SU832733A1 - Digital adaptive signal corrector - Google Patents

Description

(54) DIGITAL ADAPTATION 1st SIGNAL CORRECTOR.

I

. The invention relates to communication and can be used for the adaptive correction of intersymbol interference in received signal data transmitted in one and two phase planes by dual-band and single-band multi-position modulation methods.

A digital adaptive signal equalizer is known that contains a receiver, the outputs of which are connected to the first inputs, respectively, of an analog-to-digital converter, a memory block of samples of a demodulated signal, polarity, and a deviation sign of the amplitude of the output signal from the nominal, program block whose outputs are connected to such inputs , respectively, an analog-to-digital converter, a memory block of samples of a demodulated signal, polarities, and a sign of the deviation of the amplitude of the output signal from the nominal value and a correlator unit and the other input of the latter is connected to one of the signals of the memory block of the demodulated signal samples, the polarities and the sign of the deviation of the output signal amplitude from the nominal, the other input of which is connected to the analog-digital converter code and the other output of the memory block of the samples of the demodulated signal, field the sign of the output signal amplitude from the nominal value and the output of the memory block of the coefficients, one of the inputs of which is connected to the output of the correlation unit, are connected to the inputs of the arithmetic unit, output d which is connected to the input of the receiver l.

However, the known corrector provides for intersymbol interference correction in signals transmitted by dual-band modulation methods only.

Claims (1)

The purpose of the invention is to provide the possibility of adaptive correction of intersymbol interference in signals transmitted by dual-band and single-band modulation methods. This goal is achieved by the signal corrector containing the receiver, whose outputs are connected to the first inputs, respectively, of an analog-digital converter, a demodulated signal sample memory, polarities, and a deviation sign of the output signal amplitude from the nominal, program block, whose outputs connected to clock inputs, respectively, of an analog-to-digital converter, a memory block of samples of a demodulated signal, a bandwidth, and a sign of the deviation of the amplitudes of the output signal from the nominal and correlator block the other input of the latter is connected to one of the outputs of the memory block of samples of the demodulated signal, the polarities and the sign of the deviation of the amplitude of the output signal from the nominal, the other input of which is connected to the output of the analog-digital converter, and the other output of the memory block of samples of the demodulated signal, field and the sign of the deviation of the output signal amplitude from the nominal value and the output of the transfer coefficient memory unit, one of the inputs of which is connected by the output of the correlation unit, is connected to. The inputs of the arithmetic unit whose output is connected to the receiver input are entered into the modulation mode selection block, the pulse addition block, and the pulse suppression block, while the other outputs of the program block are connected to the clock inputs of the pulse addition block and the pulse exclusion block, other inputs of which are connected to the output of the modulation mode selector unit, the output of the pulse addition unit is connected to another input of the memory block of the transfer coefficients, and the output of the pulse elimination unit is connected to another input of the arithmetic unit . The drawing shows the structural electrical circuit of the proposed equalizer. The digital adaptive signal equalizer contains receiver 1, modulation mode selection block 2, analog-digital converter 3.1 block 4 of memory of samples of the demodulated 34 signal, polarity and sign of the amplitude deviation of the output signal from the nominal, block 5 of programs, block 6 of correlation, arithmetic block 7, block 8 of the memory of transmission coefficients, block 9 of the addition of a pulse and block 10 of the exception. Corrector works as follows. Depending on the modulation methods of the received signals in the corrector, the corresponding correction algorithm is implemented by the commands of block 5, as a result of which certain signals are received from block 4 to the input of block 6 where the corresponding logical operations are performed to detect intersymbol interference in the received signals. From the output of block 6 to the input of block 8, signals are first received for alternately adjusting the transfer coefficients of the regulators (not shown) of all taps via direct links, and then the signals for adjusting all taps using cross-over 4 connections. -digitary numbers go to the input of the arithmetic unit 7, and from the output of unit 4 to the arithmetic unit 7, 6-bit numbers corresponding to the samples of the received signal are supplied. The sampling process is carried out as follows. .. Analog signals from the outputs of the first and second demodulators (not shown) of receiver 1 arrive at the first; An analog-to-digital converter 3 input, in which these signals are gated at sample times, storing and storing the amplitudes of the received sampling voltages and converting these voltages into C-bit code numbers. This first converts the sampling signal from the output nejpvogo demodulator, and then - the sampling signal from the output of the second demodulator of the receiver I. In the same sequence, a record is made in block 4 of two 6-bit numbers of samples obtained as a result of the conversion. After the conversion process is completed, block 5 generates the signals necessary for operation of blocks 4 and 8 and the arithmetic unit 7. When receiving signals modulated by two-modular modulation methods, in each operation cycle of block 5 from blocks 4 and 8, two code are sent to the arithmetic unit 7 the numbers, the correspondence to the modules and fields of the coefficient of transfer coefficient of the regulator and the sample for the corresponding tap of the corrector. Moreover, first the arithmetic unit 7 receives the sample code of the first demodulator, and then the sample code of the second demodulator of the receiver 1 of the analyzed linear element of the signal to multiply by one and the same coefficient of the transmission coefficient of the regulator. The resulting products of two pairs of numbers are written by commands from block 5 to one of two adders (not shown) of arithmetic block 7 in order to sum the products separately for in-phase and quadrature samples. and following the operation cycle of block 5 from blocks 4 and 8, the code numbers corresponding to the next tap of the equalizer are supplied to the inputs of the arithmetic unit 7. The resulting works are algebraically summed in the arithmetic unit 7 with the numbers stored from the previous tact of the unit 5 for the preceding tap. This process continues as long as in accumulators arif-. The metric unit 7 did not record the sums obtained as a result of the summation of the products of the sampling codes and the transfer coefficients of the regulators for all the taps of the corrector in correcting the own mixing effect. Further, the process of multiplying the coefficient codes of the transmitters of the tap-offs and samples to effect the correction of the cross-interfering effects is repeated in the same way as in the correction of the own interfering effects. The resulting products are successively summed up in an arithmetic unit 7, Process; continues until, under the arithmetical block 7, the sums obtained as a result of summing the products of sampling codes and transmission coefficients of the regulators for all taps of the corrector nd direct and cross-linking are written. Code numbers from the outputs of the sum of the arithmetic block blocks 7 arrive in the decision block (not shown) of the receiver 1 for the purpose of their d coding and generation of corrector control signals. The modulation mode selection unit 2, in this case, generates a signal by which the blocks 9 and 10 transmit to their outputs the signals arriving at their inputs from block 5. In the process of adjusting the equalizer in block 8, such numbers of transmission coefficients are recorded for the controllers of all of its taps, at which the value of intersymbol interference is minimal. Transmission or reception of single-band signals can be considered as alternate transmission or reception of signal elements at half speed at two mutually orthogonal carrier oscillations, respectively, whose frequency is equal to the central frequency of the spectrum. In this case, the analog-to-digital converter 3 transforms from the analyzed pair of linear elements of the signal from the beginning of the sample from the output of the first demodulator and then the second, which is equivalent to the delay of the first signal by a time equal to one period of linear elements. This is necessary in order to combine in time the reading values of the demodulated signals following in turn. The process of correcting the own mixed effect in the received signals is carried out similarly to that discussed above for signals transmitted by two-band modulation methods. However, the quadrature components of the intersymbol: interference will be shifted in the same branches of the equalizer. . In order to eliminate this time offset in the arithmetic unit 7, the transmission coefficient for the cross-link controller is multiplied, for example, h-lhro tap by selecting a signal; 1a from the second demodulator for (wl) -ro tap and by sampling the signal from the output the first demodulator for the (-1} -th tap. The goal is to ensure that this multiplication is possible in block 9 by the control signals from block 2 before adding the crosshack effect to the step of adding a single pulse to the clock sequence, controlling the operation of block 8, i.e., the shift of the coefficients is shifted, which is equivalent to switching the corrector taps. Further, the multiplication and summation process in the arithmetic unit 7 is carried out in the same way as correcting signals for two-band modulation methods. There are no cross coefficients, i.e., there is no coefficient by which the signal from the output of the second demodulator can be multiplied for the latter in the cycle of operation of the block 5, it is more or less executing The impulse intended for the summations of this product, Therefore, in block 10, the control signal from block 2 excludes the last pulse from the clock sequence supplied from block 5 to the arithmetic unit 7 in order to sum up the products obtained using samples signal from the output of the second demodulator. The number of bits 6 and the capacity of blocks 4 and 8 are selected based on the required accuracy of intersymbol interference compensation and the magnitude of the initial distortion in the tonal frequency channels. The invention allows the intersymbol interference to be corrected in the received data signals transmitted by the two-band and single-band multi-position modulation methods. DETAILED DESCRIPTION A digital adaptive equalizer containing a receiver, the outputs of which are connected to the first inputs. Accordingly, the digital-electronic device, the memory block of the samples of the demodulated signal, the polarity and the sign of the amplitude deviation of the output signal from the nominal, the program block whose outputs connected to clock inputs, respectively, of an analog-digital converter, a memory block of samples of a demodulated signal, polarities, and a sign of deviation of the amplitude of the output signal from the nominal and block correlation, another input of the latter is connected to one of the outputs of the memory block of samples of the demodulated signal, the polarities and the sign of the deviation of the amplitude of the output signal from the nominal, the other input of which is connected to the output of the analog-digital converter, and the other output of the memory block of samples of the demodulated signal, polarity and the sign of the deviation of the amplitude of the output signal of the nominal value and the output of the transfer coefficient memory unit, one of the inputs of which is connected to the output of the correlation unit, are connected to the inputs of the arithmetic unit A cable whose output is connected to the receiver input, characterized in that, in order to enable adaptive correction of intersymbol interference in signals transmitted by two-way and single-sided modulation methods, a modulation mode selector unit, a pulse addition unit and a pulse elimination unit are introduced, while others the outputs of the program block are connected to the clock inputs of the pulse addition unit and the pulse elimination unit, the other inputs of which are connected to the output of the modulation mode selection unit, the output of the addition unit and The pulse is connected to another input of the memory of the transfer coefficients, and the output of the pulse elimination unit is connected to another input of the arithmetic unit. Sources of information taken into account in the examination I. US Patent 3,633,105, cl. 325-42, published. 1972 (prototype).