RU172722U1 - A device for correcting the amplitude-phase distribution of a disclosed annular antenna array - Google Patents

Abstract

The utility model relates to the field of antenna technology and can be used in the development of antenna systems that are part of radio systems for various purposes, placed on moving objects. The device comprises a control unit for operating modes and synchronization, an asymmetric vibrator located in the center of the circle, a control signal generator, the control input of which is connected to the output of the control unit for operating and synchronization modes, the output of the control signal generator is connected to the input of an asymmetric vibrator. The antenna elements of the disclosed annular antenna array through signal converters are connected to the first inputs of the analog-to-digital signal processing unit. The second input of the analog-to-digital signal processing unit is connected to the output of the operating and synchronization mode control unit. The output of the weighting unit is connected to the third input of the analog-digital signal processing unit. The first output of the analog-to-digital signal processing unit is the output from which information is taken in the operating mode of the radio system in which the proposed correction device is used. The second output of the analog-digital signal processing unit is electrically connected to the first input of the geometry determination unit of the disclosed ring antenna array. The output of the geometry determination unit of the disclosed annular antenna array is connected to the first input of the array storage unit of radiation patterns. The output of the storage unit of the array of radiation patterns is electrically connected to the first input of the matrix forming unit (matrix and pseudo-inverse matrix). The output of the matrix forming unit is connected to the second input of the weighting unit. The second inputs of the geometry determination unit of the disclosed annular antenna array, the array storage array of the radiation patterns, the matrix generation unit are connected to the output of the operation and synchronization mode control unit. Management of operating modes and synchronization of the functioning of the device blocks is carried out using commands from the control unit of the operating modes and synchronization. The technical result consists in providing control of the position of the antenna elements when opening the annular antenna array and correcting its amplitude-phase distribution in violation of the geometry of the disclosed annular antenna array. 16 ill.

Description

The utility model relates to the field of antenna technology and can be used in the development of antenna systems that are part of radio systems for various purposes, placed on moving objects.

Antennas of such radio engineering systems basically have non-directional radiation patterns in the azimuthal plane in transmission mode and directional radiation patterns in reception mode. The requirements for electrodynamic parameters are fully met by ring antennas, widely used in stationary and mobile direction finders [1 - Rembovsky A.M., Ashikhmin A.V., Kozmin V.A. Radio monitoring - tasks, methods, tools / Ed. Rembowski A.M. - M .: Hot line - Telecom. 2010.S. 347-364].

Such antenna systems should allow the presence of two states: transport (while the carrier object is moving) and deployed (working) during the operation of the radio system. In addition, restrictions are placed on the time it takes for the antenna system to be transferred from the transportation to the operational state. Another important condition is the correction of the amplitude-phase distribution in case of emergency during deployment of the antenna.

Known antenna system with circular or sector scanning [2 - Pat. No. 2385518 (RF). Antenna system with circular or sector scanning / A.L. Umnov, I.S. Shishalov. IPC H01Q 3/44. Publ. December 10, 2009], including the active radiating element and the passive re-reflectors surrounding it with the included loads with complex controlled impedance, located in the near zone of the active radiating element. Passive reflectors are located in more than one tier, while the active radiating element is made in the form of an antenna with the possibility of energy distribution to these tiers.

The disadvantage of the antenna system is the restrictions on the use in mobile communication systems, radio direction finding and radio detection due to the lack of transportation status and the impossibility of correcting the amplitude-phase distribution in emergency situations.

Known antenna system of a multi-channel direction finder, made on the basis of the antenna array and omnidirectional antenna [3 - Pat. No. 2096797 (RF). Direction finding method and multichannel direction finder / A.M. Rembovsky, V.N. Kondrashchenko. IPC G01S 3/14, G01S 3/74. Publ. 11/20/1997]. Folding antenna array includes antenna elements located at the same distance from each other around the circumference and made of symmetrical vibrators, the maximums of the radiation patterns of which are oriented along the radii from the center. The hinged mounting of the antenna elements on the base of the block and the swinging traverses ensure the deployment of the antenna array. When deployed, the traverses rotate 90 ° and are fixed on the base of the block. An omnidirectional antenna is installed in the center of the circle on which the antenna elements are aligned with it.

The disadvantages of the known antenna system are the lack of its automated deployment, which increases the time to bring the antenna system into position, the lack of the ability to control the position of the antenna elements when deploying and correcting the amplitude-phase distribution in emergency situations.

Similar disadvantages have antenna systems described in [4 - Pat. No. 2144200 (Russian Federation). The method of direction finding of radio signals and multi-channel direction finder / A.V. Ashikhmin, A.D. Vinogradov, V.N. Kondrashchenko, A.M. Rembovsky. IPC G01S 3/14, G01S 3/74. Publ. 01/10/2000; 5 - Pat. No. 2201599 (RF). The method of direction finding of radio signals and direction finder for its implementation / A.V. Ashikhmin, A.D. Vinogradov, G.V. Litvinov, V.N. Kondrashchenko, A.M. Rembovsky. IPC G01S 3/14, G01S 3/74. Publ. 03/27/2003].

Known for a number of annular antenna arrays with a control system [6 - Pat. No. 2106649 (RF). A ring antenna array with a control system / Manuilov BD, Manuilov MB, Bogachev A.Yu. IPC G01R 29/10. Bull. 7, 1998; 7 - Patent No. 2112988 (RF). A ring antenna array with a control system / Manuilov BD, Manuilov MB, Bogachev A.Yu. Bull. 16, 1998] for element-wise or parallel monitoring of the operability of channels of annular antenna arrays, phased by the method of ring harmonics. These annular antenna arrays contain a first beam-forming matrix, the inputs of which are connected to the emitters of the antenna array, a second beam-forming matrix, the outputs of which are connected to the signal inputs of the microwave switch, the output of which is in turn connected to the input of the receiver, the command device, the output of which is connected to the control input Microwave switch, as well as the source of the control signal, consisting of a control signal generator and an auxiliary antenna. As a diagram-forming matrix, matrices of parallel type (Butler matrices) or sequential type (Blass matrices) can be used.

The disadvantages of these devices is the lack of correction of the amplitude-phase distribution in emergency situations.

The closest in technical essence and the achieved result (prototype) is a device for correcting the amplitude-phase distribution of the antenna array by the method of calibrating the antenna array [8 - Pat. No. 2147753 (Russian Federation). Antenna array calibration method / Björn Gunnar Johanisson (SE), Ulf Forssen (SE). IPC G01S 7/40, H01Q 3/36. Publ. 04/20/2000] used in a mobile radio system for transmission and reception. The device for correcting the amplitude-phase distribution of the antenna array used in a mobile radio communication system for reception, in which the antenna array consists of several antenna sections, includes devices for generating an input signal (a generator generating control signals), devices for supplying said input signal to each antenna section (calibration scheme with directional couplers installed between each antenna element and low-noise amplifier), signal measuring devices at the output of each antenna section (analog-to-digital signal processing unit), devices for generating correction signals from each antenna section by comparing the supplied signal and the aforementioned measured signals (measuring unit and generating correction signals), devices for adjusting the aforementioned antenna sections using correction coefficients (block for generating weight coefficients), and the output signal of the antenna is regulated by adding correction factors to blow antenna section digitally.

The main disadvantage of the above device is the need to change the antenna array due to the introduction of directional couplers and the lack of full control of the antenna array channels, including antenna elements.

The objective of the present utility model is to develop a device for correcting the amplitude-phase distribution of the disclosed ring antenna array, which provides control of the position of the antenna elements during automatic opening of the ring antenna array and corrects the amplitude-phase distribution in case of violation of the geometry of the antenna array when the antenna is deployed.

To solve this problem, a correction device for the amplitude-phase distribution of the disclosed annular antenna array is proposed, the antenna elements of which are made of symmetrical vibrators located around the circle, consisting of a control unit for operating and synchronization modes, an asymmetric vibrator located in the center of the circle, a control signal generator, an input control which is connected to the output of the control unit of the operating modes and synchronization, the output of the control signal generator is connected to about the input of an asymmetric vibrator, signal converters, to the inputs of which are connected the antenna elements of the disclosed ring antenna array, an analog-to-digital signal processing unit, the first inputs of which are connected to the outputs of the signal converters, the second input of the analog-digital signal processing unit is connected to the output of the operating mode control unit and synchronization, the first output of the analog-to-digital signal processing unit is the output from which information is taken in the operating mode of the radio systems , Which uses the proposed correction apparatus of weight factor, the first input of which is connected to the output operation mode control unit and the synchronization unit forming the output weighting coefficients are electrically connected to the third input of the analog-to-digital signal processing unit.

According to the utility model, a block for determining the geometry of the disclosed ring antenna array, a block for storing arrays of radiation patterns, and a block for generating matrices (a matrix and a pseudo-inverse matrix) are introduced. The first input of the geometry determination unit of the disclosed ring antenna array is electrically connected to the second output of the analog-to-digital signal processing unit. The output of the geometry determination unit of the disclosed annular antenna array is connected to the first input of the array array storage unit; the output of the array array storage unit is electrically connected to the first input of the matrix forming unit. The output of the matrix forming unit is connected to the second input of the weighting unit. The second inputs of the geometry determination unit of the disclosed annular antenna array, the array storage array of the radiation patterns, the matrix generation unit are connected to the output of the operation and synchronization mode control unit.

Comparative analysis with the prototype shows that the claimed device is different in that:

- new elements have been introduced (a block for determining the geometry of a disclosed ring antenna array, a block for storing arrays of radiation patterns, and a block for forming matrices);

- communications have been changed: the first input of the geometry determination unit of the disclosed ring antenna array is connected to the second output of the analog-digital signal processing unit, the output of the matrix formation unit is connected to the second input of the weighting coefficient formation unit;

- communications were introduced: the output of the geometry determination unit of the disclosed annular antenna array is connected to the first input of the array array storage unit; the output of the array array storage unit is electrically connected to the first input of the matrix forming unit.

The technical result of the proposed device for correcting the amplitude-phase distribution of the disclosed annular antenna array is to control the position of the antenna elements when opening the annular antenna array and to correct its amplitude-phase distribution in violation of the geometry of the disclosed annular antenna array.

The combination of distinctive features and properties of the proposed device for the correction of the amplitude-phase distribution of the disclosed annular antenna array from the available literature is not known, therefore, the claimed device meets the criterion of "novelty."

An analysis of the known technical solutions (analogues) in the study area and adjacent to it allows us to conclude that the introduced and changed elements and their relationships in the indicated aggregate are unknown. Introduction of new elements (a block for determining the geometry of a disclosed annular antenna array, a storage unit for arrays of radiation patterns and a block for generating matrices), the elimination of elements (directional couplers) and connections (between the transmitter, the calibration circuit, and directional couplers), change of connections (analog-to-digital processing unit signals, a block for generating weight coefficients) and the introduction of new connections (the output of the block for determining the geometry of the ring antenna array is connected to the input of the array storage unit radiation patterns, the output of the storage block of arrays of radiation patterns is electrically connected to the input of the matrix forming unit) provides a new property - control of the position of the antenna elements during automatic opening of the annular antenna array and correction of its amplitude-phase distribution in case of violation of the geometry of the disclosed ring antenna array.

The essence of the utility model and the achieved technical result is illustrated by figures 1-16.

The figure 1 presents a structural diagram of a device for correcting the amplitude-phase distribution of the disclosed annular antenna array.

The figure 2 shows the characteristic dependence of the received antenna elements of the signal from the opening angle.

In figures 3, 4, two possible variants of the geometry of the annular antenna array are shown with incomplete disclosure of one antenna element and two antenna elements, respectively.

Figures 5-8 show radiation patterns in the case of incomplete disclosure of one antenna element in the absence and during correction of the amplitude-phase distribution in the disclosed annular antenna array.

Figures 9-16 show radiation patterns in the case of incomplete disclosure of two antenna elements in the absence and during correction of the amplitude-phase distribution in the disclosed annular antenna array.

A device for correcting the amplitude-phase distribution of the disclosed annular antenna array (figure 1), the antenna elements (AE) 1 ₁ -1 _{N of} which are made of symmetric vibrators, contains a control unit for operating and synchronization modes (BURS) 2, an asymmetric vibrator (HB) 3, located in the center of the circle, the control signal generator (GCS) 4, the control input of which is connected to the output of the BURS 2, the output of the GCS 4 is connected to the input of the HB 3, signal converters (PS) 5 ₁ -5 _N , the inputs of which are connected AE 1 ₁ - 1 _N Open Ring Antenna grating (CAR), an analog-to-digital signal processing unit (BOC) 6, the first inputs of which are connected to the outputs of the PS 5 ₁ -5 _N , the second input of the BOC 6 is connected to the output of the BURS 2, the unit for determining the geometry of the disclosed ring antenna array (GOD) 7 , the first input of which is connected to the second output of BOS 6, a storage unit for array of radiation patterns (BHM) 8, the first input of which is electrically connected to the output of BOG 7, and the output to the first input of the matrix forming unit (BFM) 9, weight generating unit ( BFVK) 10, the first input of which is connected to you BURS 2, the second input to the output of the BFM 9, and the output of the BFVK 10 is electrically connected to the third input of the BOS 6. The second inputs of BOG 7, BHM 8 and BFM 9 are connected to the input of BURS 2.

Specified in figure 1, the first output of the analog-to-digital signal processing unit 6 is the output from which information is removed in the operating mode of the radio system in which the proposed correction device is used.

Consider the operation of the device for the correction of the amplitude-phase distribution of the disclosed CAR.

In the control mode of the AE 1 ₁ -1 _N disclosure, by the BURS 2 command, the GCS 4 is turned on and the signals generated by it are transmitted through the HB 3 into free space and received by the AE (symmetric vibrators) 1 ₁ -1 _N. The received signals are reduced in frequency with the help of PS 5 ₁ -5 _N and fed to the first inputs of the BOC 6. There are two possible signal processing: parallel processing and serial processing. In the first case, a buffer storage device is installed at the outputs of the BOS 6, into which the digitized signals corresponding to the received AE 1 ₁ -1 _N signals (transmission coefficients) are recorded. These signals from the second output of BOS 6 are fed to the first input of GOD 7, where the geometry of the position of the antenna elements is determined by comparing the signals received with the reference signals.

Reference signals are determined at the stage of development of the disclosed CAR and correspond to the signal levels at the outputs of the antenna elements at different opening angles of the antenna elements (symmetric vibrators). These signals are recorded in GOD 7 in the form of dependences of the signal level on the opening angle of AE 1 ₁ -1 _N.

Based on the information obtained on the geometry of the CAR, which arrives at the first input of the BHM 8, arrays of radiation patterns of the antenna elements corresponding to the geometry of the disclosure of the CAR are selected. These arrays are fed to the first input of the BFM 9, in which the direct and inverse matrices of the coefficients are formed and a new amplitude-phase distribution (AFR) is calculated, which ensures the minimum deviation of the formed pattern from the pattern obtained during regular disclosure (regular disclosure refers to the state of a functioning KAR at its full disclosure).

Information about the new AFR is fed to the second input of BFVK 10. In BFVK 10, signals corresponding to the new weighting factors are generated.

The control actions corresponding to the found new AFR are fed to the third (control) input of the biofeedback unit 6, ensuring the formation of DN during abnormal deployment of AE 1 ₁ -1 _N , close to the given DN, corresponding to the DN of a functioning CAR (DN in the normal mode).

Let us conduct a theoretical justification of the operability of the proposed device for correcting the amplitude-phase distribution of the disclosed annular antenna array.

The radiation pattern of a CAR with a digital beam-forming device (DOW) can be represented as follows:

,

,

where xn , yn are the coordinates of the centers of the antenna elements of the CAR after deployment;

- ДН n-го антенного элемента; n=1,…,N.B _n - the complex weighting factors with which the signals of the antenna elements of the CAR are summed in the digital DOW;

- DN of the n- th antenna element; n = 1, ..., N.

After the deployment of the CAR, the position of the antenna elements is determined by measuring the transmission coefficients from the radiating element to the receiving ones and comparing the obtained values with those measured during ground tests for different aperture angles of the antenna elements. This allows you to determine the geometric position of the emitters (coordinates xn , yn , n = 1, ..., N).

From the block of storage of arrays, the arrays of DN antenna elements are selected, corresponding to the position of the antenna elements after the disclosure of the CAR.

Using the obtained data on the geometry of the CAR, after deployment, a matrix of coefficients is formed to find the required weight coefficients corresponding to the geometry of the deployed CAR

,

,

- ДН n-го антенного элемента в направлении

,

; Z - число направлений,Where

- DN of the n- th antenna element in the direction

,

; Z is the number of directions

in which according to [9 - Zelkin EG, Sokolov V.G. Antenna synthesis methods. Phased arrays and antennas with continuous opening. M. Sov. radio. 1980. 296 p.] Imposes a requirement for coincidence of a given (DN in the normal mode) and the formed DN. As a given NAM (NAM in the normal mode), NAM is used, formed during the regular disclosure of the CAR.

A new AFR B is calculated, which allows minimizing in the event of a deviation of the CAR geometry after deployment from a standard change in MD in the rms sense

,

,

where B is a vector of dimension N × 1, whose elements are signals at the outputs of the antenna elements;

α is the regularization coefficient, the choice of which determines a compromise between the difference between the given and the formed pattern and the smoothness of the obtained AFR;

E is the identity matrix of dimension N × N;

+ - determines the operation of Hermitian pairing;

. F ₀ - a vector of dimension Z × 1, the elements of which are the values of the given pattern in the directions

.

Signals are generated to set new weighting factors in the digital DOW, which minimize the change in the bottom line of the CAR caused by the abnormal deployment of antenna elements.

To assess the achieved technical result, we considered the case of an eight-element CAR with a radius of 0.73 λ ( λ is the working wavelength), which forms a beam with a beam width of 45 ° and a level of side lobes below minus 15 dB.

The characteristic of the dependence of the signal level at the output of each AE (transmission coefficient η ) is determined, as described above, at the stage of testing the disclosed CAR in the radio system. The obtained measurement results are stored and used to control the disclosure of the antenna elements after the transfer of the CAR to the working position. A typical form of the dependence of η on the opening angle α , obtained by calculation, is shown in figure 2. Curve 1 shows the dependence of the signal level in the control system when one AE is not opened correctly, curve 2 shows the signal level at the AE output when the same and neighboring AE are not opened correctly, curve 3 - dependence η for the average AE with improper disclosure of the AE itself and two neighboring (on both sides). The opening angle α is measured from the axis of the CAR. These graphs show the existence of a unique relationship between the opening angle of the controlled AE and the magnitude of the transmission coefficient, which allows us to refine the geometry of the CAR after opening.

When conducting research, the most practical cases were considered of preserving the shape of the synthesized MD during incomplete disclosure of one or two emitters, examples of which are shown in figure 3 with incomplete disclosure of one AE, in figure 4 - with incomplete disclosure of two AE.

The research results for the considered CAR in the case of incomplete disclosure of one (first) element are shown in figures 5-8. The choice of the noted case is characterized by the fact that the angular position of this element coincides with the direction of the main maximum of the SS CAR and, accordingly, its contribution to the formed CS is the largest. With this in mind, the incomplete disclosure of such an AE leads to the greatest distortion of the AF CAR. Figure 5 shows the MD with a completely undisclosed first AE, Figure 6 - with the AE opening at 15 °, Figure 7 - with the AE opening at 30 °, and Figure 8 - with the AE opening at 45 °.

In figures 5-8 and onwards, the DNs are shown with full disclosure (solid line); incomplete disclosure with AFR correction (dashed line); incomplete disclosure without AFR correction (dotted line).

The results show that, in the absence of AFR correction, there is a complete destruction of the AF of the CAR, including the displacement of the main maximum of the AF. At the same time, the performed AFR correction in accordance with the proposed algorithm makes it possible to almost completely preserve the parameters of the formed pattern.

Let us analyze the analysis of AF of the CAR with incomplete disclosure of two AEs. In the first case, we consider two neighboring (first and second) AEs, one of which is not fully disclosed, and the second opens at an angle of 15 °, 30 °, 45 °, and 60 °. The research results are presented in figures 9-12, respectively. The case in which both emitters are not opened, leads to the complete destruction of the beam. However, even in the case of the opening of the second AE at an angle of only 15 °, DN distortions arise that do not allow providing radio navigation parameters with a given accuracy. First of all, this refers to the measurement of angular coordinates, since the resulting narrowing of the main beam of the beam leads to a distortion of the direction-finding characteristic of the antenna. For the opening angles of the second AE greater than 30 °, distortions of the main beam do not occur, and the level change of the side lobes of the DN does not exceed 3 dB.

In figures 13-16 shows the patterns for the case of incomplete symmetrical disclosure of two elements of the CAR, lying on a straight line that defines the position of the main maximum of the patterns (first and fifth emitters). In this case, the ongoing AFR adjustment provides a more accurate preservation of the shape of the AF CAR, than with the incomplete disclosure of two neighboring AEs. The results obtained with other combinations of parameters of not fully disclosed elements slightly differ from the data in the above figures.

As follows from the above results, the dependence of the standard deviation of the CAR formed on regular and abnormal disclosure on the AE opening angle is not monotonic. However, when the opening angles are more than 30 °, the use of the proposed algorithm allows you to save the shape of the main lobe of the bottom of the car and the level of the side lobes. Thus, as shown by the results, even in the case of incomplete disclosure of the two elements, the use of the developed algorithm for the correction of AFR allows you to save the daylight of the CAR practically without change.

Implementation of the introduced blocks (the block for determining the geometry of the disclosed ring antenna array, the block for storing the arrays of radiation patterns and the block for forming matrices) is straightforward and can be done using the existing element base, in particular, programmable logic integrated circuits and digital signal processors that provide control functions , storage and data processing [10 - Antennas, 2005, no. 2 (93), p. 48-50; from. 64-75]. The necessary capabilities are possessed by the domestic signal controller 1892 BM3T [11 - Pletneva I.D. Implementation of control algorithms for adaptive antenna arrays based on a digital signal controller // Izv. universities. Electronics, 2009, No. 3, p. 61-67].

Thus, the technical result from the use of the claimed technical solution, in comparison with analogues and prototype, is to provide control of the position of the antenna elements when opening the annular antenna array and correcting its amplitude-phase distribution in violation of the geometry of the disclosed ring antenna array.

Claims (2)

A correction device for the amplitude-phase distribution of the disclosed annular antenna array, the antenna elements of which are made of symmetrical vibrators located around the circle, consisting of a control unit for operating and synchronization modes, an asymmetric vibrator located in the center of the circle, a control signal generator, the control input of which is connected to the output control unit operating modes and synchronization, the output of the control signal generator is connected to the input of the unbalanced vibrator, the conversion signal callers, to the inputs of which are connected the antenna elements of the disclosed ring antenna array, of an analog-to-digital signal processing unit, the first inputs of which are connected to the outputs of the signal converters, the second input of the analog-to-digital signal processing unit is connected to the output of the operating and synchronization mode control unit, the first output the analog-to-digital signal processing unit is the output from which information is taken in the operating mode of the radio system, the unit for generating weight coefficients the first input of which is connected to the output of the operating mode and synchronization mode control unit, the output of the weighting coefficient forming unit is connected to the third input of the analog-to-digital signal processing unit, characterized in that a geometry determination unit for the disclosed ring antenna array, a storage unit for radiation pattern arrays, and a unit are introduced the formation of matrices (matrix and pseudo-inverse matrix), the first input of the geometry determination unit of the disclosed ring antenna array is connected to the second output of analog-digital a new signal processing unit, the output of the geometry determination unit of the disclosed annular antenna array is connected to the first input of the array pattern storage unit, the output of the array pattern storage unit is connected to the first input of the unit matrix generation, the output of the matrix forming unit is connected to the second input of the weighting coefficient forming unit, the second inputs of the geometry determination unit of the disclosed ring antenna array, the array storage unit of radiation patterns, the matrix forming unit are connected to the output of the operating and synchronization mode control unit.

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