RU2367972C1 - Method for evaluation of accuracy in detection of radio-wave radiation source location by passive range-difference system - Google Patents

Abstract

FIELD: physics, measurement.

SUBSTANCE: invention is related to the field of passive radio location and is intended for performance of full-scale tests of pilot samples of passive range-difference system (RDS) in case of absence of one of receiving posts. Substance of suggested method consists in the fact that mutual-correlation measurement of RRS signals time delays received by master and slave receiving posts, and missing slave receiving post is additionally imitated by definition of its location coordinates, which is symmetrical to location of slave receiving post relative to the line "master receiving post - RRS", and as RRS signal received by imitated slave receiving post, signal is used from existing slave receiving post, and then RRS location is defined by full-scale test method.

EFFECT: provides for possibility to evaluate accuracy in detection of radio-wave radiation source (RRS) location by passive RDS in case of one receiving posts in not available in its composition.

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Description

The invention relates to the field of passive radar and is intended for field testing of prototypes of a passive differential-rangefinding system (RDS) in the absence of one of the receiving posts.

Prototypes of equipment received for preliminary, state, interdepartmental tests may not come fully equipped, but contain separate components (GOST RV 15.210-2001, Military equipment. Tests of prototypes of products and prototypes of repair products. General provisions, Gosstandart of Russia , M., 2001).

There is a method of evaluating the accuracy of determining the location of an IRI passive RDS, including cross-correlation measurement of the time delays of the IRI signal received by the leading and slave receiving posts, statistical processing of measurement results and assessing the accuracy of the location of the IRI according to the formula ("Radio systems" ./ Ed. Yu.M. .Kazarinova. M.: Higher school, 1990, pp. 239-240)

where σ _r is the standard error of measuring the location of the IRI;

c is the propagation velocity of the radio wave;

σ _τ is the standard error of the measurement of time delays of the IRI signal;

φ is the angle of intersection of the position lines (hyperbole);

ψ1, ψ2 - base angles of the first and second pairs of reception posts.

This method is implemented using simulation mathematical modeling. The basis of simulation mathematical modeling is the replacement of a real physical system by its approximate display in the form of an algorithm and corresponding software that reproduces on a computer interesting aspects of the functioning of the original system (V. T. Radzievsky, A. A. Sirota. “Information support of electronic systems in conflict ". IPRZhR, M., 2001, pp. 66-87).

The method is experimental-theoretical and has drawbacks before full-scale testing. Real physical systems, paths, signals do not participate in tests whose technical characteristics affect the accuracy of the location. For example, the second channel of the correlator, a computing device, the propagation path r ₁₄ , r ₂₄ , etc.

The method requires the development of additional measuring equipment for each prototype.

The closest to the proposed method in terms of technical nature and the achieved positive result is a method for assessing the accuracy of determining the location of an IRI passive RDS with three receiving posts, including a cross-correlation measurement of the time delays of the IRI signal received by two pairs of receiving posts, one of which is the leading one, and by known coordinates Reception posts determine the location of Iran. (Theoretical Foundations of Radar. / Ed. By J.D. Shirman. Sov. Radio, M., 1970, pp. 494-497).

This method does not determine the location of the IRI in the absence of one of the reception posts, which is typical during preliminary, state and interdepartmental tests.

The technical result is the provision of assessing the accuracy of determining the location of the source of the radiation of a passive RDS in the absence of one of the receiving posts.

The technical result is achieved by the fact that in the known method for evaluating the accuracy of determining the location of the IRI of a passive RDS, including cross-correlation measurement of the time delays of the IRI signal received by the master and slave receiving posts, and additionally simulate the missing slave receiving post, for which the coordinates of its location are determined, which symmetrical to the location of the slave receiving post relative to the line "leading receiving post - IRI", and as the signal of the IRI received by the simulated slave receiving station that uses a signal from the current slave reception post, and then evaluated the accuracy of the Iranian position.

The analysis of the prior art allows us to establish that technical solutions characterized by a combination of features identical to all the features contained in the claims proposed by the applicant are absent, which indicates compliance of the claimed invention with the “novelty” eligibility criterion.

The search results for known solutions in this and related fields of technology, in order to identify features that match the distinctive features of the claimed device, showed that no solutions having features matching its distinctive features were found in publicly available information sources. The prior art also does not confirm the popularity of the influence of the distinctive features of the claimed invention on the technical result indicated by the applicant. Therefore, the claimed invention meets the condition of "inventive step".

The proposed technical solution is industrially applicable, since the set of characteristics characterizing it provides the possibility of its existence, performance and reproducibility, since well-known materials and equipment can be used to implement the claimed technical solution.

Figure 1 shows a diagram of the mutual placement of the elements of the RDS necessary to assess the accuracy of the location of the IRI.

Figure 2 shows the structural diagram of the RDS device that implements the claimed method, where 1 - IRI; 2 - leading reception post; 3 - slave reception post; 4 - simulated reception post; 5 - two-channel correlator; 6 - computing device. The dashed line shows the missing elements, communication lines of the device, the thick line indicates additional communications, actions that implement the method.

The implementation of the method includes calculating the coordinates of the simulated slave receiving post 4 and entering them into the computing device 5.

The coordinates of the simulated slave reception post 4 (x ₄ , y ₄ ) are determined from the condition of symmetry of its location to the current slave reception post 4 relative to the line "leading reception post - IRI" (figure 1):

where r ₂₄ , r ₂₃ - the distance between the receiving posts (base) of the system;

r ₁₄ , r ₁₃ - the distance from the corresponding slave receiving posts to Iran;

(x ₂ , y ₂ ), (x ₃ , y ₃ ), (x ₄ , y ₄ ) - rectangular coordinates of the location of the corresponding reception posts;

(x ₁ , y ₁ ) - the rectangular coordinates of the location of the IRI.

The system of equations (2) has a positive solution with respect to x ₄ , y ₄ :

The calculated coordinates of the simulated slave receiving post 4 (x ₄ , y ₄ ) are entered into the computing device 6.

The cross-correlation measurement of the time delays of the IRI 1 signal received by the leading 2 and slave 3 and 4 receiving posts in the RDS device is solved by finding the time shift between the signals in the two-channel correlator, at which the correlation functions take the maximum value

where τ is the time shift function introduced into one of the signals;

T is the integration time.

As the signal of IRI 1, received by the simulating slave receiving station 4, the method uses the signal of IRI 1 from the current receiving station S (t-τ ₄ ) = S (t-τ ₃ ). In practice, this action is implemented by additionally connecting the output of the active slave post 3 to the input of the second channel of the correlator 5. The equal delay of the IRI signal 1 in the two channels of the correlator 5 (τ ₄ -τ ₂ ) = (τ ₃ -τ ₂ ) corresponds to two symmetrical branches of hyperbolas relative to the leading reception post 2, and the point of their intersection determines the location of the IRI 1 (x ₁ , y ₁ ).

From the condition of symmetry of the locations of the slave reception posts 3, 4, the intersection point of the hyperbolas will lie on the line of symmetry (figure 1).

During the tests, the location of IRI 1 is chosen on the line of symmetry, and its coordinates (x ₁ , y ₁ ) 'are pre-determined with a high degree of accuracy, for example, using a satellite radio navigation system.

Using the RDS device, the coordinates of the IRI 1 are measured (x ₁ , y ₁ ) and compared with predetermined (x ₁ , y ₁ ) ', and then the accuracy characteristics of the RDS are determined.

From expression (1) with ψ1 = ψ2 = ψ, the mean square error of measuring the location of the IRI will be

σ_r0, где σ_r0 - предельное значение среднеквадратической погрешности измерения местоположения ИРИ, при которой имеет смысл функционирование РДС.Changing the location of the IRI, determine the boundaries of the working area of the RDS, σ _r

σ _r0, where σ _r0 is the limiting value of the standard error of measuring the location of the IRI, at which the functioning of the RDS makes sense.

Thus, the proposed method allows the field method to evaluate the accuracy of determining the location of the IRI, to test a prototype of a passive RDS in the absence of one of the receiving posts.

Claims (1)

A method for assessing the accuracy of determining the location of a radio emission source by a passive difference-ranging system, including a leading and operating slave receiving posts, characterized in that they simulate an additional slave receiving post by determining its coordinates from the condition of its location symmetry to the existing slave receiving post relative to the "leading receiving post - radiation source ", as a signal of a radio emission source received by a simulated slave receiving station, use a signal from the current slave receiving post, while the accuracy of determining the location of the radio emission source is estimated by cross-correlation measurement of the time delays of the signal of the radio emission source, received by the master, the current slave and simulated slave receiving posts of the passive differential-ranging system, and the equality of the delay of the signal received by the acting slave and simulated by slave reception posts, corresponds on the ground to two symmetric branches of hyperbolas relative to the host reception a fasting point, and the point of their intersection determines the location of the source of radio emission.

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