RU2622625C1 - Device for functioning processes simulation of the ground mobile measuring complex while operating - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: device contains the random time intervals generators, simulating the specific modes of usage, AND, OR elements, triggers, the delay elements, random numbers generators, decoders and differentiating elements, that provide simulation of the dynamics and operation specificity of the ground mobile measuring complex.

EFFECT: increase of the simulation accuracy and provision of failures occurrence and elimination simulations, while preparing and conducting the sessions with aircrafts by the ground mobile measuring complex and the transmission of the received information to consumers.

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Description

The invention relates to computer technology, namely, specialized electronic modeling tools, and can be used to study the processes of ground-based functioning, including the assessment of their performance, mobile measuring systems (NMIK) during operation, taking into account their modes and dynamics of use, as well as occurrence and elimination failures in preparation.

Closest to the proposed invention is a device for modeling the processes of functioning of a ground-based mobile measuring complex during operation [RF Patent No. 224609, class. G06F 17/00, G06F 17/60, 06/20/2005] containing a single pulse generator, first and second elements OR first, second and third triggers, first to eighth differentiating elements, a random preparation time interval generator, a random coagulation time generator , a generator of a random flow of pulses, a generator of random intervals of deployment time, from the first to third AND elements, the first and second generators of random intervals of transportation time, and the output of the first OR element is connected to the input of the installation in "1" of the first trigger, the single output of which is connected to the first inputs of the first and third and the inverse input of the second elements And and the input of the first differentiating element, the output of which is connected to the start input of the generator of random preparation time intervals, the output of which is connected to the input of the second differentiating element, the output of the random pulse stream generator is connected to the second input of the first element And, the output of which is connected to the input of the setting in "0" of the first trigger, the first output of the single pulse generator in is connected to the installation input in “1” of the second trigger, the single output of which through the third differentiating element is connected to the start input of the first generator of random intervals of transportation time, the output of which through the fourth differentiating element is connected to the start input of the generator of random deployment time intervals, the output of which is connected through the fifth differentiating element with the first input of the first OR element and with the input of the start of the random pulse stream generator, the stop input of which is connected to the second output of the single pulse generator and the direct input of the second and second input of the third element AND, the output of the second element And is connected to the installation input in "1" of the third trigger, the output of the third element And is connected to the first input of the second OR element, the single output of the third trigger is connected through the sixth a differentiating element with a second input of the second OR element, the output of which is connected to the start input of the generator of random coagulation time intervals, the output of which through the seventh differentiating element is connected to The start of the second generator of random intervals of transportation time, the output of which is connected through the eighth differentiating element to the input of the unit at “0” of the second trigger, is a block for conducting sessions that includes the first to eighth random time generators, from the first to tenth differentiating elements, from the first to sixth triggers, first to seventh AND elements, first to seventh OR elements, first and second delay elements, first and second random number generators, first and second decoders, the output of the first generator of random time intervals is connected through the first differentiating element to the first input of the first OR element, and through the second differentiating element with the installation input in "1" of the first trigger and the start input of the second random time generator, the output of which is connected through the third differentiating element to the first the input of the first AND element, the second input of which is connected to the single output of the first trigger, the output of the first AND element is connected to the first input of the second OR element, the output of which о is connected to the start input of the third random time generator, the output of which is connected through the fourth differentiating element to the start input of the fourth random time generator, the output of which through the fifth differentiating element is connected to the start input of the first random number generator, the first and second outputs of which are connected to the first and second inputs of the first decoder, respectively, the first and second outputs of which are connected to the first and second inputs of the third element OR, respectively , the output of which is connected to the stop input of the first random number generator, the first output of the first decoder is also connected to the setup input in "1" of the second trigger and the start input of the fifth random time generator, the output of which through the sixth differentiating element is connected to the setup input in "0" the second and the input of the installation in “1” of the third trigger, the single output of the latter is connected to the first input of the second element And, the second input of which is connected to the single output of the first trigger, and the output of which is connected to T the first input of the first and first input of the fifth OR element, the stop inputs of the first and second generators of random time intervals and the installation input at “0” of the fourth trigger, the single output of which is connected to the third input of the second AND element, the output of which is also connected through the first input of the fourth OR element with the installation inputs at “0” of the third trigger, the second input of the fourth OR element is connected to the installation input at “0” of the first trigger and the output of the first OR element, the second output of the first decoder is connected to the installation input and in “1” of the fifth trigger and through the first delay element with the first input of the third AND element, the second input of which is connected to the single output of the fifth trigger, the first input of the fifth AND element, the output of the third AND element is connected to the first input of the sixth OR element, the output of which is connected to the start input of the sixth generator of random time intervals, the output of which through the seventh differentiating element is connected to the first direct input of the sixth element And, with the second input of the fifth element And, the output of which is connected to the second input of the second of the first OR element and the installation input at “0” of the fifth trigger, the third input of the third and fifth elements AND is connected to the single output of the first trigger, the single output of the second trigger is connected to the inverse inputs of the sixth and seventh elements, and through the eighth differentiating element to the first direct input the seventh element And, the output of which is connected to the second input of the sixth element OR, the second direct inputs of the sixth and seventh elements And are connected to a single output of the first trigger, the output of the sixth element And is connected to the start input of the seventh random generator of time intervals, the output of which is connected through the ninth differentiating element to the start input of the eighth random time generator, whose output is connected through the tenth differentiating element to the start input of the second random number generator, the first and second outputs of which are connected to the first and second inputs of the second decoder accordingly, the first output of which is connected to the installation input in “1” of the fourth trigger, the second input of the fifth and the first input of the seventh OR element, the second the output of the second decoder is connected to the input of the installation in "1" of the sixth trigger, the input of the second delay element and to the second input of the seventh OR element, the output of which is connected to the stop input of the second random number generator, the output of the fifth element is connected to the input of the installation to "0" of the sixth trigger, the single output of which is connected to the first input of the fourth element And, the second input of which is connected to the output of the second delay element, and the third input of which is connected to the single output of the first trigger, the output of the fourth element And AND is connected to the third input of the sixth OR element, the output of the second differentiating element of the device is connected to the start input of the first generator of random time intervals of the session unit, the output of the first OR element of the session unit is connected to the second input of the first OR element and the installation input to "0" of the third trigger device.

However, this device does not allow simulating failures and their elimination when preparing a ground-based mobile measuring complex for conducting sessions with aircraft during operation, taking into account its modes and dynamics of use.

The technical result is to increase the accuracy of modeling and expand the functionality by simulating the occurrence and elimination of failures in preparation for the session and conducting ground-based mobile measuring complex sessions with aircraft and transmitting the received information to consumers

This technical result is achieved by the fact that in the device for modeling the functioning of the ground-based mobile measuring complex during operation, containing a single pulse generator, first and second elements OR, first, second and third triggers, first to seventh differentiating elements, a generator of random preparation time intervals , generator of random coagulation time intervals, generator of random pulse flow, generator of random deployment time intervals, first to three thium elements And, the first and second generators of random intervals of transportation time, and the output of the first OR element is connected to the installation input in "1" of the first trigger, the single output of which is connected to the first inputs of the first, second and third elements AND and the input of the first differentiating element, the output of the random pulse stream generator is connected to the second input of the first element And, the output of which is connected to the installation input at “0” of the first trigger, the first output of the single pulse generator is connected to the installation input in "1" of the second trigger, the single output of which through the second differentiating element is connected to the start input of the first generator of random intervals of transportation time, the output of which through the third differentiating element is connected to the start of the generator of random intervals of deployment time, the output of which is connected through the fourth differentiating element to the first the input of the first OR element and the input of the start of the generator of a random pulse stream, the stop input of which is connected to the second output of the generator unit pulses and the second inputs of the second and third elements AND, the output of the second element And is connected to the installation input in "1" of the third trigger, the output of the third element And is connected to the first input of the second OR element, the single output of the third trigger is connected through the fifth differentiating element to the second input the second OR element, the output of which is connected to the start input of the generator of random coagulation time intervals, the output of which through the sixth differentiating element is connected to the start input of the second generator time intervals of transportation, the output of which is connected through the seventh differentiating element to the installation input at “0” of the second trigger, a session unit including random time intervals from the first to eighth generators, from the first to tenth differentiating elements, from the first to the sixth triggers, from the first the seventh AND elements, from the first to the seventh OR elements, the first and second delay elements, the first and second random number generators, the first and second decoders, and the output of the first random interval generator The time signal is connected through the first differentiating element to the first input of the first OR element, and through the second differentiating element with the installation input in "1" of the first trigger and the start input of the second random time generator, the output of which is connected through the third differentiating element to the first input of the first AND element , the second input of which is connected to the single output of the first trigger, the output of the first AND element is connected to the first input of the second OR element, the output of which is connected to the start input of the third gene random time generator whose output is connected through the fourth differentiating element to the start input of the fourth random time generator, whose output through the fifth differentiating element is connected to the start input of the first random number generator, the first and second outputs of which are connected to the first and second inputs of the first decoder, respectively , the first and second outputs of which are connected to the first and second inputs of the third OR element, respectively, the output of which is connected to the input remains and the first random number generator, the first output of the first decoder is also connected to the installation input at "1" of the second trigger and the start input of the fifth random time generator, the output of which through the sixth differentiating element is connected to the installation input to "0" of the second and the installation input to " 1 "of the third flip-flops, the single output of the latter is connected to the first input of the second element And, the second input of which is connected to the single output of the first trigger, and the output of which is connected to the second input of the first and first input of the heel OR elements, stop inputs of the first and second generators of random time intervals and the installation input to “0” of the fourth trigger, the single output of which is connected to the third input of the second AND element, the output of which is also connected through the first input of the fourth OR element to the installation inputs to “0” the third trigger, the second input of the fourth OR element is connected to the installation input at “0” of the first trigger and the output of the first OR element, the second output of the first decoder is connected to the installation input at “1” of the fifth trigger and through the first element nt delay with the first input of the third AND element, the second input of which is connected to the single output of the fifth trigger, the first input of the fifth AND element, the output of the third AND element is connected to the first input of the sixth OR element, the output of which is connected to the start input of the sixth random time generator, output which through the seventh differentiating element is connected to the first direct input of the sixth element And, with the second input of the fifth element And, the output of which is connected to the second input of the second element OR and the installation input to "0" of the trigger, the third input of the third and fifth elements And is connected to the single output of the first trigger, the single output of the second trigger is connected to the inverse inputs of the sixth and seventh elements And, through the eighth differentiating element to the first direct input of the seventh element And, the output of which is connected to the second input of the sixth element OR, the second direct inputs of the sixth and seventh elements AND are connected to a single output of the first trigger, the output of the sixth element And is connected to the start input of the seventh random time generator nor, the output of which is connected through the ninth differentiating element to the start input of the eighth random time generator, the output of which is connected through the tenth differentiating element to the start input of the second random number generator, the first and second outputs of which are connected to the first and second inputs of the second decoder, respectively, the first output which is connected to the installation input in “1” of the fourth trigger, the second input of the fifth and the first input of the seventh element OR, the second output of the second decoder is connected to the input ohm of setting the sixth trigger in “1”, the input of the second delay element and with the second input of the seventh OR element, the output of which is connected to the stop input of the second random number generator, the output of the fifth OR element is connected to the installation input in “0” of the sixth trigger, whose single output is connected to the first input of the fourth element And, the second input of which is connected to the output of the second delay element, and the third input of which is connected to the single output of the first trigger, the output of the fourth element And is connected to the third input of the sixth electric OR, the output of the first OR element of the session unit is connected to the second input of the first OR element and the installation input is “0” of the third trigger of the device, an additional training unit is introduced, which includes two random time generators, a random pulse flow generator, five differential elements, a trigger , and an OR element, the output of which is connected to the start input of the first random time generator, the output of which is connected through the first differentiating element with the first input of the first element And, and through the second differentiating element with the start input of the random pulse stream generator, the output of which is connected to the first input of the second element And, the output of which is connected through the third differentiating element with the stop input of the first random time generator, the output of the second element And is also connected to the start input the second generator of random time intervals, the output of which is connected to the inputs of the fourth and fifth differentiating elements, the outputs of which are connected to the inputs of the installation in "0" and "1" trig hera, respectively, the output of the fifth differentiating element is also connected to the first input of the OR element and the stop input of the random pulse stream generator, the single output of the trigger is connected to the second inputs of the first and second elements And, the second input of the OR element is connected to the output of the first differentiating element of the device, the output of the first element And the preparation unit is connected to the start input of the first generator of random time intervals of the session unit

Comparative analysis with the prototype shows that the claimed device is distinguished by the presence of an additionally introduced preparation unit containing an OR element, two random time interval generators, five differentiating elements, a trigger, two And elements, a random pulse flow generator, and corresponding functional relationships with other elements of the device, which meets the criterion of novelty.

The search for technical solutions in the scientific and technical literature and related fields of technology did not reveal a solution having features that match the distinguishing features of the claimed invention, which meets the criterion of inventive step.

In FIG. 1 is a structural diagram of the device, FIG. 2 is a block diagram of a session unit; FIG. 3 shows a block diagram of a preparation unit.

The device comprises a generator of 1 single pulses (orders), a second 2 trigger, a second 3 differentiating element, a first 4 generator of random intervals of transportation (movement) time, a third 5 differentiating element, a generator of 6 random intervals of deployment time, a fourth 7 differentiating element, the first 8 element OR, first 9 trigger, random pulse stream generator 10, simulating the receipt of applications in the ground-based mobile measuring complex for conducting sessions, the first 11 AND element, the first 12 differential adjustment element, preparation unit 13, output 14 of preparation unit 13, sessions unit 15, generator 16 random coagulation time intervals, sixth 17 differentiating element, second 18 generator of random transportation time intervals, seventh 19 differentiating element, second 20 OR element, second 21 And element, third 22 trigger, fifth 23 differentiating element, third 24 element I.

Session block 15 includes: first 25, second 26, third 27, fourth 28, fifth 29, sixth 30, seventh 31 and eighth 32 random time generators, first 33, second 34, third 35, fourth 36, fifth 37, sixth 38, seventh 39, eighth 40, ninth 41 and tenth 42 differentiating elements, first 43, second 44, third 45, fourth 46, fifth 47 and sixth 48 triggers, first 49, second 50, third 51, fourth 52, fifth 53, sixth 54 and seventh 55 AND elements, first 56, second 57, third 58, fourth 59, fifth 60, sixth 61 and seventh 62 OR elements, first 63, second 64 generators luchaynyh numbers, the first 65, the second decoders 66, the first 67, second 68 delay elements, the input 69 and output 70 of the session block.

Preparation block 13 includes: block input 71, third 72 differentiating element, OR73 element, first 74 and second 75 random time interval generators, first 76 and second 77 AND elements, random pulse stream generator 78, second 79, fourth 80, first 81, fifth 82 differentiating elements, trigger 83 and output 14.

Generator 1 generates single pulses: at the first output, a pulse (command, order) for transportation, and at the second output, a pulse (command, order) for coagulation. The generators 10 and 78 generate random flows of pulses that simulate the receipt of applications in the ground-based mobile measuring complex for conducting sessions and the occurrence of failures in the preparation of NMIK for conducting sessions, respectively. Generators 4, 6, 13, 16, 18, 25 ... 28, 74 and 75 generate single pulses after startup, with a random duration corresponding to random time intervals distributed according to the laws of the time spent by the ground-based mobile measuring complex in the considered modes (states).

In the device, the output 1 of the generator 1 is connected to the installation input in “1” of trigger 2, the input of the installation in “0” of which is connected to the output of the differentiating element 19, and the unit output of which is connected through the differentiating element 3 to the start input of the generator 4, the output of which is connected through differentiating element 5 with the start input of the generator 6, the output of which through the differentiating element 7 is connected to the first input of the OR element 8 and the start input of the generator 10, the stop input of which is connected to the second output of the generator 1, the second input of the element the I21 and the second input of the I24 element, the output of which is connected to the first input of the OR20 element, the output of which is connected to the start input of the generator 16, the output of which is connected through the differentiating element 17 to the start input of the generator 18, the output of which is connected through the differentiating element 19 to the installation input "0" trigger 2. The output of the I21 element is connected to the input of the installation in "1" of the trigger 22, a single output of which is connected through the differentiating element 23 with the second input of the OR20 element. The output of the generator 10 is connected to the second input of the I11 element, the output of which is connected to the installation input at “0” of the trigger 9, the installation input to “1” of which is connected to the output of the OR element 8, and the unit output of which is connected to the first input of the I11 element, with the first the input of the I21 element and the first input of the I24 element, as well as through the differentiating element 12 with the input 71 of the preparation unit 13 (the second input of the OR73 element), the output 14 of the preparation unit 13 (the output of the I76 element) is connected to the input 69 of the block 15 (the start input of the generator 25 of the block fifteen). The output of the generator 25 is connected through the differentiating element 33 to the first input of the OR56 element, and through the differentiating element 34 with the installation input to trigger 1 “43” and the start input of the generator 26, the output of which is connected through the differentiating element 35 to the first input of the I49 element, the second input of which connected to a single output of the trigger 43, the output of the I49 element is connected to the first input of the OR57 element, the output of which is connected to the start input of the generator 27, the output of which is connected through the differentiating element 36 to the start input of the generator 28, whose output through the differentiating element 37 is connected to the start input of the first random number generator 63, the first and second outputs of which are connected to the first and second inputs of the first decoder 65, respectively, the first and second outputs of which are connected to the first and second inputs of the element OR58, respectively, the output of which is connected to the stop input of the generator 63, the first output of the decoder 65 is also connected to the installation input in "1" of the trigger 44 and the start input of the generator 29, the output of which through the differentiating element 38 is connected to the input of the installation to “0” of the trigger 44 and the input of the installation to “1” of the trigger 45, the single output of the latter is connected to the first input of the I50 element, the second input of which is connected to the single output of the trigger 43, and the output of which is connected to the second input of the OR56 element and the first input of the OR60 element, the stop inputs of the generators 25 and 26 and the installation input to “0” of the trigger 46, the single output of which is connected to the third input of the And50 element, the output of which is connected through the first input of the OR59 element to the installation input to the “0” of the trigger 45, the second input of the element OR59 connected to input before the trigger 43 is set to “0” and to the output of the OR56 element, the second output of the decoder 65 is connected to the installation input in the “1” trigger 47 and through the delay element 67 to the first input of the I51 element, the second input of which is connected to the single output of the trigger 47, the first the input of the I53 elements, the output of the I51 element is connected to the first input of the OR61 element, the output of which is connected to the start input of the generator 30, the output of which through the differentiating element 39 is connected to the first direct input of the I54 element, with the second input of the I53 element, the output of which is connected to the second input element OR57 and the installation input to “0” of trigger 47, the third input of elements I51, I53 is connected to a single output of trigger 43, the single output of trigger 44 is connected to the inverse inputs And of elements I54, I55, and through the differentiating element 40 to the first direct input of element I55 the output of which is connected to the second input of the element OR61, the second direct inputs of the elements I54, I55 are connected to the single output of the trigger 43, the output of the element I54 is connected to the start input of the generator 31, the output of which is connected through a differentiating element 41 to the start input of the generator 32, the output of which is connected through a differentiating element 42 to the start input of the generator 64, the first and second outputs of which are connected to the first and second inputs of the decoder 66, respectively, the first output of which is connected to the installation input in "1" of the trigger 46, the second input of the OR element 60 and the first input of the element OR62, the second output of the decoder 66 is connected to the installation input in "1" of the trigger 48, the input of the delay element 68 and to the second input of the element OR62, the output of which is connected to the stop input of the generator 64, the output of the element OR60 is connected to the installation input and at "0" trigger 48, the single output of which is connected to the first input of the I52 element, the second input of which is connected to the output of the delay element 68, and the third input of which is connected to the single output of the trigger 43, the output of the I52 element is connected to the third input of the OR61 element, the output the differentiating element 14 of the device is connected to the input of the start of the generator 25 of the block conducting sessions, the output of the element OR56 of the block conducting sessions is connected to the second input of the element OR8 and the input to the setting “0” of the trigger 22 of the device.

In the preparation block 13, the input 71 (the second input of the OR element 73 of block 13) to the output of the differentiating element 12, the output of the OR element 73 is connected to the start input of the generator 74, the output of which is connected through the differentiating element 81 to the first input of the I76 element, and through the differentiating element 79 with the input the start of the generator 78, the output of which is connected to the first input of the I77 element, the output of which is connected through the differentiating element 72 with the stop input of the generator 74, the output of the I77 element is also connected to the start input of the generator 75, the output of which is connected n through the differentiating elements 80 and 82 with the installation inputs “0” and “1” of the trigger 83, respectively, the output of the differentiating element 82 is also connected to the stop input of the generator 78 and the first input of the OR73 element, the single output of the trigger 83 is connected to the second inputs of the I76 elements and I77. The output of the element And 76 is the output 14 of the block 13.

The device simulates the functioning of a ground-based mobile measuring complex (NMIK), conducting sessions with aircraft outside the place of constant residence and having the following cycle of application. Having received an order (command), the NMIK is transported (moves) to the place of the sessions with aircraft (LA). Arriving at the place, NMIK is deployed and takes its initial state - it is waiting for the application for sessions. At the same time, NMIK can have no more than one application. The received application for the session puts the NMIK in preparation for the session. During the preparation of the NMIK, failures that need to be eliminated can be detected (occur). Only after they are eliminated and the work on preparing the NMIK is started, they begin to conduct a session with the aircraft, including receiving from the aircraft, forming and storing a complete information frame (PIC), reproducing the PIC, forming a shortened information frame (SIC), display and analysis of the SEC, separate transmission LIC and PIC and analysis of the quality of the transmission of PIC. At the end of the session, the NMIK again goes into standby mode and the sessions continue. When forming, displaying and analyzing SICs and PICs, qualitative or poor-quality implementation is possible. Having received an order (command) to complete the work, the NMIK collapses (if there are sessions in the NMIK, then they are carried out), and then it is transported (moves) to the place of his permanent stay or to another place. Upon receipt of the next command, the NMIK is transported to a new venue for the sessions, where the above-described functioning cycle is repeated. The considered processes of NMIK functioning start at random time instants and proceed at random time intervals distributed according to various laws.

The task of the device is as follows. Using the device, we simulate the functioning processes of a ground-based mobile measuring complex during operation for various laws of distribution of random time intervals of their course, taking into account the dynamics and specifics of their application, as well as the occurrence of failures and their elimination in preparation for conducting sessions with an aircraft. and counting the statistical characteristics of these processes according to the readings of meters connected to various elements of the device, it is possible to evaluate various probabilistic-temporal statistical indicators, as well as to study the effect on them of the main operational and technical characteristics of a ground-based mobile measuring complex, taking into account the reliability, dynamics and specifics of their functioning, substantiate the requirements for them and recommend ways to ensure them.

The device operates as follows. In the initial state, trigger 9 is set to a state in which there is no enable voltage at the first inputs of I11, I21, I24, triggers 2, 22 are set to a state where there is no enable voltage at their individual outputs, trigger 43 is set to there is no resolution voltage at the second inputs of the elements I49, I50, I51, I52, I53, I54, I55, the trigger 44 is set to the position where the inverse inputs of the elements And 54. I55 there is a resolution voltage, the triggers 45, 46 are set to which m, at the first and third inputs of the I50 element, respectively, there is no resolution voltage, the trigger 47 is set to a position where there is no second input of the I51 element, the first input of the I53 element, the trigger 48 is set to the position where there is no I52 element at the first direct input. Device generators are not running. The trigger 83 of the block 13 is installed in a position in which at the second inputs of the elements I76 and I77 there is a resolution voltage.

After the device is turned on, the triggers are set to their initial state, then the device operates as follows. A signal (instruction) from the first output of generator 1 transfers trigger 2 to a single state, while a positive pulse appears at the output of the differentiating element 3, which starts the generator 4, generating a random pulse of adequate duration, adequate to the transport (movement) time, after which (arrival of the NMIK to the venue of the sessions) from the differentiating element 5, a generator 6 is launched, generating a pulse of random duration adequate to the deployment time of the NMIK, after which the differential guide member 7 is started generator 10 generates a random pulse stream, simulating receipt of requests for sessions with LA and through the first or 8 element input translates trigger 9 in one state, simulating the standby mode and AI elements I21, I24 are opened on the first input. After a certain time interval, the generator 10 begins to generate a random stream of pulses that simulate the receipt of applications for conducting sessions with the aircraft. The pulse that appears at the output of the generator 10 passes through the second input of the open element And 11 and puts the trigger 9 in its original state, while from the differentiating element 12 is launched through the input 71 of the preparation unit 13, simulating failures and their elimination in this mode, as well as generating a pulse random duration adequate to the time of preparation of the NMIK.

The operation of block 13 is as follows:

A) If there are no failures, then in this case the pulse from the output of the differentiating element 12 enters through the input 71 of block 13 (the second input of the OR element 73) to the start input of the generator 74, which generates a pulse of random duration, adequate to the preparation time of the NMIK, which comes through the differentiating element 81 (differentiation on the trailing edge of the pulse of the generator 74) to the first input of the open element And76, then to the output 14 (the output of the element And76) block 13 and starts the generator 25 of block 15 (input 69 of block 15).

B) In the event of failures, their elimination and preparation of the NMIK, the operation of block 13 is reduced to the following. The pulse from the output of the differentiating element 12 enters through the input 71 of block 13 (the second input of the OR73 element) to the input of the start of the generator 74, generating a pulse of random duration adequate to the preparation time of the NMIK, which comes through the differentiating element 79 (differentiation along the leading edge of the pulse of the generator 74) to the start input of the generator 78, forming a case of a stream of pulses that simulate NMIK failures in preparation. If a pulse appears at the output of the generator 78 during the duration of the pulse of the generator 74, it passes through the open element I77 and the differentiating element 72 (differentiation along the leading edge of the pulse of the generator 78) and enters the stop input of the generator 74. The pulse from the output of the I77 element also starts the generator 75, generating a pulse of random duration, adequate to the time to eliminate the failure of the NMIK, which enters through the differentiating element 80 (differentiation along the leading edge of the pulse of the generator 75) to the input and in “0” of trigger 83, i.e. moves trigger 83 to the position at which the I76 and I77 elements close at the second inputs, which corresponds to the beginning of the elimination of the failure. The pulse from the output of the generator 75 also passes through the differentiating element 82 (differentiation with respect to the trailing edge of the pulse of the generator 75) and arrives at the input of the setup in trigger 1 of trigger 83, bringing it to its original state, i.e. it opens the I76 and I77 elements at the second input, stops the generator 78 and, acting through the first input of the OR73 element, starts the generator 74. Next, the block 13 operates as described above.

At the end of the preparation time interval from the output 14 of the preparation unit 13 (the output of the I76 element), the impulse that appears starts the generator 25 in block 15 (input 69), generating a pulse of random duration adequate to the time of the session with the aircraft. At the same time, the trigger 43 is brought into a single state from the differentiating element 34 (along the leading edge of the pulse of the generator 25) and the generator 26 is launched, generating a pulse of random duration, adequate to the time of reception, formation and storage of the complete information frame from the aircraft. In this case, from the differentiating element 35 (along the trailing edge of the pulse of the generator 26), the pulse passes through the first input of the open element I49 and the element OR57 and starts the generator 27, generating a pulse of random duration, adequate to the formation time of the reduced information frame.

In this case, from the differentiating element 36 (along the trailing edge of the pulse of the generator 27), the pulse starts the generator 28, which generates a pulse of random duration, adequate to the time of display and analysis of the reduced information frame (LMS). In this case, from the differentiating element 37 (along the trailing edge of the pulse of the generator 28), the pulse starts the generator 63, which generates pulses at the first (high-quality LMS) or second (low-quality LMS) outputs, depending on the quality of the display and analysis of the LMS.

1. Let’s say the pulse appeared at the first output of the generator 63 (that is, a quality control system), then, passing through the first input and the first output of the decoder 65, it will translate the trigger 44 into a single state, through the OR58 element to the stop input of the generator 63 and start the generator 29, generating a pulse of random duration adequate to the transmission time of the LMS. Moreover, from the differentiating element 38 (along the trailing edge of the pulse of the generator 29), the pulse transfers the trigger 45 to a single state, the trigger 44 to its original state.

2. If the pulse appeared at the second output of the generator 63 (that is, the SIC is of poor quality), then it, passing through the second input and the second output of the decoder 65, will translate the trigger 47 into a single state, through the OR58 element to the stop input of the generator 63 and through the element delays 67, the open element I51 and the element OR61 and will start the generator 30, forming a pulse of random duration, adequate to the playback time of the full information frame (PIC). In this case, from the differentiating element 39 (along the trailing edge of the pulse of the generator 30), the pulse passes through the open I53 element and enters the installation input at “0” of the trigger 47, translating it to its initial state, and through the second input of the OR57 element to the start input of the generator 27. Further, the device operates similarly to paragraph 1. If during the session it was not possible to obtain a high-quality LMS, then at the end of the pulse at the output of the generator 25, the differentiating element 33 generates a pulse that is fed to the first input of the OR56 element and translates gger 43 in the initial state, and the second input member or 8, transferring the trigger 9 in one state, thereby simulating NMIK transition to standby mode. If a pulse appears from the first output of generator 1, then the device then operates according to the above scheme. If a high-quality LMS transmission is implemented, which is simulated by the appearance of a pulse of random duration at the output of the generator 29, then a pulse appears at the output of the differentiating element 38 (along the trailing edge of the pulse from the generator 29), which transfers the trigger 44 to its initial state, opening the I54 elements on the inverse inputs, I55, the appearing pulse at the output of the differentiating element 40 passes through the I55, OR61 elements and starts the generator 30, generating a pulse of random duration, adequate to the PIC playback time. In this case, from the differentiating element 39 (along the trailing edge of the pulse of the generator 30), the pulse through the open element I54 starts the generator 31, which generates a pulse of random duration adequate to the transmission time of the PIK. In this case, from the differentiating element 41 (along the trailing edge of the pulse of the generator 31), the pulse starts the generator 32, generating a pulse of random duration, adequate to the analysis of the quality of the transmission of the PIC.

At the same time, from the differentiating element 42 (along the trailing edge of the pulse of the generator 32), the pulse starts the generator 64, which, depending on the quality of the PIC transmission, generates pulses at the first (high-quality PIK) or second (low-quality PIK) outputs.

3. Suppose the pulse appeared at the first output of the generator 64 (that is, the PIC is high-quality), then, having passed through the first input-output of the decoder 66, it will transfer the trigger 46 to a single state, through the OR62 element to the stop input of the generator 64, and also opens the I50 element, and the pulse from its output will stop the generators 25 and 26 and transfer the trigger 46, and through the OR59 element and the trigger 45 to the initial state, as well as passing the OR element 56, set the trigger 43 to the initial state and go to the second input of the OR8 element ( through the output 70 of block 15), which corresponds to the mode o liquids. Further, the process of functioning of the device is similar to the above.

4. If the pulse appeared at the second output of the generator 64 (that is, the PIC is of poor quality), then, having passed through the second input-output of the decoder 66, it will transfer the trigger 48 to a single state, through the OR element 62 to the stop input of the generator 64 and through the delay element 68, the open element I52 and the element OR61, and will start the generator 30, generating a pulse of random duration, adequate to the playback time of the full information frame (PIC). In this case, from the differentiating element 39 (along the trailing edge of the pulse of the generator 30), the pulse passes through the open element I54 (the I53 element is closed at the first input from the trigger 47) to the start input of the generator 31. Further, the device operates similarly to paragraph 3.

If after a retransmission (before that there was a poor-quality PIK), a pulse appears again at the second output of the generator 64, then the device is repeated as described in step 4. If, after a retransmission (before that there was a poor-quality PIK), a pulse appears at the first output of the generator 64 , then the functioning of the device occurs, as described in paragraph 3. In this case, the pulse from the first output of the decoder 66 transfers the trigger 48 to the initial state through the OR60 element.

If during the session it was not possible to obtain a high-quality PIK, then at the end of the pulse at the output of the generator 25, the differentiating element 33 generates a pulse that arrives at the first input of the OR56 element and transfers the trigger 43 to its original state, closing the I49, I50, I51, I52 elements, I53, I54, I55, as well as to the second input of the OR8 element, translating trigger 9 into a single state, thereby simulating the transition of the NMIK into standby mode. If a pulse appears from the first output of generator 1, then the device then operates according to the above-described scheme. An impulse to terminate the operation of the NMIK from the second output of the generator 1 in the absence of an application for a session with the aircraft arrives through the open element I24 and the element OR20 to the input of the start of the generator 16, which generates a pulse of random duration adequate to the coagulation time of the NMIK. At the end of the coagulation time interval, the pulse from the differentiating element 17 starts the generator 18, generating a pulse of random duration, adequate to the time of transportation of the NMIK. At the end of the transportation time interval (arrival at the place of permanent residence), the pulse from the differentiating element 19 sets the trigger 2 to the zero state, thereby preparing the NMIK for a new extension to the venue of the sessions with the aircraft. If there is an application to the NMIK to conduct a session, the pulse to end operation from the second output of the generator 1 through the open I21 element sets the trigger 22 to a single state, at the end of the session, the pulse from the output of the OR56 element of block 15 (output 70 of block 15) sets the trigger 22 to zero state, and the impulse from the differentiating element 23 through the OR element 20 starts the generator 16 random NMIC coagulation time intervals. Further, the device operates similarly to the above description.

The statistical characteristics of the functioning processes of the ground-based mobile measuring complex, taking into account the dynamics and specifics of its application, as well as the occurrence of failures and their elimination during preparation, can be determined by the readings of meters connected to various elements of the device. The obtained statistical characteristics for various laws of distribution of random time intervals of the functioning processes of ground-based mobile measuring complexes, taking into account the dynamics and specifics of their application, as well as the occurrence of failures and their elimination in preparation, allow us to solve the problems of estimating, predicting and providing probability-time indicators of operational properties (for example , efficiency, availability, reliability, speed of information delivery and others) as at the stages of rabotki new, improvement and operation of modern terrestrial mobile measuring systems.

Thus, as can be seen from the description of the operation of the device, the specified technical result is achieved.

Claims (1)

A device for modeling the functioning processes of a ground-based mobile measuring complex during operation, containing a single-pulse generator, first and second OR elements, first, second and third triggers, first to seventh differentiating elements, a random preparation time interval generator, a random coagulation time generator, a generator random flow of pulses, generator of random deployment time intervals, first to third elements AND, first and second case generators intervals of transport time, and the output of the first OR element is connected to the installation input in "1" of the first trigger, the single output of which is connected to the first inputs of the first, second and third AND elements and to the input of the first differentiating element, the output of the random pulse stream generator is connected to the second the input of the first element And, the output of which is connected to the installation input at "0" of the first trigger, the first output of the single pulse generator is connected to the input of the installation to "1" of the second trigger, whose single output is cut the second differentiating element connected to the start input of the first generator of random intervals of transportation time, the output of which through the third differentiating element is connected to the start input of the generator of random time intervals of deployment, the output of which is connected through the fourth differentiating element to the first input of the first OR element and to the input of the random generator pulse flow, the stop input of which is connected to the second output of the single pulse generator and the second inputs of the second and of the third AND element, the output of the second AND element is connected to the installation input in "1" of the third trigger, the output of the third AND element is connected to the first input of the second OR element, the unit output of the third trigger is connected through the fifth differentiating element to the second input of the second OR element, the output of which is connected to the input of the start of the generator of random coagulation time intervals, the output of which through the sixth differentiating element is connected to the start input of the second generator of random intervals of transport time, the output of which connected through the seventh differentiating element to the input of the installation at "0" of the second trigger, the unit for conducting sessions, including from the first to eighth random time generators, from the first to tenth differentiating elements, from the first to sixth triggers, from the first to seventh elements first to seventh OR elements, first and second delay elements, first and second random number generators, first and second decoders, the output of the first random time generator being connected via the first differentiation the first element with the first input of the first OR element, and through the second differentiating element with the installation input in "1" of the first trigger and the start input of the second random time generator, the output of which is connected through the third differentiating element to the first input of the first AND element, the second input of which is connected with a single output of the first trigger, the output of the first AND element is connected to the first input of the second OR element, the output of which is connected to the start input of the third random time generator, the output of which о is connected through the fourth differentiating element to the start input of the fourth random time generator, the output of which through the fifth differentiating element is connected to the start input of the first random number generator, the first and second outputs of which are connected to the first and second inputs of the first decoder, respectively, the first and second outputs of which connected to the first and second inputs of the third OR element, respectively, whose output is connected to the stop input of the first random number generator, the first output q of the first decoder is also connected to the installation input in “1” of the second trigger and the start input of the fifth random time generator, the output of which through the sixth differentiating element is connected to the installation input to “0” of the second and the installation input to “1” of the third trigger, single output the latter is connected to the first input of the second AND element, the second input of which is connected to the unit output of the first trigger, and the output of which is connected to the second input of the first and first input of the fifth OR element, stop inputs of the first and second generators of random time intervals and the installation input to “0” of the fourth trigger, the single output of which is connected to the third input of the second AND element, the output of which is also connected through the first input of the fourth OR element to the installation inputs to “0” of the third trigger, the second input of the fourth OR element connected to the installation input at "0" of the first trigger and the output of the first OR element, the second output of the first decoder is connected to the installation input at "1" of the fifth trigger and through the first delay element with the first input of the third AND element, the second input of which is connected to the single output of the fifth trigger, the first input of the fifth AND element, the output of the third AND element is connected to the first input of the sixth OR element, the output of which is connected to the start input of the sixth random time generator, the output of which through the seventh differentiating element is connected to the first direct the input of the sixth AND element, with the second input of the fifth AND element, the output of which is connected to the second input of the second OR element and the installation input in the “0” of the fifth trigger, the third input of the third and fifth element s AND is connected to the single output of the first trigger, the single output of the second trigger is connected to the inverse inputs of the sixth and seventh AND elements, and through the eighth differentiating element to the first direct input of the seventh AND element, the output of which is connected to the second input of the sixth OR element, the second direct inputs of the sixth and the seventh element And are connected to the single output of the first trigger, the output of the sixth element And is connected to the start input of the seventh random time generator, the output of which is connected through the ninth different coding element with the start input of the eighth random time generator, the output of which is connected through the tenth differentiating element to the start input of the second random number generator, the first and second outputs of which are connected to the first and second inputs of the second decoder, respectively, the first output of which is connected to the installation input in 1 "of the fourth trigger, the second input of the fifth and the first input of the seventh element OR, the second output of the second decoder is connected to the input of the installation in" 1 "of the sixth trigger, the input of the second the delay element and with the second input of the seventh OR element, the output of which is connected to the stop input of the second random number generator, the output of the fifth OR element is connected to the setting input “0” of the sixth trigger, whose single output is connected to the first input of the fourth AND element, the second input of which connected to the output of the second delay element, and the third input of which is connected to a single output of the first trigger, the output of the fourth AND element is connected to the third input of the sixth OR element, the output of the first OR element is checked Sessions are connected to the second input of the first OR element and the installation input at “0” of the third trigger of the device, characterized in that a training unit is introduced, which includes two random time generator, a random pulse flow generator, five differential elements, a trigger, and an OR element, the output of which is connected to the start input of the first random time generator, the output of which is connected through the first differentiating element with the first input of the first And element, and through the second differentiating element with the start input of the random pulse stream generator, the output of which is connected to the first input of the second AND element, the output of which is connected through the third differentiating element with the stop input of the first random time generator, the output of the second And element is also connected to the start input of the second random time generator, the output which is connected to the inputs of the fourth and fifth differentiating elements, the outputs of which are connected to the inputs of the installation in "0" and "1" of the trigger, respectively, the output of the fifth differential the coding element is also connected to the first input of the OR element and the stop input of the random pulse stream generator, a single output of the trigger is connected to the second inputs of the first and second elements And, the second input of the OR element is connected to the output of the first differentiating element of the device, the output of the first element AND of the preparation unit is connected to the start input of the first generator of random time intervals of the block conducting sessions.

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