RU2137312C1 - Method and device controlling transmission of data package over common-user communication channel - Google Patents

Abstract

FIELD: radio engineering, data transmission technology. SUBSTANCE: invention can be used in radio communication networks with package information transmission. Signal of number of k-th priority of priority transmission with duration ΔTmk with generation of permission signal with specified probability is formed in advance on m-th setting of package radio transmission, where m= 1, 2, . . .M. kε=1, 2, ...K and K is number of lowest priority of priority transmission. In this case ΔTm1 >...> ΔTmk and O <ΔTmk <T, where T is duration of clock of operation of common-user channel and random pulse has duration Δtc with equally probable law of its distribution over time interval ] O,T[. With realization of condition Δtcε]0,ΔTmK[ priority transmission of k-th priority is sent. Otherwise or with presence of busy signal operations for formation of permission signal are repeated during next clocks, when n= DK and D is number of clocks of operation for setting of package radio transmission with which sending of priority transmission of first priority occurs with specified probability P at least once. In this case signal of number of k-th priority of priority transmission is formed k times by D clocks with proper duration ΔTmk,...,ΔTm1. Device for realization of method has counter, former of long pulses, flip-flop, synchronizer, OR gates, generator of signals of permission of transmission, comparator, two inhibition gates, D flip-flop, shift register, delay line, unit of AND gates, decoder, K pulse weighing units, incriminator and reading unit. EFFECT: provision for higher traffic-carrying capacity of common-user channel with priority transmission under conditions of high information load. 4 cl, 22 dwg

Description

 The inventions are united by a single inventive concept, relate to the field of communication, namely to the technology of data transmission and can be used in radio communication networks with packet information transfer.

 In radio data networks in order to improve the efficiency of using the total time-frequency resource of a communication channel, various methods are used, and in particular, a method based on packet switching [1, p.6-10]. Using this method allows all packet radio communication installations (UPR) operating in control systems to collectively use the all-in-one shared frequency of the transmission and reception of a communication channel (such communication channels are called public communication channels (CPC)). In this case, the UPR networks transmit packets at any time independently from each other. However, in the case of the simultaneous transmission of data packets (PD) by several SIRs in the CPC, overlays in time of the data packets occur, leading to their collisions. Such situations are called conflict. Emerging collisions distort the transmitted information and do not allow the reception of PD. Such conflicts do not allow the use of ORS in control systems in which the principle “timely or never” is used when transmitting priority information (data packets) [15]. To reduce the number of collisions, and hence the likelihood of conflict situations, CPCs use various methods of controlling the transmission of data packets. In the General case, the control of the transmission of PD is to determine the unambiguous and mandatory for all RNR network actions to transfer data packets to the public communication channel.

 A known method of flexible control of the transmission of data packets in the CPC [2, p. 54]. This method provides the following procedure.

When a data packet arrives at the j-th control unit, where j∈ {1,2, ... N}, and the N-total number of control units operating in the packet radio network (PRO), the latter carries out reception (or control) at the working reception frequency -transmission of the carrier oscillation signal of the k-th OPR (where k ≠ j, k∈ {1,2, ..., N}), which is understood as car: busy signal of the CPC. If the busy signal is not detected, then the j-th ASR transmits the AP after a random period of time Δτ _c . Otherwise, the above actions are repeated starting from the moment of monitoring the status of the CPC.

 Timing diagrams of the state of the CPC for a method with flexible control of PD transmission are presented in the book [2, p. 54].

There is also a method with "hard" control of the transfer of data packets to the CPC, described in the book [2, p. 55]. Its difference from the previous one lies in the fact that the beginning of the transmission of PDs to the CPC does not occur after a random period of time from the moment the busy signal (carrier oscillation frequency) ends at the operating transmit-receive frequency, but immediately. With this method, as well as with the previous one, after the end of the PD transmission, the UPR expects confirmation (receipt) of their receipt in a specially allocated time interval Δt _wait immediately after the end of the transmission of the PD.

 The book [2, p. 55] presents time diagrams of the state of the CPC for a method with "hard" control of PD transmission.

 However, these analogues have disadvantages. For example, they have low bandwidth, which is explained by a large number of conflict situations in the public communication channel with a high input information flow of the PD circulating in the packet radio communication network. The procedure for controlling the transfer of data packets to the CPC does not allow the successful transfer of PD taking into account the categories of urgency.

 The closest in its technical essence in relation to the claimed method is the method of P-hard control of the transfer of PD to the CPC, described in the book [2, p. 57]. This method belongs to the number of synchronous ones, and provides for the tactless operation of the ORS with a frequency of 1 / T, where T is the duration of the network operation cycle. In the prototype method, the j-th OPR, at the input of which the PD arrived, first monitors the employment of the CPC for the presence of a carrier frequency signal. In the absence of employment, the j-th ASR with probability P begins to transmit the AP, or with probability (1-P) repeats the procedure described above in the next step of its operation, starting from the moment of control of the CPC. Reception of the receipt (or confirmation) is similar to the procedure described in the methods with flexible and "hard" control of the transfer of PD to the CPC.

 However, the method with P-tight control of the transmission of data packets to the CPC, as well as others, has insufficient bandwidth in conditions of high information load. In addition, the prototype method does not take into account the categories of urgency of PD arriving at the control unit for transmission to the CPC. As a result of this, PDs with various categories of urgency have equal probabilities of both being transferred and getting into conflict situations in the CPC. Such conflicts will lead to unequal delays in transmitting PDs with different priorities. For example, a high-priority PD and a low-priority PD will have the same probability of being transferred to the CPC, whereas according to the requirements for the first, it is envisaged to bring them to the corresponding SPS immediately, and to the latter in the last turn.

 Known devices for controlling the transmission of data packets over the air.

 Thus, a device for controlling the transmission of data packets over a radio channel [3] contains a first trigger and a first FORBID element, as well as a delay element, an AND element, and an OR element, a first and second pulse shaper, a second inhibit element and a second trigger, connected in series, and also a third pulse shaper and a third trigger. The synchronizer output is connected to the second input of the first prohibition element, the output of which is connected to the first input of the OR element. The output of the second trigger is connected to the second input of the OR element. The first input of the first trigger is combined with the first input of the AND element, the second input of the second inhibit element and the input of the third pulse shaper. The output of the latter through the delay element is connected to the second input of the first trigger. The output of the second pulse shaper is connected to the second input of the And element, the output of which is connected to the first input of the third trigger. The second input of the third trigger is combined with the second input of the second trigger and the third input of the first element is inhibited.

 However, the known device has the following disadvantages. Thus, the device has a low bandwidth and does not allow for a high information load in the CPC to reduce the likelihood of conflict (overlapping data packets in time) between the controllers when transmitting APs with a different urgency category. In addition, after an unsuccessful transfer of the PD to the CPC, it is necessary to re-send the TRANSFER REQUEST command to the input of the device in order to resume the process, bringing the PD to the appropriate control.

 The closest in its technical essence is the device described in [4].

 The prototype device consists of a series-connected synchronizer, a first AND element, a delay element, an OR element, a counter, a transmission cycle trigger, a random number generator, a comparison unit, a transmission enable trigger, a second And element, and a pulse shaper. The input of the latter is connected to the first input of the OR element, to the input of which, as well as to the input of the delay element, the output of the transfer enable trigger is connected. The second input of the trigger to enable transmission is connected to the first input of the second element I. To the second and third inputs of the second element And are connected respectively the output of the synchronizer and the output of the trigger of the transmission cycle. The second input of the latter is combined with the second input of the first AND element, to the third and fourth inputs of which the output of the trigger of the transmission cycle and the output of the delay element are connected, respectively. The output of the first AND element is connected to the counter input, the second output of which is connected to the second input of the comparison unit, and the output of the second AND element is connected to the input of the random number generator.

 However, the prototype device has disadvantages. Firstly, the device has a low bandwidth of the public communication channel when transmitting PDs with various priorities in the worst transmission conditions (high input information stream in the CPC). This is due to the high likelihood of conflict situations in the conditions when all the control networks of the network simultaneously attempt to transmit data packets to the public communication channel. Secondly, it does not allow controlling the transmission of data packets taking into account the categories of urgency of the latter.

 The aim of the claimed objects of the invention is to develop a method and device for controlling the transmission of data packets in a public communication channel, which provide priority transmission of data packets under high information load higher bandwidth of the public communication channel.

This goal is achieved by the fact that in the known method, which consists in receiving a busy signal of a public communication channel of each of M packet radio installations, where M≥3, generating with a given probability a permission signal for transmitting data packets, synchronously generating control command signals, transmitting data packets upon receipt of a transmission authorization signal and the simultaneous absence of a busy signal for a public communication channel, repeated synchronous generation of a control command signal when there is no the presence of the transmission enable signal or the presence of the busy signal of the public communication channel in the current cycle and transmission in the subsequent cycle of the communication channel operation, when generating, with a given probability, a data packet transmission permission signal, previously at the m-th packet radio communication installation, where m = {1, 2, ..., M}, form a signal of the kth priority number of the data packet of duration ΔT _mk , where k∈ {1,2, ..., K} K is the lowest priority number of the data packet, and ΔT _m1 > .. .> ΔT _mk-1 > ΔT _mk >...> ΔT _mK and 0 <ΔT _mk <T where T is the duration of the clock cycle of the common communication channel signal, and a random pulse of duration Δt _c , with an equally probable law of its distribution over the time interval] O, T [, and when the condition Δt _c ∈] 0, ΔT _mk [transmit data packets of kth priority, otherwise or if the busy signal, the steps to generate the transmit enable signal are repeated in n subsequent clock cycles, where n = D • k, and D is the number of clock cycles of the packet radio installation in the network at which, with a given probability P, the transmission of first priority data packets occurs at least once, the signal of the kth prio number The data packet size is formed k-times from D cycles with the corresponding durations ΔT _mk , ΔT _mk-1 , ..., ΔT _m2 , ΔT _{m1 The} duration of the random pulse Δt _{c is} chosen within the limits Δt _c = (0.05 ... 0, 1) (T / L). When receiving a data packet with k-th priority, an acknowledgment signal is additionally generated on the corresponding packet radio installation, a confirmation signal is transmitted, and in the absence of a confirmation signal, the actions to control the transmission of the data packet with k-th priority are repeated.

 The above set of essential features allows you to increase the throughput of the CPC when transmitting data packets with different priorities by push-pull the formation of increasing values of the transmission probabilities k-times when controlling the transmission of AP in conditions of high information load.

 The goal in the claimed device is achieved by the fact that in the known device for controlling the transmission of data packets to a public communication channel containing a counter, a long pulse shaper, a trigger, a synchronizer, an OR element, a transmission enable signal generator, the output of which is connected to the first input of the comparison unit, additionally the first and second elements are PROHIBITED, D-trigger, the information input of the shift register is connected to the output of the first element OR, the first input of which is connected to the information input devices, and on the second - the information output of the shift register, from the jth to j + nth information outputs of the shift register are connected to the corresponding information inputs of the first reading unit, from the 1st to nth information inputs of the block of OR elements are connected to the corresponding the outputs of the first readout block, where n = {2,3, ...}, and from the 1st to the n-th enable inputs of the OR block of elements are connected to the corresponding outputs of the AND block, whose n allow inputs are connected to the output of the first multi-input element OR, n outputs of a block of elements OR connected to the corresponding n inputs of the storage register and the first decoder, n outputs of the storage register are connected to the corresponding n information inputs of the second reading unit, the output of the second multi-input element OR is connected to the clock input, n outputs of the second reading unit are connected to the corresponding information inputs of the incrementer, to the sync input of which the output of the first multi-input element OR is connected, n outputs of the incrementator are connected simultaneously to the corresponding n information inputs of the electronic unit elements And and n inputs of the second decoder, To the outputs of which are simultaneously connected to the corresponding To inputs of the long pulse shaper and the third multi-input OR element, K = {2,3, ...}, the output of the long pulse shaper is connected to the information input of the comparison unit, to the output of the transmit enable signal generator is connected to the output of the third multi-input element OR, the output of the comparison unit is connected to the direct input of the second BAN element, the output of which is simultaneously the TRANSMITTER ON and connected to the first input of the second OR element, the second input of which is connected to the output of the D-flip-flop, the output of the second OR element is connected to the input of the control pulse dispenser, the output of which is simultaneously connected to the clock input of the shift register and to the counter input, an external input of the EMPLOYMENT SIGNAL is connected to the inverse input of the first and the second BAN elements, the output of the first of which is connected simultaneously to the second input of the AND element and to the input of the delay line, the counter output is simultaneously connected to the direct input of the first BAN element and to the clock odes K of pulse dispensers, the kth output of the first decoder, where k = {1, ..., K}, is connected to the START input of the corresponding kth pulse dispenser, the TIMER output of which is connected to the kth input of the first multi-input element OR, and the BUTTER output to the k-th input of the multi-input element OR, the external TRANSFER REQUEST input is simultaneously connected to the S-inputs of the first and second RS-flip-flop, to the shift register reset input, to the R-input of the D-flip-flop, the S-input of the first RS-flip-flop the external input of the RECEIPT is connected, the output of the synchronizer is connected to the information input of the D-trigger, you One delay line is connected to the R-input of the second RS-trigger, the output of which is connected to the first input of the And element, and the output of the first RS-trigger is connected to the sync input of the D-trigger, the output of the And element is connected to the reset input of the first readout block, the information output of the shift register is the output of the device.

 In FIG. 1 shows time diagrams of the state of a public communication channel when using the proposed method for transmitting PD transmission in an ORS; in FIG. 2 is a block diagram of a device that implements the inventive method; in FIG. 3 is a diagram of a shift register; in FIG. 4 is a diagram of a reading unit; figure 5 - block diagram of the elements OR; figure 6 is a diagram of the shaper of long pulses; in FIG. 7 and 8 are, respectively, a diagram of a generator for transmitting permission signals and time charts explaining the principle of its operation; figure 9 is a diagram of a memory block; figure 10 is a diagram of a pulse dispenser; figure 11 is a diagram of the counter; in FIG. 12 is a diagram of the element "FORBID"; in FIG. 13 is a diagram of a synchronizer: in FIG. 14 is a diagram of a storage register; in FIG. 16 and 15, respectively, the probability-time characteristics of the proposed methods and tables of their calculation; in FIG. 18 and 17, respectively, the probability-time characteristics of the known method and the table of their calculation. The possibility of implementing the proposed method is confirmed as follows.

All N OPR networks operate synchronously with a clock frequency of 1 / T. Synchronization in a packet network is supported by receiving sync packets transmitted by one of the UPR networks [10, 13]. Upon receipt of the j-th control gear for transmitting the kth priority AP (where k∈ {1,2, ..., K} is the urgency priority number. K is the lowest urgency priority), a priority number signal is generated - a pulse of duration ΔT _jk Duration this pulse corresponds to the PD of k-th priority, where 0 <ΔT _jk <T and ΔT _j1 > ΔT _j2 >..> ΔT _jk ..> ΔT _jK (Fig. 1b). At the same time, a random pulse Δt _{c is} generated with an equally probable distribution law over the interval] O, T [(Fig. 1c), and a busy signal (S3) is received in the CPC at the operating transmit-receive frequency. If the SOC in the CPC is not detected and the generated pulse Δt _c coincided in time with the duration of the generated signal of the priority number ΔT _jk, then the transmission permission signal of the PD of k-priority is issued (Fig. 1d).

The transmission enable signal will be generated with a probability P _jk = ΔT _jk / T whose value is directly proportional to the duration of the signal of the priority number ΔT _jk (Fig. 1b). A pulse of duration Δt _c , the location of which is equally probable in the time interval T, overlaps with the pulse ΔT _jk statistically exactly ΔT _jk / T - the number of times, i.e. the probability of their coincidence is P _jk = ΔT _jk / T. Thus, the probability of generating a transmission permission signal for a data packet of kth priority is the ratio of the pulse duration T to the pulse duration ΔT _jk .

For the data packet of the Kth priority, the probability of generating a transmission enable signal will be P _jk = ΔT _jk / T.

 With the completion of the formation of the transmit permission signal, a permission signal for transmitting data packets of kth priority will be issued if, at this point in time, corresponding to this cycle of the packet radio network in the CPC, there is no busy signal at the transmit-receive frequency.

However, with the probability Q _jk = 1-P _jk or Q _jk = 1-ΔT _jk / T, the transmission permission signal of the kth priority PD will not be generated.

 In this case, the transmission procedure of the k-th priority AP is repeated in the following D-cycles of the operation of the control unit, as well as in cases where there is no acknowledgment of the receipt of the AP (receipt signal), starting from the control of the state of the CPC.

The number of D-cycles is equal to the number of attempts in which, with probability P ₁ (for example, P ₁ = 0.998), the transmission of PD of the first priority will occur at least once [14, pp. 16-26].

However, k-th priority PD transmission in D-cycles may not occur. the probability of transmission will be much less than P ₁ : P ₁ > P _k ---> P _k = 1- (1-p _k ) ^D , because p _k <P ₁ .

For this purpose, upon completion of the D-clocks of the network, the transmission process continues in subsequent D-clocks with the only difference that the signal of the priority number is already formed with a duration ΔT _jk-1 i.e. ΔT _jk-1 <ΔT _jk . While maintaining the above conditions, this is the signal of the number ΔT _jk-1 and the signal of the control command Δt _c coincided in time, and the SOC is absent in the CPC, the transmission of the kth priority PD is carried out. Otherwise, or in the absence of a confirmation signal, the described procedure is repeated in subsequent D-strokes of the control. However, as in the first case, the probability of transmitting an AP of k-th priority will be less than P ₁ , therefore, the transmission process can be carried out at least k-2 times in D-cycles when each time a signal of priority number of the corresponding duration ΔT _{jk is generated -2} <... <ΔT _j2 <ΔT _j1
In the last attempt, the transmission of the kth priority PD will occur with probability P ₁ = 0.998, because the signal of the priority number ΔT _j1 corresponds to the number of the first priority and the event will occur at least once during the D-cycles of the control. Thus, in the worst case, the k-th priority PD will be transferred for k • D-cycles of the control.

 The control device for the transmission of data packets in the public communication channel, shown in figure 2, consists of the first 1 and second 12 elements OR, shift register (PC) and, the first 3 and second 7 reading unit (BSch), the block of elements OR 4, storage register (PX) 5, block of elements And 6, incrementator (In) 8, element And 9, second 10 and first 20 RS-flip-flops, dispenser control pulses (DUI) 11, delay line (LZ) 13, the first 14 and second 22 decoders (Дш), counter 17, first 18 and second 25 elements FORBID, K pulse dispensers 15.1-15.К, first 16.1, second 1 6.2 and the third 26 multi-input elements OR, D-flip-flop 20, synchronizer (SN) 21, long-pulse shaper (FDI) 23, comparison unit (BS) 24, transmission enable signal generator (GSRP) 27, information input 28 and output 29 of the device , external signal input 30 (SZ), external signal input 31 TRANSMISSION REQUEST (REQUEST REQUEST), external input 32 of the RECEIPT signal, output 33 of the control signal ENABLING THE TRANSMITTER (ON PRD). The information input of PC 2 is connected to the output of the first element OR 1, the first input of which is connected to the information input 28 of the device, and the second is the information output of PC 2, from the jth to j + nth information outputs of PC 2 are connected to the corresponding information inputs the first BSch 3, from the 1st to the n-th information inputs of the block of elements OR 4 are connected to the corresponding outputs of the first BSch 3, where n = {2,3, ...}, and from the 1st to the n-th enable inputs block of elements OR 4 are connected to the corresponding outputs of the block of elements AND 6, n permitting inputs of which are connected the output of the first multi-input element OR 15.2, n outputs of the block of elements OR 4 are connected to the corresponding n inputs of PX 5 and the first LR 14, n outputs of PX 5 are connected to the corresponding n information inputs of the second BSh 7, to the sync input of which the output of the second multi-input element OR 15.1 is connected, n outputs of the second BSCh 7 are connected to the corresponding information inputs of In 8, to the sync input of which the output of the first multi-input element OR 15.2 is connected, n outputs of In 8 are connected simultaneously to the corresponding n information inputs of the element block And ntov 6 and n inputs of a second Aco 22, which simultaneously outputs connected to respective inputs of K PDI 23 and the third multi-input OR gate 26, K = - (2.3. . . 3-, the output of the FDI 23 is connected to the information input of the BS 24, the output of the third multi-input element OR 26 is connected to the input of the GSRP 27, the output of the BS 24 is connected to the direct input of the second element BAN 25, the output of which is simultaneously the control output ON PRD 33 and connected to the first the input of the second element OR 12, to the second input of which the output of the D-flip-flop 20 is connected, the output of the second element OR 12 is connected to the input of the DUI 11, the output of which is simultaneously connected to the clock input of PC 2 and to the input of the counter 17, the external input of SZ 30 is connected to the inverse entrance first 18 and the second element 25 inverted, the first output of which is connected both to the second input of the AND gate 9 and to the input of LZ 13, the output of counter 17 is connected both to the direct input of the first member 18 and inverted to the clock pulses CI 15.1-15. K, the k-th output of the first Дш 14, where k = {1, ..., K}, is connected to the START input of the corresponding k-th DI 15.k, the TIMER output, which is connected to the k-th input of the first multi-input element OR 16.2, and the output of the BUNCH to the k-th input of the second multi-input element OR 16.1, the external input REQUEST PRD 31 is simultaneously connected to the S-inputs of the first 18 and second 10 RS-flip-flops, to the reset input PC 2, to the R-input of the D-flip-flop 20 , S-input of the first 19 RS-flip-flop connected to the external input RECEIPT 32, output Sn 21 is connected to the information input of the D-flip-flop 20. output LZ 22 is connected to the R-input of the second 10 RS-flip-flop, output otorrhea connected to a first input of AND gate 9, and the output of the first RS-flip-flop 19 is connected to a clock terminal D-flip-flop 20, an output of AND 9 is connected to the reset input of the first BSch 3, PC data output device 2 is output.

 PC 2 is designed to record a k-priority data packet in the form of binary information received at its information input from an external source under the influence of clock pulses and to overwrite a previously recorded k-priority data packet to its information input and simultaneously output it to the device output.

 The PC 2 construction scheme that implements such tasks in the claimed device is known and described, for example, in [9; with. 135, fig. 3.35].

 In contrast to the specified link in the inventive device, taking into account the peculiarities of the relationship of PC 2 with other elements of the device, the circuit takes on the form shown in FIG. 3.

Scheme PC 2 includes a collection of m series-connected D-flip-flops. The outputs of the D-flip-flops are connected respectively to the D-input of the subsequent D-flip-flop. The output of the last m-th D-flip-flop is the output of PC 2, and the input of the first is the input of PC 2. In parallel, the input for clock pulses is connected to the C-inputs of all D-flip-flops, and the installation input is connected to the R ^* inputs.

 The first 3 and second BSCh 7 are designed to read part of the service information of the data packet, the first - information about the true priority, the second - commands to change the priority number on the clock signal of the corresponding inputs. Schemes for constructing BSh 3 and 7, implementing such functions, are identical and is presented in FIG. 4.

 BSch contains n elements And-In. The first inputs of the elements I1-In are n included BSch. The second inputs of the elements I1-In are connected to the read input. The outputs of the n elements I1-In are n-outputs BSch.

 The block of elements OR 4 is designed for logical isolation between the signals coming from the outputs of the first BSCh 3 and from the outputs of the block of elements AND 6 to the inputs of PX 5. A diagram of the construction of a block of elements OR 4 implementing such functions is presented in FIG. 5.

 The block of elements And 6 is designed to issue a command to change the priority number. The diagram of the construction of the block of elements And 6, which implements such functions, is similar to the diagram of the reading block 3 (7) and is presented in figure 4.

The calculator 8 is designed to pass an n-bit binary number l _n supplied to the n-inputs corresponding to the PD priority number without changing at the level at the control input equal to the logic level “1”, or subtracting one from the n-bit number, i.e. the formation at the n-outputs of the number l _n -1.

 The construction scheme of In 8 that implements such tasks in the inventive device is known and described, for example [8, p. 132-133].

 DUI 11 is intended for the issuance of a signal of a single series of pulses arriving at its input, which contains exactly m pulses cut from a continuous sequence of clock pulses coming from a master oscillator.

 The construction scheme of DUI 11, which implements such tasks in the inventive device, is known and described, for example, in [8; with. 273, fig. 9.11a]. Considering the interconnections with other elements, the DUI circuit 11 takes the form shown in FIG. ten.

 DUI 11 contains a master oscillator (GP) 11.1, the element BAN 11.2, binary counter (DS) 11.3. The output of ЗГ 11.1 is connected to the direct input of the element BAN 11.2. The output of the BAN 11.2 element is simultaneously the output of the DI 11 and the summing input of the DS 11.3. The input DI 11 is connected to the R-input of the DS 11.3, the output of which is connected to the inverse input of the element BAN 11.2.

 The counter 17 is designed to issue a single pulse at its output at the time of receipt of the last clock pulse from a series of m-pulses at its input.

 The construction scheme of the counter 17, which implements such tasks in the inventive device, is known and described, for example [8; with. 265-266, fig. 9.8a]. Considering the interconnections with other elements, the circuit of the counter 17 takes the form shown in FIG. eleven.

 The first 18 and second 25 elements of the PROHIBITION are intended to form a logical unit at its output only if there is a logical zero at its inverse input and a logical unit at the direct input. A schematic diagram of this element is shown in FIG. 12.

 The circuit of the element FORBID includes the element NOT 1 and the element AND 2. The input of the element NOT 1 and the second input of the element And 2 are, respectively, the inverse and direct inputs of the element FORBID. The output of the element NOT 1 is connected to the first input of the element AND 2, the output of which is the output of the element BAN.

 D-flip-flop 20 is designed to generate a signal of the beginning of the process of controlling the transmission of a data packet with k-th priority on clock signals emerging from the output of the synchronizer 21 to its D-input and, moreover, only when there is a voltage potential corresponding to the logical voltage on its C-input units.

 The construction scheme of the D-flip-flop 20, which implements such tasks in the inventive device, is known and described, for example, [8; with. 172-174, fig. 6.6c].

 The synchronizer (SN) 21 is designed to maintain clock synchronization between the synchronizers of the PD transmission control devices for packet radio communications using synchronization signals transmitted by one of the controllers.

 The construction scheme of SN 21 with such functions in the claimed device is known, the principle of operation and its calculation are given, respectively, in [5; p.17-30] and [6; 1962, N6, p. 3-9]. Taking into account the peculiarities of interconnections with other elements of the device, the circuit 21 takes on the form shown in FIG. 13. As a radio receiver, you can use, for example, a radio receiver R-160p, [12], which has a mode of receiving synchronization signals and issuing the corresponding sequence of synchronization pulses to a linear output.

 The SN 21 circuit includes a radio receiver (Rx) 21.2 with an antenna 21.1, the output of which is connected to the input of a discrete servo system with a controlled divider (BSS) 21.3, In turn, the BSS 21.3 contains a frequency doubler 21.4 to the input of which a Rx 21.2 output is connected, and the output to the first input of the phase discriminator (PD) 21.5. The output of the PD 21.5 is connected to the input of the averager 21.6. The output of the averager 21.6 is connected to the first input of the controlled device 21.7 (UE). The output of UU 21.7 is connected to the input of UD 21.8. The output of the generator 21.9 is connected to the input of the UU 21.7. The output of UD 21.8 is connected to the second input of PD 21.5 and to the output of Sn 21.

 Dispensers of impulses (DI) 15.1-15. k are intended for the issuance of a START signal at the output of the BUNCH single packet containing a given number of pulses cut from a continuous sequence of clock pulses, and at the output of the TIMER pulse complete the formation of a single burst. The scheme of building the DI 15.1-15. k that implements such tasks in the inventive device is known and described in [8, p. 273, fig. 9.11a].

 Storage Register 5 is intended to store the priority number of the PD. The construction scheme of PX 5 that implements such tasks in the inventive device is known and described, for example, [9, p.134, Fig. 4.34]. In view of (connections with other blocks of the device, the PX 5 circuit takes the form shown in Fig. 14.

FDI 23 is intended for forming, upon receipt of one of its inputs K, a signal of priority number — a pulse of the corresponding duration ΔT _k where k∈ {1, K}; K is the number of the PD with the lowest category of urgency, while ΔT ₁ > ΔT ₂ >...> ΔT _k >...> ΔT _K
The PDI 23 scheme that implements such functions in the inventive device is known and described, for example, in [9; c.211-212, Fig. 7.5g] and taking into account the features of the relationship with other elements of the device takes on the form shown in FIG. 6.

FDI 23 includes K pulse shapers (FI) 23.1, the outputs of which are connected to the K-input element OR 23. 2. The output of the K-input element OR 23.2 is the output of the FDI 23, the K-inputs of which are the outputs of the corresponding K-FI 23.1. In turn, each FI 23.1 contains: the first 23.3 and the second 23.8 elements OR NOT. The first input of the first element OR 23.3 is the input of FI 23.1, and the second is connected to the output of the second element OR 23.8. The emitter of the transistor 23.6 and the output of the first resistor 23.7 are connected to the input of the second element OR 23.8. The second output of the first resistor 23.7 is connected to a common housing. The base of the transistor 20.6 is connected to the first terminal of the second resistor 23.5 and the first terminal of the capacitor 23.4, the second terminals of which are connected respectively to the positive terminal of the external power supply Un and the output of the first OR NOT 23.3. The collector of transistor 23.6 is connected to the positive terminal of an external power source. To generate the pulses of the required durations in the FI 23.1, the capacitances of the capacitors 23.4 are selected so that the duration of the generated pulses at the output of the first FI 23.1 is longer than the second FI 23.1, etc. to the K-1st FI 23.1, i.e. when C ₁ > C ₂ >..> C _k >..> C _K , the durations of the generated pulses would be ordered ΔT ₁ > ΔT ₂ >...> ΔT _k >...> ΔT _{K /}
BS 24 is designed to provide a transmitter enable enable signal if two input signals coincided in time at both of its inputs.

 The BS 24 construction scheme that implements such a function in the inventive device is known and described, for example, in [8; with. 14, Fig. 1.2] and can be implemented on the element And, performing a logical operation - conjunction.

 GSRP 27 is designed to generate a pulse about the uniform distribution law over the time interval] О, Т [.

 Scheme GSRP 27 that implements such tasks in the inventive device is shown in FIG. 7.

 GSRP 27 consists of a noise source (IS) 27.1, a clamp of instantaneous voltage values (FMZ) 27.2, a linearly varying voltage generator (GLIN) 27.3, a comparator 27.4, a delay line (LZ) 27.5 and the element BAN 27.6. Information input FMZ 23.2 is connected to the output of IS 27.1. The output of the FMZ 27.2 is connected to the first input of the comparator 27.4. The output of GLIN 27.3 is connected to the second input of the comparator 27.4. The input of the GSRP 27 is connected simultaneously to the input of the GLIN 27.3 and the control input of the FMZ 27.2. The inverse input of the element BAN 27.6 through LZ 27.5 is connected to the output of the comparator 27.4. The direct input of the element BAN 27.6 is directly connected to the output of the comparator 27.4. The output of the BAN 27.6 element is the output of the GSRP 27.

 In turn, FMZ 27.2 is designed to store for a given period of time the instantaneous voltage values coming from the output of IS 27.1. The scheme of such FMZ 27.2 is known and its work is described, for example, in [7, p. 46, fig. 2.6]. In the claimed GSRP 27, taking into account the peculiarities of interconnections about other elements, the FMZ scheme 27.2 takes on the form shown in FIG. 9, and includes: the first resistor 27.21, the first output of which is the information input of FMZ 27.2, and the second is connected simultaneously to the first output of the second resistor 27.22 and the direct input of the element BAN 27.23, to the inverse input of which is connected the control input FMZ 27.2. The output of the BAN 27.23 element is simultaneously connected to the first output of the capacitor 27.24 and to the input of the direct current amplifier (DCT) 27.25. The output of UPT 27.25 is connected to the second terminals of the second resistor 27.22 and capacitor 27.24, as well as to the output of FMZ 27.2.

 All other elements included in the general (Fig. 2) and private (Fig. 3, 7, 8, 9, 11, 12) circuits of the claimed device are known. So the principle of operation and the circuit of the OR element are given in [8; with. 15, fig. 3.1], the element And in [8; with. 14, fig. 1.2], the decoder in [8; p. 87-89, fig. 3.1], the generator 10.1 in [8; with. 240-241, Fig. 7.9c]; counter [8; with. 252-253; fig. 9.1]; RS-trigger in [8; with. 166-172, fig. 6.1].

 The inventive device operates as follows.

 In the initial state, the public communication channel is monitored by receiving a busy signal - a carrier wave at the transmit-receive frequency. The synchronizer 21 generates clock pulses with a repetition period T, which are constantly supplied to the information input of the D-flip-flop 20. However, the sync-pulses in this case do not change the logical state of the latter, since the first RS-flip-flop 19 is in the zero state and, therefore, to the sync input D -trigger 20 has a signal with a logic level of "0", which makes the latter "opaque."

 Suppose that the CPC is busy - a carrier wave signal has been received at the transmit-receive frequency. From the external input of the SZ 3D signal with a voltage level equal to the logic level “1”, it is supplied to the first 18 and second 25 inputs of the BAN elements, the first of which blocks the process of controlling the transmission of data packets of the k-th priority, and the second - the output ON PRD 33 to busy signal duration in CPC. In this case, when the k-th priority device is received at the information input 28 of the PD device, transmission will not be carried out.

Suppose that the CPC is free (or freed) and the k-th priority PD has arrived at the information input 28 of the device. At the same time, a signal in the form of a pulse with a voltage level equal to the logic level “1”, which starts the device as a whole and the process of controlling the transmission of data packets in particular, is supplied from the external input REQUEST PRD 31. In this case, a pulse with a voltage level of logical "1" is supplied to the S-input of the second RS-trigger 10 and the S-input of the first RS-trigger 19, which puts the first trigger to zero, and the second trigger to a single state, in which it is formed on direct output signal with a logic level of "1". The logic signal "1" from the direct output of the first RS-flip-flop 19 is fed to the clock input of the D-flip-flop 20 and puts it in a "transparent" state. Now, the logical state of the D-flip-flop 20 at the output will be determined by the clock signals arriving at its information input from the output of the synchronizer 21. At the moment the next sync-pulse arrives at the information input of the D-flip-flop 20, a pulse will be generated at its output with the logic level “1”, which will arrive through the second input of the second element OR 12 to the input of the DUI 11. By this command, the DUI 11 generates a single series of clock pulses, the number of which is n, where n is the amount of PD in bits. The generated series of clock pulses is fed to the read input of PC 2 and records the PD of the kth priority in the memory cells. At the same time, a series of clock pulses is fed to the input of the counter 17. At the moment of the arrival of the last n-th pulse of this series, a pulse is generated at the output of the counter 17, which is fed to the direct input of the first element BAN 18 and the clock inputs K of the pulse metering devices 15.1-15.K. From the output of the first element BAN 18, the logical "1" pulse simultaneously enters the second input of the element And 9 and through LZ 13 to the R-input of the second RS-trigger 10, which will be in the zero state for a time t _s , where t _s - delay time LZ 13. In this situation, when there is a logical “1” pulse at the second input of AND 9 and a logical “1” pulse at the first input during time t _s , a pulse with a logical level will be generated at its output 1". This pulse will go to the READ-IN input of the first reading unit 3. This command will read information about the priority number received by the AP and recorded in PC 2 in PX 5 and in the first Dsh 14 through the first BLS 3 and the block of elements OR 4.

 In the first Dsh 14, the binary priority code of the PD is converted to a unary code, which will appear as a logical "1" signal on the corresponding k-th output. This signal triggers the k-th DI 15.k, in which a pulse train D will be formed at its output-BATCH. The number of pulses in the packet is equal to the number of clock cycles of the device operating on the network at which the transmission of the AP will occur at least once with a given probability P. The burst of pulses is “cut out” from the sequence of pulses arriving at the sync input of the k-th DI 15. k from the output of the first element is PROHIBITED 18. The pulses of the burst are tactlessly sent through the k-th input of the multi-input element OR 16.k to the sync input of the second BL-7. This command reading the binary code of the priority number of the PD in the calculator 8.

 The calculator 8 operates as follows. In the absence of a logical “1” at the sync input, In 8 passes the n-bit binary number supplied to its inputs without changing, if there is a logical “1” signal at the sync input, it takes one from the n-bit binary number received at the input.

 Thus, at the outputs of In 9 an n-digit number will be generated corresponding to the k-th priority number of the PD. Next, an n-digit binary number simultaneously arrives at the second inputs of the block of elements And 6 and the second LH 22. If there is no signal at the enable inputs of the block of elements And 6 and at the sync input In 8, the n-digit number will not change when rewriting it in PX 5. At the same time, n -digit number received on the second DS 22 will be converted into a unary code, which will be presented as a logical "1" at the k-th output. This logical "1" will go to the k-th input of the FDI 23 and the k-th input of the third multi-input element OR 26.

FDI 23 generates a long pulse ΔT _K where 0 <ΔT _k <T; k∈ {1,2, ..., K} The duration of this pulse unambiguously corresponds only to the k-th priority of the AP. The third multi-input element OR 26 will give a signal to start the GSRP 27. This signal will simultaneously be fed to the control input FMZ 27.2, the output of which will be stored voltage (Fig. 8b), corresponding at this point in time to the instantaneous value of the noise voltage at the output of IS 27.1 (Fig. 8a). At the same time, CLAY 27.6 starts. At the moment of equal voltage at the outputs of the GLIN 27.6 (Fig. 8c) and FMZ 27.2 (Fig. 8b), the comparator 27.3 is triggered. As a result, a pulse is generated at the output of comparator 27.3 (Fig. 8f) with a voltage level equal to the logical level “1” and a duration with a uniform distribution law over the time interval] O, T [. This is because the sample of instantaneous voltage values from the implementation of the random process IS 27.1 is evenly distributed in a certain range of noise voltages. The received pulse with a random duration is fed to the direct input of the element BAN 27.6 and to the input LZ 27.5. In LZ 27.5, the pulse is delayed by Δt _c . Further, from the output of LZ 27.5, the pulse is supplied to the inverse input of the element BAN 27.6. It is known that the element BAN 27.6 forms a logical unit at its output only when there is a logical zero at its inverse input and at a direct input of a logical unit. Thus, pulses with a duration Δt _c (Fig. 8n) will be formed at the output of the GSRP 27, whose presence in the interval] O, T [is equally probable.

The long pulse ΔT ₁ thus obtained and the evenly distributed pulse Δt _c are fed to the inputs of the BS 24. In the event of a time difference at the output of the BS 24, there will be no ON ON signal and until the end of the current clock cycle of the ORS network, no actions will take place in the device. With the beginning of the next clock cycle of the UPR and the network as a whole, the synchronizer 21 will again issue another sync pulse. This clock will arrive at the D-input of the D-flip-flop 20 and the process described above will be repeated starting from the moment of formation of a single series of clock pulses.

 Sn 21 works as follows. PFP 21.1 receives synchronization signals at a known frequency and generates a sequence of synchronization signal pulses (MSS) at its linear output. Next, the MSS is fed to the input of the MSS 21.4. In DOS 21.4, the reference frequency of synchronization signals is monitored and adjusted in the event of a frequency drift, thereby ensuring a constant repetition rate of the MSS.

If there is a coincidence in time of a long pulse ΔT ₁ and a uniformly distributed pulse Δt _c from the output of BS 24 to the direct input of the second element, PROHIBIT 25, a transmission enable signal will be sent. If an external SOC arrives at the inverted input of the second element BAN 25, the last one will not give the ON ON signal and the PD transmission control process will be repeated in the same way as described above, with the only difference being that the external SOC present at the inverted input of the first BAN 18 element will not give a signal to the second input of the And 9 element, and information about the priority number of the PD will not be read.

In the case of a free communication channel for general use, and therefore the absence of an external input 30 SZ, the output of the second inhibit element 25 will generate an ON ON signal, which will simultaneously go to the control output ON PRD 33 and the first input of the OR element 12. Having passed through the element OR 12, the signal will start DUI 11. In DUI 11, a single series of clock pulses will be generated, which will be fed to the reading input of PC 2 and counter 17. In PC 2, the PD will be read with k-priority to information output 29 and overwrite via the feedback circuit and through a second input of the first OR element 1 to its data input. The remaining time in the current cycle of operation NRM network, equal to the time t _{the coolant} (where: T = t _pr + t _{p ^;} t _pr - the time of transmission; t _standby - timeout RECEIPT) is sending an acknowledgment PD with 1st priority with external input RECEIPT 32.

 If the RECEIPT signal has not been received, then the process of retransmitting the AP is similar to the above, starting from the next measure. For this case, the feedback in PC 2 serves to save the PD with K-priority for subsequent transmission.

 Otherwise, the PD was transmitted successfully, the RECEIPT signal will go to the installation input of PC 2, to the R-input of the first RS-flip-flop 19 and to the INPUT-RESET of the D-flip-flop 20. In PC 2, the memory cells are zeroed, and in the first RS-flip-flop 19 and D-flip-flop 20 - initialization (zero) state.

 Let us conduct a comparative analysis of the known method for controlling the transmission of PD to the public communication channel and the claimed one. To carry out such a study, we will use the well-known method [13], in which the probability-time characteristic of the message (data packet) being in the public communication channel is used as a generalized indicator of the quality of the information volume of PD in radio networks with packet switching.

The distribution function of the residence time of the data packet T _PD can be represented in a compact form as
F _Tpd (t) = P (T _pd ≤ t). (1)
Due to the Poisson nature of the PD transmission stream in a packet radio network, the time intervals between the arrival of neighboring data packets are random variables with an exponential distribution function [13.1 p.16]. With this statement in mind, the distribution function F _Tpd (t) will look as follows
FT _pd (t) = P (T _pd ≤t) = 1-exp (-νt), (2)
where ν - is the average number of data packets transmitted per unit time.

(3)
где p_i - вероятность передачи ПД в КОП i-й УПР сети.We will analyze the claimed and known methods of controlling the transmission of PDs to the CPC in a situation of high information load, which is the worst in the functioning of a packet radio network, in which PDs for transmission are simultaneously received on all RNM networks. Under these conditions, in the CPC there is the greatest number of conflicts between the UPR in the public communication channel. In this situation, the probability of successful transmission of the PD of the i-th control in the current cycle of the network is determined by the expression [11, p. 78]

(3)
where p _i is the probability of transmitting PD to the CPC of the i-th control network.

If the transmission rate R is known, then taking into account expression (3), we can determine the average transmission time of a data packet of a given volume V
T $\genfrac{}{}{0ex}{}{\text{*}}{\text{pd}}$ = V / (RP $\genfrac{}{}{0ex}{}{\text{*}}{\text{i}}$ ), (4)
and the average number of data packets transmitted per unit time is found from the expression
ν = 1 / T $\genfrac{}{}{0ex}{}{\text{*}}{\text{pd}}$ . (5)
To simplify the calculations, suppose that 9 anti-packet radio installations are deployed in the missile defense system. According to the first method, when transferring PDs, priorities are not taken into account, and according to the claimed method when transmitting PDs, categories of urgency are accounted for. In addition, we consider the volume of the data packet V and the transmission rate R equal to 1, PD of the 1st, 2nd, and 3rd categories, respectively, comes only to each third of the UPR of the total.

In FIG. 16.1-16.3 and FIG. _Figure 18 shows plots of the distribution function F _Tpd (t) for the analyzed methods. The calculations were performed according to expressions (2) - (5) and the technique described in the book [13]. The graph comparison in FIG. 16.1-16.3, FIG. 18 and the tables in FIGS. 15.1-15.3, FIG. 17 shows that the UPR, using the inventive method of transmitting data packets to the CPC, has the best VVH compared with the known. This is due to the fact that in the first 11 clock cycles of the network operation according to the proposed method it has the greatest probability of formation and the probability of being transmitted at the allowable time for bringing the PD of the first priority. Whereas PDs of 2nd and 3rd priority in the same period have a lower probability of transmission. With the onset of the next 11 clock cycles, the 2nd priority PD will be transferred necessarily, and by the end of the last 11 clock cycles, the 3rd priority PD will also be transferred. When a missile defense system using known methods [2, 3, 4], multi-priority APs have the same probability of being transmitted, and therefore, the CPC has a low throughput. Therefore, it is very problematic to use such networks in control systems exchanging information (data packets) of various priorities according to the principle “in a timely manner or never” [15].

List of sources of information:
[1] Telecommunication, N9.1994.

 [2] Bunin S.G. Voiter A.P. Packet radio computing networks. K.: Technique, 1989.223 s.

 [3] A.S. 1162057 H 04 L 7/00 B.I. 22.85 g.

 [4] A.S. 1162058 H04L 7/00 B.I. 22.85 g.

 [5] Bukhviner V. E. Discrete circuits in phase radio communication systems. M .. Communication, 1969, 144 p.

 [6] Bukhviner V.E. Calculation of a discrete synchronization system / Telecommunication, 1962, N6, S. 3-10.

 [7] Bobnev M.P. Generation of random signals. M.: Energy. 1971, 240 p.

[8] Potemkin I.S. Functional units of digital automation.-M.: Energoatomizdat, 1988.-300s .: ill. [nine]
[9] Microcircuits and their application: Reference manual / V. A. Batushev et al. -M. : Radio and communications, 1983 - 272 p., Ill. - (Mass radio library; issue 1070)
[10] Radio N9, 1990.

 [11] Problems of Information Transmission, Volume XV, no. 4, 1979.

 [12] Radio receiver R-160p: Technical description and operating instructions, TSL2.003.067 TO, Omsk, 1987.

 [13] Radio communication networks with packet information. A.N. Sharov et al. / Ed. A.N.Sharova. SPb .: YOU, 1994, p.216.

 [14] Arrival A.M. Fundamentals of calculations in statistical radio engineering. -M., Communication, 1969.

 [15] Communication at sea. V.I.Soloviev et al., -L ..- Shipbuilding, 1988.

Claims (3)

1. A method of controlling the transmission of data packets in a public communication channel, comprising receiving a busy signal of a public communication channel of each of M packet radio installations, where M ≥ 3, generating, with a given probability, a data packet transmission permission signal, synchronously generating control command signals, transmission of data packets upon receipt of a transmission permission signal and the simultaneous absence of a busy signal of a public communication channel, repeated synchronous generation of a command signal control in the absence of a transmission permission signal or the presence of a busy signal of the public communication channel in the current cycle and transmission in the subsequent cycle of the communication channel, characterized in that for generating with a given probability the signal permission to transmit data packets previously on the m-th packet radio installation, where m = {1,2, ... M}, form a signal of the k-priority number of the data packet of duration ΔT _mk , where k ∈ {1,2 ..., K}, K-number of the lowest priority of the data packet, and ΔT _m1 >..> ΔT _mk-1 > ΔT _mk >...> ΔT _mk and 0 <ΔT _mk <T, where T the cycle time of the public communication channel, and a random pulse of duration Δt _c with an equally probable distribution law over the time interval] О, Т [, and when the condition Δt _c ∈] 0, ΔT _mk [transmit data packets of k-th priority, in Otherwise, or if there is a busy signal, the steps for generating the transmission enable signal are repeated in n subsequent clock cycles, where n = D ^o C k, and D is the number of clock cycles of the packet radio installation in the network, at which, with a given probability P, the transmission of first priority data packets occurring Odita at least once, the numbers k-th priority data packet signal formed by time k-D cycles with respective durations ΔT _mk, ΔT _mk-1, ..., ΔT _m2, ΔT _m1
2. The method according to claim 1, characterized in that the duration of the random pulse Δt _{c is} selected in the range Δt _c = (0.05 ... 0.1) (T / K).  3. The method according to claim 1, characterized in that when receiving a data packet with k-th priority, a confirmation signal for receiving it is additionally generated on the corresponding packet radio installation, a confirmation signal is transmitted, and in the absence of a confirmation signal, actions to control the transmission of the data packet with k -th priority is repeated.  4. A device for controlling the transmission of data packets in a public communication channel, comprising a counter, a long pulse shaper, a trigger, a synchronizer, a first OR element, a transmission enable signal generator, the output of which is connected to the first input of the comparison unit, characterized in that it additionally introduced, the first and second elements are PROHIBITED, a D-trigger, the information input of the shift register is connected to the output of the first OR element, the first input of which is connected to the information input of the device, and the second to formation output of the shift register, from the Jth to the J + nth information outputs of the shift register are connected to the corresponding information inputs of the first reading unit, from the 1st to the nth information inputs of the OR block are connected to the corresponding outputs of the first reading unit, where n = {2,3, ...}, and from the 1st to the nth enable inputs of the OR block of elements are connected to the corresponding outputs of the AND block, the n allow inputs of which are connected to the output of the first multi-input OR element, n outputs of the block of elements OR connected to match n inputs of the storage register and the first decoder, n outputs of the storage register are connected to the corresponding n information inputs of the second reading unit, to the sync input of which the output of the second multi-input element OR is connected, n outputs of the second reading unit are connected to the corresponding information inputs of the incrementer, to the sync input of which the output is connected of the first multi-input OR element, n incremental outputs are connected simultaneously to the corresponding n information inputs of the block of AND elements and n inputs of the second about the decoder, To the outputs of which are simultaneously connected to the corresponding To inputs of the long pulse shaper and the third multi-input element OR, K = {2,3, ...}, the output of the long pulse shaper is connected to the information input of the comparison unit, to the input of the transmission permission signal generator the output of the third multi-input element OR is connected, the output of the comparison unit is connected to the direct input of the second BAN element, the output of which is simultaneously the TRANSMITTER ON and connected to the first input of the second ele OR gate, the output of which is connected to the second input D = trigger, the output of the second element OR is connected to the input of the dispenser of control pulses, the output of which is simultaneously connected to the clock input of the shift register and to the counter input, an external input of the EMPLOYMENT SIGNAL is connected to the inverse input of the first and second element PROHIBITION, the output of the first of which is connected simultaneously to the second input of the AND element and to the input of the delay line, the output of the counter is simultaneously connected to the direct input of the first element of PROHIBITION and to the clock inputs K of the pulse dispensers , the k-th output of the first decoder, where k = {1, ..., K}, is connected to the START input of the corresponding k-th pulse dispenser, the TIMER output of which is connected to the k-th input of the first multi-input element OR, and the output of the BUNCH to k-th input of the multi-input element OR, the external input TRANSMISSION REQUEST is simultaneously connected to the S-inputs of the first and second RS-trigger, to the shift register reset input, to the R-input of the D-trigger, the S-input of the first RS-trigger is connected to the external input RECEIPT, the synchronizer output is connected to the information input of the D-trigger, the delay line output is connected it is connected to the R-input of the second RS-trigger, the output of which is connected to the first input of the And element, and the output of the first RS-trigger is connected to the sync input of the D-trigger, the output of the And element is connected to the reset input of the first reading unit, the information output of the shift register is the output of the device .

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