JP3038780B2 - Array antenna - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an array antenna having an array antenna aperture divided into a plurality of sub-arrays.

[Conventional technology]

FIG. 2 shows, for example, the AP-S International Simp
FIG. 3 is an explanatory view of an array antenna aperture of the conventional array antenna device shown in osium '86, where (1) is an element antenna,
(2) is a sub-array in which a plurality of element antennas (1) described later are grouped together.

Generally, in an array antenna device, when aiming to maximize the gain by directing a beam in a certain direction while suppressing the side lobe level to a certain fixed value or less, the phases and amplitudes of all the element antennas of the array antenna device are changed. Thus, the optimum directivity is synthesized. However, when the number of element antennas increases, it is difficult to provide a variable phase shifter and a variable amplitude unit for each element antenna and control the phases and amplitudes of all the element antennas. Therefore, as shown in the configuration diagram of the array antenna shown in FIG. 3, several element antennas (1) are grouped into a sub-array (2), and the aperture of the array antenna is configured in the array of the sub-array (2). A variable phase shifter (11) and a variable amplitude unit (12) are provided.
Directivity synthesis is performed by controlling the power supply phase and power supply amplitude.

In the conventional array antenna device, the array antenna aperture is configured by regularly arranging sub-arrays having the same number of equal-element antennas and the same shape, and forming a beam by controlling the feed phase and the feed amplitude of each of the sub-arrays. FIG. 2 shows an example in which the array antenna aperture is regularly divided into sub-arrays as described above.

FIG. 4 is an explanatory view showing an example of a conventional array antenna aperture in which sub-arrays having the same number of elements and the same shape are regularly arranged in a matrix, and 16 element antennas in the vertical direction and 18 element antennas in the horizontal direction. Are arranged in a square at an interval of 0.8λ (λ: wavelength), and the four corners are cut by three elements. Three sub-arrays are formed by grouping three element antennas in the horizontal direction, and the sub-array rows are divided into four sub-arrays at equal intervals in the vertical direction, and the total number of sub-arrays is 24.
Note that all element antennas are excited with the same phase and the same amplitude in one sub-array. In the figure, solid circles indicate the element antenna (1), crosses indicate the electrical center point of the subarray (2), (3) indicates a linear axis in a direction in which the number of divisions into the subarray (2) is small, and (4) indicates a subarray (2). )), The open circle is the orthographic point obtained by orthogonally projecting the electrical center point of the sub-array (2) onto the linear axis (3), and the triangle is the electrical axis of the sub-array (2). This is an orthogonal projection point obtained by orthogonally projecting the center point onto the linear axis (4). In this array antenna aperture, when the electrical center point of the sub-array (2) is orthogonally projected onto the linear axis (3) and the linear axis (4), four linear axes and three linear axes (4) are projected. Projection points are created. That is, when scanning the beam in the direction of the linear axis (3), four wave sources are equivalently on the linear axis (3), and when scanning the beam in the direction of the linear axis (4), the four wave sources are equivalent. ) Can be regarded as having six wave sources.

Next, the operation of the conventional array antenna device having the array antenna aperture regularly divided into sub-arrays as described above will be described.

A case will be described as an example where the array antenna device is installed in a geosynchronous orbit of a satellite and a beam is directed on the earth. 5 and 6 are views of the earth, and the beam irradiation area (service area) is indicated by hatching. In the figure, (A
1) and (A2) are the areas where the beam is directed, and (I1) and (I2) are the areas that must be at a level below a certain value compared to the beams directed to (A1) and (A2). A
1), the level difference between the area (A2) and the area (I1), the area (I2) is called isolation. Taking isolation is equivalent to reducing the sidelobe level.

In this case, the aperture of the array antenna shown in FIG. 4 is adjusted so that the linear axis (3) and the linear axis (4) match the linear axes (5) and (6) shown in FIGS. 5 and 6, respectively. And scan the beam in two directions. Here, the linear axis (3) and the linear axis (4) correspond to a straight line on the array antenna aperture formed by intersecting a plane formed by the beam irradiation direction and the boresight direction with the array antenna aperture. In addition, a circular microstrip antenna is used as the element antenna (1), and the power supply to each sub-array (2) is adjusted by a variable phase shifter and a variable amplitude device, provided that the frequency is 1.54 GHz and the isolation is 18 dB or more. By doing
FIG. 7 shows a simulation result when the gain is maximized in the area (A1) and the area (A2). As can be seen from FIG. 7, the gain is lower in the area (A1) than in the area (A2).

[Problems to be solved by the invention]

In the conventional array antenna device, the division of the sub-array in the array antenna aperture is configured as described above. As is apparent from the above description of the operation, the direction of the linear axis (3) having only four orthographic projection points is apparent. There is a problem that a large gain difference occurs when the beam is scanned in the direction of the linear axis (4) having six orthogonally projected points.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is possible to obtain a desired gain while maintaining a predetermined isolation in a direction in which gain is to be corrected without changing the number of sub-arrays in the array antenna aperture. It is an object of the present invention to provide an array antenna having an array antenna aperture divided into subarrays having a degree of freedom of change in phase and amplitude, and having a small difference in gain depending on a beam scanning direction.

[Means for solving the problem]

An array antenna aperture comprising a plurality of arrayed element antennas, wherein the plurality of element antennas are divided into a plurality of sub-arrays, and a variable phase shifter which is connected to each of the sub-arrays and sets a phase and an amplitude for each sub-array. An array antenna having a variable amplitude device and irradiating a beam in a plurality of directions. On at least one side of the array antenna aperture with respect to the axis, the sub-arrays are divided such that the orthogonally projected points on the linear axis by the electrical center point of each sub-array do not overlap.

[Action]

In the direction in which the gain of the array antenna configured as described above is desired to be corrected, the plane formed by the beam irradiation direction and the boresight direction for which the gain is to be corrected intersects the array antenna aperture with respect to a linear axis on the array antenna aperture. On at least one side of the array antenna aperture, the sub-arrays are divided so that the orthogonal projection points on the linear axis by the electrical center points of the respective sub-arrays do not all overlap. The degree of freedom in changing the phase and amplitude to obtain a desired gain while maintaining isolation is increased.

〔Example〕

FIG. 1 is an explanatory diagram showing an array antenna aperture of the array antenna of the present invention. In this embodiment, in order to clarify the comparison with the conventional example, 16 element antennas in the vertical direction and 18 element antennas in the horizontal direction have a spacing of 0.8λ (λ: wavelength ) Are arranged in a square, and the four corners are cut by three elements. Here, a case is shown in which the direction of the linear axis (3) is the direction in which the gain is to be corrected. In the direction of the linear axis (4), as in FIG. (S6) constitutes six subarray rows, but in the direction of the linear axis (3), six subarray rows (S3) and (S4), four subarray rows (S2) and (S5), The sub-arrays (S1) and (S6) are divided into two sub-arrays and the linear axis for gain correction (3)
On at least one side of the array antenna aperture,
This is an example in which the sub-arrays are divided so that the orthogonal projection points on the linear axis (3) by the electrical center points of the respective sub-arrays do not all overlap. However, the total number of sub-arrays is the same as in Fig. 4.
Individual. The configuration of the array antenna is the same as that shown in FIG. 3. A variable phase shifter (11) and a variable amplitude unit (12) are connected to the sub-array as shown in FIG.
In this way, the power supply is adjusted, and all the element antennas (1) are excited with the same phase and the same amplitude in one sub-array (2).

When the electrical center point of each sub-array of this array antenna is orthogonally projected on the linear axis (3), 12 orthogonally projected points are formed.
However, when orthogonal projection is performed on the linear axis (4), the number is six.
It is the same as the figure. Therefore, when scanning the beam in the direction of the linear axis (3), it can be regarded as equivalently that 12 wave sources are arranged in the direction of the linear axis (3), and when scanning the beam in the direction of the linear axis (4), Equivalently, it can be considered that six wave sources are arranged on the linear axis (4).

Next, the operation of this array antenna and a simulation result for comparison with the conventional example will be described.

The array antenna of FIG. 1 controls the phase and amplitude by adjusting the power supply to each sub-array (2) with a variable phase shifter (11) and a variable amplitude device (12), as in FIG.
Manipulate beam direction, gain and side lobe level. Next, simulation is performed under the same conditions as in the above-described conventional example. That is, a case where the array antenna of the present invention is installed in a geosynchronous orbit of a satellite to direct a beam on the earth will be described with reference to the earth diagrams shown in FIGS. 5 and 6. Also in this case, the aperture of the array antenna shown in FIG. 1 is adjusted so that the linear axis (3) and the linear axis (4) match the linear axes (5) and (6) shown in FIGS. 5 and 6, respectively. It shall be arranged and scan the beam in two directions. In addition, a circular microstrip antenna is used as the element antenna (1), and the condition that the frequency is 1.54 GHz and the isolation is 18 dB or more, and the power supply to each sub-array (2) is controlled by a variable phase shifter (1).
By adjusting with 1) and the variable amplitude unit (12), the area (A
1), maximize the gain in the area (A2).

The results of the above simulation are shown together with the results of the conventional example shown in FIG. As is clear from FIG. 7, in both the array antenna of the present invention and the conventional array antenna, when the beam is scanned in the direction of the linear axis (4), the maximum gain is almost the same between 25.89 dB and 25.83 dB. Absent.
However, when the beam is scanned in the direction of the linear axis (3), it is 24.84 dB for the array antenna of the present invention and 23.60 dB for the conventional array antenna, which is smaller than the case where the beam is scanned in the direction of the linear axis (4). In the array antenna of the present invention, the gain reduction is 0.99 dB, and in the conventional array antenna, the gain reduction is 2.29 dB.

From the above results, even if the total number of sub-arrays is the same, the present invention having 12 equivalent wave sources in the direction of the linear axis (3) is more effective than the conventional example having only four equivalent wave sources. When the beam is scanned while suppressing the side lobe level, the degree of freedom of the phase and amplitude changes is large so that the desired gain can be obtained while maintaining the isolation.
It is clear that the reduction in gain can be smaller. Further, in the above description, the simulation results were shown and verified in two directions, ie, the direction of the linear axis (3) and the direction of the linear axis (4).
Since a large number of orthogonal projection points can be obtained without overlapping in the intermediate direction between the direction and the linear axis (4), an array antenna with a small gain difference depending on the beam scanning direction can be obtained based on the above simulation results. It is clear that there is an effect that can be done.

In the above-described embodiment, an example is shown in which the sub-arrays are divided symmetrically with respect to the linear axis (3) in the direction in which the gain is to be corrected. However, the present invention is not limited to those having symmetry.

〔The invention's effect〕

As described above, according to the present invention, in an array antenna having an array antenna aperture composed of a plurality of sub-arrays, a plane formed by a beam irradiation direction for gain correction and a boresight direction intersects with the array antenna aperture. Since the sub-array is divided so that all the orthogonal projection points on the linear axis by the electrical center point of each sub-array do not overlap on at least one side on the array antenna aperture with respect to the linear axis on the array antenna aperture,
Since the number of orthogonal projection points can be increased and the degree of freedom of phase and amplitude changes to obtain a desired gain while maintaining a predetermined isolation is increased, an array antenna having a small gain difference depending on the beam scanning direction is used. There is an effect that can be obtained.

[Brief description of the drawings]

FIG. 1 is an explanatory view showing an array antenna opening of an array antenna of the present invention, FIG. 2 is an explanatory view of an array antenna opening of a conventional array antenna device, FIG. 3 is a configuration diagram showing a configuration of the array antenna, FIG. The figure is an explanatory view showing an example of a conventional array antenna aperture in which sub-arrays having the same number of elements and the same shape are regularly arranged in a matrix. FIGS. 5 and 6 are diagrams of the earth for explaining the operation of the array antenna. FIG. 7 is a diagram showing simulation results for the present invention and the conventional example. In the figure, (1) is an element antenna, (2) is a sub-array, (3) and (4) are linear axes, (5) and (6) are linear axes,
(11) is a variable phase shifter, and (12) is a variable amplitude shifter. In the drawings, the same reference numerals indicate the same or corresponding parts.

──────────────────────────────────────────────────続 き Continuation of the front page (72) Inventor Seiji Mano 5-1-1, Ofuna, Kamakura-shi, Kanagawa Prefecture, Electronic Systems Laboratory, Mitsubishi Electric Corporation (56) References JP-A-1-129509 (JP, A) Hikaru 1-156620 (JP, U) (58) Fields investigated (Int. Cl. ⁷ , DB name) H01Q 3/26-3/42 H01Q 21/00-21/30

Claims (1)

(57) [Claims] 1. An antenna comprising a plurality of element antennas arranged,
An array antenna aperture in which the plurality of element antennas are divided into a plurality of sub-arrays, and a variable phase shifter and a variable amplitude unit that are connected to each of the sub-arrays and set a phase and an amplitude for each sub-array; An array antenna that irradiates a beam on the array antenna aperture with respect to a linear axis on the array antenna aperture formed by intersecting the plane of the beam irradiation direction and the boresight direction for gain correction with the array antenna aperture An array antenna, wherein the sub-arrays are divided on at least one side so that all orthogonally projected points on the linear axis by the electrical center point of each sub-array do not overlap.