RU2743622C1 - Ornitological situation monitoring system in the airport area - Google Patents

Abstract

FIELD: automated monitoring systems.

SUBSTANCE: invention relates to ornithological situation monitoring system in the airport area. System comprises interrelated with each other elements as follows: unit for receiving transactions from sensors of the environment ornithological monitoring, ornithological environmental control sensors, unit for receiving information from the database of the system server, database server, unit for setting time cycles of scanning the ornithological environmental control scanners, unit for fixing the given number of the cycles of the scanning sensors for ornithological monitoring of the environment, unit for addressing signals of scanning the environmental ornithological control sensors, unit for selecting addresses of the environmental ornithological monitoring sensors in the database of the system server, unit for issuing target designation data to an unmanned aerial vehicle, unit for identifying critical readings of sensors for the environmental ornithological monitoring, unit for sequential sampling of coordinates of location of sensors for the environmental ornithological monitoring.

EFFECT: increased efficiency of automated monitoring of the ornithological situation in the airport area.

1 cl, 7 dwg, 2 tbl

Description

The invention relates to computer technology, in particular, to a system for monitoring the ornithological situation in the airport area.

Every year, the International Civil Aviation Organization (ICAO) registers about 5,000 helicopter and aircraft collisions with birds around the world. At the airports, teams of bird watchers work every day to ensure that birds do not interfere with aircraft and prevent emergencies.

The main task of the bird service is to make the airport area as less attractive for birds as possible. With the onset of spring, bird watchers have more work: the number of birds in the city and its surroundings is increasing due to spring migration, which means that the potential danger of their collision with aircraft during takeoff and landing increases.

To scare away birds, they use both the latest technical means, such as bioacoustic posts, portable laser guns, reflective balls, and traditional methods - birds of prey. Recently, unmanned aerial vehicles have been introduced into the airport bird service.

At the same time, the existing monitoring systems do not allow everywhere and constantly monitoring and observing the appearance of birds and promptly notifying ornithological services about the possibility of emergencies in the environment of the airport.

All this testifies to the specific difficulties arising in the study of the air environment of airports, and determines high requirements for the quality of ornithological control.

The direction of solving this problem is the creation of automated monitoring of the surrounding air environment of airports - a system for operational monitoring of the state of the air situation, as well as timely assessments and forecasts.

Known technical solutions to the problem [1, 2].

The first of the known technical solutions contains at least one processor and at least one memory containing a computer program code, wherein said at least one memory and said computer program code are configured so that, together with said at least one processor to ensure that the specified device performs at least the following: determining a change in the position of the specified device; and processing at least one audio signal for uplink transmission depending on said position change, wherein said at least one audio signal includes at least one audio signal received from at least , one microphone, and the processing of the specified at least one audio signal depending on the specified change in position ensures that the specified device performs at least one selection of at least one specified audio signal for signal output depending on the specified change in position [ one].

The disadvantage of this technical solution lies in the low speed of the device, since the device gives out the data for making a decision only after the end of the collection and processing of all input information.

Another technical solution is known, containing a unit for receiving transactions from sensors for environmental monitoring of the air condition, a unit for identifying sensors for environmental monitoring of the air condition, first, second and third memory blocks, a unit for counting the number of incoming transactions, the first and second comparators, the first and second blocks of addressing records input transactions of sensors for environmental monitoring of air conditions. [2].

The disadvantage of this technical solution also consists in low speed, due to the large amount of time spent on solving computational problems.

The purpose of the invention is to eliminate this disadvantage, i. E. in increasing the speed of the system by eliminating the time spent on identifying extreme situations that require immediate response.

This goal is achieved by the fact that the system containing a block for receiving transactions from sensors of ornithological monitoring of the environment, the information and synchronization inputs of which are the first information and synchronization inputs of the system, respectively, while the first information input of the system is intended for receiving transactions from sensors of ornithological monitoring of the environment, the first synchronizing input of the system is designed to receive synchronizing signals of entering transactions from sensors of ornithological control of the environment into a block for receiving transactions from sensors of ornithological control of the environment, a block for receiving information from the database of the system server, the information and synchronizing inputs of which are the second information and synchronizing inputs of the system, respectively , while the second information input of the system is intended for receiving data from the database of the system server, and the second synchronizing input of the information receiving unit and from the database of the system server is intended for entering data into the block for receiving information from the database of the system server, the block for setting the time cycles of polling the sensors of ornithological monitoring of the environment, one clock input of which is the clock input of the system, designed to receive system start pulses, the first synchronizing output of the block setting the time cycles of polling the sensors of ornithological environmental control is connected to the counting input of the block for fixing a given number of polling cycles of the sensors of the ornithological control of the environment, and the other synchronizing output of the block setting the time cycles of polling the sensors of ornithological control of the environment is connected to the synchronizing input by the input of the block for fixing the given number of polling cycles ornithological environmental control sensors, a block for addressing interrogation signals of the sensors of ornithological environmental control, the clock outputs of which are the clock outputs of the system, p Designed for issuing signals from polling sensors for ornithological environmental control, characterized in that the system contains a block for selecting addresses of sensors for ornithological control of the environment in the database of the system server, the information input of which is connected to the first information output of the block for receiving transactions from sensors of ornithological control of the environment, and the synchronizing input of the unit for selecting addresses of sensors for ornithological monitoring of the environment in the system server database is connected to the first synchronizing input of the system, while the address output of the unit for selecting addresses of sensors for ornithological monitoring of the environment in the database of the system server is the address output of the system intended for issuing read addresses to the address input of the system server, and the synchronizing output of the address selection block of the sensors of ornithological environmental control in the system server database is the synchronizing output of the system, before designated for issuing signals to the input of the first interrupt channel of the database server, the unit for issuing target designation data to an unmanned aerial vehicle, the information input of which is connected to the first information output of the unit for receiving transactions from sensors of ornithological monitoring of the environment, and the information output of the target designation data output unit for the unmanned aerial vehicle is the information output of the system, the unit for identifying critical readings of the ornithological environmental monitoring sensors, one information input of which is connected to the second information output of the unit for receiving transactions from the sensors of ornithological environmental monitoring, another information input of the unit for identifying critical readings of the ornithological environmental monitoring sensors is connected to the information output of the unit receiving information from the database of the system server, synchronizing the input of the identification unit for critical readings of ornithological control sensors environment is connected to the second synchronizing input of the system, while one output of the unit for identifying critical readings of ornithological environmental monitoring sensors is connected to the synchronizing input of the unit for issuing target designation data to the unmanned aerial vehicle and to the third synchronizing input of the unit for setting the time cycles of polling the sensors of ornithological environmental monitoring, and the other output of the unit for identifying critical readings of the ornithological environmental monitoring sensors is connected to the second synchronizing input of the unit for setting the time cycles of polling the sensors of ornithological environmental monitoring, and a unit for sequential sampling of coordinates of the location of the ornithological environmental monitoring sensors, the information input of which is connected to the information output by the input of the fixation unit of the specified number of polling cycles of sensors of ornithological control of the environment, synchronizing input of the block of sequential sampling of coordinates location of sensors for ornithological control of the environment, while the information output of the block for fixing a given number of polling cycles of sensors for ornithological control of the environment is connected to the information input of the block for addressing polling signals of sensors for ornithological control of the environment, and the synchronizing output of the block for fixing a given number of cycles of polling for sensors of ornithological control of the environment connected to the synchronizing input of the block for addressing polling signals of the sensors of ornithological monitoring of the environment.

The essence of the invention is illustrated by drawings, where FIG. 1 is a block diagram of the system; FIG. 2 is a block diagram of a block for selecting addresses of sensors for ornithological monitoring of the environment in the database of the system server; FIG. 3 is a block diagram of a unit for identifying critical readings of sensors for ornithological monitoring of the environment; FIG. 4 is a block diagram of a block for setting time cycles of polling of sensors for ornithological monitoring of the environment; FIG. 5 is a block diagram of a block for fixing a predetermined number of polling cycles of sensors for ornithological monitoring of the environment; FIG. 6 is a block diagram of a unit for sequential sampling of coordinates of the location of sensors for ornithological monitoring of the environment; FIG. 7 is a block diagram of a block for addressing polling signals from sensors of ornithological monitoring of the environment.

The system (Fig. 1) contains a block 1 for receiving transactions from sensors of ornithological control of the environment, block 2 for selecting addresses of sensors for ornithological control of the environment in the database of the system server, block 3 for identifying critical readings of sensors for ornithological control of the environment, block 4 for receiving information from the database system server data, block 5 for issuing target designation data to an unmanned aerial vehicle, block 6 for setting time cycles for polling sensors for ornithological environmental control, block 7 for fixing a given number of polling cycles for sensors for ornithological monitoring of the environment, block 8 for sequential sampling of coordinates of the location of sensors for ornithological monitoring of the environment, block 9 addressing signals of polling sensors ornithological monitoring of the environment.

FIG. 1 shows the first 10 and second 11 information inputs, the first 12 and second 13 synchronizing and clocking 14 inputs of the system, as well as the address 15, information 16, synchronizing 17, and clocking 18-20 outputs of the system.

Block 1 (Fig. 1) for receiving transactions from sensors of ornithological monitoring of the environment is made in the form of a register having information 10 and synchronizing 12 inputs, as well as the first 21 and second 22 information outputs.

Block 2 (Fig. 2) selection of addresses of sensors of ornithological monitoring of the environment in the database of the system server contains a decoder 50, read-only memory 51, elements 52-54 AND, register 55, and elements 56-58 delay. The drawing shows information 26, synchronizing 27 inputs, as well as address 15 and synchronizing 17 outputs.

Block 3 (Fig. 3) for identifying critical readings of sensors of ornithological monitoring of the environment contains a comparator 60 and a delay element 61. The drawing shows the first 30 and second 31 information inputs and the first 33 and second 34 outputs, respectively.

Block 4 (Fig. 1) for receiving information from the database of the system server is made in the form of a register having information PI synchronizing 13 inputs, as well as information output 23.

Unit 5 (Fig. 1) for issuing target designation data to an unmanned aerial vehicle is made in the form of a group of elements AND, having information 25 and synchronizing 29 inputs, as well as information 16 output.

Block 6 (Fig. 4) for setting the time cycles of polling the sensors of ornithological monitoring of the environment contains a trigger 62, a clock generator 63, an AND element 64, an OR element 65, and a delay element 66. The drawing shows the first 14, second 36 and third 37 timing inputs, as well as the first 33 and second 34 outputs.

Block 7 (Fig. 5) fixing a predetermined number of polling cycles of sensors of ornithological monitoring of the environment contains a counter 68, a register 69 and a comparator 70. The drawing shows the counting 38 and synchronizing 39 inputs, as well as information 40 and synchronizing 41 outputs.

Block 8 (Fig. 6) for sequential sampling of the coordinates of the location of the sensors of ornithological monitoring of the environment, contains a decoder 77, read-only memory 78, register 79, elements 80 - 82 AND, and elements 83, 84 delay. The drawing shows information 42 and synchronizing 43 inputs, as well as information 44 and synchronizing 45 outputs.

Block 9 (Fig. 7) for addressing interrogation signals of sensors of ornithological monitoring of the environment contains a decoder 85 and a group of elements 86 - 88 I. The drawing shows information 46 and synchronizing 47 inputs, as well as 18-20 timing outputs of the unit.

All units and elements of the system are made on standard potential-impulse elements.

The monitoring system works as follows.

The airport birdwatching service usually monitors birdlife within a 15 km radius of the airport control point. For this purpose, sensors for ornithological monitoring of the environment are installed along the perimeter and radial directions of the control zone.

Determining the exact location of the sensor of ornithological monitoring of the environment plays a key role in the implementation of continuous monitoring of the state of the ornithological situation, and most importantly in the prompt response to an emergency and providing data for the most accurate analysis of critical situations.

The system is started up by applying a pulse to input 14, from where this pulse passes through element 65 OR to the direct input of trigger 62 and sets it to a single state, in which the latter opens high potential element 64 AND, to the other input of which the clock generator 63 is connected ...

As a result, the first clock pulse of the generator 63 passes through the element 64 AND, and from the output 24 of the block 6 is fed to the counting 38 input of the block 7, from where it is fed to the counting input of the counter 68, which records the fact of polling the first sensor of ornithological environmental control.

The readings of the counter 68 are fed to the input 71 of the comparator 70, nm another informational 72 input of which comes the code of the total number of sensors of ornithological control of the environment from the input of register 69, entered into it from the control panel of the system.

In parallel with this, the timing pulse from the output of the element 64 AND block 6 is delayed by the element 66 for the duration of the counter 68 of the block 7, and from the output of the delay element 66, firstly, it is fed to the setting input of the flip-flop 62, returning it to its original state and blocking, thus, the operation of element 64 I.

Secondly, the signal from the output of the delay element 66 through the output 25 of block 6 is fed to the synchronizing input of the comparator 70 of block 7. According to this signal, the comparator 70 compares the readings of the counter 68 with the readings of the register 69. Considering that at this moment in time the readings of the counter 68 are much less readings of register 69, the comparator 70 generates a signal at the output 74, from where from the output 41 of block 7 it is fed to the synchronizing input 43 of block 8.

By this time, the code for reading the counter 68 from the output 40 of block 7 entered the input 42 of the decoder 77 of block 8. The decoder 77 decrypts the indicated code and opens one of the elements 80 - 82 AND, for example, element 80 I. As a result, the synchronizing pulse from the input 43 of block 8 passes element 80 AND, and enters the readout input of the fixed memory cell of the read-only memory 78, in which the coordinates of the corresponding sensor of ornithological monitoring of the environment are recorded.

The read coordinates of the corresponding sensor of ornithological control of the environment from the output of ROM 78 are fed to the information input of register 79, where they are entered by a synchronizing pulse from the input 43 of block 8, delayed by a delay element 83 for the time of reading data from ROM 78.

From the output of register 79, the coordinate code of the corresponding sensor of ornithological control of the environment through the information output 44 of block 8 is fed to the address output 46 of block 9. At the same time, the synchronizing pulse from the output of the delay element 83 is delayed by the delay element 84 for the time when the coordinate code is entered into the register 79 , and then from the output 45 of block 8 is fed to the synchronizing input 47 of block 9.

Decoder 85 decodes the coordinate code of the corresponding sensor of ornithological environmental control and opens one of the elements 86 - 88 AND, for example, element 86 I. As a result, the synchronizing pulse from the input 47 of block 9 passes to the output of the element 86 I, and from the output 18 of the system is issued to the synchronization input of the corresponding sensor of ornithological control of the environment as a signal for polling its readings.

With the arrival of this polling signal, the corresponding ornithological environmental control sensor generates a transaction codogram, which has the following form:

The specified codogram is transmitted to the information processing center and through the information input 10 of the system enters the information input of block 1, made in the form of a register. According to the synchronizing signal arriving at the synchronizing 12 input of block 1, the codogram is entered into the register of block 1.

The structure of the transaction codogram in the register of block 1 is as follows:

The code of the sensor identifier from which this transaction came from the output 21 of block 1 is fed to the address 26 input of block 2 and then to the input of the decoder 50, and the synchronizing pulse from the input 12 of the system through the input 27 of block 2 of the system is delayed by the delay element 58 for the time of entering the code sensor identifier in register 1 and decoder operation 50, and then goes to the inputs of elements 52 - 54 I.

The decoder 50 decrypts the received code and prepares the signal path from the output of the delay element 58, opening one of the elements 52 - 54 I. For definiteness, let us assume that a high potential arrived at one input of the element 52 I.

Taking into account the fact that only the AND element 52 will be open at one input, after passing this AND element, the sync pulse arrives, firstly, at the read input of the fixed memory cell of the read-only memory (ROM) 51, which stores the address code of the threshold indicator of this birdwatching environmental sensor in the system database server.

The code of the specified address is read to the information input register 55, into which it is entered by a synchronizing pulse from the output of element 58, delayed by the delay element 56 for the time of reading data from ROM 51. From the output of register 55, the code of the address for recording the threshold indicator of this ornithological environmental monitoring sensor in the server system database through the system output 15 is issued to the information input of the database server.

At the same time, the synchronizing pulse from the output of the delay element 56 is delayed by the delay element 57 for the time when the address code is entered into the register 55, and then from the synchronizing 17 output of the system it is fed to the input of the first interrupt channel of the system database server.

With the arrival of this signal, the database server goes through the subroutine for reading the data of the quantitative value of the threshold indicator of the ornithological environmental control sensor at the specified address and issuing it to the information input of the system 11 through the information input of block 4, made in the form of a register.

The synchronizing pulse from the input 13 of the system goes to the synchronizing input of the register of block 4 and, firstly, enters the quantitative value of the threshold indicator of the sensor of ornithological monitoring of the environment into the register of block 4, and secondly, the synchronizing pulse goes to the synchronizing 32 input of block 3.

At this point in time, from the output 22 of block 1, the current value of the quantitative indicator of the sensor of ornithological control of the environment arrives at the input 30, and the quantitative value of the threshold indicator of the sensor of ornithological control of the environment is fed to the input 31 of the comparator 60 of block 3 from the output 23 of block 4.

According to the synchronizing signal from the input 32, delayed by the delay element 61 for the time when data is entered into the register of block 4, supplied to the synchronizing input of the comparator 60, the comparator 60 compares the current value of the quantitative indicator of the sensor of ornithological control of the environment with the quantitative value of the threshold indicator of the same sensor of ornithological control of the environment. Wednesday.

If the current quantitative value of the indicator does not exceed its threshold value, then the comparator 60 of block 3 of interrogation of the next sensor of ornithological monitoring of the environment.

If the current quantitative value of the indicator of the sensor of ornithological control of the environment exceeds its threshold value, then the comparator 60 of block 3 generates a signal at the output 33 of block 3, and, firstly, outputs it to the synchronizing input 29 of block 5, to the information input of which the code is supplied coordinates of the location of this sensor ornithological monitoring of the environment.

According to the synchronizing signal from the input 29 of the unit 5, the coordinates of the ornithological environmental control sensor from the output 16 of the system are given to the information input of the unmanned aerial vehicle, which is directed along a predetermined route to eliminate the crisis situation.

Secondly, the signal from the output 33 of block 3 is fed to the input 37 of block 6, again starting the procedure for polling the next sensor of ornithological monitoring of the environment.

Thus, the introduction of new units and blocks made it possible to significantly increase the system performance by eliminating the time spent on identifying extreme situations requiring an immediate response.

Sources of information taken into account when drafting the application description:

1. RF patent No. 2542586 (20.02.2015)

2. RF patent No. 146677 (10.12.2013) (prototype).

Claims (1)

The system for monitoring the ornithological situation in the airport area, containing a block for receiving transactions from sensors of ornithological monitoring of the environment, the information and synchronization inputs of which are the first information and synchronization inputs of the system, respectively, while the first information input of the system is intended for receiving transactions from sensors of ornithological monitoring of the environment, the first synchronizing input of the system is designed to receive synchronizing signals of entering transactions from sensors of ornithological control of the environment into a block for receiving transactions from sensors of ornithological control of the environment, a block for receiving information from the database of the system server, the information and synchronizing inputs of which are the second information and synchronizing inputs of the system, respectively , while the second information input of the system is intended for receiving data from the database of the system server, and the second synchronizing input of the block for receiving information from the database of the system server is intended to enter data into the unit for receiving information from the database of the system server, the unit for setting the time cycles of polling the sensors of ornithological monitoring of the environment, one clock input of which is a clock input of the system intended for receiving system start pulses, the first synchronizing the output of the block for setting the time cycles of polling the sensors of ornithological environmental control is connected to the counting input of the block for fixing a given number of polling cycles of the sensors of the ornithological control of the environment, and the other synchronizing output of the block for setting the time cycles of polling the sensors of ornithological environmental control is connected to the synchronizing input by the input of the block for fixing the given number polling cycles of sensors of ornithological control of the environment, a block of addressing of signals of interrogation of sensors of ornithological control of the environment, the clocking outputs of which are clocked outputs of the system, intended for issuing signals from polling sensors of ornithological control of the environment, characterized in that the system contains a block for selecting addresses of sensors for ornithological control of the environment in the database of the system server, the information input of which is connected to the first information output of the block for receiving transactions from sensors of ornithological control environment, and the synchronizing input of the selection unit of addresses of the sensors of ornithological control of the environment in the database of the system server is connected to the first synchronizing input of the system, while the address output of the selection unit of addresses of sensors of ornithological monitoring of the environment in the database of the server of the system is the address output of the system intended for issuing readout addresses to the address input of the system server, and the synchronizing output of the selection unit of addresses of the ornithological environmental monitoring sensors in the system server database is the synchronizing output by the system progress, designed to issue signals to the input of the first interrupt channel of the database server, the target designation data output unit for the unmanned aerial vehicle, the information input of which is connected to the first information output of the unit for receiving transactions from the ornithological environmental monitoring sensors, and the information output of the target designation data output unit for the unmanned aerial vehicle the aircraft is an information output of the system, the unit for identifying critical readings of ornithological environmental monitoring sensors, one information input of which is connected to the second information output of the unit for receiving transactions from sensors of ornithological environmental monitoring, another information input of the unit for identifying critical readings of environmental ornithological monitoring sensors is connected to information output of the unit for receiving information from the database of the system server, synchronizing the input of the unit for identifying critical readings of ornithol sensors ogic environmental control is connected to the second synchronizing input of the system, while one output of the unit for identifying critical readings of ornithological environmental monitoring sensors is connected to the synchronizing input of the unit for issuing target designation data to the unmanned aerial vehicle and to the third synchronizing input of the unit for setting the time cycles of polling the sensors of ornithological monitoring of the environment , and the other output of the unit for identifying critical readings of the ornithological environmental monitoring sensors is connected to the second synchronizing input of the unit for setting the time cycles of polling the sensors of ornithological environmental monitoring, and a unit for sequential sampling of coordinates of the location of the ornithological environmental monitoring sensors, the information input of which is connected to the information output by the input of the block fixing a given number of polling cycles of sensors of ornithological monitoring of the environment, synchronizing the input of the sequence unit sampling of the coordinates of the location of the sensors of ornithological control of the environment, while the information output of the block for fixing a given number of polling cycles of the sensors of the ornithological control of the environment is connected to the information input of the block for addressing polling signals of the sensors of ornithological control of the environment, and the synchronizing output of the block for fixing a given number of cycles of environmental monitoring is connected to the synchronizing input of the block for addressing the polling signals of the sensors of ornithological environmental monitoring.

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