SU1483662A1 - Device for reception of data signals - Google Patents

Abstract

The invention relates to telecommunications. The purpose of the invention is to increase the reception fidelity by simplifying the conversion of the data signal. The device contains an input filter 1, a demodulator 2, linear filters 3, 8 and 9, a subtractor 4, decision blocks 5, 7 and 10, storage blocks 6 and 11, and a comparison block 12. In the input signal having intersymbol interference, filter 1 limits the bands channel noise frequencies. Then, demodulator 2 extracts the modulating data signal, samples it over time and level quantization. Further, if the estimate of the transmitted digital message is accurate, then intersymbol interference is suppressed using filter 3, subtractor 4, decision block 5, and filter 8. If an error occurred while transmitting one data symbol, which further leads to error multiplication, then using filter 9 and decision block 10, independent estimates of the transmitted data symbol sequence are made. Based on the estimates obtained, such a decision is made using the storage units 6 and 11, the comparison unit 12 and the decision unit 7, which is characterized by a lower level of errors. 1 il.

Description

The invention relates to telecommunications and can be used in data transmission systems.

The purpose of the invention is to increase the fidelity of reception by simplifying the conversion of the data signal.

The drawing shows a structural electrical diagram of the proposed device.

A device for receiving data signals contains an input filter 1, a demodulator 2, a first line filter 3, a subtractor 4, a first decision block 5, a first memory block 6, a second decision block 7, a second and third 'line filters 8 and 9, a third decision block 10 , a second storage unit 11 and a comparison unit 12,

The device operates as follows | as follows.

From the output of the telecommunication channel, in which there is intersymbol interference due to linear distortions of the data signal, the input signal is fed to the input filter 1, where the noise frequency band is limited in the channel, and then to the demodulator <torus 2 with the converter, where modulating data signal; it is discretized in time and quantized in level. Further, to suppress intersymbol interference, the data signal is processed in a decision feedback equalizer (BOCP), which consists of filter 3, a subtractor 4, decision block 5, and filter 8. Such an equalizer effectively suppresses intersymbol interference if an estimate of the transmitted digital message accurate. However, if an error occurred during the transmission of one data symbol, then the solution feedback leads to the propagation of errors, i.e. at the output of the decision block 5, grouped error symbols (error packets) appear in the sequence of data symbols.

Linear processing of the data signal less effectively suppresses intersymbol interference. However, the nature of the error distribution at the output of the decision block 5, the decision in which is reduced to quantization of the aligned data signal, is more independent, i.e. the probability of errors ι side is greater than in the VOSR, but they are not grouped. The device has a second independent branch, consisting of a linear filter 9 and a decisive block 10, which makes decisions independent (with respect to BOCR) (estimation) of the transmitted sequence of data symbols. In this case, the decision made by VOSR and the decision made in a linear independent branch, at a finite time interval, the length of which should exceed the duration of the burst of errors at the output of VOSR, are memorized, respectively, by bi 11 storage blocks.

The final segments of the estimates of the transmitted message are compared in block 12 comparison. The result of the comparison (the final sequence is O and 1, where 0 corresponds to the equality of the corresponding symbols (solutions), and I to the difference) is submitted to the decision block 7, where the sequence of zeros and ones is analyzed. If the units are grouped in batches, it is decided that the output of the BOCP was propagated by errors and the estimates obtained in the linear part at the output of the decision block 10 are more accurate. In this case, the final sequence of estimates is read from the memory block 11 to the receiver output and goes to the receiver information. If the units are distributed individually or not, then the decision is made that the estimates at the output of the VOSR are more accurate, i.e. at the output of decision block 5, and from the storage block 6, the final sequence of estimates is read out. After reading from the storage unit 6 (11), the corresponding symbols are erased and new estimates (solutions) are received in their place.

Thus, based on the validity of the hypothesis of grouping errors in VOSR and independent errors in linear processing, a decision is made that is characterized by a lower level of errors, i.e. the noise immunity of such a proposed receiver is higher than the noise immunity of the VOSR or linear receiver.

Claims (1)

Claim A device for receiving data signals, containing an input filter, the output of which is connected to the input of de1483662 modulator, the output of which is connected to the input of the first line filter, the output of which is connected to the first input of the subtractor, the output of which is connected to the input of the first decision block, the output of which is through the second line filter connected to the second input of the subtractor, and the first storage unit, characterized in that, in order to increase the fidelity of reception by simplifying the conversion of the data signal, the second and third decisive b oki, a comparison unit, a second memory block and a third line filter, the output of which is connected to the input of the third decision block, the output of which is connected to the input of the second memory block, the first output of which is connected to the first input of the second critical block, the second input of which is connected to the first output the first memory block, the input of which is connected to the output of the first decision block, while the output of the demodulator is connected to the input of the third line filter, and the second outputs of the first and second memory blocks are connected ootvetstvenno to first and vto15 rum inputs of the comparator, whose output is connected to the third input of the second casting unit.