SU955116A2 - Device for calculating transmitting radio center - Google Patents

Description

The invention relates to electronic modeling of elements of communication systems and systems, and, in particular, can be used to study the functioning of transmitting radio centers under stochastic load conditions.

According to the main author. St. No. 860092, there is known a device for simulating a radiating radio center, containing a multi-channel simulator of the application flow, a control unit, a group of output elements OR and K service channels, each of which contains a first security element, the output of which is connected to the input of the first sensor of random time intervals, the first element And , the output of which is connected to the input of the first counter, the first reversible counter, the outputs of which are connected> to the inputs of the second element And, the second counter, multi-input element And, additional (K-1) e AND elements, and in the service channel a third counter, a second inhibit element, a third AND element, a second reversible counter and a second random time interval sensor, in addition, each channel, except the first, contains an OR element, the output of which is connected to the first inputs of the first element for ₁₀ prets and the first element And, and in each channel the output of the first inhibit element is connected to the summing input of the first reversible counter, the subtracting input of which is connected, 5 hours to the output of the first sensor of random time intervals, the output is second about the And element is connected to the second inputs of the first And element and the first inhibit element, the outputs of the second elements of the And (K-1) -th and K-th service channels are connected to the 'inputs of the (K-1) -th additional element And, the first input of each of the previous additional elements And is connected to the output of the subsequent additional element And, the second input of each of the previous additional elements And is connected to the output of the second element And the corresponding service channel, the outputs of the additional elements And and the output of the second element And the K-th channel the connections are connected to the first inputs of the output elements of the OR group, the second inputs of which are connected to the outputs of the corresponding zero elements of the ban of the corpse, the second inputs of which are the group of inputs of the control unit, the outputs of the elements of the ban of the group of inputs with the inputs of the multi-input OR element, the output of which is connected to the second input the prohibition element, the third input of which is connected to the output of the clock generator 10 ow 0].

A disadvantage of the known device discharges of the second reversible counters of the corresponding service channels, the outputs of the output elements OR. the groups are connected to the group of inputs 15 of the control unit, the outputs of which are connected to the subtracting inputs of the second reversible counters of the corresponding service channels, the outputs of the multi-channel simulator of the application flow jq are connected to the summing inputs of the second reversible counters, with the inputs of the second counters and with the first inputs of the second elements of the prohibition of the corresponding service channels - $ Nia _2, in each channel service of the second element is connected to the output prohibition 'a third input of the counter, outputs the second bit reverse ELAPSED Single connected to inputs of the third AND gate, the output of which Cpd ~ nen to a second input of the second element prohibition, the output of the second up-down counter connected to the second input of the random time intervals, a first output of the second sen- ³⁵ snip random time slots of the first channel is connected to the second service the inputs of the first element And the first element of the ban, the first inputs of the second sensors are random. time intervals (K-1) of the service channels are connected to the first inputs of the OR elements * of the corresponding service channels, the output of the first element And of each service channel ⁴⁵ , except the last, is connected

- with the second input of the OR element of the subsequent service channel, in addition, the control unit contains a prohibition element, a clock generator of 50 pulses, a multi-input OR element, a distributor and a group of prohibition elements, the outputs of which are the outputs of the control unit, the input of which is the first input. 55 that the prohibition, the output of which is connected to the input of the distributor, the outputs of which are connected to first inputs of co ^J is that in the simulation process is functioning the transmitter ignores a possible radio center Exit from the system as a control system and radiopathes, i.e. does not provide sufficient simulation accuracy of the transmitting radio center. ·

The purpose of the invention is to improve the accuracy of modeling a transmitting radio center.

This goal is achieved by the fact that a random pulse generator, a counter, a sensor of random time intervals, a trigger are additionally introduced into the device for modeling the transmitting radio center, and the first, second and third additional OR elements, an additional element NOT, an additional element AND are additionally introduced into each service channel , an additional generator of random pulses, and the output of the generator of random pulses is connected to the inputs of the counter and sensor of random time intervals and is connected to to the first inputs of all additional elements of the service channels and to the first input of the trigger, the output of which is connected to the additional inputs of the elements of prohibition of the service channels and to the additional input of the multi-input element And, the other inputs of which are connected to the inputs of the additional elements NOT corresponding to the service channels, the output of the sensor is random time of intervals connected to the second input of the trigger, the output of the additional element NOT of each channel is connected to the second input of the additional element AND, the output of which connected to a first input of the first additional element, or the second input of which is connected to the first input of the second additional element and OR is connected to the first output of the random generator, a second output of which is

955 is connected to the first input of the third additional OR element, the second input of which is connected to the output of the first sensor of random time intervals, the output of the third additional 5 OR element is connected to the subtracting input of the first reversible counter, the summing input of which is connected to the output of the second additional OR element, the second the input 10 of which is connected to the output of the first prohibition element, the third input of the first additional OR element is connected to the corresponding output of the multichannel flow simulator k, 15 additional output of the first OR gate is connected to the summing input of the second down counter.

The drawing shows the proposed device. 20

The device contains a simulator 1 of the application flow, a control unit 2, a group of output elements OR a prohibition element 4, a sensor 5 random time intervals, an element And 6, 25 counter 7, reversible counter 8, element And 9, counter 10, multi-input element And 11, (K-1) elements And 12, counter 13, element 14 prohibition, element And 15, reversible counter _Z d 16 and the sensor 17 random time intervals, element OR 18, block 19 modeling the reliability of the control system and trigger 20, block 21 modeling reliability radio path, elements OR 22 and 23, element and NOT 24, element AND 25, e OR element 26, random pulse generator 27, sensor 28 random time intervals, counter 29Do

The control system reliability modeling block 19 and the radio path reliability modeling block 21; 21 k are identical in construction and are designed to simulate the _4J failure (failure) and restoration of the control system and radio paths, respectively. Each reliability modeling unit consists of a failure simulator, a counter, and a sensor for random time intervals. Random Pulse Generator 27 produces single pulses separated by random time intervals with any desired distribution law. The pulse from the output of the generator 27 goes to the input of the counter 29, to the input of the sensor 28 at random time intervals and to the first output of the

6 modeling simulations 19 (21; -21 ^), simulating the moment of failure of the control system (radio path). After a random period of time corresponding to the recovery time of the control system (radio path); at the output of the sensor 28, a pulse appears, which is fed to the second output of the block 19 (21; -21 _k ), simulating the moment of restoration of the control system (radio paths). The block counters 19 ”21; -21 _{to the} simulation count the number of failures of the control system and radio paths, respectively.

The coordination element 20 is designed to convert the failure and recovery impulses received at its inputs from the control system modeling block 19 into the corresponding voltages.

The device operates as follows.

In the initial state, the reversible counters 16 and 8 are in the position when there are no recorded pulses in them, i.e. all transmitters and queues are free. The signal from the zero discharge of each counter 16 is fed to the input of the control unit 2 through the OR 3 element. If there are no requests in the queue, the control unit 2 of the command for servicing applications does not generate, despite the signal Free, coming from the sensors 17 random time intervals through the And 11 element another input of control unit 2. The prohibition elements 14 in the initial state are closed, and the prohibition elements 4 are open.

The signal received from the output of the simulator 1 is counted by the counter 10 and recorded in the reverse counter 16, simulating the receipt of a service request Let, for example, this signal go to the first service channel. When recording a signal in a reversible counter ib; from its zero discharge the signal is removed, which came through the element OR 3; to control unit 2, signaling the receipt of an application in the queue of the first service channel. The control unit 2 generates a request service command, which is fed to the subtracting input of the reverse counter 16 ;. As a result, the request from the queue is transferred for service to the control system, i.e. the pulse from the output ‘9551 of the reverse counter 16 is supplied to the input of the sensor 17 random time intervals.

After a random period of time corresponding to the time of compiling 5 radio paths by the control system, an impulse appears at the output of the sensor 17-j, which through the open prohibition element 4 ^ and the OR element 22? simultaneously enters the summing 10 input of another reverse counter 84 and the input of another sensor 54 random time intervals, occupying one of the delay lines in it. The recording of the pulse in the second reversible 15 counter 84 simulates the occupation of the transmitter of the first group for transmitting messages. After a random time interval corresponding to the busy time of the transmitter for transmitting the message, a pulse appears at the output of the sensor 5 4, which is fed to the subtracting input of the reverse counter 84, simulating the release of the transmitter. Simultaneously with the arrival of 25 pulses to the output of the sensor 17 (the signal Free is taken from its additional output, which through the And 11 element warns the control unit 2 about the busy control system. _Z d The operation of the remaining service channels is similar to the operation of the first channel.

After filling in the queue of the service channel, i.e. There are voltages on all the digits of the reversible counter, voltage appears at the output of element And 15, which opens the inhibit element 14, allowing the passage of the next requests coming into the channel to the counter 13, which counts the number of applications that left this channel unattended.

When filling out all the bits of the reverse counter 8, simulating the busyness of all the transmitters in the group, the output element And 9 appears. ^and a voltage which closes the ban element 4 and opens the AND gate 6 to allow the passage of a single application, which is not accepted for service by this group of transmitters to ob- ⁵⁰ Serviceability in the last group of transmitters, ie the pulse from the output of the sensor 17 through the element And 6 of the previous service channel is fed to the input of the element OR 18 of the next 55th service channel and then through the inhibit element 4 of this channel is fed to the summing input of the reverse

8 counters 8. Thus, the service request can fall into any subsequent group of transmitters. The number of applications moving to service from one group to another is counted by 7-

Since the transmitters of the last group can serve the requests of all substreams, the signal about the occupancy of all transmitters of this group from the output of the And 9 element goes through the And 2 and the OR 3 elements to all control inputs of the control unit 2, while the signals about the busy transmitters of the first groups through the element And 12f and the element OR З-f are received only at the first control input of block 2 (only the first sub-stream requests are served by transmitters of the first group).

During operation, the control system and radio path elements (channel, transmitter, antenna-feeder device) may fail. When simulating a failure of the control system, the pulse from the first output of block 19 is supplied to the first inputs of the elements And 25 <“25 k and to the first input of the trigger 20. From the output of the trigger 20, the control voltage through the element And 11 goes to the control unit 2, signaling the output the control system is out of order (equivalent to its employment), and to the additional inputs of the elements of the ban 44-4 K., closing them and prohibiting further maintenance of the requirement located in the control system. A request whose service has been interrupted is sent again to the general queue of the service channel in which its service was interrupted. If at the time of failure of the control system the requirement is served in the first channel, then from the additional output of the 17g sensor, the signal through the element NOT 24 d is fed to the second input of the element And 25 ^ l preparing it, so the pulse from the output of block 19 passes through the element And 25d and further, through the OR element 26 4, the request from the simulator 1 enters the queue as well. After simulating the restoration of the control system, the pulse from the second output of the modeling block • 19 enters the second input of element 20. As a result, the element

The prohibition ID 4 ^ -4 ^ is opened and a signal is sent to the control unit 2 to restore (release) the control system. The device goes into normal mode. 5

The imitation of the failure of the radio center is based on the principle that the failure of the radio path is tantamount to its employment, and the restoration of the release, while the requirement, 10 the service of which was interrupted, is again sent to the general queue.

When the radio path fails, the pulse from the first output of the modeling unit 21 enters through the 15 element OR 22 to the summing input of the reverse counter 8, simulating the radio path occupancy, and through the OR element 26 it enters the general queue of the service channel. 20

When restoring the radio path, the pulse from the second output of the modeling unit 21 through the OR element 28 is fed to the subtracting input of the reverse counter 8, simulating the release of the radio path.

A device for simulating a radiating radio center due to the presence of elements and the connections between them allows you to take into account the failure of the control system, which increases the accuracy of the simulation.

the output of the random pulse generator is connected to the inputs of the counter and the sensor for a random time interval.) and connected to the first inputs of all additional elements of the service channels and to the first input of the trigger, the output of which is connected to the additional inputs of the first elements of the ban of service channels and to the additional input of the multi-input element And the other inputs of which are connected to the inputs of the additional elements NOT corresponding to the service channels, the output of the sensor of random time intervals is connected to the second with the trigger input, the output of the additional element NOT of each channel is connected to the second input of the additional element AND, the output of which is connected to the first input of the first additional OR element, the second input of which is connected to the first input of the second additional OR element and connected to the first output of the random pulse generator, second output coupled to a first input of the third additive element or _l a second input coupled to an output of the first sensor random time intervals, the output of the third additional dome tional OR element connected to the subtracting input of the first down counter, a summing input of which is connected to

Claims (1)

The invention relates to electronic modeling of the elements of communication systems and systems and, in particular, can be used to study the functioning of transmitting radio centers under stochastic load conditions.  According to the main author.  St.  No. 860092 is known a device for simulating a radiating radio center containing a multichannel flow simulator, a control unit, a group of output elements OR and K service channels, each of which contains a first protection element whose output is connected to the input of the first sensor of random eip intervals, the element whose output is connected to the input of the first counter, the first reversible counter, the outputs of which are connected to the inputs of the second element I, the second counter, the multi-input element I. additionally (K-1) elements And, and in the service channel, the third counter, the second element of the prohibition, the third element And, the second reversible estimator and the second sensor of random time intervals, besides, each channel except the first one contains the element OR, the output of which is connected to the first inputs of the first prohibition element and the first element I, and in each channel the output of the first prohibition element is connected to the summing input of the first reversible counter, the subtracting input of which is connected to the output of the first random sensor Nervalov, the output of the second element And is connected to the second inputs of the first element And the first element of the ban, the outputs of the second elements And (K-1) -th and K-th service channels are connected to the inputs (K-1) of the additional element And, the first the input of each of the previous additional elements And connected With the output of the subsequent additional element And, the second input of each of the previous additional elements And connected to the output of the second element And the corresponding service channel, the outputs of the additional elements And and the output of the second el changed that K-th channel service are connected to first inputs of the output, the element or group, the second inputs of which are connected to the outputs of the zero bits of the second reversible counters corresponding service channel output or output elements.  the groups are connected to the group of inputs of the control unit whose outputs are connected to the subtractive inputs of the second reversible counters of the corresponding service channels, the outputs of the multichannel flow simulator are connected to the summing inputs of the second reversible counters, to the second bar inputs of the corresponding service channels In each service channel, the output is second. prohibition element is connected to the input. The third counter, the bit inputs of the second reversible counter are connected to the inputs of the third element AND whose output is connected to the second input of the second prohibition element, the output of the second reversible counter connected to the input of the second random time interval sensor, the first output of the second random time interval sensor of the first service channel connected to the second inputs of the first element And the first prohibition element, the first inputs of the second sensors of random, time intervals (K-1) service channels with the first inputs of the OR elements of the corresponding service channels, the output of the first element AND of each service channel, except for the last one, is connected to the second input of the OR element of the subsequent service channel, in addition, the control unit contains a prohibition element, a clock pulse generator, a multi-lead element OR, a distributor and a group of prohibition elements whose outputs are the outputs of the control unit whose input is the first input. prohibition element, the output of which. n with the distributor input, the outputs of which are connected to the first inputs with 9 64 corresponding group inhibiting elements, the second inputs of which are a group of inputs of the control unit, the outputs of the group inhibiting elements are connected to the inputs of the multi-input element OR, the output of which is connected to the second input of the prohibition element, the third input which is connected to the output of the clock pulse generator 1.  A disadvantage of the known device is that it does not take into account the possible failure of both the control system and the radio paths, etc., when modeling the functioning processes of the transmitting radio center. e.  does not provide sufficient accuracy of transmitting radio center modeling.   The purpose of the invention is to improve the accuracy of modeling the transmitting radio center.  The goal is achieved by adding a random pulse generator, a counter, a random time interval sensor, a trigger, and the first, second, and third additional elements are serviced and added to each channel, and the additional element is NOT an additional element. And, an additional generator of random pulses, with the output of the random pulse generator connected to the inputs of the counter and the sensor of random time intervals and connected the first inputs of all additional elements And service channels and the first input of the trigger, the output of which is connected to the additional inputs of the prohibit elements of the service channels and to the additional input of the multi-input element AND, the other inputs of which are connected to the inputs of additional elements NOT corresponding to the service channels, the output of the sensor random time intervals connected to the second input of the trigger, the output of the additional element NOT of each channel is connected to the second input of the additional element AND, the output which is connected to the first input of the first additional element OR, the second. the input of which is connected to the first input of the second additional OR element and connected to the first output of the random pulse generator, the second output of which 5 is connected to the first input of the third additional OR element, the second input of which is connected to the output of the first random time sensor, OR is connected to the subtractive input of the first reversible counter, the summing input of which is connected to the output of the second additional element OR, the second input of which is connected to The output of the first prohibition element, the third input of the first additional element OR is connected to the corresponding output of the multichannel flow simulator. The output of the first additional element OR is connected to the summing input of the second reversible counter.  The drawing shows the proposed my device.  The device contains a simulator 1 for current flow, a control unit 2, a group of output elements OR. , prohibition element k, sensor 5 random time intervals, element 6, counter 7, reversible. counter 8, element And 9, counter 10, multi-input element And 11, (K-1) elements And 12, counter 13, element And prohibit element And 15, reversible counter 16 and sensor 17 random time intervals, element OR 18, block 19 simulation of the reliability of the control system and the trigger 20, block 21 of the simulation of the reliability of the radio path, elements OR 22 and 23, element ii NOT 2k, element AND 25, element OR 26, generator 27 random pulses, timer 28 random time intervals counter 29 Block 19 reliability modeling control systems and radio reliability simulation block such as are for / of identical construction and are designed to simulate of failure (failure) and the reduction of the control system and radiopathes respectively.  Each reliability simulation unit consists of a failure simulator, a counter, and a random time sensor.  The random pulse generator 27 produces single pulses separated by random time intervals with any desired distribution law.  The pulse from the output of the generator 27 is fed to the input of the counter 29 to the sensor input 28 random time intervals and to the first output of the simulation block 196 19 (21-21st}, simulating the moment of the control system (radio path) failure.  After a random time interval corresponding to the recovery time of the control system {radio path) j, a pulse appears at the output of sensor 28, which arrives at the second output of block 19 (2C-21k), simulating a moment. restoration of the control system (radio paths).  The counters of blocks 19, (4 simulations count the number of failures of the control system and radio paths, respectively.  The matching element 20 is designed to convert the failure and recovery pulses to its inputs from the control system modeling unit 19 to the corresponding voltages.  The device works as follows.  In the initial state, the reversible counters 16 and 8 are in the position where the recorded pulses are in HW.  no, t. e.  all transmitters and queues are free.  The signal from the zero bit of each counter 16 is fed to the input of the control unit 2, the element OR 3.  If there is no queued request in the queue, the unit 2 control commands for servicing the requisition does not generate, despite the Free signal, 17 random time intervals from the sensors 11 are received from the sensors to another input of the control unit 2.  Elements of prohibition 1 in the initial state are closed, and elements of prohibition 4 are open.  The signal received from their output 1 is counted by counter 10 and is recorded in reversing counter 16, simulating the receipt of application for service. Let, for example, this signal go to the first service channel.  When a signal is written to the reversible counter ib from its zero-bit, the signal that is fed through the OR 3f element to the control unit 2 is removed, signaling that the application received the first service channel in the queue.  Control unit 2 Generates a command for servicing the application, which is fed to the subtractive input of the reversible counter I6j (.  As a result, the application from the queue is transferred to the management system for servicing, i. e.  the pulse from the output 7 of the reversible counter 16 is fed to the input of the sensor 17 random time intervals.  After a random time interval corresponding to the time when the control system creates a radio path, the output of the sensor 17. (An impulse appears which, through the open interdiction element k and the element OR 22, simultaneously arrives at the summing input of another reversible counter 8 and at the input of another sensor SA of random time intervals, occupying one of the delay lines in it.  Record the pulse to the second reversible counter 8, (simulates the use of the transmitter of the first group to transmit messages.  Through a random time intsuval, corresponding to the transmitter's busy time, to transmit a message, a pulse appears at the output of sensor 5 i, which arrives at the subtracting input of the reversible counter 8, simulating the release of the transmitter.  Simultaneously with the arrival of a pulse at the output of the sensor 17, the signal / 1 is released from its additional output, which, through element 11, warns the control unit 2 about the control system's operation. The remaining service channels are similar to the first channel after filling the service channel queue, t. e.  At all digits of the reversible counter, there are voltages; at the output of the AND 15 element, a voltage appears that opens the prohibition element, allowing the passage of the next request entering the channel, to the counter 13.  which counts the number of quotes left the channel unattended.  When filling all the bits of the reversible counter 8, imitating the occupancy of all the transmitters in the group at the output of the element And 9, a voltage appears that closes the prohibition element 4 and opens the element And 6, ensuring the passage of one which is not accepted for service group of transmitters, to service the last group of transmitters, t. e.  pulse. from the output of sensor 17, through the AND 6 of the previous service channel, enters the input of the element OR 18 of the subsequent service channel and then through the prohibition element of this channel, supplies the summing input of the reversible counter 8.  Thus, the application for service can fall into any subsequent group of transmitters.  The number of quotations, their transfer to service from one group to another, is counted by counters 7. Since the transmitters of the last group can serve the requests of all subflows, the signal of all transmitters of this group from the output of the AND 9 element enters through the element 12 and the element OR 3 to all the control inputs of control unit 2, while the signals about the transmitters of the first group through the element 12: f and the element OR 3 only go to the first control input of unit 2 (transmitters of the first group are served by requests of the first sub-stream).  In the process of operation, the control system and the elements of the radio path (channel, transmitter, antenna-feeder device) may fail.  When imitating a control system failure, the impulse from the first output of block 19 goes to the first inputs of the elements And to the first input of the trigger 20.  From the output of the trigger 20, the control voltage through the element 11 is fed to the control unit 2, signaling that the control system is out of operation (equivalent to its occupation), and to the additional inputs of the inhibit elements, closing them and prohibiting further maintenance of the requirement control system.  The interrupted service is forwarded again to the common queue of the service channel in which its service was interrupted.  If at the time the control system fails, the requirement is serviced in the first channel, then from the additional output of the sensor 17f, the signal through the NOT 2k element goes to the second input of the AND 25 element preparing it, therefore the pulse from the output of block 19 passes through the AND 25-f element and further through the element OR 26 enters the queue as the demand from the simulator 1.  After simulating the recovery of the control system, the pulse from the second output of the modeling unit 19 is fed to the second input of the element 20.  As a result, the prohibition elements are opened and the control unit 2 receives a signal about the restoration (release) of the control system.  The device transition to a shady mode of operation.  The imitation of a radio center outage is based on the principle that a radio link outage is equivalent to its occupancy, and the restoration to exemption, while the demand for which service was interrupted is again sent to the common queue.  When the radio path fails, the pulse from the first output of the modeling unit 21 goes through the element OR 22 to the summing input of the reversible counter 8, simulates the occupancy of the radio path, and through the element OR 26 enters the common queue of the service channel.  When the radio path is restored and the pulse from the second output of the modeling unit 21 through the OR element 28, it hits the subtracting input of the reversible counter 8, simulating the release of the radio path.  A device for simulating a radiating radio center due to the presence of elements and the connections between them makes it possible to take into account the failure of the control system, which increases the accuracy of the simulation.  The invention The device for modeling the transmitting radio center by author.  St.  No. 860092 characterized in that, in order to improve the accuracy of the simulation, a random pulse generator, a counter, a random time interval sensor, a trigger, and the first, second and third additional elements are additionally introduced into each device of the service OR , additional element I, additional generator of random pulses, with the 1610 output of the random pulse generator connected to the inputs of the counter and sensor of random time intervals and connected to the first input A of all additional elements of the service channels and to the first input of the trigger, the output of which is connected to the additional inputs of the first elements of the prohibition of the service channels and to the additional input of the multi-input element And the other inputs of which are connected to the inputs of the additional elements NOT of the corresponding service channels, the output of the sensor of random time intervals connected to the second input of the trigger, the output of the additional element NOT of each channel is connected to the second input of the additional element AND, then connected to the first input of the first additional element OR, the second input of which is connected to the first input of the second additional element OR and connected to the first output of the random pulse generator, the second output of which is connected to the first input of the third additional element OR-, the second input of which is connected to the output of the first random time sensor, the output of the third additional element OR is connected to the subtractive input of the first reversible counter, the summing input of which is connected the second additional output of the OR gate, a second input coupled to an output of the first element of the ban, the third input of the first additional element or is connected to the corresponding output stream for a multichannel simulator wok, an additional output of the first OR gate is connected to the summing input of the second down counter.  Sources of information taken into account during the examination 1.  USSR Copyright Certificate № 860092, cl.  G 06 G 7L8, 1979 (prototype).