RU194828U1 - Device for resource distribution of a radar station for over-the-horizon detection by observation objects - Google Patents

Abstract

The technical result is to increase the accuracy of the resource distribution of the radar station for over-the-horizon detection over the objects of observation due to the automation of this process. conditions on location routes, mutual location eniya station horizon detection and surveillance of objects, the relative importance of the various objects under observation, and recommendations to this embodiment, which provides a rational allocation of its resources on the objects of observation.

Description

The utility model relates to radio engineering and, specifically, to airspace control systems, and can be used to distribute the resource of a radar station for over-the-horizon detection among objects of observation.

A device is known for resource allocation of a radar station for horizontal detection by observation objects [1], which contains interconnected interface lines for adapting to geophysical conditions, a unit for searching working channels, a unit for processing the results of units for adapting to geophysical conditions and searching for working channels, a unit for generating recommendations on the distribution of the resource of a radar station for over-the-horizon detection by observation objects in the prevailing geophysical and electromagnetic th environment.

A disadvantage of the known device is the low accuracy of resource allocation of the radar station for over-the-horizon detection over the objects of observation, caused by the complexity of the operator’s automated processing of a large amount of information under significant time constraints. The effective distribution of the resource of the over-the-horizon detection radar station according to the objects of observation consists in choosing the rational number and position of the continuous monitoring zones within the boundaries of the field of view, taking into account the geophysical conditions on the location routes, the relative position of the over-the-horizon detection station and the objects to be observed, and the relative importance of different objects of observation. Several hundreds of observation objects (aerodromes from which the take-off of the aircraft is supposed to be detected) can be located in the field of view of a radar station for horizontal detection, while simultaneous observation within the boundaries of the field of view can be carried out only within the boundaries of continuous monitoring zones, the sizes of which are 15- 20 times less than the area of the field of view, and their maximum number is limited by the design features of a particular radar station [1, 2].

The objective of the utility model is to eliminate the disadvantage of the known device, namely, increasing the accuracy of the distribution of the resource of the radar station for over-the-horizon detection over the objects of observation.

The technical result that ensures the solution of the problem is to automate the decision-making process for the distribution of the resource of a radar station for over-the-horizon detection over observation objects, taking into account geophysical conditions on the location routes, the relative position of the station for over-the-horizon detection and observation objects, and the relative importance of various observation objects.

Achievement of the claimed technical result and, as a result, the solution of the problem is ensured by the fact that the resource distribution device for the radar station of over-the-horizon detection by observation objects (Fig. 1), containing an adaptation unit to geophysical conditions 1 interconnected by interface lines, an operating channel search unit 2, a block for processing the results of work of blocks for adapting to geophysical conditions and searching for working channels 3, a block for generating recommendations on the distribution of radiol resource a station for over-the-horizon detection by observation objects in the prevailing geophysical and electromagnetic environment 4, according to a utility model, it additionally contains a block for automated calculation of the angle characterizing the relative position of the station for over-the-horizon detection and the direction of the runway of the airfield from which the take-off of a plane is connected according to the utility model 5, an automated calculation unit for the expected magnitude of the Doppler frequency offset signal 6, an automated calculation unit for the minimum detectable magnitude of the Doppler frequency shift of the probing signal 7, a unit for comparing the expected and minimum detectable magnitude of the Doppler frequency offset of the probing signal 8, the output of which is connected to the first input of the unit for forming the matrix of weights of elementary sections of the viewing zone 10, the second input of which connected to the output of the memory data block on the importance of the objects of observation in the field of view of the station for trans-horizon detection 9, the output of the block of the matrix of the weights of the elementary sections of the viewing zone 10 is connected to the first input of the unit for evaluating the effectiveness of the use of a radar station for horizontal detection on a variety of alternative options for the number and positions of the zones of continuous monitoring 12, the second input of which is connected to the output of the block unit for evaluating the effectiveness of the use of a radar station for over-the-horizon detection on a variety of alternative variants of quantity and of the zones of continuous monitoring 12 is connected to the input of the selection block of a rational option for the number and position of zones of continuous monitoring 13, the output of which is the output of information about the recommended distribution of the resource of the radar station for over-the-horizon detection over monitoring objects.

The additional introduction of blocks 5-13 allows us to automate the decision-making process on the distribution of the resource of the radar station for over-the-horizon detection by the objects of observation, which in turn allows us to solve the problem, namely, to increase the accuracy of the distribution of the resource of the radar station over-the-horizon detection on the objects of observation.

In FIG. 1 is a functional diagram of a resource distribution device for a radar station of over-the-horizon detection by observation objects, explaining the essence of the utility model.

In FIG. 1 adopted the following notation:

1 - block adaptation to geophysical conditions;

2 - block search working channels;

3 - processing unit of the results of the work of adaptation units to geophysical conditions and search for working channels;

4 - a block for generating recommendations on the distribution of the resource of a radar station for over-the-horizon detection over observation objects in the prevailing geophysical and electromagnetic environment;

5 is a block for automated calculation of the angle characterizing the relative position of the over-the-horizon detection station and the direction of the runway of the airfield from which the take-off of the aircraft is detected;

6 - block automated calculation of the expected value of the Doppler frequency shift of the probe signal;

7 - block automated calculation of the minimum detectable value of the Doppler frequency shift of the probe signal;

8 is a block comparing the expected and minimum detectable magnitude of the Doppler frequency shift of the probe signal;

9 is a block of memory data about the importance of the objects of observation in the field of view of the station beyond the horizon detection;

10 - block forming a matrix of weights of elementary sections of the viewing area;

11 is a block for the formation of matrixes of weights of elementary sections of zones of continuous control;

12 is a unit for evaluating the effectiveness of the use of a radar station for over-the-horizon detection on a variety of alternative options for the number and positions of zones of continuous monitoring;

13 - block selection of a rational option for the number and position of zones of continuous monitoring.

The resource distribution device for the over-the-horizon detection radar station for monitoring objects includes interconnected interface lines for adapting to geophysical conditions 1, a unit for searching working channels 2, a unit for processing the results of units for adapting to geophysical conditions and searching for working channels 3, for generating recommendations for distribution the resource of a radar station for over-the-horizon detection by observation objects in the prevailing geophysical and electromagnetic environment ke 4, a block for automated calculation of the angle characterizing the relative position of the station for horizontal detection and the direction of the runway of the airfield from which the take-off of the aircraft 5 is detected, a block for automated calculation of the expected value of the Doppler frequency shift of the probe signal 6, a block for automated calculation of the minimum detectable value of the Doppler frequency shift probe signal 7, a unit for comparing the expected and minimum detectable values of the Doppler shift ca the frequency of the probing signal 8, the output of which is connected to the first input of the unit for forming the matrix of weights of the elementary sections of the viewing zone 10, the second input of which is connected to the output of the data block of memory on the importance of the objects of observation in the field of view of the overseas detection station 9, the output of the block for the formation of the matrix of weights of the elementary areas of the zone 10 is connected to the first input of the unit for evaluating the effectiveness of the use of a radar station for overseas detection on a variety of alternative options for the number and positions of continuous monitoring 12, the second input of which is connected to the output of the block for the formation of matrixes of weights of elementary sections of the zones of continuous monitoring 11, the output of the unit for evaluating the effectiveness of the use of a radar station for horizontal detection on a variety of alternative options for the number and positions of the zones of continuous monitoring 12 is connected to the input of the block for selecting a rational variant of the quantity and the provisions of the zones of continuous monitoring 13, the output of which is the output of information on the recommended distribution of the radar resource constant station horizon detection of objects of observation.

Block 1 is designed to process information about the signals of the reciprocating sounding of the ionosphere in order to determine the ranges of the optimal operating frequencies of the trans-horizon detection station in a changing geophysical environment. Block 2 is designed to process information about the electromagnetic environment in a range of optimal operating frequencies determined by block 1. Block 3 is designed to process the results of the operation of blocks 1 and 2 in order to calculate the probability of correct detection of aircraft at a given probability of false alarms in the prevailing geophysical and electromagnetic environment. Block 4 is intended to formulate recommendations on the distribution of the resource of a radar station for over-the-horizon detection by observation objects in the prevailing geophysical and electromagnetic environment. Block 5 is intended for automated calculation of the angle characterizing the relative position of the station for over-horizon detection and the direction of the runway of the airfield from which the take-off of the aircraft is detected. Blocks 6 and 7 are intended, respectively, for the automated calculation of the expected and minimum detectable magnitude of the Doppler frequency shift of the probe signal based on the results of the operation of block 5. Block 8 is intended to compare the expected and minimum detectable magnitude of the Doppler frequency shift of the probe signal. The comparison results are transmitted to block 10. Block 9 is designed to store data on the quantitative value of the importance of the objects of observation in the field of view of the over-the-horizon detection station. Blocks 10 and 11 are intended, respectively, for the formation of matrixes of weights of elementary sections of the viewing zone and zones of continuous monitoring of the over-the-horizon detection station. Block 12 is designed to evaluate the effectiveness of the use of over-the-horizon radar on a variety of alternative options for the number and position of zones of continuous monitoring. Block 13 is designed to select a rational option for the number and position of zones of continuous monitoring and to formulate recommendations to the operator on the distribution of the resource of a radar station for over-the-horizon detection over objects of observation.

Blocks 1-13 are made in the form of software and hardware modules on a PC expansion card with an architecture of type X86 installed in the control center of the over-the-horizon radar station.

The operation of the resource allocation device of the radar station for over-the-horizon detection by monitoring objects is as follows. Block 1 receives information about the signals of the reciprocating sounding of the ionosphere in order to determine the ranges of the optimal operating frequencies of the over-the-horizon detection station in a changing geophysical environment. The range of optimal operating frequencies is determined by estimating the probability of correct detection with a fixed probability of false alarms of a given type of objects in elementary sections of the station's field of view.

In block 2, information about the electromagnetic environment is processed in the range of optimal operating frequencies determined by block 1. Processing information about the electromagnetic environment consists in the formation of time-smoothed azimuth-frequency panoramas of active noise averaged for given frequency bands in the range of optimal operating frequencies of the station.

In block 3, the processing of the results of the operation of blocks 1 and 2 is carried out in order to calculate the probability of correct detection of aircraft at a given probability of false alarms in the prevailing geophysical and electromagnetic environment.

The results obtained are the source data for the distribution in block 4 of the resource of the radar station of over-the-horizon detection by observation objects in the prevailing geophysical and electromagnetic environment.

In block 5, the angle is calculated that characterizes the relative position of the over-the-horizon detection station and the direction of the runway of the airfield. Initial data for the assessment are information on the geographical coordinates of the aircraft-based aerodromes and the directions of their runways, the coordinates of the receiving position of an over-the-horizon detection station, the expected take-off speed of aircraft from the airfields, and the operating frequency of the probe signal of the radar station (F _ss ). The initial data is entered by the operator in block 5.

Next, in block 6, the radial component of the expected takeoff speed of the aircraft from the airfield is estimated (V _rad ). The obtained values allow us to estimate the expected value of the Doppler frequency shift of the probing signal (F ^d ):

where c is the propagation velocity of an electromagnetic wave in a vacuum.

The minimum detectable Doppler frequency shift of the probe signal is estimated in block 7 based on the minimum detectable radial speed of the aircraft V ^radmin :

In block 8, the values of the expected (F ^d ) and minimum (F ^dmin ) Doppler frequency shifts of the probing signal are compared. If F is greater than F ^dmin , then the detection of aircraft take-off from the aerodrome is possible, otherwise not.

Block 9 stores data on the importance values of observation objects (aerodromes) in the field of view of an over-the-horizon detection station. The importance of each aerodrome is characterized by a number from 0 to 1, depending on the priority of observing it in order to detect aircraft take-off. The more priority the object of observation, the higher the value of this parameter.

The formation of a matrix of weights of elementary sections of the viewing area in block 10 is as follows. The elementary section of the field of view is a section of the field of view limited by the size of the smallest possible step of rearranging the zone of continuous monitoring in azimuth (ΔB) and range (ΔD), respectively. The minimum permutation step depends on the algorithm for controlling the zones of continuous monitoring implemented in the station and is a characteristic of the station. In the General case, the number of elementary sections of the viewing area is determined by the expressions:

where M is the number of elementary sections of the viewing area in azimuth,

N is the number of elementary sections of the range of the range,

In - the size of the viewing area in azimuth,

D is the size of the range of the field of view.

Each elementary site is assigned a weight (С ^ЭУ_ЗО ), which characterizes the value of this site when observing it. This weight is calculated based on the importance of the observation object within its boundaries and the station’s ability to observe it; the observation object is considered to be point-like:

where С ^ОН - importance of the object of observation, С ^ОН_ЗО ∈ [0; 1],

P ^HFC - the probability of aircraft detection by geophysical conditions, calculated in block 3, P ^HFC ∈ [0; 1]

K ^d - Doppler detection parameter, calculated in block 8,

K ^d = 1, for F ^d > F ^dmin otherwise K _d = 0.

The totality of the weights of the elementary sections of the viewing area form a matrix, the rows of which correspond to the possible positions of the continuous monitoring zone in range, and the columns in azimuth.

In block 11 is the formation of matrices of weights of elementary sections of zones of continuous control. The number of matrices depends on the number of formed zones of continuous monitoring, which in turn is determined by the capabilities of a particular station for over-the-horizon detection. The station operator can control the number of generated continuous monitoring zones, while the energy potential of the transmitting system is proportionally distributed between the formed monitoring zones. The more control zones, the lower the energy potential of each of them. The size of the elementary section of the continuous monitoring zone is determined similarly to the size of the elementary section of the viewing zone:

where U is the number of elementary sections of the zone of continuous control in azimuth,

V is the number of elementary sections of the zone of continuous range monitoring,

In ^ZNK - the size of the zone of continuous control in azimuth,

D ^ZNK - the size of the zone of continuous monitoring by range.

The weight of each such site depends on the number of formed control zones and is determined by the ratio:

- количество формируемых зон контроля.

k - максимальное количество формируемых зон контроля.Where

- the number of formed control zones.

k is the maximum number of formed control zones.

The calculation is carried out for k variants of the number of zones of continuous monitoring.

Block 12 evaluates the effectiveness of the use of a radar station for over-the-horizon detection on a variety of alternative options for the number and position of zones of continuous monitoring.

в решаемую радиолокационной станцией задачу, а каждый из UxV элементарных участков зоны непрерывного контроля характеризуется весом

. Количественно эффективность применения радиолокационной станции загоризонтного обнаружения при работе одной зоной непрерывного контроля будет характеризоваться значениями элементов матрицы (Y), содержащей результаты двумерной дискретной свертки матрицы весов элементарных участков зоны обзора (X) с матрицей весов элементарных участков зоны непрерывного контроля (Н):The observation of each of the MxN elementary sections of the field of view is characterized by its contribution

to the problem solved by the radar station, and each of the UxV elementary sections of the continuous monitoring zone is characterized by weight

. Quantitatively, the efficiency of the use of an over-the-horizon detection radar station during operation with one continuous monitoring zone will be characterized by the values of the matrix elements (Y) containing the results of two-dimensional discrete convolution of the weight matrix of elementary sections of the viewing zone (X) with the matrix of weights of elementary sections of the continuous monitoring zone (N):

In this case, the maximum efficiency of the use of an over-the-horizon detection radar will be ensured by the position of the monitoring zone in the field of view that corresponds to the position of the maximum element in the Y matrix. The value of this element is a quantitative assessment of the effectiveness of the station when the rational position of the continuous monitoring zone is.

Далее, аналогично производится оценка для второй зоны непрерывного контроля, при этом, элементарным участкам зоны обзора, которые соответствуют найденному на первом этапе расчетов положению первой зоны контроля присваиваются нулевые значения важности (С^ЭУ_ЗО), а элементарным участкам зон непрерывного контроля присваиваются веса в соответствии с количеством формируемых зон контроля. Запоминается количественное значение эффективности применения станции при найденном положении второй зоны контроля

и процедура повторяется для имеющего количества (k) зон непрерывного контроля.With the simultaneous operation of several zones of continuous monitoring in the field of view, the procedure for evaluating the effectiveness of the station is as follows. At the first stage, the matrix Y is formed for one control zone, the rational position of the control zone is found by the position of the maximum element of the matrix, and the quantitative value of the station application efficiency for the found position is stored

Further, an assessment is made similarly for the second continuous monitoring zone, while the elementary sections of the viewing zone that correspond to the position of the first monitoring zone found at the first stage of the calculations are assigned zero importance values (С ^ЭУ_ЗО ), and the elementary sections of the continuous monitoring zones are assigned weights in accordance with the number of formed control zones. The quantitative value of the effectiveness of the station at the found position of the second control zone is stored.

and the procedure is repeated for having the number (k) of continuous monitoring zones.

варианта количества

образуется суммой оценок эффективности всех зон непрерывного контроля рассматриваемого варианта:Next, an array is formed of estimates of the effectiveness of the use of an over-the-horizon detection station, the elements of which characterize k variants of the number of control zones. Rating

quantity options

formed by the sum of the effectiveness evaluations of all zones of continuous monitoring of the considered option:

The result of the operation of block 12 is a multitude of assessments of the effectiveness of the use of an over-the-horizon detection station, characterizing possible options for the number of formed zones of continuous monitoring with their rational position in each variant.

In block 13, a rational choice is made for the number and position of zones of continuous monitoring. The selection criterion is the maximum value of the efficiency indicator calculated in block 12. The result of the block is information on the recommended option for distributing the resource of the radar station for over-the-horizon detection by observation objects, including the rational number of zones of continuous monitoring and the position of each of them within the boundaries of the field of view, taking into account geophysical conditions on location routes, the relative position of the over-the-horizon detection station and the objects of observation, and relative five different objects of observation.

The utility model is developed at the level of a mathematical model and computer program. The test results of the model showed an increase in the accuracy of the distribution of the resource of the radar station for over-the-horizon detection by observation objects by 10-12%.

Sources taken into account when drawing up the description and formulas of the utility model:

1. Introduction to the design of ionospheric over-horizon radars / V.F. Akimov, Yu.K. Kalinin. - M.: NPK NIIDAR OJSC, 2017.

2. Giuseppe A. Fabrizio High-frequency radar: fundamental principles, signal processing and practical application. Translation from English edited by Doctor of Technical Sciences, Doctor of Economics, prof. S.F. Boeva, Moscow. Technosphere, 2016.

Claims (1)

A device for resource distribution of a radar station for over-the-horizon detection by observation objects, containing a unit for adapting to geophysical conditions interconnected by interface lines, a block for searching working channels, a block for processing the results of blocks for adapting to geophysical conditions and for searching for working channels, a block for generating recommendations for allocating a resource for radar over-the-horizon detection stations for observation objects in the prevailing geophysical and electromagnetic environment e, characterized in that it further comprises a block for automated calculation of the angle characterizing the relative position of the station for horizontal detection and the direction of the runway of the aerodrome from which the take-off of the aircraft is detected, a unit for automated calculation of the expected value of the Doppler frequency shift of the probe signal, unit for automated calculation of the minimum detectable magnitude of the Doppler frequency offset probing of the first signal, a unit for comparing the expected and minimum detectable values of the Doppler frequency shift of the probe signal, the output of which is connected to the first input of the unit for generating the matrix of weights of elementary sections of the viewing zone, the second input of which is connected to the output of the data block of memory on the importance of observation objects in the field of view of the overseas detection station , the output of the block forming the matrix of weights of elementary sections of the viewing zone is connected to the first input of the block for evaluating the effectiveness of the use of the radar station over-the-horizon detection on a set of alternative options for the number and position of zones of continuous monitoring, the second input of which is connected to the output of the block for the formation of matrixes of weights of elementary sections of zones of continuous monitoring, the output of the unit for evaluating the effectiveness of the use of radar station for over-horizon detection on many alternative options for the number and positions of zones of continuous monitoring is connected with the input of the block for choosing a rational option for the number and position of zones of continuous monitoring, exit which is the output of information on the recommended distribution of a resource of radar-horizon detection of objects of observation.

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