DE3533867C2 - - Google Patents

Description

The invention relates to a method for echo cancellation according to the preamble of claim 1.

A process of this kind (O.E. Agazzi: Large scale integration of hybrid method digital subscriber loops; dissertation University of California Berkeley, 5/20/82) meets the requirements to be placed on an echo canceller, quite close. These requirements include that because of the high sampling rate, which is twice the bit rate  of the digital signals is therefore within the cycle time 3.1 µs the smallest possible number of consecutive Operations to be handled. It is also necessary to that the digital-to-analog converter has a monotonous converter characteristic which also has only low non-linearities shows. The resolution for positive and negative signal amplitudes should be at least 12 bits including the sign bit amount for the analog-digital conversion of the Residual signal is for a short adaptation time of the echo canceller to request a resolution of up to 8 bits. Interference voltages injected via the operating voltages will or arise on the building block itself, should influence the individual functions as little as possible. Furthermore, adjustment processes that are essential Represent cost factor, be avoided. Finally is it is desirable that such an echo canceller or Analog part of the same to which the capacitor network described heard with the smallest possible chip area can be realized in CMOS technology.

Especially with regard to the monotony in the zero point range the characteristic and its linearity, as well with regard to the possibility of a space-saving The construction of the capacitor network used is the aforementioned Process cheaper than other known ones Processes operating capacitor networks. Here is z. B. a method (T.L. Mc Creary "Successive Approximation Analog-to-digital conversion techniques in MOS Integrated Circuits "Dissertation University of California, Berkeley 1975) name that works with a capacitor network, whose largest capacity is 248 times the smallest capacity amounts and in order to a sufficient monotony to achieve the converter characteristic, the capacitor with the smallest capacity should be large enough  must, however, the desire for space-saving effort runs counter to and also in terms of working speed is problematic.

A procedure should also be mentioned (O.E. Agazzi, D.G. Messerschmitt, D.A. Hodges, "Nonlinear Echo Cancelation Of Data Signals, I.C.C. 1982 Conf. record 7 G 6.1-6.5), accordingly, only the low-order ones with an A / D conversion Bits due to charge redistribution in a capacitor network be formed for the formation of the higher order In contrast, bits are a voltage divider with changeable taps is provided. The chip area and the capacitance values the capacitors used are clear here less than in the above case, because of the Use of resistors is the nonlinearity of the Conversely, the converter characteristic curve is relatively large.

In this respect, one from US Pat. No. 4,129,863 is cheaper known method in which to form the higher order Bits a charge redistribution in a capacitor network done with binary weighted capacities based on that charged the full value of a reference voltage potential and the lower-order bits, too are formed by charge redistribution, however in Connection with a network capacitor of small capacitance, depending on the binary value of the lower order bits again using a voltage divider is charged to a binary divided reference voltage.

This, as well as the other aforementioned methods, except the former method according to Agazzi, however, is liable the crucial disadvantage that they are not in the As desired, the situation is in the course of compensation to subject any remaining signal to an A / D conversion, a digital correction signal for the transversal filter  of the compensation circuit to get there there at the base of the capacitors of the capacitor network there is no neutral starting position in which all ground potential or reference voltage potential. In the method mentioned in the introduction. Agazzi is one ensures such A / D conversion because for storage a separate capacitor is provided for the signal voltage is. Such an additional capacitor that is not like that bits of a digital signal assigned to other capacitors has a capacity twice that of that capacitor assigned to the most significant bit.

However, as a calculation shows, there are tolerances, in particular of the capacitance value, this additional capacitor or deviations of its capacity value from the value of the Sum of all capacitors capacities to nonlinearities the converter characteristic and to a non-monotonous one Behavior of the D / A converter. In connection with echo cancellation this will interfere with the adaptation process causes.

The object of the present invention is therefore to to provide a method of echo cancellation that is like that The aforementioned method using a capacitor network of the specified type works, but especially regarding linearity and monotony the converter characteristic curve comes to more favorable results.

This is used to solve this task Features of claim 1 characterized method.  

Due to the procedure of the invention D / A conversion of the compensation signal, regardless of what polarity this is, no charge contributions from the Additional capacitor used. That means that Charge contributions that lead to the formation of a positive echo compensation voltage  lead from the same capacitors be delivered as in the formation of a negative Echo compensation voltage, so that the characteristic, the acc. the D / A conversion takes place, is zero-point symmetrical and even-order nonlinearities do not occur can. In the first-mentioned method acc. Agazzi is the additional capacitor in the formation of the a kind of compensation signals, namely the positive Compensation signals, involved with a charge contribution.

Also the monotony of the characteristic curve in the D / A conversion is in the inventive method because of the lack active participation of the additional capacitor in the charge redistribution cheaper than the known one mentioned above Method.

With the A / D conversion of the one with a residual echo, if applicable Result signal, which is used as a correction variable for the transversal filter the additional capacitor is on of charge redistribution may still be involved, as still will be executed, but then again independent of polarity in the same way what the elimination of non-linearities even order means.

In one embodiment of the method according to the invention is used as a criterion for the switching measure of the third step that comparator input voltage used in the corresponding rating, which according to an intermediate step following the second step results in the base points of low-value capacitors acc. a random sequence in the presence of negative echo signals at reference voltage potential or more positive if present Echo signals are applied to earth potential.  

The invention is described below using exemplary embodiments explained in more detail with reference to a drawing. The drawing shows:

Fig. 1 is a block diagram of an echo canceller,

Fig. 2a to 2f, a capacitor network, as it takes place in carrying out the method using the present invention for two different input conditions and in various operating states.

In FIG. 1, T denotes the transmission amplifier located in the transmission branch 4 T of a four-wire line and R denotes the reception amplifier located in the reception branch 4 R of this four-wire line. The branches of the said four-wire line are connected via a hybrid circuit G for the two-wire / four-wire transition by a two-wire line D 2 in combination.

Due to an insufficiently high fork attenuation of the hybrid circuit G, it can happen that information arriving on the four-wire line branch 4 T, which is intended for further transmission on the two-wire line 2 D, is partly echoed on the receiving branch 4 R of the four-wire line, so that the signals occurring there are a mixture of useful signals that come from the two-wire line 2 D and such echo signals.

The echo canceller described below is used to eliminate such echo signals. It consists here of a digital adaptive transversal filter Tr, which is acted upon by the signal arriving at the transmission branch 4 T of the four-wire line and intended for transmission on the two-wire line in order to generate a compensation signal corresponding to this signal as a digital signal. This compensation signal is converted into an analog signal by a digital / analog converter D / A. Another component of the echo canceller is a sample and hold circuit S / H, which samples the aforementioned echoed useful signal. The signal emitted by the sample and hold circuit and the compensation signal present in analog form are superimposed on one another in a subtraction circuit S in such a way that the echo component in the echo useful signal is compensated for.

Normally, however, the output signal of the subtracting circuit, which is passed on as a received signal to the receiving amplifier R and the receiving branch 4 R of the four-wire line, is still subject to residual echo. It is therefore also fed to an analog-to-digital converter A / D, which provides the transversal filter with a corresponding digital signal, which serves as a correction signal for the adaptive setting thereof, and accordingly leads to a correction of the compensation signal.

In the figure, the sample and hold circuit S / H are the Subtractor S, the digital-to-analog converter D / A and the analog-to-digital converter A / D as those parts of the echo canceller a dashed frame indicates its function with an echo canceller of the type mentioned at the beginning, so using a network of binary weighted Capacitors is built up by operating this Network can be realized.

Such a capacitor network is shown in the sub-figures of FIG. 2 in its various operating states assumed when the method according to the invention was carried out, in each case on the left-hand side if negative echo signals are present and on the right-hand side if positive echo signals are present.

Provided that with an A / D conversion with Help this network 5 bits and a sign comprehensive  This network is made up of digital words with from six capacitors C to C ′ / 16, whose capacitance from capacitor to capacitor by a factor of 2 differs, with the exception of the last two capacitors C / 16 and C ′ / 16, the capacity of which is the same. The capacitor C is the sign bit, the other capacitors are in the order of their capacity value assigned to the remaining bits of a digital word.

The capacitor network also has an additional capacitor 2 C, the capacity of which is twice as large as that of the capacitor C.

The one assignments of these capacitors, here as head points are connected to each other and to the an input of a comparator V connected, the other input is at ground potential. The other assignments of the capacitors, here called base points, are with Using switches S1 to S7 between an earth potential leading circuit point and a reference voltage Vref leading switching point switchable.

A capacitor Cs is also connected to the headpoints of the capacitors, which, depending on the switching position of a switch S8 with its other assignment, is either connected to ground potential or to the input voltage Vin, which is the echoed useful voltage mentioned in connection with FIG. 1. A switch S9 is also provided which, in the closed state, connects the top points of the capacitors to ground potential.

Only the left parts of FIGS. 2a to 2e are considered below.

At the stage shown in FIG. 2a, the switch S8 assumes such a switch position that the capacitor Cs is connected to the input voltage Vin. The switch S9 is closed, that is, it connects the top points of the capacitors of the capacitor network with ground potential.

The base point of the additional capacitor 2 C lies at the reference voltage Vref, the same applies to the base points of those capacitors which are assigned bits of a digital word having the binary value 1, that is here the capacitors C / 2 and C / 16, whereas the capacitors, the bits of the relevant digital signal word which have the binary value 0 are assigned, that is to say the capacitors C, C / 4, C / 8 and the capacitor C '/ 16 are connected to ground potential via the switches S1 to S6 in question. The mentioned digital signal word is the gem. Fig. 1 from the transversal filter Tr digital compensation signal to be subjected to a D / A conversion.

Due to the illustrated switch position of FIG. 2a is a scanning is performed on the one hand of the echo-affected useful signal, in which the capacitor Cs is charged by this voltage, whereby the function of the sample and hold circuit S / H shown in FIG. 1 is realized, on the other hand, a preparation of D / A conversion of the digital compensation signal emitted by the transversal filter.

According to FIG. 2b, in a second step of the method according to the invention, the headpoints of the capacitors are separated from earth potential by opening switch S9 and the occupancy of the holding capacitor Cs previously connected to the input voltage is connected to earth potential. Furthermore, with the exception of the additional capacitor 2 C, the base points of those capacitors which were previously connected to the reference voltage Vref are connected to ground potential. This results in a redistribution of the charge of the capacitors Cs, C / 2 and C / 16 to the entirety of the capacitors C to C '/ 16 and thus a compensation of the echo superimposed on the useful signal voltage. The voltage that results between the top points of the capacitors and ground potential and that represents the input voltage Vx of the comparator V has the value:

where US is the input signal voltage and UE is the echo signal voltage. If necessary, the base point of one or more low-order bits of capacitors assigned to the reference voltage potential is then applied according to a random address. In Fig. 2c this is the case with the capacitor C '/ 16. In this case, the input voltage Vx of the comparator V has the value:

If the input voltage of the comparator V is then greater than 0, which means the presence of undercompensation, then, as shown in FIG. 2d, the base point of the additional capacitor 2 C is connected to earth potential and left there. In further successive steps, the base points of the other capacitors in the network, starting with capacitor C, are also connected to reference potential and, depending on whether the resulting input voltage of the comparator is greater or less than 0, switched back to earth potential or left at reference potential.

If a comparator input voltage results in the operating state according to FIG. 2c, which is smaller than 0, which means the existence of an over-compensation, then in deviation from the above explanations of the foot point of the additional capacitor is left for 2 C at the reference voltage Vref. The successive steps affecting the other capacitors are handled in the same way as described.

As the representations on the right-hand side of FIGS. 2a to 2e show, if positive echo signals are present with respect to the base points of the capacitors, the meaning of earth potential and reference potential are reversed, and is also a decision criterion for the procedure according to FIGS. 2d and 2e and for the successive steps mentioned swapped the meaning of falling below and exceeding the zero value by the comparator input voltage.

The switch position of the base points of the capacitors C to C '/ 16 after the completion of these procedures then corresponds to the digital signal representation of the useful signal with a residual echo signal corresponding to the function of the device A / D in FIG. 1. From a register, not shown, whose register stages correspond to the switch positions in If the capacitor network is set accordingly, this digital signal is then fed to the transversal filter of the echo canceller as a correction variable.

Claims (2)

1. A method for echo compensation using a network of capacitors with binary gradations in their capacitance, (C to C ′ / 16), the head points of which are connected to one another and the foot points of which can be connected either to earth potential or to a reference potential (Vref), and both in the case of a digital / analog conversion of the digital compensation signals supplied by an adaptive transversal filter, and also in the case of the superimposition of such compensation signals converted to analog signals and the echoed useful signals, and also in the case of the analog-digital conversion which is processed according to the interactive method due to the compensation Resulting and possibly with a residual echo, as a digital correction signal to be fed to the transversal filter, as well as an additional capacitor (2C) that can be switched in the same way and has twice the capacitance as that of the binary graded capacitor tors (C) with the largest capacitance, the network for the useful signals being accessible via a sampling capacitor (Cs) of the same capacitance as that of the additional capacitor (2C), characterized in that
that if negative echo signals are present in a first step ( FIG. 2a), the sampling capacitor (Cs), the assignment of which is connected to the headpoints of the capacitors (C to C ′ / 16), which are at this stage at ground potential, with the echoed useful signal voltage ( Vin) is applied and the base points of the additional capacitor (2C) and those capacitors that are assigned the binary value 1 bits of the digital compensation signal (e.g. C / 2, C / 16) at reference voltage potential (Vref) and the base points of the other capacitors (C, C / 4, C / 8, C ′ / 16f) are connected to earth potential,
in a second step ( FIG. 2b), the head points of the capacitors are separated from earth potential and the assignment of the sampling capacitor (Cs) previously connected to the useful signal voltage (Vin) is connected to earth potential and, apart from the additional capacitor (2C), the base points of all capacitors are connected to earth potential if this is not already the case, if the voltage then prevailing between the head points of the capacitors and the ground potential, which represents the input voltage of the comparator (V), is greater than 0, in a third step ( Fig . 2c is placed) of the base of the additional capacitor (2C) to ground potential when the voltage is less than 0, however, left in reference voltage potential (Vref),
that in further successive steps, the base points of the capacitors, beginning with the capacitor (C) which is the most significant after the additional capacitor (2C), are each connected to the reference voltage potential (Vref) and, depending on whether the resulting input voltage of the comparator (V) is greater or less than 0 is switched back to earth potential or left at reference voltage potential (Vref), and
that in the presence of positive echo signals with respect to the base points of the capacitors, the meaning of earth potential and reference potential and as a decision criterion for the procedure according to the third and the further successive steps, the meaning of the falling below and exceeding the zero value by the comparator input voltage are interchanged. 2. The method according to claim 1, characterized in
that as a criterion for the switching measure of the third step, that comparator input voltage is used in a corresponding evaluation, which results after an intermediate step following the second step, through the base points of lower-value capacitors (e.g. C '/ 16) according to a random sequence in the presence of negative ones Echo signals at reference voltage potential (Vref) or, if positive echo signals are present, at ground potential.