JP2002124817A - Phased-array antenna - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a phased-array antenna, the performance of which is not deteriorated by the deformation of the antenna itself. SOLUTION: When the phased-array antenna is deformed, the signal corresponding to the deformation is outputted to a strain detector by means of a piezoelectric element incorporated in the antenna and the strain detector detects the deformation of the antenna. The deformation is found as element coordinate errors on individual element antenna coordinates by means of an element coordinate error detector by interpolating the deformation with data based on the relative positional relation between the piezoelectric element and each element antenna. The element coordinate errors are imputed to a phase operator. An element coordinate correcting circuit 16 adds the coordinate errors to element coordinate data and inputs the sums to a phase shifting amount computing circuit set to each phase shifter. The computing circuit computes the phase shifting amount to be set to each phase shifter based on the corrected element coordinate data.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to correction of mechanical distortion of a phased array antenna.

[0002]

2. Description of the Related Art FIG. 4 shows a conventional phased array antenna, in which 1 is an element antenna, 2 is a phase shifter, 3 is a feeding circuit, 4 is a transmitter, 5 is a phase calculator, 6
Denotes element coordinate data held in the phase calculator 5, 7 denotes a phase calculation circuit in the phase calculator 5, and 8 denotes a beam controller for instructing a beam directing direction.

[0003] The operation of the phased array antenna will be described below. Since the antenna is reciprocal, the case where the antenna is transmitting will be described. The signal generated by the transmitter 4 is input to the power supply circuit 3, distributed by the power supply circuit 3, and input to the phase shifter 2. The phase of the signal input to the phase shifter 2 is changed by the phase shift amount calculated by the phase calculator 5, and the signal is radiated from the element antenna 1 to space.

The phase shift amount へ set in the phase shifter 2 is calculated by the phase calculation circuit 7 in the phase calculator 5 from the beam direction information from the beam controller 8 and the element coordinate data 6 according to equation 1. Is done. In Equation 1, (x, y, z) is the three-dimensional coordinate (θ, φ) of the element antenna 1 is beam pointing information in a polar coordinate system.

[0005]

(Equation 1)

FIG. 5 is a diagram showing how the phased array antenna is attached. In the figure, 9 is an antenna frame, 10 is a structure for mounting an antenna, and 11 is a fastening screw. On the other hand, when installing on a relatively soft structure such as a vehicle or an aircraft by the method shown in FIG. 5, the attached structure itself may be deformed. In this case, deformation of the structure causes deformation of the antenna itself. FIG.
It is a figure which shows the force applied to an antenna, and the modification of the antenna accompanying it. In the figure, 12 is a force for distorting the antenna, 1 'is the position of the element antenna due to deformation as an antenna, and 9' is a deformed antenna frame. As a result of the deformation of the antenna, a deviation occurs between the element coordinate data used for the phase shift amount calculation and the element coordinate data when the antenna itself is deformed, as shown in FIG. 6, and the antenna performance is deteriorated.

[0007]

The conventional phased array antenna has a problem that the antenna performance is deteriorated due to a physical change of element coordinates due to deformation of the antenna itself.

The present invention has been made to solve the above-described problems, and is configured to prevent the antenna performance from deteriorating due to deformation of the antenna itself.

[0009]

According to a first aspect of the present invention, there is provided a phased array antenna comprising: a plurality of element antennas; a phase shifter connected to the element antenna; a power supply circuit for supplying power to the plurality of phase shifters; A phase calculator for calculating a phase shift amount set for forming a desired beam in the phase shifter, a phased array antenna provided on the antenna surface and outputting a signal in accordance with the distortion amount of the antenna surface A signal output element, a distortion detection device that detects a distortion amount based on a signal from the signal output element, an element coordinate error detector that determines a shift amount of the element antenna coordinates from the distortion amount, and the element coordinate error detection. And an element coordinate correction circuit for correcting the element antenna coordinate shift obtained by the detector.

A phased array antenna according to a second aspect of the present invention uses a ぇ piezoelectric element as the signal output element.

A phased array antenna according to a third aspect of the present invention is a phased array antenna, comprising: a plurality of element antennas; a phase shifter connected to the element antenna; a power supply circuit for supplying power to the plurality of phase shifters; In a phased array antenna comprising a phase calculator for calculating a phase shift amount set to form a beam, a pickup antenna arranged on an antenna surface for receiving a radiation signal from the element antenna, and the pickup antenna And a phase difference calculator for calculating a phase difference between the reference phase measured in a state where the antenna is not distorted therein and the reference phase and the phase measured by the phase receiver. A phase difference detector comprising a circuit and a correction phase calculation circuit for obtaining a phase difference of the element antenna from the phase difference; It is obtained; and a phase correction circuit for correcting the phase difference obtained by the adder.

[0012]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiment 1 FIG. 1 shows a first embodiment of the present invention, in which 1 is an element antenna, 2 is a phase shifter, 3 is a power supply circuit, 4 is a transmitter, 5 is a phase calculator, and 6 is a phase calculator 5 , 7 is a phase calculation circuit in the phase calculator 5, 8 is a beam controller for designating a beam directing direction, 13 is a piezoelectric element embedded in an antenna, and 14 is a piezoelectric element embedded in the antenna. A distortion detecting device 15 for detecting the amount of distortion based on the electric signal. Reference numeral 15 denotes an element coordinate error detector for obtaining a deviation of element antenna coordinates from antenna distortion data detected by the distortion detecting device 14.
Reference numeral 6 denotes an element coordinate correction circuit in the phase calculator 5.

FIG. 2 is a view showing an example of embedding the piezoelectric element 9. In the figure, reference numeral 17 denotes a main structural member having sufficient strength and rigidity in an airframe or the like, and the piezoelectric element 13 needs to measure three-dimensional distortion applied to the antenna.
It is attached to the gap between the main structural member 17 and the antenna structure or the antenna attachment portion in three axial directions of XYZ. 13a is a piezoelectric element for detecting a shift in the X direction,
b denotes a piezoelectric element for detecting a shift in the Y direction, and 13c denotes a piezoelectric element for detecting a shift in the Z direction.

Hereinafter, the operation of the phased array antenna will be described. Since the antenna is reciprocal, the case where the antenna is transmitting will be described. Transmitter 4
Are input to the power supply circuit 3, distributed by the power supply circuit 3, and input to the phase shifter 2. The signal input to the phase shifter 2 changes its phase by the phase shift amount calculated by the phase calculator 5 and is radiated from the element antenna 1 to space.

Next, when this phased array antenna is installed on a relatively soft structure such as a vehicle or an aircraft,
The attached structure itself may be deformed. In this case, deformation of the structure causes deformation of the antenna itself.
An example of the modification is as shown in FIG.

When the antenna is deformed, an electric signal corresponding to the amount of deformation is output by the piezoelectric element 9 built in the antenna. As an example, a case of deformation in the XY plane shown in FIG. 6B will be described. In this case, strain is applied to the piezoelectric elements 13a and 13b, and an electric signal corresponding to the amount of strain is output from the piezoelectric elements 13a and 13b. Also,
In the modification shown in FIG. 6C, an electric signal corresponding to the amount of distortion is output from the piezoelectric element 13c in the Z direction.
This electric signal is transmitted to the piezoelectric element 13 by the strain detecting device 14.
It is obtained as the amount of distortion at the installation location.

The amount of deformation of the antenna detected by the distortion detecting device 14 is input to an element coordinate error detecting device 15, and the data is stored in the element coordinate error detecting device 15 based on the relative positional relationship between the piezoelectric element 13 and each element antenna 1. It is interpolated and obtained as a deviation of element coordinates at the coordinates of each element antenna. The deviation of the element coordinates is obtained by Expression 2. Here, (X (i), Y (i), Z (I)) represent the coordinates of the element antenna i,
(Xa (j), Ya (j), Za (j)) represents the coordinates of the piezoelectric element 13a by (ΔXa
(j), ΔYa (j), ΔZa (j)) are the shift amounts of the position of each piezoelectric element 13a, and (Xb (j), Yb (j), Zb (j)) are the coordinates of the piezoelectric element 13b. To
(ΔXb (j), ΔYb (j), ΔZb (j)) are the shift amounts of the positions of the piezoelectric elements 13b, and (Xc (j), Yc (j), Zc (j)) are the piezoelectric elements 13c. Is the coordinates of (ΔXc (j), ΔYc (j), ΔZc (j)), and the deviation of the position of each piezoelectric element 13c is (ΔX (i), ΔY (i), ΔZ (i)). 6 shows an element coordinate error of an element antenna i. When j = 1 in the piezoelectric element 13c, it indicates that the element is a piezoelectric element in the Z direction arranged at the center of the antenna.

[0018]

(Equation 2)

Next, the element coordinate error obtained by the element coordinate error detecting device 15 is input to the phase calculator 5, and the element coordinate data 6 held inside the phase calculator 5 and the element coordinate correction circuit 16 And is input to a phase shift amount calculation circuit 7 set in each phase shifter.

The phase shift amount calculating circuit 7 calculates the phase shift amount to be set in each phase shifter 2 based on the corrected element coordinate data according to Equation 1 as in the case of the conventional phased array antenna.

At this time, since the element coordinate data used for the phase calculation is a value taking into account the amount of deformation of the antenna, desired antenna characteristics can be obtained.

Here, the phase calculator 5, the phase calculator 7,
The same functions of the distortion detecting device 14, the element coordinate error detector 15, and the element coordinate correction circuit 16 may be realized by software.

Embodiment 2 FIG. FIG. 3 shows a second embodiment of the present invention, in which 1, 2, 3, 4, 5,.
6, 7, and 8 are the same as those in FIG. 1, 18 is a pickup antenna embedded in the antenna, 19 is a phase receiver for receiving a signal from the pickup antenna 18, and 20 is measured by the phase receiver 19. A phase difference detector for calculating a phase correction amount to be set in each phase shifter 2 from the phase data obtained, and a phase difference detector 20 in the phase calculator 5
This is a phase correction circuit that adds the input phase difference and the phase shift amount calculated by the phase shift amount calculation circuit 7. Further, the phase difference detector 20 includes a reference phase 21 obtained in a state where the antenna is not deformed, the reference phase 21 and the phase receiver 1.
Phase difference detection circuit 2 for calculating the difference from the phase data obtained by step 9
Two. Since the pickup antenna 18 transmits and receives radio waves due to inter-element coupling with each of the element antennas 1, the pickup antenna 18 is arranged so as to have inter-element coupling such that a measured signal has a level sufficiently higher than a measurable level. .

The operation will be described below. The operation in which the signal generated by the transmitter 4 is radiated into the space from the element antenna 1 is the same as in the first embodiment.

The pickup antenna 18 built in the antenna receives the signal radiated from each element antenna 1 and sends it to the phase receiver 19. And the phase receiver 19
Is input to the phase difference detector 20.

When the antenna is deformed, the relative coordinates between each element antenna 1 and the pickup antenna 18 are shifted. As a result, the propagation distance of the signal propagating due to the coupling between the elements changes, and the phase of the signal received by the pickup antenna 18 changes.

The phase difference detector 20 holds a reference phase 21 acquired in a state where the antenna is not deformed. The difference data from the phase data at the time of antenna deformation inputted from the phase receiver 19 is stored in the phase difference detector 20. It is calculated by the phase difference detection circuit 22. The calculation of the difference data is obtained by Expression 3. Here, Δφ (i) is difference data of the element antenna i,
φ (i) is the measured phase data of element antenna i, φ
₀ (i) is reference phase data of the element antenna i.

[0028]

(Equation 3)

The phase difference data obtained by the phase difference detector 20 is input to the phase calculator 5, and the phase shift amount calculated by the phase calculator 11 in the phase calculator 5 and the phase shifter 23 After the addition, it is set in each phase shifter 2.

Here, the same functions of the phase difference detector 20, the phase difference detection circuit 22, and the phase correction circuit 23 may be realized by software.

Further, the phased array antennas in the first and second embodiments may be not only flat but also curved.

[0032]

According to the present invention, it is possible to obtain the desired antenna performance even when the antenna is deformed.

Further, according to the present invention, it is possible to directly measure and correct the influence of radio waves due to antenna deformation.

[Brief description of the drawings]

FIG. 1 is a diagram showing Embodiment 1 of a phased array antenna according to the present invention.

FIG. 2 is a diagram showing an arrangement example of a piezoelectric element according to the first embodiment of the phased array antenna according to the present invention.

FIG. 3 is a diagram showing Embodiment 2 of a phased array antenna according to the present invention.

FIG. 4 is a diagram showing a conventional phased array antenna.

FIG. 5 is a diagram showing an example of mounting an antenna.

FIG. 6 is a diagram illustrating an example of antenna distortion due to a force applied to the antenna.

[Explanation of symbols]

1 element antenna, 2 phase shifter, 3 feeding circuit, 4 transmitter, 5 phase calculator, 7 phase shift calculator, 8 beam controller, 9 antenna frame, 10 structure,
12 fastening screw, 13 piezoelectric element, 14 distortion detecting device, 15 element coordinate error detector, 16 element coordinate correction circuit, 17 structural member, 18 pickup antenna,
19 phase receiver, 20 phase difference detector, 22 phase difference detection circuit, 23 phase correction circuit.

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) H04B 7/08 H04B 7/08 D 7/10 7/10 A F term (Reference) 5J021 AA05 AA09 CA06 DB02 DB03 EA04 FA14 FA15 FA16 FA17 FA20 FA32 GA02 HA04 HA05 HA10 5J047 AA02 AA10 AB03 BG10 5J070 AD10 AF03 AF06 AK04 AK32 5K059 CC03 CC04 DD31 5K060 AA12 CC04 CC19 KK03 KK06 PP05

Claims (3)

[Claims] 1. A plurality of element antennas, a phase shifter connected to the element antenna, a power supply circuit for feeding power to the plurality of phase shifters, and a setting for forming a desired beam in the phase shifter A phased array antenna having a phase calculator for calculating the amount of phase shift to be performed, a signal output element disposed on the antenna surface and outputting a signal in accordance with the distortion amount of the antenna surface, and a signal from the signal output element A distortion detecting device for detecting the amount of distortion by the method, an element coordinate error detector for calculating the deviation of the element antenna coordinates from the distortion amount, and correcting the element antenna coordinate deviation obtained by the element coordinate error detector A phased array antenna, comprising: 2. The phased array antenna according to claim 1, wherein said signal output element is a piezoelectric element. 3. A plurality of element antennas, a phase shifter connected to the element antenna, a power supply circuit for supplying power to the plurality of phase shifters, and a setting for forming a desired beam in the phase shifter. A phased array antenna having a phase calculator for calculating the amount of phase shift to be performed, a pickup antenna disposed on the antenna surface for receiving a radiation signal from the element antenna, and measuring a signal from the pickup antenna A phase receiver, a reference phase measured in a state where the antenna is not distorted therein, a phase difference calculation circuit for calculating a phase difference between the reference phase and a phase measured by the phase receiver, and the phase difference And a phase difference detector for correcting the phase difference obtained by the correction phase calculator. A phased array antenna comprising a positive circuit.