RU2138128C1 - Device controlling transmission of data packages - Google Patents

Abstract

FIELD: computer engineering. SUBSTANCE: invention can be used at centers of package ( message ) commutation of data communication networks employing communication channels of various physical nature and providing for transmission of bath data and other types of information, for instance, speech after package processing. Device controlling transmission of data packages includes address unit 1 of establishment of connections, address unit 2 of directions, program unit 3, reception/transmission register 4, profile storage 5, adder 6, collection circuit 7, unit 8 of comparison and summing, automatic control unit 9, storage 10 of additional pitches, unit 11 generating directions, m formers 12₁...12_m of additional pitches, former 13 of virtual channel and has three controlling inputs, information input and profile output, four controlling outputs, information receipt input, m information two-input groups. Device controlling transmission of data packages makes it feasible to control automatic commutation of messages both during data transmission and during transmission of other types of loads such as speech messages in real time. EFFECT: enhanced operational reliability of device. 2 cl, 4 dwg

Description

 The invention relates to computer technology and can be used at the centers (nodes) of switching packets (messages) of data transmission networks (PD) using communication channels of various physical nature and providing both data transmission and the transmission of other types of information (for example, speech after packet processing).

 Known control devices that provide route selection in PD networks with message switching, described in the book of I.A. Mizin and others "Information transfer in networks with message switching". -M.:, “Communication”, 1972, p. 319, taking into account the number of transit sections, the state of channels and other factors. However, these devices cannot be used in communication networks transmitting both data and other types of information in real time, since various switching methods must be applied to the data and to the real-time load. It is assumed that the transmission of a voice message is carried out only after the creation of the transmit-receive path (the so-called virtual connection is made), and the data packets of one message can be transmitted using the datagram method (that is, along different routes) / I.A. Mizin, V.A. Bogatyrev, A.P. Kuleshov "Network packet switching." -M.: "Radio and Communications", 1986, p. 89-93 /.

 The closest analogue (prototype) to the claimed device is essentially a technical solution is a decentralized network management device (UDUS), described in the collection of articles "Discrete Automation and Communication Networks". -M. :, "Science", 1970, pp. 24-25, Fig. 2 and containing the address block for establishing connections (in the prototype, this block is called the address device for establishing connections), address block for directions (in the prototype, the address device for directions), program block ( in the prototype, a software device), a transmission reception register, a relief memory block, an assembly block (in the prototype, an assembly diagram), a comparison and summation block (in the prototype, a comparison and summation device), a direction issuing unit (in the prototype, a direction issuing device) unit automatically oh control (in the prototype, an automatic control device). In this case, the inputs of the address block for establishing connections and the address block for direction are connected to the outputs of the switching system. The five outputs of the software block are connected respectively to the inputs of the address block for establishing connections, the address block for directions, the block for relief memory, the block for comparing and summing, the block for issuing directions. The output of the address block of directions is connected to the input of the block of memory of the relief. The output of the address block for establishing connections is connected to the input of the relief memory block. The input of the UDUS connected to the outputs of the neighboring UDUS is connected in parallel with the input of the transmit-receive register and the input of the automatic control unit, the output of which is connected in parallel with the output of the receive-transmit register, the input of the automatic control unit and is the output of the device connected to the inputs of the neighboring UDUS. Another output of the transmit-receive register is connected to the input of the relief memory block, the output of which is connected to the assembly circuit. The output of the assembly circuit is connected to the input of the comparison and summing unit, the output of which is connected to the direction issuing unit. The output of the direction issuing unit is the output of the device and is connected to the control device of the switching system.

 However, this device is strictly focused only on packet data transmission with a specific message delivery time and in accordance with the use of a datagram switching method. The transmission of voice messages, which requires a real-time transmission path, that is, when the so-called virtual connection of the message source and receiver along a fixed route is possible, is not possible using this device, which limits the scope and narrows its functionality when transmitting various types of information.

 Thus, the task is to develop a device for controlling the transmission of data packets having advanced functionality both for data transmission and for transmitting other types of information, for example, voice messages in real time.

 The specified technical result is achieved by the fact that in the known device for controlling the transmission of data packets containing an address block for establishing connections, an address block of directions, a program block, a transmit-receive register, a relief memory block, an assembly block, a comparison and summing block, an automatic control block, a block issuing directions, the first input of the address block establishing connections is the first control input of the device, and the output is connected to the first input of the relief memory block, the first input of the address block the direction window is the second control input of the device, and its output is connected to the second input of the relief memory block, the first output of the software block is connected to the control input of the address block for establishing connections, the second output of the software block is connected to the control input of the comparison and summing block, the third output of the software block is connected with the control input of the relief memory unit, the fourth output of the program unit is connected to the control input of the direction issuing unit, the fifth output of the program unit is connected to the control input of the address block of directions, the output of the assembly block is connected to the first input of the comparison and summing block, the output of which is connected to the second input of the direction issuing block, the output of which is the first control output of the device, the input of the transmit-receive register is the information input of the device relief, connected to the first the input of the automatic control unit, the output of the serial code of the transmit-receive register is connected to the second input of the automatic control unit, the output of the automatic control unit the role is connected to the output of the serial code of the transmit-receive register and is the information output of the relief of the device, the output of the parallel code of the transmit-receive register is connected to the information input of the relief memory block, an adder, a storage unit for additional heights, m blocks for generating additional heights, a virtual education block channel, the first input of the address block establishing connections is connected to the second input of the block forming a virtual channel. The first input of the virtual channel formation unit is the third control input of the device. The output of the direction issuing unit is connected to the third input of the virtual channel generation unit, the fourth input of which is the information input of the device receipt. The first, second and third outputs of the virtual channel generation unit are the second, third and fourth control outputs of the device, respectively. The output of the relief memory block is connected to the first input of the adder, the output of which is connected to the input of the assembly block. The third output of the program unit is connected to the control input of the storage unit for additional heights, the output of which is connected to the second input of the adder. The output of the address block of directions is connected to the second input of the block for storing additional heights. The output of the address block for establishing connections is connected in parallel with the address input of the block for storing additional heights, the first inputs of m blocks for generating additional heights, the outputs of which are connected respectively to the information inputs of the block for storing additional heights. The second and third inputs of m blocks for the formation of additional heights are respectively m two-input groups of information inputs of the device.

 The virtual channel formation unit contains a delay line, random access memory (RAM), first and second decoders, a register, an OR element, a trigger, a timer, and a key. The first and second inputs of the key are respectively the first and second inputs of the virtual channel formation unit, the output of the key is connected to the input of the register entry. The first input of the delay line is connected to the register reading input and is the third input of the virtual channel formation block. The output of the OR element is connected to the input of the register reset, the output of which is connected to the input of the first decoder, the first output of which is connected to the first input of RAM, the output of which is the first output of the virtual channel generation unit. The output of the delay line is connected in parallel with the second RAM input and the timer start input. The input of the second decoder is the fourth input of the virtual channel generation unit, and its output is connected in parallel with the first input of the OR element, the first input of the trigger and the timer reset input. The timer output is connected in parallel with the second input of the OR element, the second input of the trigger and the reset reset input. The first and second outputs of the trigger are respectively the third and second outputs of the virtual channel generation unit.

 The unit for generating additional heights contains the first and second delay lines, the first and second dividers, the adder, the first and second accumulating adders, and a timer. The third input of the adder is the first input of the unit for generating additional heights, the output of the adder is the output of the unit for generating additional heights. The timer input is connected to the first input of the first accumulating adder and is the second input of the unit for generating additional heights, the output of the adder is connected to the input of the first divider, the output of which is connected to the input of the first delay line, the output of which is connected to the first input of the adder. The timer output is connected in parallel with the second input of the first accumulating adder and the input of the second delay line, the output of which is connected to the second input of the second accumulating adder. The output of the second accumulating adder is connected to the input of the second divider, the output of which is connected to the second input of the adder. The first input of the second accumulating adder is the third input of the unit for generating additional heights.

 Thus, the specified set of essential features of a control device for transmitting data packets, in contrast to the prototype, allows you to expand its functionality and provide not only data transfer, but also other types of information, such as, for example, voice messages in real time, by creating a virtual channel according to two criteria. The choice of a virtual channel is carried out, firstly, by the shortest path (first criterion), and secondly, taking into account the reliability of the chosen direction (second criterion).

The inventive device is illustrated by drawings, which show:
in FIG. 1 is a structural diagram of the inventive device for controlling the transmission of data packets;
in FIG. 2 is a block diagram of a virtual channel formation unit;
in FIG. 3 is a structural diagram of a block for generating additional heights;
figure 4 - graph of the communication network (option).

The data packet transmission control device shown in FIG. 1, contains an address block for establishing connections (ABUS) 1, an address block for directions (ABN) 2, a program block (BOP) 3, a transmit-receive register (RPP) 4, a memory block for relief (BPR) 5, an assembly block (BS) 7 , comparison and summation unit (BSS). 8, automatic control unit (LHC) 9, direction issuing unit (BVN) 11, adder 6, additional altitude storage unit (BHDV) 10, additional altitude generation units (BFDV) 12 ₁ ... 12 _m , virtual channel formation unit ( BOVK) 13. The first input of ABUS 1 is the control input of the relief of the device, and its output is connected to the first input of the BPR 5. The first input of ABN 2 is the second control input of the relief of the device, and its output is connected to the second input of the BPR 5. The first output of PB3 is connected to control input ABUS 1. The second output PB3 is connected to the control input BSS 8. The third output of PB3 is connected to the control input of BPR 5. The fourth output of PBZ is connected to the control input of BVN 11. The fifth output of PBZ is connected to the control input of ABN 2. The output of BS 7 is connected to the first input of BSS 8, the output of which is connected to the second input BVN 11, the output of which is the first control output of the device. The input of the RPP 4 is an information input of the relief of the device and is connected to the first input of the LHC 9. The output of the serial code of the RPK 4 is connected to the second input of the LHC 9. The output of the LHC 9 is connected to the output of the serial code of the LHP 4 and is the information output of the relief of the device. The output of the parallel code RPP 4 is connected to the fourth input of the BPR 5. The second input of the BOWC 13 is the first control input of the device. The first input BOVK 13 is the third control input of the device. The output of the BVN 11 is connected to the third input of the BOVK 13, and its fourth input is the information input of the receipt of the device. The first, second and third outputs of the BOVK 13 are the second, third and fourth control outputs of the device, respectively. The output of the BPR 5 is connected to the first input of the adder 6, the output of which is connected to the input of the BS 7. The third output of the BOP 3 is connected to the control input of the BHDV 10, the output of which is connected to the second input of the adder 6. The output of the ABN 2 is connected to the second input of the BHDV 10. ABUS output 1 is connected in parallel with the address input of BHDV 10 and the first inputs of BFDV 12 ₁ ... 12 _m . The outputs of the BFDV 12 ₁ ... 12 _{m are} connected to the information inputs of the BDKV 10. The second and third inputs of the BFDV 12 ₁ ... 12 _m are respectively m two-input groups of information inputs of the device.

 The control unit for the transmission of data packets can be installed on the switching center, and all its inputs and outputs are connected to an automated message switch (ACS).

 BOVK 13, shown in figure 2, is used to generate ACS control signals by analyzing the presence of a virtual channel by transmitting a service packet to the node with which the virtual channel is formed and receiving a receipt from it. BOVK 13 contains a delay line (LZ) 13.1, random access memory (RAM) 13.2, the first 13.3 and second 13.4 decryptors, register 13.5, OR 13.6 element, trigger 13.7, timer 13.8 and key 13.9. The first and second inputs of the key 13.9 are respectively the first and second inputs of the BOWC 13, the output of the key 13.9 is connected to the input of the register entry 13.5. The first input of LZ 13.1 is connected to the read input of register 13.5 and is the third input of the BOVK 13. The output of the OR element 13.6 is connected to the reset input of register 13.5, the output of register 13.5 is connected to the input of the first decoder 13.3, the first output of which is connected to the first input of RAM 13.2. The output of RAM 13.2 is the first output of BOVK 13. The output of LZ 13.1 is connected in parallel with the second input of RAM 13.2 and the start input of the timer 13.8. The input of the second decoder 13.4 is the fourth input of the BOWC 13, the output of the second decoder 13.4 is connected in parallel with the first input of the OR element 13.6, the first input of the trigger 13.7 and the reset input of the timer 13.8. The output of the timer 13.8 is connected in parallel with the second input of the OR element 13.6, the second input of the trigger 13.7 and the reset input of the timer 13.8. The first and second outputs of flip-flop 13.7 are, respectively, the third and second outputs of BOVK 13. The second output of the first decoder 13.3 is connected to the second input of LZ 13.1. The output of timer 13.8 is connected to the reset input of timer 13.8.

где n - число пакетов, переданных по данному направлению, k-число поступивших на переданные пакеты квитанций.BFDV 12 ₁ ... 12 _m , shown in figure 3, serves to form additional heights by analyzing the reliability of packet delivery in the direction of transmission. By height is meant the value of g, determined by the expression

where n is the number of packets transmitted in this direction, k is the number of receipts received on the transmitted packets.

BFDV block 12 ₁ . ..12 _m contains the first 12.1 and second 12.2 delay lines (LZ), the first 12.3 and second 12.4 dividers, the adder 12.5, the first 12.6 and the second 12.7 accumulating adders, a timer 12.8. The third input of adder 12.5 is the first input of BFDV 12, the output of adder 12.5 is the output of BFDV 12. The input of timer 12.8 is connected to the first input of the first accumulating adder 12.6 and is the second input of BFDV 12. The output of the first accumulating adder 12.6 is connected to the input of the first LZ 12.1. The output of the first LZ 12.1 is connected to the first input of the adder 12.5. The output of the timer 12.8 is connected in parallel with the second input of the first accumulating adder 12.6 and the input of the second LZ 12.2. The output of the second LZ 12.2 is connected to the second input of the second accumulating adder 12.7, the output of which is connected to the input of the second divider 12.4. The output of the second divider 12.4 is connected to the second input of the adder 12.5. The first input of the second accumulating adder 12.7 is the third input of the BFDV 12. The output of the second accumulating adder is connected to the input of the second divider 12.4.

 ABUS1 is designed to receive and store the node address received in serial code from the ACS and issue it to the corresponding input of BPR5, BHDV10 and BFDV 12. It is implemented in the same way as described in the article by V. I. Laptev "On the decentralized control system of a switched communication network." in the collection Discrete automata and communication networks. -M .: "Science", 1970, pp. 25-27, fig. 3-5, is a combination of series-connected counter and decoder.

 ABN1 is designed to receive and store the direction address received in a serial code from the ACS and issue it to the corresponding address input of the BPR5 and BHDV10, implemented similarly to ABUS 1.

 BSS8 serves to compare integer functions and sums the minimum number from the set of integer functions with unity in the process of choosing a direction. It is implemented similarly to that described in the article by V.I. Lapteva "On a decentralized system for managing a switched communication network." in the collection Discrete automata and communication networks. -M .: "Science", 1970, p. 28-30, Fig. 9.

 The adder 6 is designed to add the elements of the matrices stored in BPR5 and BHDV10, implemented similarly to BSS8.

 BPR5 is designed to store relief matrices. It is implemented similarly to that described in the article by V.I. Lapteva "On a decentralized system for managing a switched communication network." in the collection Discrete automata and communication networks. -M. : "Science", 1970, pp. 26-28, Fig. 7.8.

BHDV10 is used to store matrices of additional heights formed in BFDV12 ₁ ... 12 _m and is implemented similarly to BPR5.

 PB3 provides the necessary control signals that are supplied to the units included in the device. It is implemented similarly to that described in the article by V.I. Lapteva "On a decentralized system for managing a switched communication network." in the collection Discrete automata and communication networks. -M .: "Science", 1970, pp. 30-31, Fig. 10, 11.

 BAK9 is designed to provide information about the terrain through the ACS to neighboring switching centers, implemented similarly to that described in the article by V.I. Lapteva "On a decentralized system for managing a switched communication network." in the collection Discrete automata and communication networks. -M .: "Science", 1970, pp. 31-33, fig. 12.

 RPP4 is designed to receive information from the ACS coming in a serial code from similar devices (UPPD) of neighboring nodes and converting it into a parallel code for recording in BPR5. It is implemented similarly to that described in the article by V. I. Laptev "On a decentralized system for managing a switched communication network." in the collection Discrete automata and communication networks. -M .: "Science", 1970, pp. 26-28, Fig. 6.

 BS7 is designed to interface multi-output random access memory and a low-input comparison and summing unit; it is implemented as described in the article by V. I. Laptev “On a decentralized control system of a switched communication network.” In the collection Discrete Automation and Communication Networks. -M .: "Science", 1970, p. 24.

 BVN11 provides the shortest direction and performs the function of intermediate memory when finding the shortest direction, is implemented similarly to that described in the article by V.I. Lapteva "On a decentralized system for managing a switched communication network." in the collection Discrete automata and communication networks. -M .: "Science", 1970, p. 24.31.

 Timers-elements 12.8 and 13.8 are implemented similarly to those described in A. Goldenberg Impulse devices. M .: "Radio and communications", 1981, pp. 77-79.

 Delay lines 12.1, 12.2, 13.1 are implemented as described in the manual edited by V.P. Borovsky Handbook of circuitry for a radio amateur. -K .: "Technics", 1987, p. 308, fig. 14.5.

 The adder 12.5 is implemented similarly to that described in the manual A. Papernov Logical foundations of digital computing. Textbook for technical colleges. -M.:, "Soviet Radio.", 1972, p. 147-150, Fig. 2.5.

 The accumulating adders 12.6 and 12.7 are implemented similarly to those described in the manual A. Papernov Logical foundations of digital computing. Textbook for technical colleges. -M.:, "Soviet Radio.", 1972, p. 158, Fig. 13.

 Divisors 12.3 and 12.4 are implemented similarly to those described in V. I. Shlyapobersky. Fundamentals of discrete message transmission technology. - M .: "Communication", 1973, p. 133, Fig. 3.25.

 Decoders 13.3, 13.4 are identical to those described in V. Shlyapobersky. Fundamentals of discrete messaging technology. -M .: "Communication", 1973, p. 142-143, Fig. 3.33, p. 47, fig. 3.38.

 Register 13.5 is implemented similarly to that described in the book Goldenberg L.M., Butylsky Yu.T., Polyak M.N. Digital devices on integrated circuits in communication technology. -M .: "Communication"; 1979, pp. 44-45, Fig. 2.13.

 The OR 13.6 element is implemented similarly to that described in the book by V. I. Shlyapobersky. Fundamentals of discrete message transmission technology. -M .: "Communication", 1973, pp. 44.48-50, Fig. 2.4,2.7,2.8.

 The trigger 13.7 is implemented similarly to that described in the book Goldenberg L. M., Butylsky Yu.T., Polyak M.N. Digital devices on integrated circuits in communication technology. -M .: "Communication"; 1979, pp. 67-70, fig. 3.3- 3.7.

 Key 13.9 is implemented similarly to that described in the book of Goldenberg L.M. Impulse devices. -M. : "Radio and communications." 1981, p. 62, fig. 2.33, or in the reference manual edited by V.P. Borovsky Handbook of circuitry for a radio amateur. -K .: "Technics", 1987, p. 306-307, fig. 14.3.

 RAM 13.2 is implemented similarly to that described in the book edited by S. Yakubovsky. Analog and digital integrated circuits. -M.: "Soviet Radio", 1979, p. 137, Fig. 3.15.

 For communication networks, the structure of which for one reason or another is changing, the list of paths between any pair of nodes is not constant and in the general case should be determined anew with each change in the network structure. The task of network management is to find the shortest way from a large number of possible ways each time for various situations on the network.

 A data packet transmission control device implements an algorithm for finding the shortest path / Article A. Butrimenko “Search for optimal paths in a graph with its changes” / Izv. USSR Academy of Sciences, Rel. Technical cybernetics. -M .: 1964, N6./.

In accordance with the algorithm of A. V. Butrimenko, each device makes up the network topography for its node. The relief compilation procedure is as follows. On the network branches (Fig. 4), special integer functions are introduced that define the topography. Consider an arbitrary switching node (CC), for example CC _a . On the branches incident to CC _a (that is, branches having a direction), we set the function equal to 1. We set the value of the function on the branches adjacent (adjacent) to them and those on which the function is not defined, etc. 2, etc. until the function is defined on all branches. Moreover, it is said that the network with the function values so selected on the branches is provided with an A-relief. In this way, a relief is formed on each switching node.

r_ij = 1 + V_ij, (3)
где V_ij -целочисленная функция, характеризующая кратчайшее расстояние от узла Y_i до узла Y_j.In general, the relief can be written with a matrix of the form:

r _ij = 1 + V _ij , (3)
where V _{ij is an} integer function characterizing the shortest distance from the node Y _i to the node Y _j .

 Essentially, the inventive device, when managing a communication network, performs two operations: the operation of forming a relief and the operation of finding the shortest path. The search for the shortest path starts from the moment of receipt of the application for choosing the path, and the relief formation operation is always carried out at the initial moment of the system start-up, at the time of removal or restoration of network edges and is repeated periodically with a given frequency.

The inventive device control the transmission of data packets operates in two modes:
- data transfer mode;
- real-time load transfer mode.

Consider the operation of the device in the second mode, when all the blocks of the device are involved. Information about the relief in the serial code is sent to RPP4 from the ACS through the information input of the relief. After entering in RPP4, information in the parallel code is read in BPR5 from the output of the parallel code RPP4, for which purpose the signal from the third output of PB3 is fed to the control input of BPR5. As a result, the relief matrix is recorded in BDP5. From the output of the RPP4 serial code, the information in the serial code goes to the information output of the device relief and then to the ACS and simultaneously to the second input of the BAC9, which checks the correctness of the reliefs received from neighboring ACS. Matrices of additional heights are formed during the operation of the device in the BFDV 12 ₁ ... 12 _m and are recorded in the BCDF 10.

 If it is necessary to exchange information in real time on the first input of ABUS 1 and the second input of BOVK 13 from the first control input of the device, the code of the node with which it is necessary to establish a connection is received. At the same time, the first input of the BOVK 13 receives a single signal about the need for real-time information exchange from the third control input of the device. All control and information inputs and outputs of the device are connected to the ACS. In ABUS 1, the host code is decrypted and fed to the first input of the BDP 5 and the address input of the BCHDV 10, i.e. to those memory cells that correspond to the node that is the destination. At the same time, the second inputs of the BPR 5 and BHDV 10 receive enable signals from the output of the ABN 2, the input of which receives the direction code from the second control input of the device. The control inputs of the BPR 5 and BHVD 10 receive signals from the third output of the PB 3. As a result, the outputs of the BPR 5 and BHVD 10 receive the signals to the inputs of the adder 6, with the help of which the value of the total height h is formed in the adder 6. Assembly block 7 is an interface block between multi-output BHDV 10, BPR5 and low-input BSS 8.

 Thus, BSS 8 compares between integer functions and sums the minimum number of the set of integer functions with unity in the process of forming the relief. BVN 11 selects the shortest direction and performs the function of intermediate memory when finding the shortest direction. With BVN 11, the signal characterizing the shortest direction (a single signal from the corresponding direction trigger) is supplied through the first control output of the device to the ACS, and is also transmitted to the third input of the BOVK 13. A service packet is generated in the BOVK 13, which is transmitted from the third output of the BOVK 13 to the fourth control output of the device and then through the ACS in the selected direction of transmission. If a receipt for a service packet is received from the node with which it is necessary to establish a connection, then through the ACS and the information input of the device receipt it goes to the fourth input of the BOVK 13. Upon receipt of the receipt, the BOVK 13 generates a signal that the virtual channel is ready to transmit information, which appears on the third output of BOVK 13 and through the fourth control input of the device enters the ACS. If within a period of time Δt (timer 13.8) the receipt of a service packet is not received, BOVK 13 generates a signal about the impossibility of working on this route, which comes from the second output of BOVK 13 to the third control output of the device and then to the ACS.

BFDV 12 ₁ . ..12 _m performs reliability analysis of packet delivery in the direction of transmission. The block diagram of the BFDV 12 ₁ ... 12 _m is shown in FIG. 3. In BFDV 12 ₁ . . . 12 _m , arithmetic operations of the form (1) are performed. We consider the operation of the BFDV 12 ₁ ... 12 _m using the example of the i-th block of the BFDV 12 _i . Counting the number of packets received for transmission in this direction (in this case, the number of single pulses from the ACS to the second input of the BFDV 12 _i ) is carried out in the first accumulating adder 12.6, and with the arrival of the first packet, the timer 12.8 starts. The operation time of the timer can vary depending on the operating conditions (packet transmission via wired, radio, and other communication channels) and corresponds to the duration of one cycle of the unit. Counting the number of receipts received from the ACS at the third input of the BFDV 12 _{i is} carried out in the second accumulating adder 12.7. After a time interval Δt (corresponding to the timer operation time), a single signal appears at the output of timer 12.8, which simultaneously enters the second input of the first accumulating adder 12.6 and through the delay line 12.2 to the second input of the second accumulating adder 12.7. As a result, the obtained values n + 1 (where n is the number of transmitted packets) and k + l (where k is the number of received receipts) are read in the respective adders into dividers 12.3 and 12.4, where arithmetic operations of the form are performed, respectively: 1 / (k + l ) and 1 / (n + 1), and the accumulating adders 12.6 and 12.7 are reset to zero. Thanks to the delay lines 12.1 and 12.2, the values 1 / (n + 1) and 1 / (k + l) simultaneously arrive at the first and second inputs of the adder 12.5, where their difference is calculated. The obtained value of the additional height r from the output of the BFDV 12 _{i is} recorded in the corresponding cell in the RAM of the BCHDV 10. In the future, the cycle of the unit is repeated. The simultaneous recording and reading of information from BCDF 10 is excluded, since the read signal from the output of ABUS 1 to the first input of BCDF 10 is simultaneously fed to the first input of the corresponding BFDV 12 ₁ ... 12 _m and blocks the reading of information from the corresponding element of the BFDV 12 ₁ .. .12 _m .

It should be noted that the relief formation operations (main heights) in BPR5 and BFDV12 ₁ ... 12 _m in BHDV 10 are carried out independently of each other. If the formation of the relief (main heights) is carried out periodically or at the moment of failure (restoration) of the direction, then the formation of additional heights is carried out continuously.

 BOVK 13 is used to generate control signals on the ACS. The structural diagram of the BOWC 13 is presented in figure 2. The block operates as follows. Upon receipt of the serial code of the node from the ACS to the second input of the BOVK 13, it is recorded in register 13.5 provided that there is a single signal at the first input of the BOVK 13 and, accordingly, the first input of the key 13.9. The presence of this single signal from the ACS to the third control input of the device will indicate the need for real-time information transfer. Upon receipt of the control unit signal from the BVN 11 at the third input of the BOVK 13, the parallel code of the node address is read from register 13.5 into the first decoder 13.3, in which it is decoded (decrypted). The combination at the output of the decoder 13.3 corresponds to the address of the service packet recorded in RAM, which is intended for transmission in the selected direction. Under the action of a single signal arriving through the delay line 13.1 with BVN 11, the service packet corresponding to the selected direction is read from the output of RAM 13.2 and then to the first output of the BOVK 13 and to the second control output of the device. At the same time, a single signal from the delay line 13.1 starts the timer 13.8, whose operating time is Δt. If during this period of time a receipt for a service packet is received, which arrives at the fourth input of the BOVK 13 from the information input of the device receipt, then at the output of the second decoder 13.4 and accordingly at the first input of the OR 13.6 element and the first input of trigger 13.7, a single signal will appear, under the action of which at the first output of trigger 13.7 and, respectively, at the third output of the BOVK 13 and the fourth control output of the device, a single signal appears, indicating the establishment of a virtual channel. At the same time, the signal from the output of the decoder 13.4 will reset timer 13.7 and register 13.5 through the OR element 13.6. If a receipt is not received within the time interval Δt, then a single signal will appear at the output of timer 13.8, which will be sent to the second inputs of trigger 13.7 and the OR element 13.6, as well as to the second input (reset) of timer 13.8. This signal through the element OR 13.6 also sets register 13.5 to its initial state and stops (reset) timer 13.8. At the second output of trigger 13.7, a single signal appears, indicating that the virtual channel is not formed. This signal is transmitted through the second output of the BOVK 13 to the third control output of the device and then to the ACS.

 In the data transfer mode, the device operates similarly to the real-time load transfer mode, except that the BOVK 13 does not participate in the operation of the device, since the signal from the ACS is not supplied to the third control input of the device.

 The effectiveness of the claimed device can be judged on the basis of its functionality. Firstly, it implements a decentralized control procedure, secondly, it provides control of both data transmission and other types of information, thirdly, it provides high reliability of packet delivery in comparison with known devices.

Claims (3)

 1. A data packet transmission control device comprising an address block for establishing connections, an address block of directions, a program block, a receive-transmit register, a relief memory block, an assembly block, a comparison and summing block, an automatic control block, a direction issuing unit, and the first input of the address the connection block is the first control input of the device, and its output is connected to the first input of the relief memory block, the first input of the address block of directions is the second control input of the device VA, and its output is connected to the second input of the relief memory block, the first output of the software block is connected to the control input of the address block for establishing connections, the second output of the software block is connected to the control input of the comparison and summing block, the third output of the software block is connected to the control input of the relief memory block , the fourth output of the program block is connected to the control input of the block issuing directions, the fifth output of the program block is connected to the control input of the address block of directions, the output of the block assembly is connected to the first input of the comparison and summing unit, the output of which is connected to the second input of the direction issuing unit, the output of which is the first control output of the device, the input of the transmit-receive register is the information input of the device relief and connected to the first input of the automatic control unit, the output of a serial code the transmit-receive register is connected to the second input of the automatic control unit, the output of the automatic control unit is connected to the output of the serial register code pr receive-transmission is the information output of the relief of the device, the output of the parallel code of the transmit-receive register is connected to the information input of the relief memory block, characterized in that an adder, a storage unit for additional heights, m blocks for generating additional heights, where m = 1, 2 , 3 ... is the number of serviced communication directions, as well as a virtual channel generation unit, the first input of the address block for establishing connections being connected to the second input of the virtual channel generation unit, the first input the virtual channel generation unit is the third control input of the device, the output of the direction issuing unit is connected to the third input of the virtual channel generation unit, the fourth input of which is the information input of the device receipt, the first, second and third outputs of the virtual channel generation unit are the second, third and fourth control the outputs of the device, the output of the relief memory unit is connected to the first input of the adder, the output of which is connected to the input of the assembly unit, the third output q the software unit is connected to the control input of the additional heights storage unit, the output of which is connected to the second input of the adder, the output of the address block of directions is connected to the second input of the additional heights storage unit, the output of the address block for establishing connections is connected in parallel with the first input of the additional height storage unit, the first inputs m blocks for the formation of additional heights, the outputs of m blocks for the formation of additional heights are connected respectively with the address inputs of the storage unit lnyh heights, second and third inputs of m blocks formation of additional heights are respectively the m groups of information inputs of two-input device.  2. The device according to claim 1, characterized in that the virtual channel generation unit comprises a delay line, random access memory, first and second decoders, a register, an OR element, a trigger, a timer and a key, the first and second inputs of which are respectively the first and second the inputs of the virtual channel generation unit, and the output is connected to the register entry input, the first delay line input is connected to the register read input and is the third input of the virtual channel formation unit, the output of the OR element is connected to the input with register dew, the output of which is connected to the input of the first decoder, the first output of which is connected to the first input of random access memory, the output of which is the first output of the virtual channel generation unit, the output of the delay line is connected in parallel with the second input of random access memory and the timer start input, the input of the second the decoder is the fourth input of the virtual channel formation unit, and its output is connected in parallel with the first input of the OR element, the first input of the trigger, and Odom reset timer, the output of which is connected in parallel with the second input of the OR gate, the second input of the flip-flop and the reset input of the timer, the first and second outputs of the latch are respectively the third and second outputs of the block formation of the virtual channel, the second output of the first decoder is connected to a second input of the delay line.  3. The device according to claim 1, characterized in that the unit for generating additional heights contains the first and second delay lines, the first and second dividers, the adder, the first and second accumulating adders and a timer, the third input of the adder being the first input of the unit for generating additional heights, the output of the adder is the output of the unit for generating additional heights, the input of the timer is connected to the first input of the first accumulating adder and is the second input of the unit for generating additional heights, the output of the first accumulative the first adder is connected to the input of the first divider, the output of which is connected to the input of the first delay line, the output of which is connected to the first input of the adder, the timer output is connected in parallel with the second input of the first accumulating adder and the input of the second delay line, the output of which is connected to the second input of the second accumulating adder the output of which is connected to the input of the second divider, the output of which is connected to the second input of the adder, the first input of the second accumulating adder is the third input of the forming unit I have extra heights.

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