RU2558375C2 - Apparatus for controlling data transmission via radio link - Google Patents

Abstract

FIELD: physics, computer engineering.

SUBSTANCE: invention relates to computer engineering and can be used in message switching nodes of a data transmission network of an automated control system when controlling transmission of data via a multipoint broadcast channel. The technical result is high quality of controlling data transmission in a radio link. Said result is achieved in an apparatus for controlling data transmission via a radio link, which includes a report storage unit, a switching matrix, first and second report processing units, a unit for determining a report of the desired rank and logic AND and OR elements.

EFFECT: apparatus for controlling data transmission via a radio link provides fast processing of a signal sample obtained when testing a radio link to obtain statistical characteristics of the radio link and therefore high quality of controlling data transmission in a radio link.

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Description

The invention relates to computer technology and can be used in switching nodes of messages (packets) of a data transmission network (PD network) of an automated control system (ACS) when controlling data transmission over a broadcast multi-point radio channel.

A device is known for controlling data transmission over a radio channel (AS USSR No. 1162016.16, IPC5 H04L 7/00, 1985), comprising a synchronizer and a first AND element in series, as well as a delay element, an OR element, and a counter and a trigger connected in series a transmission cycle, a random number generator, a comparison unit and a transmission enable trigger, as well as a second AND element and a pulse shaper connected in series, which allows increasing the utilization of the channel capacity. However, this device does not have a sufficient transmission rate over the air; there are no means for processing a sample of test signals in the device.

The closest in technical essence and the functions performed to the claimed one is a device for controlling data transmission over a radio channel (AS USSR No. 1319298, IPC5 H04L 7/00, published 23.06.87), containing a random number generator, synchronizer, counter, the first element And, the first input of which is the control input of the device, the RS-trigger, the second element And, the comparison unit, and the output of the synchronizer is connected to the input of the counter and the first input of the second element And, the group output of the counter is connected to the counting input of the comparison unit, input d random numbers which is connected to the group output of the random number generator, the output of the first element And is connected to the input of the random number generator and the zero input of the RS-trigger, the output of which is connected to the second input of the second element And, the output of which is connected to the second input of the first element And, the output the comparison unit is connected to a single input of the RS-trigger. The device provides an increase in the speed of information transmission over the air.

However, the prototype device does not provide sufficient bandwidth, since it does not implement accelerated processing of a sample of test signals to obtain statistical characteristics of the radio channel.

The aim of the invention is to improve the quality of control of data transmission in the radio channel.

This goal is achieved in that the control device for transmitting data on a radio channel containing a random number generator, a synchronizer, a counter, a first element And, the first input of which is the control input of the device, an RS trigger, a second element And, a comparison unit, and the output of the synchronizer is connected to the counter input and the first input of the second element AND, the group output of the counter is connected to the counting input of the comparison unit, the random number input of which is connected to the group output of the random number generator, the output of the element And is connected to the input of the random number generator, the output of the first element And is connected to the input of the random number generator and the zero input of the RS-trigger, the output of which is connected to the second input of the second element And, the output of which is connected to the second input of the first element And, the output of the comparison unit is connected with a single RS-trigger input, a third AND element, a sample storage block, a switching matrix, n separation blocks, first and second sample processing blocks, an OR element and a block for determining the desired rank are additionally introduced moreover, the first information input of the sample storage unit is the information input of the device, n outputs of the sample storage unit are inputs of a switching matrix, n-1 pairs of outputs of which are connected to the corresponding inputs of n-1 separation blocks, the first outputs of which are connected to n-1 inputs of the first block processing of samples, and the second outputs are connected to n-1 inputs of the second block of processing samples, while the clock inputs of the first, second blocks of processing samples and the block determining the count of the desired rank are connected to m output of the sample storage unit, and the information outputs of the first and second sample processing units are connected to the second and first inputs of the OR element, respectively, the output of which is connected to the second information input of the sample storage unit, while the counting output of the first sample processing unit is connected to the first counting input of the block determining the count of the desired rank, and the counting output of the second block of processing samples is connected to the second counting input of the block of determining the count of the desired rank, the first and second signal the outputs of which are connected to the signal inputs of the second and first samples processing units, respectively, and the first and second group control outputs of the sample determination unit of the desired rank are connected to the group control inputs of the first and second samples processing units, the third signal output of the sample determination unit of the desired rank is connected to the second input the third element And, the first input of which is connected to the output of the comparison unit, the output of the third element And is the control output of the device, the fourth signal The output of the unit for determining the count of the desired rank is connected to the signal input of the unit for storing the samples, and the code output of the unit for determining the count of the desired rank is the code output of the device.

Thanks to a new set of essential features, through the introduction of a sample storage unit, a switching matrix, separation blocks, a first and second sample processing unit, a unit for determining the required rank, a third AND element, and an OR element, accelerated processing of the signal sample obtained during testing of the radio channel is provided to obtain statistical characteristics radio channel and, accordingly, improving the quality of data transfer control in the radio channel.

The analysis of the prior art made it possible to establish that analogues that are characterized by a combination of features that are identical to all the features of the claimed technical solution are absent, which indicates compliance of the claimed invention with the condition of patentability “novelty”. Search results for known solutions in this and related fields of technology in order to identify features that match the distinctive features of the claimed object from the prototype showed that they do not follow explicitly from the prior art. The prior art also did not reveal the popularity of the impact provided by the essential features of the claimed invention, the transformations on the achievement of the specified technical result. Therefore, the claimed invention meets the condition of patentability "inventive step".

The inventive device is illustrated by drawings, which show:

Figure 1 - Functional diagram of a control device for transmitting data over the air;

Figure 2 - Scheme of the block storage samples;

Figure 3 - Diagram of the switching matrix;

Figure 4 - Diagram of the separation unit;

5 is a diagram of a first sample processing unit;

6 is a diagram of a second sample processing unit;

7 is a block diagram of the determination of the count of the desired rank;

Fig. 8 is a diagram of a random number generator;

Fig.9 is a diagram of an electronic key;

Figure 10 - Diagram of the pulse distributor.

The inventive control device for transmitting data over the air, shown in figure 1, consists of: a random number generator 1, synchronizer 2, the first element And 3, counter 4, RS-trigger 5, the second element And 6, the comparison unit 7, the third element And 8, a storage unit for samples 9, a switching matrix 10, separation units 11 ₁ -11 _m , a first processing unit for samples 12, a second processing unit for samples 13, an OR element 14, and a unit for determining a sample of the desired rank 15. The first input of the first element And 3 is the control device input. The output of the synchronizer 2 is connected to the input of the counter 4 and the first input of the second element And 6. The group output of the counter 4 is connected to the counting input of the comparison unit 7. The input of random numbers of the comparison unit 7 is connected to the group output of the random number generator 1. The output of the first element And 3 is connected to the input of the random number generator 1 and the reset input R of the RS-trigger 5. The input of the installation S of the RS-trigger is connected to the output of the comparison unit 7 and the first input of the third element And 8. The output of the second element And 6 is connected to the second input of the first element And 3. RS output -t rigger 5 is connected to the second input of the second element And 6. In this case, the n outputs of the sample storage unit 9 are inputs of the switching matrix 10. n-1 pairs of outputs of the switching matrix 10 are connected to the corresponding inputs of n-1 of the separation blocks 11. The first outputs of the separation blocks 11 are connected with p-1 inputs of the first sample processing unit 12, and the second outputs are connected to n-1 inputs of the second sample processing unit 13. In this case, the clock inputs of the first 12, second 13 samples processing units and the sample determination unit of the desired rank 15 are connected to the clock the output of the sample storage unit 9. The information outputs of the first 12 and second 13 samples processing units are connected to the second and first inputs of the OR element 14, respectively. The output of the OR element 14 is connected to the second information input of the sample storage unit 9. In this case, the counting output of the first sample processing unit 12 is connected to the first counting input of the sample determination unit of the desired rank 15, and the counting output of the second sample processing unit 13 is connected to the second counting input of the determination unit counting the desired rank 15. The first and second signal outputs of the block determining the counting of the desired rank 15 are connected to the signal inputs of the second 13 and the first 12 blocks of processing samples, respectively. The first and second group control outputs of the sample determination unit of the desired rank 15 are connected to the group control inputs of the first 12 and second 13 samples processing units. The third signal output of the reference determination unit of the desired rank 15 is connected to the second input of the third element And 8. The first input of the third element And 8 is connected to the output of the comparison unit 7. The output of the third element And is the control output of the device. The fourth signal output of the reference determination unit of the desired rank 15 is connected to the signal input of the sample storage unit 9. The code output of the reference determination unit of the desired rank 15 is the code output of the device.

The sample storage unit is designed to store samples of a signal sample in a parallel code until they are processed (including subsequent iterations). Can be implemented in accordance with the circuit shown in figure 2. It consists of a clock generator 9.1, a first element OR 9.2, a code converter 9.3, a second element 9.4, a short pulse shaper 9.5, an RS flip-flop 9.6, a counter 9.7, a third element OR 9.8, a decoder 9.9, electronic keys 9.10 ₁ -9.10 _n , shift registers 9.11 ₁ -9.11 _n .

The switching matrix is designed for switching sample samples to the corresponding inputs of the separation blocks. Can be implemented in accordance with the circuit shown in figure 3.

The separation unit is designed to implement the procedure of comparing two samples of a signal sample and transmitting the compared sample to one of the sample processing units. Can be implemented in accordance with the circuit shown in figure 4. It consists of a comparison unit 11.1 and the first and second electronic keys 11.2 and 11.3.

The first sample processing unit is intended for the formation and intermediate storage of a sequence of sample samples having a rank lower than the rank of the first sample in the sequence. Can be implemented in accordance with the circuit shown in figure 5. It consists of a pulse distributor 12.1, first shift registers 12.2 ₁ -12.2 _m , first elements OR 12.3 ₁ -12.3 _m , electronic keys 12.4 ₁ -12.4 _m , delay elements 12.5 ₁ -12.5 _m , second shift registers 12.6 ₁ -12.6 _m , second elements OR 12.7 ₁ -12.7 _m , elements AND 12.8 ₁ -12.8 _m , the first 12.9 and second 12.10 multi-input OR elements.

The second sample processing unit is intended for forming and intermediate storage of a sequence of sample samples having a rank higher than the rank of the first sample in the sequence. Can be implemented in accordance with the circuit shown in Fig.6. It consists of the first shift registers 13.1 ₁ -13.1 _m , the first elements OR 13.2 ₁ -13.2 m, the delay elements 13.3 ₁ -13.3 _m , the second shift registers 13.4 ₁ -13.4 _m , the second elements OR 13.5 ₁ -13.5 _m , the elements AND 13.6 ₁ -13.6 _m and multi-input element OR 13.7.

The unit for determining the count of the desired rank is designed to control the process of processing a sample of the signal and finding the count of the required rank. Can be implemented in accordance with the circuit shown in Fig.7. It consists of the first 15.1, second 15.5 and third 15.15 counters, the first 15.2 and second 15.12 short pulse shapers, the first 15.3 and second 15.13 RS triggers, the first 15.4, the second 15.11 and the third 15.14 electronic keys, the first 15.6 and second 15.16 decoders, binary adder 15.8, delay element 15.9, comparison circuit 15.10, OR element 15.18.

The random number generator 1 is intended for random selection of the moment the transmission begins. Can be implemented in accordance with the circuit shown in Fig. 8. It consists of p D-flip-flops (elements 1.1 ₁ -1.1 _p ) and p noise generators (elements 1.2, -1.2 _p ). Clock inputs From all D-flip-flops are combined and are the input of the block. The information inputs D of D-flip-flops are connected to the outputs of noise generators 1.2 ₁ -1.2 _p . The outputs of the D-flip-flops 1.1 ₁ -1.1 _p are the group output of the block.

Noise generator 1.2 ₁ -1.2р is designed to generate output voltages randomly changing in time and is described -Elements of electronic devices. / B.I. Short, - M .: Radio and communications, 1988, fig. 7.24, p. 107.

D-flip-flops 1.1 ₁ -1.1 _p described - Fundamentals of pulsed and digital technology / Ed. AM Sidorova, - SPVVIUS, 1995, p. 90-91.

Synchronizer 2 is a clock generator and is described - Microcircuits and their application: Handbook / 1984, p.213, Fig.7.6. It can be implemented on integrated circuits (ICs) of the 511, 176 series.

Counter 4 is described - Radio Magazine, 1987, 1, p. 43. It can be implemented on the IC KA561IE15b (counter with a variable division ratio).

Comparison unit 7 is described - Pulse digital devices / I.O. Lebedev, A.M. Sidorov. - L .: YOU, 1980, p. 51, fig. 2.33, 2.34. It can be implemented on the IC series 133, 564.

Clock generator 9.1 is described - Microcircuits and their application: Handbook / 1984, - p.213, Fig.7.6. It can be implemented on integrated circuits (ICs) of the 511, 176 series.

Counters 9.7, 15.1, 15.5, 15.15 are known and described - Fundamentals of pulse and digital technology / Ed. A.M. Sidorova, - SPVVIUS, 1995, Fig. 5.38, p. 169-172.

Shift registers 9.11, 12.2, 12.6, 13.1, 13.4 are known and described - Fundamentals of pulsed and digital technology / Ed. A.M. Sidorova, - SPVVIUS, 1995, Fig. 5.28, p. 158-159.

Pulse shapers 9.5, 15.2, 15.12 are known and described - Fundamentals of digital technology. / L.A. Maltseva, - M .: Radio and communications, 1986, - fig. 21, p.30.

Logic elements And 12.8, 13.6 are known and described - Fundamentals of digital technology / L.A. Maltseva, E.M. Fromberg. - M .: Radio and communications, p.30-31. They can be implemented on the IC series 133 and 564.

Logic elements OR 9.2, 9.4, 9.8, 12.3, 12.7, 12.9, 12.10, 12.11, 13.2, 13.5, 13.7, 13.8, 15.18 are known and described - Fundamentals of pulse and digital technology / Ed. A.M. Sidorova, - SPVVIUS, 1995, Fig. 2.4, p. 39-41.

RS-flip-flops 9.6, 15.3, 15.13 are known and described - Microcircuits and their application: Reference manual / V.A. Batushev, V.N. Veniaminov, V.G. Kovalev et al. - M.: Radio and Communications 1984, - p. 122, Fig. 4.16. They can be implemented on the IC series 133, 564.

Comparison blocks 11.1, 15.10 are known and described - Popular digital circuits: a reference. / V.L. Shilo, - Chelyabinsk: Metallurgy 1989, - p. 261.

Delay elements 12.5, 13.3, 15.9 are known and described - Digital Integrated Circuits: Reference. / P.P. Maltsev et al., M.: Radio and Communications, 1994, p. 52.

Decoders 9.9, 15.6, 15.16 known and described - Popular digital circuits. Reference book / V.L. Shilo, - M.: Radio and Communications, 1987, Fig. 1.95, p. 130-142.

Code converter 9.3 is known and described - Shilo V.L. Popular Digital Chips: A Guide. 2nd ed. - Chelyabinsk: Metallurgy, 1989, fig. 2.52a, p. 246-250.

Binary adder 15.8 is known and described - Fundamentals of pulsed and digital technology / Ed. A.M. Sidorova. - St. Petersburg: SPVVIUS: 1995, - Fig.5.5, p.137-139.

Electronic keys 9.10, 11.2, 11.3, 12.4, 15.4, 15.11, 15.14 can be implemented in accordance with the circuit shown in Fig.9.

The pulse distributor 12.1 can be implemented in accordance with the circuit shown in Fig.10.

The invention consists in the following.

For robust methods of processing data of testing radio channels implemented in radio communication systems, the main operation is to find a sample reference with a given rank. Known methods for solving this problem require a large number of comparisons and, accordingly, time-consuming. In the inventive device, the calculation of the rank of the first sample in the sample is carried out by comparing with all other samples. In subsequent iterations for samples that obviously do not satisfy the given conditions, the rank is not calculated. When a reference is found that potentially satisfies the conditions, its rank is calculated, and if the condition is not met, the search limits are narrowed. In this case, the cost of calculating the rank decreases linearly with a decrease in the uncertainty interval.

Implemented in the inventive device algorithm for finding a sample of a sample with a given rank allows you to reduce the number of comparisons from 500000 to 5000 (with a sample size of 1000 samples).

The functional diagram of a device that implements the described functions of the control of data transmission over the air is shown in figure 1.

The claimed device operates as follows.

When you turn on the power (power scheme is not shown), trigger 5 is set to the storage mode of the logical unit. Synchronizer 2 generates pulses with a time interval equal to the duration of the packet transmission interval, while pulses are fed to the first input of the second element And 6 and to the clock input of counter 4, causing a sequential change of code combinations at the output of counter 4 (the number of code combinations is equal to the number of "windows" in the transmission cycle).

When it becomes necessary to transfer a packet to the control input of the device, a transmission request signal is received (in the form of a logical unit level). In this case, the next signal from the output of the synchronizer 2 (in the form of a single pulse) through the open second element And 6 is fed to the control input of the first element And 3. Since the first element And 3 is opened at the signal input by the signal of the transfer request, a single pulse from the output of the first element And 3 goes to the input R of trigger 5, turning it into a zero state, and also to the control input of the random number generator 1, which issues a code combination corresponding to the window number to the second signal input of the comparison unit 7 in the transmission cycle selected for transmission of the packet. In this case, trigger 5 closes the second element And 6.

At the moment of coincidence of the code combinations at the first and second inputs of the comparison unit 7, the latter generates a “Transmission permission” signal in the form of a single pulse through the open third element And 8 (the third element And 8 is open if the algorithm for finding the reference sample of test signals is completed) to the control output device, and also puts trigger 5 in single mode (the signal "Transfer Request" is removed from the control input of the device). Thus, the device is ready to transmit the next packet.

Samples in the serial code are received from the ADC at the first information input of the sample storage unit 9, where they are written in the parallel code in the corresponding shift registers. After that, these samples in parallel code also go to the corresponding inputs of the switching matrix 10, which provides the switching required for pairwise comparison of these samples with the first of them.

From the outputs of the switching matrix 10, pairwise grouped samples (1-2, 1-3, 1-4, ..., 1-n) are fed to the inputs of the respective separation units 11 ₁ -11 _n , in which the comparison operations are performed and, ultimately, the determination of all samples larger or smaller than the first sample in the sample.

During the first iteration, the entire set of sample samples is divided into two groups with respect to the first sample sample with rank r ₁ . All samples having a rank less than r ₁ are recorded and stored in the first sample processing unit 12. Accordingly, all samples having a rank greater than r ₁ are recorded and stored in the second sample processing unit 13.

At the same time, in the block for determining the count of the desired rank 15, the rank of the first reference r ₁ is compared with the rank that is the desired (r _claim ). Depending on the outcome of the comparison, further work is done either with data stored in block 12, or with data stored in block 13.

For example, if r ₁ <r is a _claim , then the samples stored in block 13 (whose rank is greater than r ₁ ) are read in a sequential code to the second information input of the block of storage of samples 9 (respectively, in block 12, the data of processing the samples are reset).

Next, the second iteration of finding a reference with a given rank is performed (the number of samples recorded in the shift registers of block 9 can be from 0 to n-1).

Ultimately, after the completion of the last iteration, the code combination corresponding to the found sample with the desired rank comes from the output of block 15 to the code output of the device, while a signal with a logic level appears on the third signal output of block 15, which opens the third AND 8 element on the second input , the signal “Transfer Permission” is sent to the control output of the device.

Block storage samples 9, a functional diagram of which is shown in figure 2, operates as follows.

At the first iteration, the sampling samples come from the ADC to the first information input of block 9 and then through the first element OR 9.2 to the information input of the code converter 9.3. The clock input of the code converter 9.3 receives a sequence of clock pulses from the clock generator 9.1. At the same time, at the output of the code converter 9.3 with a frequency of 1 / n in the parallel code, code combinations appear corresponding to the received sample samples. Since all combinations corresponding to the readings are nonzero, the logical unit signal periodically appearing at the output of the second OR element is fed to the input of the pulse shaper 9.5, which transfers the RS-trigger 9.6 into the logical unit storage mode with a short pulse. In turn, trigger 9.6 delivers a signal with the level of a logical unit to the counting input of binary counter 9.7. In this case, the code combination coming from the output of the counter 9.7 to the input of the decoder 9.9 causes the appearance of a signal with the level of a logical unit at one of its n outputs. This signal is fed to the control input of one of the n electronic keys 9.10 and ensures the passage of the code combination of this sample from the output of the code converter 9.3 to the input of the corresponding shift register 9.11. At the same time, the code combination from the output of counter 9.7 causes the output of the third element OR 9.8 to output a signal with a logic unit level, which puts the RS flip-flop 9.6 into logical zero storage mode (until the next code combination corresponding to the next sampling sample appears at the output of the code converter 9.3).

The separation unit 11, the functional diagram of which is shown in figure 4, operates as follows.

From the outputs of the switching matrix 10 to the first (A) inputs of all comparison blocks 11.1, a code combination of the sample, the first in the sample of samples of test signals, is received. The second (B) inputs of all comparison blocks 11.1 receive the corresponding code combinations of the remaining samples of the sample. If the current sample is greater than the first (A <B), then a signal with a logic level from the output "A <B" of the comparison unit 11.1 opens the electronic key 11.3, while the code combination of the sample in the parallel code goes to the second sample processing unit 13. Otherwise case (A> B, that is, the current sample is less than the first), the electronic key 11.2 is opened, and the code combination of the sample enters the first sample processing unit 12.

The first sample processing unit 12, the functional diagram of which is shown in FIG. 5, operates as follows.

As a result of processing the sample of test signals in the separation blocks 11 ₁ -ll _m (mn-1), some combinations of all sample samples with a rank lower than the rank of the first sample sample r ₁ will be recorded in some shift registers 12.2 ₁ -12.2 _m . In this case, the remaining shift registers will be empty. To determine the number of samples recorded in the shift registers of the first sample processing unit 12, the pulse distributor 12.1 generates in a cycle the signals with the level of a logical unit in turn to the control inputs of electronic keys 12.4 ₁ -12.4 _m .

If a code combination is recorded in the corresponding shift register 12.2 _i , then it is supplied through the corresponding electronic key 12.4 _i in the parallel code to the inputs of the multi-input element OR 12.10 and causes (since it is non-zero) the signal with the level of a logical unit to appear briefly at the output of this element OR 12.10 entering further into the block for determining the count of the desired rank 15. Polling an empty register shift does not produce such a signal. Therefore, in block 15, from block 12, there will be as many signals with a logical unit level as many sample samples have a rank less than r ₁ .

At the same time, all code combinations of the samples go to the inputs of the corresponding shift registers 12.6 ₁ -12.6 _m and to the corresponding elements OR 12.7 ₁ -12.7 _m , causing signals with a logic level to appear at the first inputs of the corresponding elements AND 12.8 ₁ -12.8 _m

Further, depending on the decision taken by the determination unit of the desired rank 15, either the contents of the shift registers 12.1 ₁ -12.1 _{m are} reset (by a signal with the level of a logical unit coming from block 15 to the signal input of the first processing unit of samples 12), or the second iteration of processing of samples begins why the signals coming to the group control input from block 15 with the level of a logical unit provide sequential reading of all code combinations of samples stored in the first processing unit o counts 12 (that is, a shortened sequence of samples), through the element OR 12.9 and the element OR 14 (figure 1) in the storage unit of samples 9.

The second sample processing unit 13, the functional diagram of which is shown in Fig.6, operates as follows.

As a result of processing the sample of test signals in the separation blocks 11 ₁ -11 _m (m = n-1), code combinations of all sample samples with a rank greater than the rank of the first sample sample r ₁ will be recorded in some shift registers 13.1 ₁ -13.l _m .

At the same time, all code combinations of the samples go to the inputs of the corresponding shift registers 13.4 ₁ -13.4 _m and to the corresponding elements OR 13.5 ₁ -13.5 _m , causing signals with a logic level to appear at the first inputs of the corresponding elements AND 13.6 ₁ -13.6 _m .

Further, depending on the decision taken by the determination unit of the desired rank 15, either the contents of the shift registers 13.4 ₁ -13.4 _{m are} reset (by a signal with a logic level coming from block 15 to the signal input of the second sample processing unit 13), or the second iteration of sample processing begins why the signals coming to the group control input from block 15 with the logic unit level provide sequential reading of all code combinations of samples stored in the second processing unit in a sequential code samples 13 (that is, a shortened sequence of samples), through the element OR 13.7 and the element OR 14 (figure 1) in the storage unit of samples 9.

The unit for determining the count of the desired rank 15, the functional diagram of which is shown in Fig.7, operates as follows. The following operations are performed in this block:

- determining the rank of the first sample in the sample (r ₁ );

- comparison of r ₁ with the desired rank r _claim ;

- depending on the results of the previous operation, the selection of one of two shortened sequences of sampling samples for further processing;

- control reading the selected shortened sequence of blocks 12 or 13 in the block storage samples 9.

The single pulses arriving at the counting input of block 15 from block 12 determine the number of sample samples with r _i <r ₁ recorded in the shift register of block 12. After the required delay, the code combination corresponding to the rank of the first sample in the sample arrives at input B of comparison block 15.10 r ₁ (r ₁ is defined as the number of samples of the shortened sequence with r _i <r ₁ , increased by one in the adder 15.8). The input code A of the comparison block 15.10 receives the code combination corresponding to the desired rank r _lawsuit .

If A> B (i.e. r _claim > r ₁ ), then a shortened sequence of samples with a rank greater than r ₁ is subject to further processing. At the same time, the shift registers of block 12 are reset to zero by a signal with a logic level from the first signal output of block 15, and a circuit consisting of elements 15.2-15.7 is started, which ensures reading in serial code from block 13 to block 9 of this shortened sequence.

In this case, a short single pulse from the output of the pulse shaper 15.2 puts the RS-trigger 15.3 in the storage mode of the logical unit. A signal with a logical unit level from the output of trigger 15.3 opens an electronic key 15.4 for the passage of the required number of clock pulses required for the full cycle of operation of the counter 15.5 and the decoder 15.6. The last (single) code combination, coming from the output of the counter 15.5 to the input of the And 15.7 element, causes a signal with the level of a logical unit to appear at its output, which puts trigger 15.3 into logical zero storage mode.

Otherwise (if A <B, that is, r _claim <r ₁ ), the shift registers of block 13 are reset to zero (by a signal with a logic level from the second signal output of block 15), the reading circuit of the shortened sequence of samples from block 12 starts (elements 15.12-15.17 )

In both cases, the signal with the level of a logical unit from the outputs A> B or A <B of the comparison block 15.10 through the OR element 15.18 is fed to the fourth signal output of block 15 and then to the signal input of the storage unit of samples 9, resetting the shift registers of this block.

Claims (1)

A radio channel data transmission control device comprising a random number generator, a synchronizer, a counter, a first AND element, the first input of which is a control input of the device, an RS trigger, a second And element, a comparison unit, the synchronizer output being connected to the counter input and the first input of the second element And, the group output of the counter is connected to the counting input of the comparison unit, the input of random numbers of which is connected to the group output of the random number generator, the output of the first element And is connected to the input of the generator and random numbers and the zero input of the RS-trigger, the output of which is connected to the second input of the second element And, the output of which is connected to the second input of the first element And, the output of the comparison unit is connected to a single input of the RS-trigger, characterized in that the third element And is additionally introduced , a sample storage unit, a switching matrix, n separation units, a first and second sample processing unit, an OR element and a sample determination unit of a desired rank, the first input of a test signal of the sample storage unit being a test input of the device signal, n outputs of the sample storage unit are inputs of a switching matrix, n-1 pairs of outputs of which are connected to the corresponding inputs of n-1 separation units, the first outputs of which are connected to n-1 inputs of the first sample processing unit, and the second outputs are connected to n -1 inputs of the second sample processing unit, while the clock inputs of the first, second sample processing units and the sample determination unit of the desired rank are connected to the clock output of the sample storage unit, the information outputs of the first and second the sample processing units are connected to the second and first inputs of the OR element, respectively, the output of which is connected to the second input of the test signal of the sample storage unit, while the counting output of the first sample processing unit is connected to the first counting input of the sample determination unit of the desired rank, and the counting output of the second processing unit of samples is connected to the second counting input of the unit for determining the count of the desired rank, the first and second signal outputs of which are connected to the signal inputs of the second and first processing units reference points, respectively, and the first and second group control outputs of the reference rank determination unit are connected to the group control inputs of the first and second samples processing units, the third signal output of the target rank determination unit is connected to the second input of the third element And, the first input of which is connected to the output comparison unit, the output of the third element AND is the control output of the device, the fourth signal output of the unit for determining the count of the desired rank is connected to the signal input ohm of the sample storage unit, and the code output of the sample determination unit of the desired rank is the code output of the device.

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