristic damping curve can be due to hardware failure or a fault in the overall transmission path is closed become.

The properties of the line and the subscriber line are tested during the ongoing operation of data transmission.

If the line parameters are changed, the amts sided switchboard adapted accordingly ter set of impedance parameters used.

The subscriber line device also has a transmission and evaluation functionality in the form of a digital signal pro zessors.

According to the invention, a method for determination is also used line delays and to determine the transmission characteristics in the upstream and downstream direction ansprucht. A test code is sent to the subscriber line device  from the official switchboard facility sent from. The subscriber line facility generates and sends a test signal based on the test code this one out. The reflected test signal is then evaluated and the test result of the official mediator device sent back.

Other advantages, features and characteristics of the present Invention are now based on exemplary embodiments explained in more detail on the accompanying drawings.

Fig. 1 shows schematically the structure of an office side switching centers means (line card),

Fig. 2a shows diagrammatically the transmission link to be qualified Übertra,

FIG. 2b shows schematically the to be qualified Übertra transmission link separately for upstream and downstream,

Fig. 3a shows the Multitonspektrum received from the DSP data,

FIG. 3b shows the Multitonspektrum the data sent from the DSP,

FIG. 4a shows the Multitonspektrum received from the DSP data with B filter,

FIG. 4b shows the Multitonspektrum the data sent by the DSP with B filter,

Fig. 5a shows the characteristic attenuation curve for poorly matched RT modem,

Fig. 5b shows the characteristic attenuation curve with perfectly matched RT modem,

Fig. 5c shows reflectance curves as a function ner Various cable lengths and line terminations.

In Fig. 1, the structure of an office side switching centers means (line card) 1 is shown schematically. A total of eight wire pairs 2 , z. B in the form of two-core telephone cables to which the two AHV ports (Advanced High Voltage Port) 3 are connected. These are connected to two AFE components (Analog Front. End) 4 which digitize the analog signals coming from the AHV ports 3 .

On the one hand, the digital data are fed to a DFE (Digital Front End) 5 which filters out the low-frequency voice data and then forwards them to an interface (interface speech) 6 . The latter outputs the quantized speech signal data in PCM format (Pulse Code Modulation) 7 . Control information relating to the format of the voice data is transmitted via the CN channel (Control Net) 8 and defines, for example, the gain in the AHV 3 or the sampling rate in the AFE 4 . The CP speech (Control Processor Language) 9 converts the CN information into commands that can be read by the AHV- 3 and AFE- 4 . In addition, the CP-Speech 9 stores measurement results (which, for example, characterize the properties of the line) in a DPRAM (Dual Ported Random Access Memory) 10 , which the Control Processor Data 11 of the high bit rate data branch can access (in order to detect line faults, for example) ,

On the other hand, the digitized data are fed to a PLD (Pro grammable logic device) 12 , which filters out the high-bit rate (high-frequency) data of the respective wire pair and feeds the corresponding DSP (digital signal processor) 13 . The task of the PLD 12 is also to bring the high bit rate data into a form that the DSP 13 can process. In the case of a line card 1 with eight wire pairs (ports) 2 , four DSPs 13 are required, since a DSP 13 can currently only process two ADSL channels. The high bit rate data is sent to two different interfaces via the Control Processor Data 11 , ATM-PHY 14 and Ethernet-PHY 15 , and can thus be transmitted in two ways: First, in ATM-25 mode (asynchronous transfer mode with 25 Mbit / sec) 16 and secondly in 10BaseT mode (via Internet with 10 Mbit / sec) 17 . The high bit rate data stream is synchronized with the voice data stream via a PLL (Phase Lock Loop) 18 of the DFE 5 .

The operating system of the Control Processor Data 11 and the test codes for the DSPs 13 are stored in permanent memory, the FLASH 19 . Both are loaded into the SDRAM (Synchronous Dynamic Random Access Memory) 20 during booting. The test code is then written by the Control Processor Data 11 into the memory of the DSP 13 .

The DSP 13 can generate a test signal based on the test code and can thus be used as a function generator that sends and receives special test patterns.

Fig. 2a shows schematically the transmission path to be qualified. On the basis of the test code, the data DSP 21 on the line card 1 sends out a test signal which transmits the transmission link "Data Downstream 22 → AFE → 4 HV-SLIC (High Voltage Subscriber Line Interface Circuit) 23 → line 2 → subscriber line device 24 → Line 2 → HV-SLIC 23 → AFE 4 → Data Upstream 25 "passes and is finally recorded again in the receive buffer of the Data DSP 21 . A subsequent analysis of transmit and receive data then illustrates the transmission characteristics of the route to be quali fied in the high bit rate data area.

Conclusions about the transmission path can be drawn from the data words sent and received. In this case, errors in the hardware components as well as defects in the line to the subscriber connection 24 have a disruptive effect from the data transmit path to the data receive path. A comparison of the results with setpoints shows errors in the transmission path (for example defective hardware components).

Instead of the Data DSP 21 , the Voice DSP 26 can also be used for testing. The Voice DSP 26 of FIG. 2 summarizes the functions of the DFE We sentlichen the (speech) 5/18, CP 9 Speech and Speech interface 6 of Fig. 1 together. This procedure provides information about the voice path. This method is already used in the integrated line tests of line cards 1 for the speech path.

Figure 2b differs from Figure 2a in that the downstream and upstream paths are tested separately. Here the RT modem 32 also has an RT-DSP 27 , which is also loaded with a test code and then the analysis of the transmission path in the upstream direction "RT-DSP Transmit 28 → Line 2 → HV-SLIC 23 → AFE 4 → Data Upstream 25 "for the data area or" RT-DSP Transmit 28 → Line 2 → HV-SLIC 23 → AFE 4 → Voice Upstream 29 "for the voice area. Similarly, the two downstream paths "Data Downstream 22 → AFE 4 → HV-SLIC 23 → Line 2 → RT-DSP Receive 30 " for the data area and "Voice Downstream 31 → AFE 4 → HV-SLIC 23 → Line 2 → RT -DSP Receive 30 "for the speech area can be analyzed.

Fig. 3b shows a test signal sent by the DSP 13 , which is a multitone signal, that is, a signal that has signal components in the usable frequency band each at a defined distance. If, as in FIG. 3a, individual discrete tones in the spectrum are omitted, the signal course is referred to as the "missing tone signal", which provides information about the modulation characteristics and intermodulation of neighboring carriers.

Fig. 3a shows the spectrum of the received from the DSP 13 Sig Nals after it has run the whole to be qualified by the system. If the difference between the received data words in the frequency range is formed on the discrete spectral lines visible in the figures (FIGS . 3a and 5b), the characteristic of the transmission path results from this. By sending out individual spectral lines, signal-to-noise characteristics can be established, intermodulation measurements can be carried out and signal delays can be determined.

The test is particularly suitable for pre-qualification when installing line cards 1 and for commissioning them.

When installing line cards 1 , the question arises as to the line quality and the quality of subscriber devices 24 . How long is line 2 , what diameter does it have, how many branch points exist and how many different line sections does the entire line 2 consist of? These factors are decisive for a correspondingly high or low data rate. Likewise, the type of subscriber terminal device 24 , ie the terminating impedance of subscriber modem 32 , additional components connected in parallel such as telephone, fax, etc. 33 and their electrical properties, are of essential importance for the use of high bit rate data transmission methods.

Even when commissioning line cards 1 , it is essential to obtain information about the type of line and the subscriber connection device 24 . The data transmission method can then be adapted to the properties of the line of the terminal device in order to achieve the maximum possible bit rates. In the case of unsuitable subscriber connection devices 24 , this information can be passed on to the subscriber with the suggestion to carry out a modification in the subscriber access area, for example to use a different RT modem 32 or certain devices for optimizing the end connection.

The advantage of this test method is also the flexi balance in relation to changing requirements.

Once a data transmission link is permanently installed, so There may be deviations in the usable during operation Data rate are coming. Abnut can cause interference appearance, cable break or other long-term errors be perfect. Interference can also be caused by parallel other services. It can FEXT (Far End Cross Talk = long distance crosstalk) and NEXT (Near End Cross Talk) Interferer to be added, which do not work during commissioning or not were sufficiently taken into account. Here is an appropriate one Line monitoring essential to detect errors in time cover, locate or prophylactically move in to prevent errors from occurring in the first place.

With the test procedure described, fault diagnostics and statistics can be created here. By the DSP can be programmed free 13 - the signal is specified in the frequency domain and by means of IFFT (Inverse Fast Fourier transfor mation) generate - within a very short time a qualification of the line card 1, but also the line 2 and the subscriber terminal equipment 24 , carry out. With a variable setting of the period of the time signal, the frequency resolution can be kept flexible and thus the test duration. A resolution of y frequencies can be achieved, for example, within a time of 2yT, where T is the sampling time.

The only limiting element in these tests is that Upstream bandwidth. Is this smaller than the downstream Bandwidth, which is generally the case, so the  Tests are repeated multiple times across all frequency ranges to illuminate separately.

The speed and flexibility of the test procedure also makes a "Fast Retrain" of xDSL data transfer procedures possible. Here, the properties of the line 2 and the subscriber line device 24 are tested while the data transmission is in operation. If, for example, there has been a change in the line parameters (on-hook / on-hook or off-hook / accepted if the subscriber is also telephoning in parallel with the data transmission), the CO modem 1 can continue to use a different set of impedance parameters and thus save time - the data transmission link does not have to be reinitialized every time short-term changes occur.

Deviations from the target values, which lead to a reduction in the usable data transmission, can with the test procedure can also be measured and documented. With the knife It is then possible to take corrective measures to restore the maximum possible data rate.

The test procedure can also be used to train xDSL data transfer procedures. The line including subscriber connection device 24 is measured precisely in order to obtain information about the signal-to-noise ratio in the different frequency ranges. These results determine how many bits can be transmitted in which frequency ranges (frequency bins) and how the "bit loading" is to be carried out. With the procedure presented here, these tests can be carried out very quickly and efficiently.

Crucial for a high bit rate data transmission by means of xDSL method is the B filter (balancing filter) that as additional component on the line card thoroughly tested  should be. The B filter is used for echo compensation the analog user interface.

FIG. 4a and FIG. 4b show the Multitonspektrum of the data received from the DSP and transmitted with activated B filters. If one forms the difference of the received data words in the frequency range on the discrete spectral lines visible in the figures, this results in the attenuation characteristic (echo reflection attenuation curve) of the B filter (FIGS . 5a to 5c).

Fig. 5a shows the characteristic attenuation curve for poorly matched RT modem.

Fig. 5b shows the characteristic attenuation curve with an optimally adapted RT modem when the entire transmission path is error-free. Deviations in the course of the curve with respect to such a reference curve can be used to infer a hardware fault or a fault in the overall transmission path.

In Fig. 5c echo reflection attenuation curves are shown with different lengths of lines and different terminations. The attenuation (specified in dB) shows strong dependencies on the line termination (impedance) and also on the line length.

The multi-tone signal used here is just one example several possible test signals. It can also do other test signals are used around the line and subscriber final properties in the frequency and time domain sen. For example, correlation measurements would be in the time domain rich or other methods of evaluating the transmission properties conceivable.

It is essential that these are loadable test patterns which are loaded onto a DSP 13 in the CO modem 1 , which then sends out the test pattern and records the returning signal and correlates it with the original in order to derive properties of the transmission path. As already described above, communication between the DSP 13 of the CO modem 1 and a DSP 27 of the RT modem 32 for measuring the individual transmission links is also conceivable.

Claims (13)

1. Method for quantitative analysis of the properties of line ( 2 ) and / or subscriber line devices ( 24 ) and for testing of office-side switching center devices ( 1 ) for hardware errors and malfunctions, characterized by the following steps:

• - Loading a test code from a memory ( 19 ) of an office-side switching center device ( 1 ) into a digital signal processor ( 13 ) of the office-side switching center device ( 1 ),
• - Generating a test signal by the digital signal processor ( 13 ) based on the loaded test code
• - Send this test signal, and
• - Evaluation of a reflected test signal for quantitative determination of the transmission properties of the transmission path traversed by the test signal.

2. The method according to claim 1, characterized, that a multi-tone signal is used as the test signal in the usable frequency band at a defined distance Sig has nal components. 3. The method according to claim 1 or 2, characterized, that a multi-tone signal is used as the test signal, wel ches in the usable frequency band at a defined distance Has signal components, and in the single signal compo be suppressed. 4. The method according to claim 1, 2 or 3, characterized in that the multitone signal is specified in the frequency domain by the test code and is generated by the digital signal processor ( 13 ) by means of inverse Fast Fourier Transformation. 5. The method according to claim 1, 2 or 3, characterized in that the multitone signal is determined by means of inverse Fast Fourier Transformation Off-Line on a personal computer, the calculated data set then being part of the code to be loaded into the digital signal processor ( 13 ) , 6. The method according to claim 1, 2 or 3, characterized in that a B filter located on the office-side switching center device ( 1 ) is activated. 7. The method according to claim 6, characterized, that from the difference between the sent and the emp catch the damping discrete spectral lines of the test signal characteristic of the B filter is determined. 8. The method according to any one of the preceding claims characterized, that from the damping characteristic of the B filter he targetable reflection loss is determined. 9. The method according to any one of the preceding claims characterized, that if there is a deviation from one with error-free transmission stretch characteristic damping curve to hardware failure ler or a fault in the total transmission path closed can be sen. 10. The method according to any one of the preceding claims, characterized in that the properties of the line ( 2 ) and the subscriber line device ( 24 ) are tested during operation of the data transmission. 11. The method according to claim 10, characterized in that when the line parameters are changed, a set of impedance parameters appropriately adapted by the office-side switching center device ( 1 ) is used. 12. The method according to any one of the preceding claims, characterized in that the subscriber line device ( 24 ) has a transmission and evaluation functionality in the form of a digital signal processor ( 27 ). 13. A method for determining line delays and for determining the transmission characteristics in the upstream and downstream direction, comprising the following steps:

• - Sending a test code to the subscriber line device ( 24 ) from the office-side exchange device ( 1 ),
• - Generating a test signal by the digital signal processor ( 27 ) of the subscriber line device ( 24 ) on the basis of the loaded test code
• - sending the test signal,
• - Evaluation of a reflected test signal for quantitative determination of the transmission properties of the transmission path traversed by the test signal.
• - Returning the test result of the subscriber line device ( 24 ) to the office-side switching center device ( 1 ).