RU2542579C1 - Radio system - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: invention can be used to determine spatial coordinates of a stationary or mobile radio signal receiving radio facility (RO). A radio system (RS) comprises a ground radio signal transmitting system with N≥5 radio signal transmitting stations, coordinates of phase centres of antennae of which are known at the RO. The transmitting stations are configured for synchronised ordered transmission of radio signals in series, with given separate features and with given time delays between radio signals, which provide ordered arrival of radio signals at the RO, located at any point in a service area. Each RO comprises a radio signal receiving device configured to receive and identify radio signals of the corresponding transmitting station, a recorder for recording the reception time thereof in a time reference system specified at the RO and an information system configured, based on said coordinates and reception time of radio signals in the series, taking into account said time delays between radio signals, to measure coordinates of phase centres of the antenna of the RO according to the proposed measurement equations.

EFFECT: higher efficiency and simplification of corresponding radio systems.

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Description

The invention relates to communication technology, and more particularly to radio systems for transmitting and receiving radio signals and extracting information. Such systems include, in particular, radio navigation and radar systems, radio reconnaissance systems for radio equipment, radio surveillance of the Earth’s surface, etc. [Radio systems / Yu.M. Kazarinov et al. Ed. Yu.M. Kazarinova. - M .: IC "Academy", 2008, p. 7]. The inventive system contains radio signals receiving radio engineering objects, stationary or mobile, and a ground-based point transmitting radio signals system, including at least five orderly numbered transmitting radio signals, coordinates of the phase centers of the antennas of which are known on radio signals receiving radio signals. The implementation of the system will make it possible, among other things, to determine the spatial coordinates of the indicated radio engineering objects, simplify the corresponding information extraction systems, and increase their technical and economic efficiency, taking into account all the components that affect the cost and technical indicators.

Known radio engineering systems for transmitting and receiving radio signals and extracting information are used, inter alia, to determine the coordinates of radio engineering objects and are based on the use of goniometric, rangefinder, difference and total-rangefinder and combined methods for determining the location of an object with amplitude, time, frequency, phase and pulse -phase methods for measuring the parameters of the radio signal [RF patents №№2018855, 2115137, 2258242, 2264598, 2309420, 2325666, 2363117, 2371737, 2378660; Fundamentals of testing aircraft / E.I. Krynetsky et al. Ed. E.I. Krynetsky. - M .: Mashinostr., 1979, p. 64-89; Radio engineering systems / Yu.M. Kazarinov et al. Ed. Yu.M. Kazarinova. - M .: IC "Academy", 2008, p.17-18, pp. 7.1-7.4, ch.10 .; Melnikov Yu.P., Popov S.V. Radio intelligence. Methods for assessing the effectiveness of the determination of radiation sources. - M .: "Radio Engineering", 2008, Ch. 5]. Known systems have certain disadvantages, for example, the need for mechanical movement of the antenna system, the impossibility of unambiguous determination of the coordinates of the object, the need for a priori information about the location of the object, the need for general synchronization of radio objects transmitting and receiving radio signals, and insufficient reliability. According to the criterion of minimum sufficiency, the closest is the system for transmitting and receiving radio signals and extracting information according to patent RU No. 2453996.

An advantage of the claimed system compared to the known ones is the possibility of increasing the technical and economic efficiency of radio engineering complexes for measuring spatial coordinates and other characteristics of an object functionally related to its coordinates, including ensuring the accuracy and reliability of their measurement in accordance with modern requirements. This is achieved by the fact that the claimed system, in particular, does not require general synchronization of the aggregate of transmitting and receiving radio signals of radio engineering objects. Also, the inventive system allows you to determine the spatial coordinates through indirect measurements using simple expressions that depend on the measured moments of the times of receiving radio signals at a radio signal receiving radio object. This simplifies the unambiguous determination of spatial coordinates.

To achieve the technical result in accordance with the present invention, the radio engineering system comprises a ground-based point transmitting radio signals system and receiving radio signals radio engineering objects, stationary or mobile, while the specified ground-based point transmitting radio signals system includes orderly numbered transmitting radio signals points, in an amount of N at least five, each of them contains antenna devices, the phase centers of the transmitting antennas of which are in predetermined, e coplanar and known, including said object points with the coordinates X _n, Y _n, Z _n, where index n varies from 1 to N, respectively, in a predetermined three-dimensional Cartesian coordinate system (X, Y, Z ), and radio signal transmitting devices connected to antenna devices configured to synchronize the ordered transmission of radio signals in series, preferably one radio signal from each radio transmitting point in the series, with not necessarily the same intervals between in series, if necessary, said radio transmitting devices are capable of transmitting radio signals with predetermined individual characteristics, including complex and composite radio signals with predetermined individual characteristics of their elements and the possibility of their separation when receiving, and if necessary with predetermined, not necessarily the same, and known at said radio signal receiving radio objects, time delays between the radio signals, and each radio signal receiving radio signal the object contains an antenna device, a radio signal receiving device connected to it, configured to receive radio signals from a ground-based point transmitting radio signals system and identifying them with corresponding radio signal transmitting points, a time recorder of radio signal receiving times from said radio signal transmitting points in a time reference system specified on the radio signal receiving radio object connected to the device receiving radio signals, and an information system, function cial associated with the registrar and configured to store the predetermined coordinates _{X n, Y n, Z n} , said predetermined delay times, if necessary, and with the possibility, if necessary, centering these moments the reception times of radio signals including the excluded if necessary specified time delays by eliminating from each time point the mean value of the time series of all moments and thus for the determination of moments of time t _n, and said information B theme configured to measure parameters d _n with the dimension of length d _n = υt _n, where υ - speed of radio propagation, and after the measured parameters d _n and the said coordinates X _n, Y _n, Z _n measurement parameters c _i, where the index i varies from 0 to 6, parameters a _j with a dimension of length to the fourth degree, where the index j varies from 1 to 6, and parameters b _k with length dimension to the fifth degree, where the index k varies from 1 to 3, in accordance with the measurement equations

$$\begin{array}{l}{c}_0=N{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n^2-{\left({\displaystyle \sum _{n=\mathrm{one}}^N{d}_n}\right)}^2},c_{\mathrm{one}}=N{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n{X}_n-{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n{\displaystyle \sum _{n=\mathrm{one}}^N{X}_n,}}}{c}_2=N{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n{Y}_n-{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n{\displaystyle \sum _{n=\mathrm{one}}^N{Y}_n,}}}\\ c_3=N{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n{Z}_n-{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n{\displaystyle \sum _{n=\mathrm{one}}^N{Z}_n,c_{\mathrm{four}}={\displaystyle \sum _{n=\mathrm{one}}^N{d}_n{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n{X}_n-{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n^2}{\displaystyle \sum _{n=\mathrm{one}}^N{X}_n},}}{c}_5={\displaystyle \sum _{n=\mathrm{one}}^N{d}_n{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n{Y}_n-{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n^2}{\displaystyle \sum _{n=\mathrm{one}}^N{Y}_n},}}}}}\\ c_6={\displaystyle \sum _{n=\mathrm{one}}^N{d}_n{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n{Z}_n-{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n^2}{\displaystyle \sum _{n=\mathrm{one}}^N{Z}_n},\text{(one)}}}\end{array}$$

$$\begin{array}{l}{a}_{\mathrm{one}}=c_0{\displaystyle \sum _{n=\mathrm{one}}^N{X}_n^2-c_{\mathrm{one}}{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n{X}_n+c_{\mathrm{four}}{\displaystyle \sum _{n=\mathrm{one}}^N{X}_n}},a_{\mathrm{four}}=c_0{\displaystyle \sum _{n=\mathrm{one}}^N{X}_n{Y}_n-c_{\mathrm{one}}{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n{Y}_n+c_{\mathrm{four}}{\displaystyle \sum _{n=\mathrm{one}}^N{Y}_n},}}}\\ a_2=c_0{\displaystyle \sum _{n=\mathrm{one}}^N{Y}_n^2-c_2{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n{Y}_n+c_5{\displaystyle \sum _{n=\mathrm{one}}^N{Y}_n}}},a_5=c_0{\displaystyle \sum _{n=\mathrm{one}}^N{X}_n{Z}_n-c_2{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n{Z}_n+c_5{\displaystyle \sum _{n=\mathrm{one}}^N{Z}_n},\text{(2)}}}\\ a_3=c_0{\displaystyle \sum _{n=\mathrm{one}}^N{Z}_n^2-c_3{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n{Z}_n+c_6{\displaystyle \sum _{n=\mathrm{one}}^N{Z}_n},a_6=c_0{\displaystyle \sum _{n=\mathrm{one}}^N{Y}_n{Z}_n-c_3{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n{Z}_n+c_6{\displaystyle \sum _{n=\mathrm{one}}^N{Z}_n},}}}}\end{array}$$

$$\begin{array}{l}{b}_{\mathrm{one}}=\left[c_0{\displaystyle \sum _{n=\mathrm{one}}^N{X}_n(D_n^2-d_n^2)-c_{\mathrm{one}}{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n}(D_n^2-d_n^2)+c_{\mathrm{four}}{\displaystyle \sum _{n=\mathrm{one}}^N(D_n^2-d_n^2)}}\right]/2,\\ b_2=\left[c_0{\displaystyle \sum _{n=\mathrm{one}}^N{Y}_n(D_n^2-d_n^2)-c_2{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n}(D_n^2-d_n^2)+c_5{\displaystyle \sum _{n=\mathrm{one}}^N(D_n^2-d_n^2)}}\right]/2,\text{(3)}\\ b_3=\left[c_0{\displaystyle \sum _{n=\mathrm{one}}^N{Z}_n(D_n^2-d_n^2)-c_3{\displaystyle \sum _{n=\mathrm{one}}^N{d}_n}(D_n^2-d_n^2)+c_6{\displaystyle \sum _{n=\mathrm{one}}^N(D_n^2-d_n^2)}}\right]/2,\end{array}$$

, с возможностью измерения через параметры a _j параметров A_l где индекс l изменяется от 0 до 6, в соответствии с уравнениями измеренийwhere is the parameter $$D_n^2=X_n^2+Y_n^2+Z_n^2$$

, with the possibility of measuring through parameters a _{j the} parameters A _l where the index l varies from 0 to 6, in accordance with the measurement equations

и с возможностью измерения пространственных координат фазового центра приемной антенны принимающего радиосигналы радиотехнического объекта x, y, z преимущественно через параметры A_l и b_k в соответствии с уравнениями измерений $$\begin{array}{l}{A}_0=a_{\mathrm{one}}{a}_2{a}_3+2a_{\mathrm{four}}{a}_5{a}_6-a_{\mathrm{one}}{a}_6^2-a_2{a}_5^2-a_3{a}_{\mathrm{four}}^2,A_{\mathrm{one}}=a_2{a}_3-a_6^2,A_2=a_{\mathrm{one}}{a}_3-a_5^2,A_3=a_{\mathrm{one}}{a}_2-a_{\mathrm{four}}^2,\\ A_{\mathrm{four}}=a_5{a}_6-a_3{a}_{\mathrm{four}},A_5=a_{\mathrm{four}}{a}_6-a_2{a}_5,A_6=a_{\mathrm{four}}{a}_5-a_{\mathrm{one}}{a}_6,\text{(four)}\end{array}$$

and with the ability to measure the spatial coordinates of the phase center of the receiving antenna of the receiving radio signals of the radio object x, y, z mainly through the parameters A _l and b _k in accordance with the measurement equations

$$\text{x}={\text{(A}}_{\text{one}}{\text{b}}_{\text{one}}+{\text{A}}_{\text{four}}{\text{b}}_{\text{2}}+{\text{A}}_{\text{5}}{\text{b}}_{\text{3}}{\text{) / A}}_{\text{0}}\text{, y}={\text{(A}}_{\text{four}}{\text{b}}_{\text{one}}+{\text{A}}_{\text{2}}{\text{b}}_{\text{2}}+{\text{A}}_{\text{6}}{\text{b}}_{\text{3}}{\text{) / A}}_{\text{0}}\text{z}={\text{(A}}_{\text{5}}{\text{b}}_{\text{one}}+{\text{A}}_{\text{6}}{\text{b}}_{\text{2}}+{\text{A}}_{\text{3}}{\text{b}}_{\text{3}}{\text{) / A}}_{\text{0}}\text{, (5)}$$

if necessary, the information system is also capable of storing the x, y, z coordinates measured in series, and measuring through them other trajectory characteristics of a radio object receiving radio signals, including using statistical methods of trajectory measurements, while a radio object receiving radio signals, if necessary, contains a display unit and a unit for transmitting information to consumers, functionally associated with the specified information system, while the ground optional radio signal transmitting system, if necessary, contains an information reception and display unit configured to receive information transmitted by said information transmission unit to consumers of a radio signal receiving radio signal object, in addition, if necessary, a control radio signal receiving radio signal object is inserted into the ground-based point transmitting radio signal system, made with the ability to receive radio signals transmitted by the said points radio signals of the system, with the coordinates of the phase center of its antenna x _k , y _k , z _k specified in the indicated three-dimensional Cartesian coordinate system (X, Y, Z), the constituent elements of which are made essentially identical to the constituent elements of the aforementioned radio signal receiving radio object, while the information the system of said control radio engineering object is additionally configured to correct said measured coordinates x, y, z by known coordinates x _k , y _k , z _k and measured coordinates x _ki , y _ki , z _{ki of the} phase center of the receiving antenna of the control receiving radio signals of a radio engineering object, also the ground-based point transmitting radio signals system contains a subsystem for controlling its operation.

In the current level of technology, no sources of information have been identified that would contain information about systems of the same purpose with the indicated set of features.

Below the invention is described in more detail with reference to the figure.

The figure shows the inventive system. The radio system 1 contains a ground-based point-to-point radio signal transmitting system (PS) 2 and a radio signal receiving (radio) radio engineering object (RO) 3. In this case, the MS 2 includes orderly numbered radio transmitting points 4 (No. 1, 2, ..., n, ..., N) in an amount of N at least five. Each of them contains antenna devices 5, the phase centers of the transmitting antennas of which are in predetermined, not located in the same plane, and known, including at the mentioned objects, points with coordinates X _n , Y _n , Z _n , where the index n varies from 1 to N, respectively, in a given three-dimensional Cartesian coordinate system (X, Y, Z). Radio antenna devices 5 are connected to antenna devices 5.

Devices 6 are configured to synchronize an ordered transmission of p / s series, mainly one p / s from each transmitting p / s point 4 in the series, and with specified not necessarily the same intervals between the series. If necessary, the device 6 is made with the possibility of transmitting r / s with predetermined individual characteristics, including complex and composite r / s with predetermined individual signs of their elements [L. Varakin Theory of signal systems. M .: “Owls. radio ”, 1978, p.18] and the possibility of their separation at reception. Also, if necessary, the device 6 is made with the possibility of transmitting r / s with predetermined, not necessarily the same, and known on the mentioned receiving r / s PO 3 time delays between r / s.

Each receiving r / s PO 3 contains an antenna device 7 and a receiving r / s device 8 connected to it. The latter is configured to receive the r / s of the ground PS 2 and identify them with the corresponding transmitting r / s points 4. The PO 3 contains a recorder of 9 moments the time of receiving r / s from transmitting r / s points 4 in the time reference system set for PO 3. The registrar 9 is connected to the receiving r / s device 8. The PO 3 contains an information system 10 operably connected to the registrar 9 and configured to store the specified coordinates X _n , Y _n , Z _n and the specified delay times, if necessary. Also, the information system 10 is configured to center, if necessary, the indicated moments of the reception times p / s, including, if necessary, with the indicated delay times excluded, and to determine the thus recorded moments of the times t _n and measure the mentioned parameters d _n , measure the mentioned parameters c _i , a _j , b _k , A _l in accordance with the measurement equations (1), (2), (3) and (4). In addition, the information system 10 is configured to measure the spatial coordinates of the phase center of the antenna of the antenna device 7 receiving r / s PO 3 mainly through the parameters A _l and b _k in accordance with the measurement equations (5).

If necessary, the information system (10) is configured to save the measured x, y, z coordinates in series, and to measure other path characteristics of PO 3 through them, including using statistical methods of path measurements. At the same time, PO 3, if necessary, contains a display unit 11 and a unit for transmitting information to consumers 12, functionally connected with the information system 10. PS 2, if necessary, contains a unit for receiving and displaying information 13, configured to receive information transmitted by the specified unit for transmitting information to consumers 12 of PO 3.

In addition, if necessary, in PS 2, a control receiver of the radio engineering object (CRO) 14 is introduced, configured to receive radio communications transmitted by points 4 with the coordinates of the phase center specified in the indicated three-dimensional Cartesian coordinate system (X, Y, Z) its antennas x _k , y _k , z _k , the constituent elements of which are made essentially identical to the constituent elements of PO 3. Moreover, the information system 10 of the KPO 14 is additionally configured to correct said measured coordinates x, y, z by known coordinates x _k , y _k , z _k and the measured coordinates x _ki , y _ki , z _{ki of the} phase center of the receiving antenna KRO 14. Also, the PS 2 contains a subsystem 15 for controlling its operation.

The proposed system 1 operates as follows.

MS 2 transmits r / s synchronously. In this case, the r / s are transmitted in order by series, mainly one r / s from each transmitting r / s point 4 containing the antenna device 5 and the transmitting r / s device 6, in a series. The intervals between series are not necessarily the same. If necessary, transmitting r / s points 4 transmit r / s with predetermined individual characteristics, including complex and composite r / s with predetermined individual characteristics of their elements and the possibility of their separation during reception. Also, if necessary, p / s are transmitted with predetermined, not necessarily the same, and known by PO 3 time delays between p / s.

The radio signals are received on a particular PO 3 and identified by their respective transmitting p / s points 4. At this object, the registrar 9 records the times of receiving p / s in a given time reference system. If necessary, in the information system 10, the corresponding indicated delay times are excluded from them. In it, the indicated moments of the reception times of the radio receivers with excluded delay times are, if necessary, centered by eliminating from each moment of time the average value of all the moments of the series. Based on the thus recorded time instants t _n, said parameters d _n are measured. In the information system 10 PO 3 through the specified coordinates X _n , Y _n , Z _n and the measured parameters d _n measure the parameters c _i , a _j , b _k and A _l in accordance with the measurement equations (1), (2), (3 ) and (4). And finally, the spatial coordinates x, y, z of the phase center of the receiving antenna PO 3 are measured mainly through the parameters A _l and b _k in accordance with the measurement equations (5). If necessary, the series and all the indicated actions in them are repeated and other trajectory characteristics of this object are measured using the x, y, z PO 3 coordinates measured in the series, including using statistical methods of trajectory measurements. If necessary, this information is displayed and transmitted to consumers in blocks 11 and 12, respectively. If necessary, the information transmitted to consumers is received and displayed in block 13 on PS 2.

In addition, if necessary, r / s PS 2 is also received at KRO 14 with the coordinates of the phase center of its receiving antenna x _k , y _k , z _k specified in the indicated three-dimensional Cartesian coordinate system (X, Y, Z). At the same time, at KPO 14 p / s, it is taken predominantly identical to receiving p / s at PO 3. The coordinates x _ki , y _ki , z _{ki of the} phase center of the receiving antenna KPO 14 are measured identically to the specified coordinate measurement of PO 3. Then the measured coordinates x, y, are corrected z PO 3 according to the known coordinates x _k , y _k , z _k and the measured coordinates x _ki , y _ki , z _{ki of the} phase center of the receiving antenna KRO 14.

We list the main advantages of the system:

- provides an unambiguous determination of the spatial coordinates of the object with great accuracy, corresponding to modern requirements,

- General synchronization of the aggregate of transmitting and receiving radio signals of radio engineering objects is not required,

- provides the ability to make measurements using one of the well-known radio engineering methods and the existing elemental base and microprocessor technology,

- the implementation of the system is simpler and cheaper than well-known analogues,

- spatial coordinates are determined by indirect measurement using simple expressions,

- allows simultaneous measurements on an unlimited number of radio objects.

The effectiveness and efficiency of the use of the claimed system is that it can be applied in practice for the development and improvement of radio engineering systems for determining, mainly, the coordinates of objects, as well as in other applications. Thus, the inventive system provides the emergence of new properties. The analysis made it possible to establish: there are no systems with a set of features identical to all the features of the claimed technical solution, which indicates the conformity of the claimed system to the “novelty” condition.

Also, the popularity of the influence of the actions provided for by the essential features of the claimed invention on the achievement of the specified result was not revealed. Therefore, the claimed invention meets the condition of patentability "inventive step".

Claims (1)

A radio engineering system comprising a ground-based point-to-point transmitting radio signals system and receiving radio signals radio engineering objects, stationary or mobile, wherein said ground-based point-to-point transmitting radio signals system includes orderly numbered transmitting radio signals points, in an amount of N at least five, each of which contains antenna devices, phase centers transmitting antennas which are in predetermined, not located in the same plane, and known, including at the mentioned objects, points with coordinates X _n , Y _n , Z _n , where the index n varies from 1 to Ν, respectively, in a given three-dimensional Cartesian coordinate system (X, Y, Z), and transmitting radio signals of the device connected to the antenna devices, configured to synchronize ordered transmitting radio signals in series from each point transmitting radio signals at predetermined intervals between series, said transmitting radio signals of the device are capable of transmitting radio signals with predetermined individual characteristics, including complex ones and composite radio signals with predetermined individual characteristics of their elements and the possibility of their separation during reception, and with the time delays between the radio signals set and known on the said radio signal receiving radio engineering objects, and each radio signal receiving radio signal object comprises an antenna device, a radio signal receiving device connected to it, configured to receive radio signals of a ground-based point transmitting radio signals system and identifying them accordingly to the points transmitting the radio signals to them, a time recorder of the times of receiving the radio signals from said points transmitting the radio signals, points in a reference system connected to the receiving signals of the radio signals at the radio signal receiving object, and an information system operatively connected to the recorder and configured to store said predetermined coordinates X _n , Y _n, Z _n, said predetermined delay times and, with said centering moments the reception times of radio signals, in ohm including excluded specified time delays by eliminating from each time point the mean value of all moments time series and thereby determine for the moments of times t _n, and said information system is arranged to measure d _n parameter with dimensions of length d _n = υt _n, where υ - radio signal propagation speed, and after the measured parameters d _n and the said coordinates X _n, Y _n, Z _n measurement parameters c _i, where the subscript i ranges from 0 to 6, with the parameters a _j length dimension in The Fourth extent where the subscript j ranges from 1 to 6 and the parameters b _k with the length dimension of the fifth power, where the index k ranges from 1 to 3, in accordance with the measurement equations

where is the parameter

, with the ability to measure through the parameters a _{j the} parameters A _l , where the index l varies from 0 to 6, in accordance with the measurement equations

,

,

,

,

,

,

, and with the possibility of measuring the spatial coordinates of the phase center of the receiving antenna of the receiving radio signals of the radio object x, y, z through the parameters A _l and b _k in accordance with the measurement equations x = (A ₁ b ₁ + A ₄ b ₂ + A ₅ b ₃ ) / A ₀ , y = (A ₄ b ₁ + A ₂ b ₂ + A ₆ b ₃ ) / A ₀ , z = (A ₅ b ₁ + A ₆ b ₂ + A ₃ b ₃ ) / A ₀ , also information the system is capable of storing the x, y, z coordinates measured in a series of specified coordinates, measuring through them other trajectory characteristics of a radio object receiving radio signals, including using statistical methods in trajectory measurements, wherein the radio signal receiving radio object contains a display unit and an information transmitting unit for consumers functionally associated with the specified information system, while the ground-based point transmitting radio signal system contains an information receiving and display unit adapted to receive information transmitted by the specified transmission unit information to consumers of a radio signal receiving radio object, in addition, to a ground-based point transmitting radio signal ly system introduced controlling a receiving radio signals Radiotechnical object configured to receive signals transmitted by said points terrestrial punktovoy transmitting radio system with specified in said three dimensional Cartesian coordinate system (X, Y, Z) coordinates of the phase center of its antenna x _a, y _a, z _k , while the information system of the said control radio engineering object is additionally configured to correct said measured coordinates x, y, z according to known coordinates x _k , y _k , z _k and the measured coordinates x _ki , y _ki , z _{ki of the} phase center of the receiving antenna of the control radio signal receiving radio object, also the ground-based point transmitting radio signal system contains a subsystem for controlling its operation.