RU2168870C1 - Device controlling data transmission over radio channel - Google Patents

Abstract

FIELD: computer engineering. SUBSTANCE: device can be used at centers of commutation of data packages in transmission network of automated control system. Device has flip-flop of transmission cycle, AND gates, pulse former, synchronizer, delay element, unit determining intensity of flow, generator of analysis intervals, OR gate, unit computing carrying capacity, unit making decisions, unit computing mean parameter of action range, unit determining removed distant station, N-input AND gate, N-input OR gate and commutation unit. EFFECT: provision for increase of carrying capacity of communication channel thanks to normalization of load and correction of number of distant stations included in channel. 6 dwg

Description

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

 A device is known for controlling data transmission over a radio channel (AS USSR N 1162058, class H 04 L 7/00, 1985), comprising a synchronizer and a first AND element in series, as well as a delay element, an OR element, and a counter connected in series and a transmission cycle trigger, a random number generator connected in series, a comparison unit and a transmission enable trigger, as well as a second AND element and a pulse shaper connected in series, which makes it possible to increase the utilization of the channel capacity. However, this device has insufficient transmission capacity over the air.

The closest technical essence and the functions performed to the claimed one is a device for controlling data transmission over a radio channel (A. p. RF N 2099889, class 6 H 04 L 7/00, 1995), containing a synchronizer, the first element And, the trigger of the transmission cycle , second AND element, pulse generator, analysis interval generator, input stream intensity determination unit, comparison unit, first OR element, decoder, N address recognition blocks 11 ₁ -11 _N , second OR element, switching block, address allocation block, third element OR, trigger times transmission decisions, the third AND element, the fourth AND element, the delay element. Moreover, the synchronizer output is connected to the direct input of the first element And, the inverse input of which is connected to the direct output of the trigger of the transfer cycle, the first input of the second element And and the inverse input of the trigger enable transmission are interconnected and are the input signal "Request transmission" of the device, the input of the carrier signal of which is the first input of the trigger of the transfer cycle, the direct output of the trigger of the enable transmission is connected to the first input of the first element OR and is the input "Enable transmission", the second input of the first element LI is connected through a delay element to the first input of the third AND element and to the first input of the fourth And element, the output of which is connected to the inverse input of the third And element, the output of which is connected to the direct input of the transmission enable trigger, the output of the first OR element and the output of the fourth And element are, respectively the outputs "Turning on the transmitter" and "Collision" of the device, as well as the comparison unit and the pulse shaper, the first and second inputs of the trigger of the transfer cycle are interconnected, and the output of the trigger of the transfer cycle with it is single with the first input of the address allocation unit and with the input of the pulse shaper, the output of which is connected to the first input of the input flow intensity determination unit, the second input of which is connected to the output of the analysis interval generator and with the first inputs of N address recognition units, the outputs of the input flow intensity determination unit are connected with the corresponding inputs of the comparison unit, the first and second outputs of which are connected via the second OR element to the first control input of the switching unit, to the second control input of which the third output of the comparison unit is connected, the outputs of the N address recognition blocks through the third OR element are connected to the address input of the switching unit, the input of the initial state of which is connected to the inverse input of the trigger to enable transmission, the first output of the switching unit is the output of "Permission of transmission at the frequency of access to the relay" device, and the second output of the switching unit is connected to the second input of the second element And, the third input of which is connected to the output of the first element And, the output of the second element And is connected to the second the input input of the first OR element, the second input of the fourth AND element and the second input of the address allocation unit are interconnected and are the input of a multiple access channel, the outputs of the address allocation unit are connected to the corresponding inputs of N address recognition units, to the control inputs of which the corresponding outputs of the decoder are connected, inputs which are the "Address Code" inputs of the device.

 With such a combination of the described elements and connections, a certain increase in the radio channel throughput is achieved in comparison with the considered device according to A.S. USSR N 1162058.

 However, the prototype device still has insufficient bandwidth, due to the lack of the ability to normalize the load by adjusting the number of correspondents included in the channel.

 The aim of the invention is the development of a device for controlling the transmission of data over a radio channel providing increased throughput by normalizing the load by adjusting the number of correspondents included in the channel.

 This goal is achieved by the fact that in a known device for controlling data transmission over a radio channel containing a trigger of a transmission cycle, the reset and installation inputs of which are interconnected and are the signal input of the device, and the output is connected to the inverse input of the first element And and the input of the pulse shaper, synchronizer, the output of which is connected to the direct input of the first element And, the output of which is connected to the first input of the second element And, the second input of which is connected to the input of the trigger setting and is controlled with the input of the device, the trigger reset input is connected to the output of the third element And, the direct input of which is connected to the first input of the fourth element And and the output of the delay element, the inverse input of the third element And is connected to the output of the fourth element And is the output "Collision" of the device, the output of the driver pulses are connected to the first input of the input flow rate determination unit, the output of the analysis interval generator is connected to the second input of the input flow rate determination unit, the output of the second And AND is connected to the first input of the OR element and the input of the delay element, the output of the OR element is the "Transmission enable" output of the device, the trigger output is connected to the second input of the OR element and is the "Turn on the transmitter" output of the device, an additional bandwidth calculation block, an acceptance block solutions, a block for calculating the average long-range parameter, a counter, a demultiplexer, N blocks for determining a long-range parameter, where N ≥ 2 is the number of correspondents in the radio channel, a block for determining the deleted Ndenta, N is the input element AND, N is the input element OR, the switching unit, while the output of the unit for determining the intensity of the input stream is connected to the first information input of the unit for calculating the bandwidth and the input "Intensity of the input stream" of the decision unit, the output of the unit for calculating the bandwidth connected to the input "Bandwidth parameter" of the decision block, the information input of the device is connected to the information inputs of N blocks for determining the long-range parameter and the second input of the quad of the ith element, i-th, where i = 1, 2, 3 ... N, the output of the counter is connected to the i-th input of the demultiplexer and the i-th input of N - the input element of And, the i-th output of the demultiplexer is connected to the control input of the i-th block for determining the long-range parameter, the output of N - the input element AND is connected to the input "Change threshold" of the block for determining the deleted correspondent, the output "Address", the block for determining the parameter of long-range action is connected to the i-th input N of the input element OR, the output of which is connected to group input of the switching unit, the output "Long-range parameter" of the i-th the long-range parameter determination unit is connected to the i-th input of the average long-range parameter calculation unit and the i-th input of the deleted correspondent determination unit, the output of which is connected to the input of the switching unit, the output of which is the device output address, the output of the medium-range parameter calculation unit is connected to the second information the input of the bandwidth calculation unit and the input of the "Medium Range Distance" of the decision unit, the output of which is the signal output of the device Twa.

 Thanks to a new set of essential features due to the introduction of a throughput calculation unit, a decision unit, an average long-range parameter calculation unit, a counter, a demultiplexer, N long-range parameter determination units, a deleted correspondent determination unit, N is an input element AND, N is an input element OR, of the switching unit, the load is normalized by adjusting the number of correspondents included in the channel, thereby increasing the throughput of the channel sets access.

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

The inventive device is illustrated by drawings, where:
in FIG. 1 shows a functional diagram of a control device for transmitting data over a radio channel;
in FIG. 2 is a diagram of a bandwidth calculation unit;
in FIG. 3 is a diagram of a decision making unit;
in FIG. 4 is a block diagram for computing an average long-range parameter;
in FIG. 5 is a diagram of a unit for determining a long-range parameter;
in FIG. 6 is a block diagram of a determination of a deleted correspondent.

The claimed radio data transmission control device shown in FIG. 1, consists of a synchronizer 1, a first element And 2, a trigger of a transmission cycle 3, a second element And 4, a pulse shaper 5, an interval generator analysis 6, a unit for determining the intensity of the input stream 7, a unit for calculating the throughput 8, the decision block 9, block computing the average long-range parameter 10, counter 11, demultiplexer 12, N blocks for determining the long-range parameter 13 ₁ -13 _N , the block for determining the deleted correspondent 14, N - input element. And 15, N - input element OR 16, switching unit 17, trigger 18, element OR 19, third element And, fourth element And 21, delay element 22. Moreover, the reset and installation inputs of the trigger of the transmission cycle 3 are interconnected and are a signal input devices, and the output is connected to the inverse input of the first element And 2 and the input of the pulse shaper 5. Synchronizer 1, the output of which is connected to the direct input of the first element And 2, the output of which is connected to the first input of the second element And 4, the second input of which is connected to the installation input flip-flop 18 is the control input of the device. The reset input of the trigger 18 is connected to the output of the third element And 20, the direct input of which is connected to the first input of the fourth element And 21 and the output of the delay element 22. The inverse input of the third element And 20 is connected to the output of the fourth element And 21 and is the output "Collision" of the device. The output of the pulse shaper 5 is connected to the first input of the unit for determining the intensity of the input stream 7. The output of the generator of intervals of analysis 6 is connected to the second input of the unit for determining the intensity of the input stream 7. The output of the second element And 4 is connected to the first input of the element OR 19 and the input of the delay element 22. Output element OR 19 is the output "Resolution" of the device. The output of the trigger 18 is connected to the second input of the OR element 19 and is the output "Turn on the transmitter" of the device. The output of the unit for determining the intensity of the input stream 7 is connected to the first information input of the unit for calculating the capacity of 8 and the input "Intensity of the input stream" of the decision unit 9. The output of the unit for calculating the capacity of 8 is connected to the input "Bandwidth parameter" of the decision unit 9, information input device coupled to the data inputs of the N blocks of long-range parameter determining January ₁₃ -13 _N and the second input of the fourth aND gate 21. i-th output of the counter 11 are connected with i-th input MUX leksora 12 and the i-th input of N - input elements 15. And the i-th output of the demultiplexer 12 is connected to the control input of i-th block of the long-range parameter determining January ₁₃ -13 _N. The output N of the input element And 15 is connected to the input “Change threshold” of the block for determining the deleted correspondent 14. The output “Address”, the block for determining the long-range parameter 13 ₁ -13 _{N is} connected to the i-th input N of the input element OR 19, the output of which is connected to the group input switching unit 17. exit "long-range parameter" i-th block of the long-range parameter determining January ₁₃ -13 _N connected to the i-th input block parameter calculating the average long-range 10 and i-th input determination unit removed correspondent 14, whose output is connected to the input switching unit 17, whose output is the output of the device address. The output of the unit for calculating the average long-range parameter 10 is connected to the second information input of the unit for calculating the throughput 8 and the input of the "Middle-range parameter" of the decision unit 9, the output of which is the signal output of the device.

 The inventive device is implemented as follows.

 The bandwidth calculation unit 8 is designed to determine the bandwidth of the multiple access channel in the current analysis interval. One embodiment of the throughput computing unit 8 may be the circuit shown in FIG. 2 and consisting of read-only memory devices 8.1 and 8.2, multipliers 8.3 and 8.4, divider 8.5 and adder 8.6. Moreover, the group input "First information input" of the bandwidth calculation unit 8 is the first group input of the read-only memory 8.1 and is connected to the first group inputs of the multipliers 8.3 and 8.4. The group input "Second information input" of the bandwidth calculation unit 8 is the second group input of the read-only memory 8.1 and is connected to the group input of the read-only memory 8.2. The group output of the read-only memory device 8.1 is connected to the second group input of the multiplier 8.3 and the first group input of the adder 8.6. The group output of the read-only memory 8.2 is the second group input of the multiplier 8.4. The group output of the multiplier 8.3 is connected to the first group input of the divider 8.5. The group output of the multiplier 8.4 is the second group input of the adder 8.6. The group output of the adder 8.6 is connected to the second group input of the divider 8.5. The group output of the divider 8.5 is the group output "Information output" of the bandwidth calculation unit 8.

Decision block 9 is designed to make decisions on adjusting the number of correspondents in a multiple access channel and issuing a signal that initiates the formation of a control packet. One embodiment of decision block 9 may be the circuit shown in FIG. 3 and consisting of read-only memory devices 9.1 and 9.2, comparison schemes 9.3 and 9.4, and AND element 9.5. Moreover, the group input "Average long-range parameter" of the decision block 9 is the group input of read-only memory 9.1 and is connected to the group input of read-only memory 9.2. The group input "Bandwidth parameter" of the decision block 9 is connected to the inputs B ₁ -B _n of the comparison circuit 9.3. The group input "Intensity of the input stream" of the decision block 9 is connected to the inputs B ₁ -B _n of the comparison circuit 9.4. The group output "S _max " read-only memory device 9.1 is connected to the inputs A ₀ -A _n comparison circuit 9.3. The group output Λ _{max of} read-only memory 9.2 is connected to the inputs A ₀ -A _n of the comparison circuit 9.3. The output "A>B" of the comparison circuit 9.2 is the first input of the AND element 9.5. The output "A <B" of the comparison circuit 9.4 is the second input of the AND element 9.5. The output of the element And 9.5 is the output of the "Signal input" block decision 9.

Одним из вариантов реализации блока вычисления среднего параметра дальнодействия 10 может быть схема, показанная на фиг. 4 и состоящая из сумматора по модулю 2 10.1 элемента ИЛИ 10.2, счетчика 10.4 и делителя 10.3. Причем первый групповой вход [α₁] блока вычисления среднего параметра дальнодействия 10 является первым групповым входом сумматора по модулю 2 10.1 и соединен со входом n элемента ИЛИ 10.2. Второй групповой вход [α₂] блока вычисления среднего параметра дальнодействия 10 является вторым групповым сумматора по модулю 2 10.1 и соединен со входом n-1 элемента ИЛИ 10.2. Групповой вход [α_i] блока вычисления среднего параметра дальнодействия 10 является i групповым входом сумматора по модулю 2 10.1 и соединен с первым входом элемента ИЛИ 10.2. Групповой выход сумматора по модулю 2 10.1 является первым групповым входом делителя 10.3. Выход элемента ИЛИ 10.2 является входом счетчика 10.4. Групповой выход счетчика 10.4 является вторым групповым входом делителя. Групповой выход делителя является групповым выходом

блока вычисления среднего параметра дальнодействия 10.The unit for calculating the average long-range parameter 10 is designed to calculate the average value of the long-range parameter for the multiple access channel in accordance with the expression

One embodiment of the unit for calculating the average long-range parameter 10 may be the circuit shown in FIG. 4 and consisting of an adder modulo 2 10.1 of the OR element 10.2, a counter 10.4 and a divider 10.3. Moreover, the first group input [α ₁ ] of the block for calculating the average long-range parameter 10 is the first group input of the adder modulo 2 10.1 and is connected to the input n of the OR element 10.2. The second group input [α ₂ ] of the block for calculating the average long-range parameter 10 is the second group adder modulo 2 10.1 and is connected to the input n-1 of the OR element 10.2. The group input [α _i ] of the middle range calculation unit 10 is the i group input of the adder modulo 2 10.1 and is connected to the first input of the OR element 10.2. The group output of the adder modulo 2 10.1 is the first group input of the divider 10.3. The output of the OR element 10.2 is the input of the counter 10.4. The group output of the counter 10.4 is the second group input of the divider. Divider group output is group output.

unit for calculating the average long-range parameter 10.

The blocks for determining the long-range parameter 13 _i are designed to determine the long-range parameter from N correspondents working in the channel. One embodiment of the long-range parameter determination unit 13 _i may be the circuit shown in FIG. 5, which consists of electronic switches 13.2 and 13.3, pulse shaper 13.1, RG triggers 13.4 and 13.5, elements 10 OR 13.6 and 13.7 of the adder modulo 2 13.8 and read-only memory 13.9. Moreover, the input "Information input" of the long-range parameter determination unit 13 _i is the information input of the electronic switch 13.2, and is connected to the input of the pulse shaper 13.1. The input "Control input" of the long-range parameter determination unit 13 _{i is} connected to the read enable input of the ROM 13.9. The output of the pulse shaper 13.1 is the control input of the electronic switch 13.2. The first output of the electronic switch 13.2 is connected to the information input of the RG-trigger 13.4. The second output of the electronic switch 13.2 is connected to the synchronization input of the RG-trigger 13.4. The group output of the RG-trigger 13.4 is the group output "Address" of the long-range parameter determination unit 13 _i and is connected to the group input of the OR element 13.6. The output of the OR element 13.6 is connected to the control input of the electronic switch 13.3 and the reset input of the RG trigger 13.4. The first output of the electronic switch 13.3 is connected to the information input of the RG-trigger 13.5. The second output of the electronic switch 13.3 is connected to the synchronization input of the RG-trigger 13.5. The group output of the RG-trigger 13.5 is the first group input of the adder modulo 2 13.8 and is connected to the group input of the OR 13.7 element. The group input of the long-range parameter determination unit 13 _i is the second group input of the adder modulo 2 13.8. The output of the OR element 13.7 is connected to the reset input of the RG-trigger 13.5. The group output of the adder but module 2 13.8 is a group input of read-only memory 13.9. The group output of which is the group output "Long-range action parameter" of the long-range parameter determination unit 13 _i .

Block definition of the deleted correspondent 14 is designed to determine the address of the most remote correspondent, switching it to another channel of multiple access allows you to normalize the streaming environment. One embodiment of the block for determining the deleted correspondent 14 may be the circuit shown in FIG. 6, which consists of OR elements 14.1 and 14.4, a counter 14.2 and a comparison scheme 14.3. Moreover, the first, second and i-th group inputs of the block are respectively the first, second and i-th group inputs of the OR element 14.1. The input "Change threshold" is the input of the counter 14.2. The group output of the OR element 14.1 is connected to the inputs A ₀ -A _n comparison circuit 14.3. The group output of the counter 14.2 is connected to the inputs B ₀ -B _n of the comparison circuit 14.3. The output "A>B" which is connected to the first input of the element OR 13.4. The output "A = B" of the comparison circuit 14.3 is connected to the second input of the OR element 14.4. The output of the OR element 14.4 is the output of the block.

 The synchronizer 1 is designed to generate clock pulses whose duration is approximately equal to the duration of the deadband. The synchronizer is a clock generator and can be implemented on integrated circuits (ICs) of the 511, 176 series and is described - Microcircuits and their application: Reference, manual. / B.A. Batushev, V.N. Veniaminov, V. G. Kovalev and others. M .: Radio and communication, 1984, p. 118, fig. 4.12.

 Logic elements AND 2, 4, 15, 20, 21 and logic elements OR 16, 19 can be implemented on the IC series 133 and 564 and described the Basics of digital technology. / L. A. Maltseva, E.M. Fromberg, V.S. Yampolsky. M .: Radio and communication, 1986, p. 20-24, fig. 9, 11.

 The pulse shaper 5 can be implemented on the IMS series 155, 176 and described - Fundamentals of digital technology. / L.A. Maltseva, E.M. Fromberg, V.S. Yampolsky. M .: Radio and communication, 1986, p. 30-31, fig. 22.

 The analysis interval generator 6 is intended for the formation of time windows during which statistics on the flow situation in the channel are accumulated. The analysis interval generator is a pulse generator with a fairly wide range of changes in the frequency of the generated pulses. The analysis interval generator 6 can be implemented on the IMS series 155, 176 and described - Fundamentals of digital technology. / L.A. Maltseva, E.M. Fromberg, V.S. Yampolsky. M .: Radio and communication, 1986, p. 28-29, fig. 18, 19.

 The unit for determining the intensity of the input stream is designed to determine the number of packets transmitted in the multiple access channel during the analysis interval. One of the options for implementing the unit for determining the intensity of the input stream 7 may be the circuit described in the description of the invention to the patent of the Russian Federation, copyright certificate 2099889, class. H 04 L 7/00, 1995, FIG. 2.

 The delay element 22 can be implemented as a pulse shaper on the IC series 155 and 176, the circuit of which is given and described. - Fundamentals of digital technology. / L.A. Maltseva, E.M. Fromberg, V.S. Yampolsky. M .: Radio and communication, 1986, p. 30-31, fig. 22.

 The switching unit 17 is designed to transmit to the address output of the device a code combination of the address of the deleted correspondent. One of the options for the implementation of the switching unit may be the circuit described in the description of the invention to the patent of the Russian Federation, copyright certificate 2099889, class. H 04 L 7/00, 1995, FIG. 5.

 Triggers 3, 18 can be implemented on the IMS series 133, 564 and described - Chips and their application: Reference, manual. / B.A. Batushev, V.N. Veniaminov, V.G. Kovalev et al. - M.: Radio and Communications, 1984, p. 118, fig. 4.12.

 The counter 11 can be implemented on the IC series 133, 564 and described - Chips and their application: Reference, manual. / B.A. Batushev, V.N. Veniaminov, V. G. Kovalev and others. M .: Radio and communication, 1984, p. 139, fig. 4.37.

 The demultiplexer can be implemented on the 555 Series IMS and described Digital Integrated Circuits: A Reference. / P.P. Maltsev, N.S. Dolidze, M.I. Kritenko et al. - M: Radio and Communications, 1994, p. 32.

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

 The claimed device operates as follows.

 When the power is turned on (the power scheme is not shown), the synchronizer 1 starts to generate pulses with a repetition period equal to τ (τ is the duration of the packet transmission interval). When a signal appears informing about the presence of a carrier in the channel (at the signal input of the device), which indicates the beginning of transmission to another (in the general case, different) subscriber, the trigger of transmission cycle 3 goes into the storage mode of the logical unit. In this case, the signal with the level of a logical unit from its output goes to the second input of the first element And 2 (thereby prohibiting the passage of the next pulse from the output of the synchronizer 1 through the first element And 2), as well as to the input of the pulse shaper 5, from the output of which the pulse goes to the signal input of the unit for determining the intensity of the input stream 7, while the latter generates and issues to its information output a code combination corresponding to the intensity of the input stream in the channel in the previous and current in breakdowns of analysis. At the end of the next analysis interval (the analysis interval generator 6 sets the duration of the analysis interval), the code combination corresponding to the maximum intensity of the input stream reached in this analysis interval arrives at the first information input of the bandwidth calculation unit 8 and the decision block 9, respectively.

All packets transmitted to the CMD arrive at the information input of the device and, respectively, at the information inputs of N blocks for determining the long-range action parameter 13 ₁ - 13 _N (N is the number of correspondents included in the CMD) in accordance with the ith correspondent of block 13 _i . From the packet header, the address of the i-th correspondent and its long-range parameter (depending on its location relative to the base node) are selected.

Binary counters 11 and demultiplexer 12 provide sequential input of code information (CI) corresponding to α _i to the information inputs of the unit for determining the deleted correspondent 14. At the same time, the CI corresponding to the address of the i-th correspondent is input to the multi-input element OR 16. In addition, the whole CI corresponding to the value α _i, is supplied to the inputs of the average parameter calculating unit 10. In the long-range determination unit removed reporter 14 compares the long-range interaction parameters for all i cor espondentov, determined by the most remote of the correspondents. In this case, the signal from the signal output of the unit for determining the deleted correspondent 14 is fed to the signal input of the switching unit 17, provides the address from the output of the multi-input element OR 16 to the address output of the device through the switching unit 17. (This KI is present at the address output of the device until until an even more distant correspondent is found in the next analysis interval). Decision block 9, processing the input data, if necessary, generates a signal for the formation of a control packet (this packet is sent to the address of the most remote correspondent in order to exclude it from the multiple access channel, which normalizes the streaming situation in the multiple access radio channel.

If necessary, start the transfer to the control input of the device and, accordingly, to the second input of the second element And 4 receives a signal request transmission. If at the given moment the channel is free, then the first element And 2 is opened by a signal with a logic zero level coming from the output of the trigger of the transfer cycle 3 to the inverse input of the first element And 2. In this case, the closest pulse from the output of the synchronizer 1 through the open first element And 2 arrives at the first input of the second element And 4. Since there is a signal with a logic level 1 at the second input of the second element And 4, the pulse from its output through the OR 19 element is fed to the control output "Transmission permission" of the device. In this case, the transmitter is switched on for a time interval determined by the duration of the pulse generated by the synchronizer 1. The carrier signal that appears in the radio channel after the transmitter is turned on leads to the appearance in all devices included in the radio channel of a signal with a logic level at the input of the trigger of the transmission cycle 3. At the same time, the signal arrives to the input of the delay element 22, the output of which then goes to the first inputs of the fourth 20 and fifth 21 elements I. The delay time of the delay element 22 is equal to the pulse duration, It is formed synchronizer 1. This time should not be less than the maximum signal propagation time between subscribers τ _p. If two or more correspondents went to the transmission simultaneously, then a signal from the channel appears at the second input of the fifth And 21 element, and a signal appears at the output of the fifth And 21 and the output “Collision” of the device, notifying of a collision when trying to transmit. According to the collision signal, the subscribers of the radio channel remove transmission request signals from the control inputs of the devices and postpone the attempt to transmit. In the absence of a carrier signal at the time of the appearance of the pulse at the output of the delay element 22, the signal is absent at the output of the fifth element And 21, and a signal appears at the output of the fourth element And 20, setting the trigger 18 to the logical 1 storage mode. At the same time, the “Transfer permission” and "Turning on the transmitter" of the device signals appear, allowing the inclusion of the transmitter and the transfer of data to the radio channel.

 At the end of the transmission, the subscriber removes the transmission request signal from the control input of the device, which leads to the installation of the trigger 18 in the initial (zero) state. The device continues to collect statistics on the operation of the CMD and the formation of control flows if necessary.

при этом исходными данными при вычислении являются значения

и Λ, получаемые от блока вычисления среднего параметра дальнодействия 10 и блока определения интенсивности входного потока 7 соответственно.Bandwidth calculation unit 8, the functional diagram of which is shown in FIG. 2, implements the calculation of the value of the throughput S in accordance with the expression:

while the initial data in the calculation are the values

and Λ obtained from the unit for calculating the average long-range parameter 10 and the unit for determining the intensity of the input stream 7, respectively.

Блоки определения параметра дальнодействия 13₁-13_N, функциональная схема которого представлена на фиг. 5, работает следующим образом. Электронный коммутатор 13.2 обеспечивает запись в регистр сдвига 13.4 адреса i-го корреспондента, выделяемого из состава заголовка пакета. Сигналом с уровнем логической единицы через элемент ИЛИ 13.6 запускается электронный коммутатор 13.3, обеспечивающий запись в регистр сдвига 13.5 координат местоположения i-го корреспондента, ранее выделяемых из состава заголовка пакета. При сложении по модулю два координат i-го корреспондента и координат данного узла на выходе сумматора 13.8 появляется комбинация, соответствующая удаленности i-го корреспондента от данного узла. При этом ПЗУ 13.9 выдает на выход блока 13 значения параметра дальнодействия для i-го корреспондента.Decision block 9, the functional diagram of which is presented in FIG. 3, it generates a control packet formation signal in the event that at the outputs of comparison circuits 9.3 and 9.4 signals with the level of a logical unit simultaneously appear. Moreover, the comparison circuit 9.3 generates this signal if the throughput of the multiple access channel S in this analysis interval exceeds the permissible S _max . Similarly, comparison circuit 9.4 generates a given signal if the input stream intensity is Λ. exceeds the permissible Λ _max .
The unit for calculating the average long-range parameter 10, the functional diagram of which is shown in FIG. 4, works as follows. The inputs of the adder modulo two 10.1 receives information (in the form of code combinations) about the values of the long-range parameter α _i for each of the correspondents. At the same time, these code combinations alternately arrive at the multi-input element OR 10.2, from the output of which a signal with the level of a logical unit goes to the counting input of the binary counter 10.4. In this case, the code combination at the output of the counter 10.4 changes (that is, the division coefficient of the divider 10.3 changes). Therefore, ultimately, in the block for calculating the average long-range parameter 10, the calculations are implemented in accordance with the expression:

The blocks for determining the long-range parameter 13 ₁ -13 _N , the functional diagram of which is shown in FIG. 5, works as follows. The electronic switch 13.2 provides an entry in the shift register 13.4 of the address of the i-th correspondent allocated from the packet header. The signal with the level of a logical unit through the element OR 13.6 starts the electronic switch 13.3, which provides the record in the shift register 13.5 of the location coordinates of the i-th correspondent, previously allocated from the packet header. When adding modulo two coordinates of the i-th correspondent and the coordinates of this node at the output of the adder 13.8, a combination appears corresponding to the distance of the i-th correspondent from this node. In this case, the ROM 13.9 gives the output of block 13 the value of the long-range parameter for the i-th correspondent.

The block for determining the deleted correspondent 14, the functional diagram of which is shown in FIG. 6, operates as follows. Through a multi-input element OR 14.1, the first inputs of the comparison circuit 14.3 from the blocks for determining the long-range parameter 13 ₁ -13 _N alternately receive code combinations corresponding to the values of the long-range parameters of each of N correspondents. The second inputs of the comparison circuit 14.3 receive the code combination from the output of the counter 14.2 (this counter sets the comparison threshold). Since the counter outputs are inverted, the comparison is first carried out with the highest threshold; after the interrogation of all blocks 13 ₁ -13 _{N, the} threshold is shifted, the comparison process is repeated until any of the parameters α _i is greater than the threshold or at least equal to it (that is, the long-range parameter of the i-th correspondent α _i is maximum; therefore, the i-th correspondent will be the most remote of the N correspondents, and if necessary, it can be removed from this multipoint channel and tied to another switching center). In this case, a signal with the level of a logical unit from the output of the comparison circuit 14.3 through the OR element 14.4 is fed to the output of the block for determining the deleted correspondent 14.

Claims (1)

 A radio channel data transmission control device comprising a transmission cycle trigger, the reset and installation inputs of which are interconnected and are the signal input of the device, and the output is connected to the inverse input of the first element AND and the input of the pulse shaper, the synchronizer, the output of which is connected to the direct input of the first element And, the output of which is connected to the first input of the second element And, the second input of which is connected to the input of the trigger setup and is the control input of the device, the reset trigger input is connected n with the output of the third element And, the direct input of which is connected to the first input of the fourth element And and the output of the delay element, the inverse input of the third element And is connected to the output of the fourth element And is the output "Collision" of the device, the output of the pulse shaper is connected to the first input of the determination unit the intensity of the input stream, the output of the analysis interval generator is connected to the second input of the input intensity determination unit, the output of the second AND element is connected to the first input of the OR element and the input delay element, the output of the OR element is the output of the "Transmission enable" device, the trigger output is connected to the second input of the OR element and is the output of the "Turning on the transmitter" device, characterized in that an additional bandwidth calculation unit, a decision block, an average parameter calculation unit are introduced range, counter, demultiplexer, N blocks for determining the range parameter, where N≥2 is the number of correspondents in the radio channel, block for determining the deleted correspondent, N-input element And, N- an OR running element, a switching unit, wherein the output of the input flow rate determination unit is connected to the first information input of the bandwidth calculation unit and the input flow rate input of the decision unit, the output of the capacity calculation unit is connected to the input “throughput parameter” of the adoption unit solutions, the information input of the device is connected to the information inputs of N blocks for determining the long-range parameter and the second input of the fourth element And, i-th, where i = l, 2, 3 ... N, in the counter stroke is connected to the i-th input of the demultiplexer and the i-th input of the N-input element And, the i-th output of the demultiplexer is connected to the control input of the i-th unit for determining the long-range parameter, the output of the N-input element And is connected to the input "Change threshold" block for determining the deleted correspondent, the output "Address" of the long-range parameter determination block is connected to the i-th input of the N-input OR element, the output of which is connected to the group input of the switching block, the "Long-range parameter" output of the i-th long-range parameter determination block The action is connected to the i-th input of the medium-range parameter calculation unit and the i-th input of the unit for determining the deleted correspondent, the output of which is connected to the input of the switching unit, the output of which is the device output address, the output of the medium-range parameter calculation unit is connected to the second information input of the calculation unit bandwidth and the input "Average long-range parameter" decision block, the output of which is the signal output of the device.

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