DE3719590A1 - Method for equalising digital signals - Google Patents

Abstract

In a method for equalising digital signals at the receiving end of a line section, first a positive and then a negative isolated test pulse or vice versa are transmitted at the distant receiving end of the line section, a predefined number of sample values are derived from the distorted signal which is produced in each case from the test signal and which occurs at the receiving end of the line section, a mean value is calculated in each case from the temporally identical sample values of both distorted signals following inversion of one of them and the mean values are stored in a coefficient memory and serve to correct the digital signals.

Description

The invention relates to a method for equalization of digital signals on the receiving side of a Line section, with a disturbed for correction Digital signals based on signal impulses controllable first memory, which correction signal instantaneous values contains, the memory content for Formation of the correction signal, which is used with the distorted digital signal is linked.

Such a method is already known. So will in EP-PS 00 19 194 a digital telecommunications system with described at least one four-wire line section, in which a read-only memory for signal equalization Current values of only one equalization signal are encoded saves and when activated to everyone Received signal pulse towards the individual instantaneous values in its coded representation feeds the decoder, which of them corresponds to one and the same, to be added to the distorted received signal pulses Equalization signal forms. Measures to generate the Correction signal instantaneous values can be the above Do not remove the patent specification.

The object of the invention is now a Process for generating these correction signal instantaneous values specify.

This task is solved in that on the (distant)  Sending side of the line section initially a positive one and then a negative isolated test pulse or vice versa is sent out from the respective on the reception side of the line section arising from the test signal distorted signal a predetermined number of samples it is determined that each time from the same Sample value of both distorted signals of the two test pulses an average is calculated after inverting one and that the mean values in a coefficient memory which are used to correct the digital signals serve.

By the method according to the invention still in a modified learning process Offset error of those in the line section Devices, such as amplifiers, are taken into account.

A further development of the invention is that only the the maximum value of the distorted signal following samples in the Coefficient memory can be saved.

The evaluation of the samples takes place in that first the maximum value is determined and then only that samples following formation of the maximum value of the mean values are taken into account.

A further development of the invention also consists in that the output signals in a buffer be written, which has as many storage spaces has how samples exist in the first memory are, the last digital signal arriving entered and the longest in the clipboard included digital signal is deleted that between two successive digital signals all in Digital signals contained in the buffer be fed to an arithmetic unit, which from the respective digital signal and the corresponding Mean values from the coefficient memory the respective Sum calculated in the context of a folding operation,  which serves to correct the input signal.

To perform the folding operation in the arithmetic unit the mean values from the coefficient memory and the symbol sequence stored in the buffer fed. A correction signal is then in the arithmetic unit calculates which is subtracted from the input signal. The corrected signal is then made after the decision sent out on the four-wire line in the outgoing direction.

Further advantages result from the subclaims.

The invention is based on an embodiment explained in more detail, which is shown in the drawing. It shows:

Fig. 1, an apparatus for equalization in the reverse direction of a four-wire portion,

Fig. 2 shows the block diagram for the device for equalization and

Fig. 3 shows the pulse shape of a distorted signal caused by a test signal.

In Fig. 1, a four-wire line section with a forward direction and a reverse direction v is shown r. A device for equalization EZ is looped in in the reverse direction. The digital signals arrive at input E and are sent to the line after a corresponding correction at output A. At the same time, the output signals are fed to the input EG of the device for equalization EZ . Furthermore, a control device ST , for example in the form of a microprocessor, is connected to the device EZ .

In the idle state of the line system, ie when no signals appear on the lines, or the synchronization words for frame synchronization, the control device ST of a device for equalization EZ at the other end of the line is caused to send out test signals. The test signal emitted by the remote device EZ reaches the device EZ under consideration. Here, as will be explained in detail below, the support values are obtained, which are obtained by sampling the distorted signal. These base values are stored in a so-called coefficient memory.

To avoid offset errors, a positive test signal is sent first, followed by a negative test signal or vice versa from the remote location. The respectively temporally identical samples of the two digital signals are taken into account by averaging the received signal of the negative test signal after an inversion together with the digital signal of the positive test signal. This mean value is then stored in the coefficient memory. It is also conceivable to send out several positive or negative test signals one after the other and then to form mean values from them in the manner already described, as a result of which the influence of interference signals can be avoided. It is also conceivable to carry out the transmission of test signals at regular intervals in order to detect long-term changes in the transmission system. The test signals are sent out by a free device, not shown, at the instigation of a control device ST . B. the control device ST of the device EZ under consideration calculates the base values.

The digital signals are equalized in that the symbol sequence created at the output A of the device ES is fed to the input EG of the device EZ . It is assumed that digital signals are transmitted on the four-wire line sections under consideration, for example in a binary, ternary or also quaternary code. As already mentioned, the signal E to be equalized is fed to the input E of the device EZ . A correction signal is then generated in the device EZ , which is calculated from the incoming symbol sequence and the content of the coefficient memory and subtracted from the value of the data word currently stored. The same is then sent out at output A of device EZ ( FIG. 1).

The structure and the mode of operation of the device EZ are described on the basis of the block diagram according to FIG. 2. The symbol sequence emitted at output A reaches the two shift registers SR via input EG . In the embodiment according to FIG. 2, it is assumed that the symbol sequence is transmitted in a ternary or quaternary, in which case two shift registers are required for the representation of the three or four possible states of a symbol.

The symbols travel through the shift registers SR in such a way that the newest symbol is entered and the symbol which has been in the shift registers for the longest time is deleted. In the exemplary embodiment, it is assumed that the shift registers SR each have 23 steps.

The coefficient memory KSP has as many memory locations as the scanning steps are taken into account. In the present example it is assumed that there are 23 sampling steps. During the transmission period of a symbol, the address generator AG successively generates the addresses for controlling the memory locations of the coefficient memory KSP and the control signals for the two multiplexers M , which successively scan the individual memory locations of the shift register SR . The outputs of the multiplexers M are connected to a switch S , which feeds the contents of the shift register SR sampled by the multiplexers M to the arithmetic logic unit RW . The control processes described run in such a way that, at the same time as the mean value of a base value read out from the coefficient memory KSP is present, the relevant symbol information is supplied from the shift registers to the arithmetic unit RW , so that the corresponding mean value of the base value is available there for an arithmetic operation . B. the mean value of the base value of the first sampling step and the information of the associated symbol. At the same time, the arithmetic unit RW contains the last data word that was transmitted from the four-wire output branch to the input E. A convolution operation is now carried out in the arithmetic unit during the dwell time of the data word, the content of all the memory locations of the coefficient memory KSP being read out one after the other and made available to the arithmetic unit and at the same time the content of all the memory locations of the two shift registers RS being made available in succession. The correction value calculated here is subtracted from the data word last arrived. The corrected, ie equalized, digital signal is available at output A.

Since in the baseband transmission considered here (ie modulation-free transmission) the line can be described almost completely by a linear, time-invariant (slow-time variant) and asymtotically stable (h (t) ≈0 for t ( M + V + 1) T _S transmission system, applies for the distorted digital signal:

Here the coefficients correspond to h _μ , µ = - v , - v +1,. . . , 0,. . . , the base values of the discrete distorted impulse response, which is composed of v +1+ M base values, ie v forerunners, the main value and M backers. Therefore, by subtracting the estimated values calculated in the arithmetic unit RW

the received signal component U _nq (k) caused by the pulse word followers is compensated. This solution is particularly advantageous for binary and ternary line codes, since then according to Eq. (2) Instead of hardware-intensive multiplications, only additions and subtractions have to be carried out.

The arithmetic unit thus works as a digital transversal filter. Here, a (k) represents a binary, ternary or also quaternary symbol sequence obtained from coding from the binary transmission data.

In the distorted digital signal shown in FIG. 3, which, as already described, has been generated by a test pulse, the individual sample values are designated V, HW, N 1 , N 2 , etc. After inverting the samples of the received signal caused by the negative test pulse, a mean value is formed from the respectively simultaneous sampling steps of the received signals of a positive and a negative test pulse, or an average value is generated from the received signals caused by a sequence of positive and negative test pulses formed, which is stored in the coefficient memory KSP . Since a correction value must be calculated during the dwell time of a data word to be corrected in the arithmetic unit RW (see FIG. 2) by means of the content of all memory locations of the coefficient memory KSP and the content of the shift register SR in the arithmetic unit, in order to avoid high implementation costs in parallel processing or To avoid a high processing speed in serial processing, the number of memory locations of the coefficient memory KSP and the length of the shift register SR and thus the number of filter coefficients to be used in the calculation are limited.

Non-eliminable intersymbol interference by impulse response followers occurs when the number N of coefficients of the equalization device EZ is smaller than the number Mv -1 of the impulse response support values h / μ to be taken into account for a given A / D converter resolution. For N < Mv -1, non-eliminable base values impair the detection. In this case, a significant improvement can be achieved with a suitable autocorrelation function of the coded symbol sequence (for example AMI code, PST, etc.) and cosine-square-shaped or similar transmission pulse shapes by multiplying the measured base values h / µ with a very simple, suboptimal window function w :

c _µ = w _µ · h _µ

w _µ decreases linearly in the range N - L + α µ < N , ie in a modified form it represents the Bartlett function known from the digital filter design. Simulations and measurements have shown that the best results can be achieved if the windowed filter impulse response decays to the value - K , K <0 and not to zero, ie with respect to w _{N -1} the condition w _{N -1} · | h _{N -1} | ≈ K can be satisfied. The required phase shift α is obtained by rounding the expression K · L / | h _{N -1} | -1.

Only the followers N 1 , N 2 , N 3 etc. are taken into account in the base values, the forerunners V and the main value HW are disregarded. When evaluating the distorted reception signals resulting from the test signals, the main value is first determined; then only the samples following this are used for averaging.

Claims (8)

1. Method for equalization of digital signals on the reception side of a line section with a first memory which can be controlled for correction of disturbed digital signals in accordance with signal pulses and which contains correction signal instantaneous values, the memory content being used to form the correction signal which is associated with the distorted signal is linked, characterized in that first a positive and then a negative isolated test pulse is emitted on the (remote) transmission side of the line section, or vice versa, that from the distorted signal arising on the reception side of the line section from the test signal, a predetermined number of samples it is determined that a mean value is calculated from the temporally identical sample value of both distorted signals of the two test pulses after inverting the one and that the mean values, which are used to correct the digital signals, are stored in a coefficient memory (KSP) earth. 2. The method according to claim 1, characterized in that only the sample values following the maximum value of the distorted signal are stored in the coefficient memory (KSP) . 3. The method according to claim 1 or 2, characterized, that several times in a row positive and negative Test pulses are sent out by each a mean value for the same samples in time Entry in the memory is formed. 4. The method according to any one of claims 1 to 3, characterized in that the output signals are written into a buffer (ZSP) which has as many memory locations as there are sample values in the first memory, the last digital signal arriving being entered and that the digital signal contained in the buffer (ZSP) longest is deleted so that between two successive digital signals, all the digital signals contained in the buffer (ZSP) are fed to an arithmetic unit, which consists of the respective digital signal and the corresponding mean values from the coefficient memory (KSP) calculates the respective sum in the context of a convolution operation which is used to correct the input signal. 5. The method according to claim 4, characterized in that the buffer (ZSP) is formed from one or more shift registers. 6. The method according to any one of claims 4 or 5, characterized, that with a binary coding of the transmission data Shift registers and at a ternary or quaternary coding two shift registers etc. available are. 7. The method according to any one of claims 4 to 6, characterized in that the individual memory locations of the buffer (ZSP) are scanned by one or more multiplexers (MX) . 8. The method according to any one of claims 1 to 7, characterized in that the number of samples or the mean values in the first memory (KSP) is limited by using a window function.