RU2743573C1 - Method for determining relative distances to facility - Google Patents

Abstract

FIELD: radio navigation.

SUBSTANCE: invention relates to radio navigation and can be used to determine relative distances to a facility, including a mobile one, from earth-based system stations. Said method includes as follows: at each station, a radio signal is transmitted synchronously in the form of two groups, each of which is formed out of three components, which are harmonic oscillations with equal amplitudes and with preset frequencies. One of the three harmonic vibrations of the first group is common with one of the three harmonic oscillations of the second group. At the facility, a set of radio signals transmitted by the stations is received in a quadrature manner. Digital quadrature components (DQC) corresponding to the received set of radio signals are formed one by one with the preset sampling frequency and the number of clock steps in a cycle. According to the generated DQC, the next three pairs of digital quadrature components (QC) corresponding to the components of the transmitted radio signals are formed in a predetermined manner. Then three pairs of digital quadrature components corresponding to the indicated groups are formed out them by summing each of the obtained QCs of the corresponding pair. Using the digital quadrature components obtained in this way, the parameters given in the method are developed and the time delays are determined according to the resulting parameters. Time shifts arising from the formation of radio signals at the stations are excluded. Based on the corrected time delays, the relative distances from the PhC antennas of the stations to the phase center (PhC) of the facility antenna are determined in a unique manner. The method enables to exclude the influence of radio signals reflected, for example from the Earth, and random phases of heterodynes of the transmitters and the receiver. No common synchronization is required between the facility and the set of transmitted stations.

EFFECT: increased accuracy and enhanced zone of unambiguous determination of the mentioned relative distances.

1 cl

Description

The invention relates to radio navigation and can be used to determine the relative distances to the phase center (FC) of the antenna of the object, including the mobile one, from the FC antennas of the ground system stations, and to control its movement in the navigation zone. At each station, a stationary ground station system transmits a radio signal. The set of radio signals transmitted by the stations is received at the facility, processed by the proposed method and the mentioned relative ranges are determined. The implementation of the method will allow, among other things, to simplify the corresponding positioning systems, to ensure the accuracy and unambiguity of the measurement of the specified relative ranges.

Known methods for determining relative ranges based on the use of goniometric, rangefinder, differential and total rangefinder and combined methods for determining the location of an object with amplitude, time, frequency, phase and pulse-phase methods for measuring radio signal parameters (RF Patents Nos. 2115137, 2213979, 2258242 , 2264598, 2309420, 2325666, 2363117, 2371737, 2378660, 2430385, 2439617, 2506605, 2507529, 2510518, 2539968, 2558640, 2559813, 2567114, 2568104, 2572589, 2684976, 2597207, 2598172, 2584976, 2597007, 259817000, 2584976 , 2653506, 2657237, 2725106; US Patent Nos. 9423502 B2, 9465099 B2, 9485629 B2, 9488735 B2, 9661604 B1, 9681267 B2, 2016/0327630 A1, 2016/0330584 A1, 2016/0337933 A1, 2019265363 A1; devices / E.I.Krinetsky et al. Edited by E.I.Krinetsky. - M .: Mashinostr., 1979, pp. 64-89; Radio engineering systems / Yu.M. Kazarinov et al. Edited by Yu. M. Kazarinova. - M .: IC "Academy", 2008, p. 7, 17-18, pp. 7 .1-7.4, ch. ten.; Melnikov Yu.P., Popov S.V. Radio-technical intelligence. Methods for assessing the effectiveness of location of radiation sources. - M .; "Radiotekhnika", 2008, ch. five; Kinkulkin I.E. et al. Phase method for determining coordinates. - M .: Sov. radio, 1979, p. 10-11, 97-100). The known methods have certain disadvantages, for example, the need for mechanical movement of the antenna system, the impossibility of their unambiguous determination, the need for a priori information about the location of the object, the need for general synchronization of transmitting and receiving radio signals of radio engineering objects, do not take into account the effect on the result of the reflection of radio waves, for example, from the ground , do not exclude random phases of the transmitters and the receiver local oscillators, have insufficient speed and accuracy.

According to the criterion of minimum sufficiency, the closest is the method for determining relative ranges according to RU patent No. 2718593.

The advantage of the proposed method for determining the relative distances to the object, including the mobile one, from the stations of the ground system in comparison with the known methods is to increase the accuracy and increase the zone of unambiguous determination of the indicated relative ranges. This is achieved by the fact that at each station, the radio signal is transmitted synchronously in the form of two groups, each of which is formed from three components, which are harmonic oscillations with equal amplitudes and with given frequencies, and one of the three harmonic oscillations of the first group is common with one of the three harmonic vibrations of the second group. At the facility, a set of radio signals transmitted by the stations is received quadrature. Digital quadrature components (CQC) corresponding to the received set of radio signals are formed one by one with a given sampling frequency and the number of clock cycles in a cycle. According to the generated CQC, the next three pairs of digital quadrature components (QC) corresponding to the components of the transmitted radio signals are formed in a predetermined manner. Then, three pairs of digital quadrature components are formed from them, corresponding to the indicated groups, by summing each of the obtained QCs of the corresponding pair. Using the digital quadrature components obtained in this way, the parameters given in the method are formed and the time delays are determined from the generated parameters. They exclude time shifts arising from the formation of radio signals at the stations. Based on the corrected time delays and when the conditions specified in the method are met, the relative distances to the phase center (FC) of the object antenna from the FC antennas of the stations are uniquely determined. And according to the relative ranges, the spatial coordinates of the FC antenna of the object are uniquely determined.

To achieve the specified technical result in accordance with the present invention in the method for determining the coordinates of an object, including a mobile one, from the measured relative ranges, at each station of the ground system, consisting of n-th orderly numbered ground stations, where the index n varies from 1 to N and N≥4, with the coordinates of the phase centers of their antennas known on the object in a given three-dimensional Cartesian system, synchronously transmit the n-th radio signal in the form of two k-th groups, each of which is formed from three components, which are harmonic oscillations with equal amplitudes and, accordingly given and known at the object frequencies F _{n, k, i} = F0 _{n, k} + (i-1) ΔF _k , where index k varies from 1 to 2, and index i changes from 1 to 3, F0 _{n, k} are given frequency, ΔF _k is the interval between adjacent i-th frequencies of the k-th group of n-th radio signals, while ΔF ₁ and ΔF _{2 are} set in such a way that ΔF ₁ <ΔF ₂ and ΔF ₂ / ΔF ₁ is a given integer numerical scrap, and for each n-th radio signal, one of its three harmonic vibrations of the first group is common with one of its three harmonic vibrations of the second group, with time shifts known at the object for each n-th radio signal that occur during the formation of radio signals, provided that that the distance between the phase centers of the antennas for any pair of N stations, referred to the speed of propagation of radio signals and increased by the absolute value of the difference between the indicated time shifts, should not exceed the period T, equal to 1 / ΔF ₁ , and a set of N radio signals is received quadrature at the object, when This either carries out the transfer of their spectra by shifting to the frequency of the local oscillator, or it is not carried out, step-by-step with a given sampling frequency dƒ at each j-th cycle, where the index j varies from 0 to a given number of clock cycles J, the corresponding to the received set of radio signals digital quadrature components I _j and Q _j , according to the generated th digital quadrature components, for each k-th group, three pairs of digital quadrature components xI _{n, k, i, j} and xQ _{n, k, i, j} are formed corresponding to the i-th components of the transmitted n-th radio signals, in accordance with the expressions

respectively, either the frequencies obtained from the mentioned frequencies F _{n, k, i} by means of a shift to the local oscillator frequency with the indicated spectrum transfer, or frequencies equal to F _{n, k, i} otherwise, and

, где s - заданное число, для сформированных таким образом трех пар цифровых квадратурных компонент, соответствующих k-тым группам n-тых радиосигналов, формируют путем суммирования каждой из полученных цифровых квадратурных компонент соответствующей пары три пары цифровых квадратурных компонент в соответствии с выражениями

, where s is a given number, for the thus formed three pairs of digital quadrature components corresponding to the k-th groups of n-th radio signals, three pairs of digital quadrature components are formed by summing each of the obtained digital quadrature components of the corresponding pair in accordance with the expressions

sequentially using the previously generated digital quadrature components form the parameters corresponding to the k-th groups of n-th transmitted radio signals

where a t a n2 (x, y) is equal to the angle (in radians) formed by the x-axis and the straight line containing the origin (0,0) and the point (x, y), in the range from -π to π, excluding (- π), and π is a known number equal to the ratio of the circumference to its diameter,

the parameters formed in this way determine the time delays dt _{n, k} in accordance with the expression

dt _{n, k are} corrected, excluding the mentioned time shifts, according to the time delays obtained in this way, uniquely taking into account the speed of propagation of the radio signal c, the relative distances to the phase center of the object antenna are determined from the indicated phase centers of the antennas of the stations D _n in the zone of unambiguous determination of the relative ranges equal to s / ΔF ₁ , with an accuracy determined by a harmonic vibration with a frequency of ΔF ₂ .

The totality of all the features makes it possible to determine the mentioned relative ranges with the achievement of the specified technical result.

In the existing prior art, no sources of information have been identified that would contain information about methods of the same purpose with the specified set of features. The invention is described in more detail below.

The essence of the method is as follows.

At each station of the ground system, consisting of n-th ordering of numbered ground stations, where the index n varies from 1 to a given N, the n-th radio signal is transmitted synchronously in the form of two k-th groups, each of which is formed from three components, which are harmonic oscillations with equal amplitudes and, respectively, given and known on the object frequencies F _n , _{k, i} = F0 _{n, k} + (i-1) ΔF _k , index k changes from 1 to 2, and index i changes from 1 to 3, F0 _{n, k} are given frequencies, ΔF _k is the interval between adjacent i-th frequencies of the k-th group of n-th radio signals. In this case, ΔF ₁ and ΔF _{2 are} set in such a way that ΔF ₁ <ΔF ₂ and ΔF ₂ / ΔF ₁ is a given integer, and for each n-th radio signal one of its three harmonic oscillations of the first group is common with one of its three harmonic vibrations of the second group. The object knows for each n-th radio signal time shifts arising from the formation of radio signals. The condition must also be met that the distance between the phase centers of the antennas for any pair of N stations, referred to the propagation speed of radio signals and increased by the absolute value of the difference of the indicated time shifts, should not exceed the period T equal to 1 / ΔF _l .

и среднеквадратическим отклонением

заданное число s позволяет изменять СКО.At the facility, a set of N radio signals is received quadrature, while their spectra are either transferred by shifting to the local oscillator frequency, or it is not carried out (depending on the element base available during the implementation of the method and the frequency range used). Then, step-by-step with a given sampling frequency dƒ at each j -th cycle, where the index j varies from 0 to a given number of cycles J in the cycle, digital quadrature components (QQC) I _j and Q _j corresponding to the received set of radio signals are formed. For each k-th group, three pairs of digital quadrature components xI _{n, k, i, j} and xQ _{n, k, i, j} , corresponding to the i-th components of the transmitted n-th radio signals, are formed according to the generated CCMs in accordance with the expressions (1) , where p (j) is a Gaussian function with expectation

and standard deviation

a given number s allows you to change the standard deviation.

For the thus formed three pairs of digital quadrature components corresponding to the k-th groups of n-th radio signals, three pairs of digital quadrature components are formed (by summing each of the obtained digital quadrature components of the corresponding pair over j) in accordance with expression (2). Then, sequentially using the generated digital quadrature components (2), the parameters (3) corresponding to the k-th groups of the n-th transmitted radio signals are formed.

The parameters (3) thus formed are used to determine the time delays dt _{n, k} in accordance with expression (4).

The dt _{n, k} values are corrected by excluding said time shifts. If these time shifts are the same, then they can be ignored. _{According to the corrected time delays, the relative distances D n} to the FC antenna of the object from the indicated FC antennas of the stations are determined accordingly, taking into account the speed of propagation of the radio signal.

In principle, although not required, the values of ΔF _k , dƒ, J can be set such that the ratio of the cycle time equal to J / dƒ to said period T is an integer. In this situation, certain relative delays, for example, for an object at rest from cycle to cycle, will not change in time. If this condition is not met, then each of the relative ranges is shifted by the same amount. In principle, after each cycle, it is possible to center the relative ranges by excluding from each relative range obtained in the cycle the average value of all the relative ranges obtained in the cycle, then the relative delays, for example, for a resting object will also not change in time.

The representation of quadrature components in digital form gives a definite advantage in solving the problem due to the simplicity of its software implementation.

In addition, the parameters IC _{n, k, i, j} , QS _{n, k, i, j,} and р (j) included in expression (1) can be calculated in advance from the given values ƒ _{n, k, i} , dƒ and J, which computationally simplifies the formation of the corresponding quadratures and significantly reduces the amount of computation.

Simultaneous joint use of a radio signal in the form of two groups allows to increase the area of unambiguous determination of relative ranges and ensure high accuracy of their determination. It is also important that the use of one common for both groups of the specified harmonic vibration allows you to use five frequencies instead of six.

An increase in accuracy and an increase in the area of unambiguous determination of relative ranges will, in turn, increase, for example, the accuracy of determining the spatial coordinates of the object's FC antenna from the measured relative distances to it by increasing the area for unambiguous determination of relative ranges.

To determine the coordinates, you can use any of the known methods, for example, from those protected by patents RU (No. 2530232, 2530241, 2624461, 2647496) or from those protected by international applications in the PCT system (WO / 2015/012738, WO / 2015/012735) or from published in the author's articles (Algorithm for determining the spatial coordinates of an object by relative distances to it // Nonlinear World. 2015. No. 5. P. 38-41; Iterative algorithm for determining the spatial coordinates of an object // Information-measuring and control systems. 2016. Vol. 14.No. 7. S. 64-69).

The method can be used to build a navigation and landing system.

Let's list the main advantages of the method:

- provides an increase in the zone of unambiguous determination of the relative distances to the object,

- increases the accuracy of determining relative ranges,

- allows you to reduce the number of used frequencies,

- no common synchronization is required between an object and a set of transmitting stations,

- eliminates the influence of signals reflected, for example, from the ground,

- allows you to exclude random phases of transmitters local oscillator and receiver local oscillator,

- greatly simplifies the reception and processing of radio signals,

- signals specified in an analytical form are easier to form and transform, thanks to, among other things, this increases the accuracy of measurements,

- provides the ability to make measurements using the existing element base, programmable logic integrated circuits (FPGA) and microprocessor technology,

- allows simultaneous measurements on a large number of objects.

The effectiveness and efficiency of using the proposed method lies in the fact that it can be applied in practice for the development and improvement of radio engineering systems for determining relative ranges, as well as in other applications. The method makes it possible to unambiguously determine the relative distances to the object with high accuracy and more simply in comparison with the known methods.

Thus, the claimed method provides the emergence of new properties that are not achieved in analogues. The analysis made it possible to establish: there are no analogues with a set of features that are identical to all features of the claimed technical solution, which indicates that the claimed method meets the "novelty" condition.

Also, the influence of the actions envisaged by the essential features of the claimed invention on the achievement of the specified result was not revealed. Therefore, the claimed invention meets the "inventive step" requirement of patentability. Thus, the claimed invention meets the criteria of "novelty" and "inventive step", as well as the criterion of "industrial applicability".

Claims (19)

A method for determining the relative distances to an object, including a mobile one, from n-th ordered numbered stations of the terrestrial system, where the index n varies from 1 to a given N, in which at each n-th station, the n-th radio signal is transmitted synchronously in the form of two k-th groups, each of which is formed from three components, which are harmonic oscillations with equal amplitudes and, respectively, given and known on the object frequencies F _{n, k, i} = F0 _{n, k} + (i-1) ΔF _k , where index k changes from 1 to 2, and the index i changes from 1 to 3, F0 _{n, k} are the given frequencies, ΔF _k is the interval between adjacent i-th frequencies of the k-th group of n-th radio signals, while ΔF ₁ and ΔF _{2 are} set such that ΔF ₁ <ΔF ₂ and ΔF ₂ / ΔF ₁ is a given integer, and for each n-th radio signal one of its three harmonic oscillations of the first group is common with one of its three harmonic oscillations of the second group, with known object for each nth p radio signal by time shifts arising during the formation of radio signals, provided that the distance between the phase centers of the antennas for any pair of N stations, referred to the propagation speed of radio signals and increased by the absolute value of the difference between the indicated time shifts, should not exceed the period T equal to 1 / ΔF ₁ , and on the object a set of N radio signals is received quadrature, while either their spectra are transferred by means of a shift to the local oscillator frequency, or it is not carried out, step by step with a given sampling frequency dƒ at each jth clock, where the index j varies from 0 to a given in the cycle of the number of clock cycles J, form the digital quadrature components I _j and Q _j corresponding to the received set of radio signals, using the generated digital quadrature components, for each k-th group, three pairs of digital quadrature components xI _{n, k, i, j} and xQ _{n, k are formed , i, j} corresponding to the i-th components of the transmitted n-th radio signals, in accordance with vii with expressions

Where

- respectively, either the frequencies obtained from the mentioned frequencies F _{n, k, i} by shifting to the local oscillator frequency with the specified spectrum transfer, or frequencies equal to F _{n, k, i} otherwise, and

, where s is a given number, for the thus formed three pairs of digital quadrature components corresponding to the k-th groups of n-th radio signals, three pairs of digital quadrature components are formed by summing each of the obtained digital quadrature components of the corresponding pair in accordance with the expressions

,

, sequentially using the previously generated digital quadrature components form the parameters corresponding to the k-th groups of n-th transmitted radio signals

where a t a n2 (x, y) is equal to the angle (in radians) formed by the x-axis and the straight line containing the origin (0,0) and the point (x, y), in the range from -π to π, excluding (- π), and π is a known number equal to the ratio of the circumference to its diameter,

the parameters formed in this way determine the time delays dt _{n, k} in accordance with the expression

where sign (x) is equal to 0, if x = 0, equal to 1 if x> 0, and equal to - 1, if x <0, dt _{n, k are} corrected, excluding the mentioned time shifts, according to the time delays obtained in this way unambiguously, taking into account the speed of propagation of the radio signal c, the relative distances to the phase center of the object antenna from the indicated phase centers of the antennas of the stations D _n in the zone of unambiguous determination of the relative ranges equal to c / ΔF ₁ are determined with an accuracy determined by the harmonic vibration with the frequency ΔF ₂ .