RU2632476C2 - Method for detecting maneuver of ballistic object by sampling products of distance and radial speed and device for its implementation - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: absolute difference between the estimate of the first increment of the distance-radial speed product obtained from a sample of a larger volume and the estimate of the first increment of the distance-radial speed product obtained from a sample of a smaller volume are determined only from a sample of a larger volume. For this purpose, in the unit for estimating the first increment of the distance-radial speed product, the fixed sampling of range-radial speed product is multiplied by predetermined weighting coefficients for determining the absolute difference between estimates obtained from samples of larger and smaller volumes, which allows to simplify the method for detecting maneuver of ballistic object and device for its implementation.

EFFECT: simplifying the method and device for detecting the ballistic object maneuver while maintaining a high probability of maneuver detection.

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Description

The invention relates to radar and can be used in radar stations (radar) to detect the maneuver of ballistic objects (BO). The task of determining the start and end time of a maneuver must be solved in order to prevent the occurrence of methodological errors in determining the parameters of the ballistic trajectory and the breakdown of auto tracking of BOs. In particular, the coordinates of the point of impact of BOs of the type of short- and medium-range missiles, calculated from the radar measurements made in the maneuver section, can be determined with a short flight or flight from several tens to several hundred kilometers.

A known method of detecting maneuver by the absolute value of the increment of speed [1, S. 346-347)]. With respect to BO, a maneuver can be detected by the absolute value of the increment of the rate of change of the horizontal Cartesian coordinate, since the rocket’s movement along the horizontal axis of the Cartesian coordinate system is uniform and the velocity component will be constant [2, P. 12-13]. In the maneuver section, the velocity component along the horizontal axis will be variable, since accelerations appear due to the action of the forces of the maneuver devices.

The main disadvantage of these methods is the low probability of detecting maneuver with rough measurements of azimuth and elevation.

There is a method of detecting the end time of an ATC by sampling range squares [3] and a maneuver detection device (UOM) described in patent No. 2510861. The decision to maneuver the BO is made if the estimate of the acceleration by the square of the range is negative, and the end of the maneuver (AUT) at the time when the sign of the assessment changes from negative to positive.

There is a method of detecting the end time of an ATE by selecting range products by radial speed [4] and UOM, described in patent No. 2509319. The decision to maneuver the BO is made if the estimate of the rate of change of the product of the range by the radial speed is negative, and the end of the maneuver (AUT) at the time when the sign of the assessment changes from negative to positive.

In these maneuver detectors, a high probability of detecting the end of the AUT of ballistic objects approaching the radar is achieved due to elimination of the influence of azimuth and elevation angle errors. However, these UOMs cannot be used to detect maneuver in the passive section of the trajectory (VLB), since estimates of the acceleration by the square of the range and estimates of the rate of change of the product of the range by the radial speed can be positive both in the unperturbed VLB and in the maneuver section of the VLB. Therefore, in these cases, it is either impossible to identify the maneuver, or the probability of its detection will be low.

The closest analogue of the claimed invention, that is, a prototype in which the influence of errors in measuring the azimuth and elevation angle is eliminated and high probabilities of detecting the BO maneuver on the VHF are achieved, is a method for radar detection of the BO maneuver on the VHF by sampling range products by radial speed [5] and UOM described in patent No. 2524208.

The essence of detecting a BO maneuver by the prototype method is that in the radar they measure the BO range and radial speed in digital form, multiply these signals and obtain range products by the radial speed, BO auto-tracking is carried out in a “sliding window” of N range products by the radial speed. Two “fixed samples” of the obtained works are formed in the “sliding window”, while a smaller sample is included in a larger sample. In each sample, an estimate of the rate of change of the range product by the radial speed is found by the optimal weighted summation of the products of the measured range values by the measured radial velocity values. Then, the absolute increment (absolute difference) of the obtained estimates and the standard error (RMS) of the estimate of the rate of change of the product of the range by the radial speed in a smaller sample are calculated. Next, the ratio of the absolute increment of the estimates of the rate of change of the product of the range and the radial speed to the standard deviation of the estimate is calculated, in each new position of the “sliding window”, the ratio of the absolute increment of the estimates of the speed to the standard deviation of the estimate with a threshold corresponding to the specified probability of detecting the maneuver is compared. As a result, the decision to detect a maneuver is made at a time when the value of the obtained ratio of the absolute increment of the estimates of the rate of change of the product of the range by the radial speed and the standard deviation of the estimate becomes more than the threshold.

As an example, figure 1 shows the structural diagram of the UOM prototype, which implements this method of detecting maneuver from samples of 5 and 3 range products at a radial speed.

The UOM prototype contains a series-connected input signal multiplier (block 1) and a block for estimating the 1st increment of the product of the range by the radial speed (block 2), which includes a storage device (block 2.1) of 4 delay lines (LZ), the outputs of which are connected with the inputs of the 1st block of multipliers 2.2 from 4 multipliers and the 2nd block of multipliers 2.4 from 2 multipliers, the outputs of which are connected to the inputs of the 1st adder 2.1 and 2nd adder 2.5, respectively. The output of the 1st adder is connected to the input of the divider for the review period (block 6), the output of which is connected to the 1st input of the adder 7. The output of the 2nd adder of block 2 is connected to the input of the divider for the review period (block 3), the output of which is connected with a delay line 4 connected in series and an inverter 5, the output of which is connected to the 2nd input of the adder 7, the output of which is connected to the 1st input of the divider on the standard deviation estimate (block 8), the second input of which is connected to the output of the standard deviation calculator, input which is connected to the input range signals. The output of the divider on the standard deviation estimate is connected to the 1st input of the threshold device (block 10), the 2nd input of which is connected to the threshold signal source, and the 1st and 2nd outputs are the outputs of the prototype.

The prototype works as follows. In block 1, the digital range signals arriving at its input are multiplied by digital radial speed signals, the range products and the radial speed are obtained and fed to the input of the storage device of block 2.

умножают в блоке 2.2 на весовой коэффициент, равный 0,2, и подают на вход 1-го сумматора 2.3. Одновременно с этим сигналом на вход сумматора 2.3 подают сигналы произведений, задержанные в блоке 2.1 на 1, 2, 3 и 4 обзора РЛС и умноженные в блоке 2.2 на свои весовые коэффициенты (0,2, 0,1, -0,1 и -0,2, соответственно). В итоге на входе сумматора 2.3 получают фиксированную выборку большего объема из 4-х взвешенных произведений дальности на радиальную скорость, а на его выходе - оценку первого приращения произведения дальности на радиальную скорость по выборке большего объема:Current value of range product by radial speed

multiply in block 2.2 by a weight coefficient equal to 0.2, and fed to the input of the 1st adder 2.3. Simultaneously with this signal, the input of adder 2.3 is supplied with product signals delayed in block 2.1 by 1, 2, 3, and 4 of the radar survey and multiplied in block 2.2 by their weight coefficients (0.2, 0.1, -0.1, and - 0.2, respectively). As a result, at the input of adder 2.3, a fixed sample of a larger volume of 4 weighted products of range by radial speed is obtained, and at its output, an estimate of the first increment of the product of range by radial speed from a larger sample is obtained:

и в предпоследнем обзоре

умножают в блоке 2.4 на свои весовые коэффициенты (0,5 и -0,5) и подают на вход 2-го сумматора 2.5. В итоге на входе сумматора 2.5 получают фиксированную выборку меньшего объема из 2-х взвешенных произведений дальности на радиальную скорость, а на его выходе - оценку первого приращения произведения дальности на радиальную скорость по выборке меньшего объема:The value of the product of range by radial velocity in the previous review

and in the penultimate review

in block 2.4 are multiplied by their weight coefficients (0.5 and -0.5) and fed to the input of the 2nd adder 2.5. As a result, at the input of adder 2.5, a fixed sample of a smaller volume from 2 weighted products of range by radial speed is obtained, and at its output, an estimate of the first increment of the product of range by radial speed from a sample of a smaller volume is obtained:

делят в блоке 6 на период обзора и получают оценку скорости изменения произведения дальности на радиальную скорость

. Эту оценку подают на 1-й вход сумматора 7. Оценку первого приращения

, полученную по выборке меньшего объема, делят в блоке 3 на период обзора и получают оценку скорости изменения произведения дальности на радиальную скорость

. Чтобы оценка

поступала на вход сумматора 7 одновременно с оценкой

, ее задерживают на период обзора в блоке 4. Чтобы получить разность оценок,

умножают на (-1) в инверторе 5.First increment score

divided in block 6 for the period of review and get an estimate of the rate of change of the product of range by radial speed

. This estimate is fed to the 1st input of the adder 7. Evaluation of the first increment

, obtained from a sample of a smaller volume, is divided in block 3 by the review period and an estimate of the rate of change of the product of range by radial speed is obtained

. To score

arrived at the input of the adder 7 simultaneously with the assessment

, it is delayed for the review period in block 4. To get the difference in estimates,

multiply by (-1) in inverter 5.

делят в блоке 8 на СКО оценки

, которую вычисляют в блоке 9 по формуле:

, где

- СКО измерения радиальной скорости.Received at the output of the adder 7 absolute increment of estimates

divided in block 8 on the standard deviation

, which is calculated in block 9 by the formula:

where

- RMS measure radial velocity.

с выхода делителя 8 подают на 1-й вход порогового устройства 10. Решение об обнаружении маневра принимают в момент времени, когда отношение абсолютного приращения оценок к СКО оценки становится больше порога

, величину которого выбирают в соответствии с заданной вероятностью обнаружения маневра.The resulting relationship value

from the output of the divider 8, they are fed to the 1st input of the threshold device 10. The decision to detect a maneuver is made at the time when the ratio of the absolute increment of the estimates to the standard deviation of the estimate becomes greater than the threshold

, the value of which is selected in accordance with a given probability of detecting a maneuver.

As shown in the table. 3 patent descriptions No. 2524208 [5], the maneuver of the Atakms rocket is detected by the prototype method with a probability close to unity. In the known method for detecting maneuvers by the absolute increment of the rate of change of the horizontal coordinate (see table. 2), maneuver is practically not detected with rough measurements of azimuth and elevation.

The disadvantages of the prototype should include the complexity of the method and circuit of the detection device maneuver.

The technical result of the invention is to simplify the method for detecting a BO maneuver from samples of range products by radial velocity and the UOM scheme in which the claimed method is implemented.

The specified technical result is achieved by the fact that in the claimed method for detecting a BO maneuver from samples of range products by radial speed, in the same way as in the prototype, the BO range and radial speed are measured in digital form, these signals are multiplied and the range products are obtained by radial speed. BO auto-tracking is carried out in a “sliding window”. The absolute increment of the estimates of the rate of change of the product of the range by the radial speed in the middle of the “sliding window” is determined from two fixed samples of the products of the range by the radial speed, while a smaller sample is part of a larger sample. Calculate the standard deviation of the estimate of the rate of change of the range product by the radial speed from a sample of a smaller volume and the ratio of the absolute increment of the estimates of the rate of change of the range product by the radial speed to the standard deviation of the estimate. In each new position of the “sliding window”, the ratio of the absolute increment of the velocity estimates to the standard deviation is compared with the threshold corresponding to the given probability of detecting the maneuver, and the decision to detect the maneuver is made at the time when the ratio of the absolute increment of the estimates of the rate of change of the range product by the radial speed and the standard deviation becomes more than a threshold.

Unlike the prototype, according to the claimed invention, the absolute increment of the estimates of the rate of change of the range product by the radial speed in the middle of the “sliding window” is determined by only one sample of a larger volume by the optimal weighted summation of the range products of the range by the radial speed, using special weight coefficients for determining the absolute difference of the estimates.

The apparatus for implementing the inventive method for detecting a maneuver of BOs based on samples of range products by radial speed comprises, as a prototype, a multiplier of input signals and a unit for estimating the 1st increment of the range product by radial speed, including a series-connected memory device from N-1 delay lines, block multipliers and the adder, the output of which is connected to the input of the divider for the review period, as well as the divisor of the absolute increment of the estimates of the rate of change of the product range at the radial speed on the standard deviation estimate, the 2nd input of which is connected to the output of the calculator of the standard deviation estimate, the output of which is connected to the input range signals. The output of the divider on the RMSE is connected to the 1st input of the threshold device, the 2nd input of which is connected to the source of the threshold signal, and the 1st and 2nd outputs are the outputs of the claimed device.

Unlike the prototype, according to the claimed invention, the output of the divider for the review period is connected to the input of the divider of the absolute increment of the estimates of the rate of change of the product of the range by the radial speed by the standard deviation.

The principle of operation of the UOM, which implements the claimed method for samples of 5 range products by radial speed, is illustrated by the circuit shown in FIG. 2.

In the claimed device, as in the prototype, in block 1, the digital range signals arriving at its input are multiplied by digital radial speed signals and the resulting products are fed to the input of the storage device 2.1 from 4 delay lines.

умножают на весовой коэффициент, равный 0,2, и подают на вход сумматора 2.3. Одновременно с этим сигналом на вход сумматора 2.3 подают сигналы произведений, задержанные на 1, 2, 3 и 4 обзора РЛС и умноженные на весовые коэффициенты (-0,4, 0,4 и -0,2, соответственно). В итоге уже на выходе сумматора 2.3 получают абсолютную разность оценок первого приращения произведения дальности на радиальную скорость по выборкам большего и меньшего объема:In contrast to the prototype, in the block of multipliers 2.2, weights are used to determine the difference between the estimates of the first increment of the product of the range by the radial speed, calculated from samples of larger and smaller volumes. So the current value of the product of the range by the radial speed

multiplied by a weight coefficient equal to 0.2, and fed to the input of the adder 2.3. Simultaneously with this signal, the input of adder 2.3 is supplied with product signals delayed by 1, 2, 3 and 4 of the radar survey and multiplied by weighting factors (-0.4, 0.4 and -0.2, respectively). As a result, already at the output of adder 2.3, the absolute difference in the estimates of the first increment of the product of the range by the radial speed is obtained from the samples of larger and smaller volumes:

, которое подают, в отличие от прототипа, на 1-й вход делителя на СКО оценки (блок 4). В дальнейшем заявленное устройство работает так же, как прототип.This difference is divided in block 3 for the review period T ₀ and get the absolute increment of the estimates of the rate of change of the product of the range by the radial speed

, which serves, unlike the prototype, at the 1st input of the divider on the standard deviation of the assessment (block 4). In the future, the claimed device works in the same way as the prototype.

However, the probability of detecting a maneuver has not changed. To confirm this, we calculate the difference between the expressions (1) and (2):

Thus, it is proved that equalities (3) and (4) are the same.

, формула 4.52а, С. 301] и

, формула 4.63, С. 308]. При увеличении объема выборок соответственно увеличивается количество линий задержки в запоминающем устройстве и количество умножителей в блоке оценивания 1-го приращения произведения дальности на радиальную скорость. Весовые коэффициенты вычисляются заранее до проведения измерений дальности и радиальной скорости.Weighting coefficients for determining the difference in the estimates of the first increments of the range products by the radial velocity and the standard deviation of estimates for other sample sizes are calculated similarly using well-known formulas:

, formula 4.52a, S. 301] and

, formula 4.63, S. 308]. With an increase in the sample size, the number of delay lines in the storage device and the number of multipliers in the unit for estimating the 1st increment of the product of the range by the radial speed respectively increase. Weights are calculated in advance of the range and radial velocity measurements.

Thus, the technical result of the claimed invention is achieved. The claimed method excludes operations of forming samples of a smaller volume, determining estimates of the rate of change of range product by radial speed from a sample of a smaller volume, and calculating the absolute increment of estimates of the rate of change of product of range by radial speed from samples of a larger and smaller volume. Simplified compared with the prototype, the circuit of the claimed device by eliminating the 2nd block of multipliers and the 2nd adder of the unit for estimating the 1st increment of the product of the range by the radial speed, the divider for the period of review, the delay unit, the inverter and the adder of the estimation of the rate of change of the product of the range radial speed for a larger sample with a delayed and inverted estimate of the rate of change of the product of range by a radial speed for a sample of a smaller volume. The probability of detecting a maneuver of a ballistic object did not decrease.

List of sources used

1. Kuzmin S.Z. Digital processing of radar information. - M.: “Radio and Communications”, 1967, 395 p.

2. Zhakov A.M., Pigulevsky F.A. Ballistic missile control. - M .: “Military Publishing House of the Ministry of Defense of the USSR”, 1965, 278 p.

3. Patent RU No. 2510861. A method for determining the end time of an active section of a ballistic missile trajectory.

4. Patent RU No. 2509319. A method for determining the end time of an active section of a ballistic missile trajectory.

5. Patent RU No. 2524208. Method for radar detection of ballistic target maneuver in a passive section of a trajectory

Claims (2)

1. A method for detecting a maneuver of a ballistic object (BW) from samples of range products by radial speed, which consists in the fact that the radar measures the range and radial speed of a BO in digital form, multiplies these signals and obtains the range products by a radial speed, BO auto tracking in the "sliding window", determine the absolute increment of the estimates of the rate of change of the product of range by the radial speed in the middle of the "sliding window" for two fixed samples produced range at a radial speed, while a smaller sample is part of a larger sample, calculate the standard error (RMS) of the estimate of the rate of change of the product of the range by the radial speed from a sample of a smaller volume and the ratio of the absolute increment of the estimates of the rate of change of the product of the distance by the radial speed to the standard deviation estimates, in each new position of the “sliding window”, the ratio of the absolute increment of the velocity estimates to the standard deviation is compared with a threshold corresponding to a given probability of detection of the maneuver, the decision to detect the maneuver is made at a time when the ratio of the absolute increment of the estimates of the rate of change of the range product by the radial speed to the standard deviation of the estimate becomes greater than the threshold, characterized in that the absolute increment of the estimates of the rate of change of the product of range by the radial speed in the middle of the “sliding window” "Determine only one sample of a larger volume by the optimal weighted summation of its products of range at a radial speed, at The volume uses special weighting coefficients for determining the absolute increment of estimates. 2. A device for detecting a maneuver of a ballistic object from samples of range products by radial speed, containing a series-connected input signal multiplier and a unit for estimating the first increment of the range product by radial speed, including a series-connected storage device, a multiplier unit and an adder, the output of which is connected to the divider input by the review period, as well as the divisor of the absolute increment of the estimates of the rate of change of the product of the range by the radial speed and RMSE estimates, the second input of which is connected to the output of the RMSE calculator, the output of which is connected to the input range signals, the output of the divider on the RMSE estimates is connected to the first input of the threshold device, the second input of which is connected to the threshold signal source, and the first and second outputs are outputs The claimed device, characterized in that the output of the divider for the review period is connected to the input of the divider of the absolute increment of the estimates of the rate of change of the product of the range by the radial speed by the standard deviation.

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