JP2003152440A - Array antenna - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain an array antenna comprising element antennas arranged on concentric circles to exhibit such radiation characteristics as the main beam is directed to a desired angular direction over a wide band when it is directed to the desired angular direction to reduce the side lobe level. SOLUTION: In a concentric circular arrangement array antenna where a plurality of element antennas having a maximum outer element dimension of D are arranged on M concentric circles on a plane, n1 element antennas are arranged at a constant interval on the first concentric circle, radius rm of the m-th concentric circle is calculated using D2 not smaller than the maximum outer element dimension D, and maximum integer of element antennas satisfying a specified formula are arranged on the concentric circle thus calculated.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an array antenna formed by arranging a plurality of element antennas used for radar or communication, and has a broad band and improved radiation characteristics of array antennas arranged concentrically. The present invention relates to an effective array antenna.

[0002]

2. Description of the Related Art FIG. 4 is an element array diagram of a conventional M-circular concentric array antenna. 1 is an element antenna, 2
Is a concentric circle on the first round, 3 is a concentric circle on the second round, 4 is a concentric circle on the third round, 5 is a concentric circle on the mth round, 6 is a concentric circle radius r _{1 on the} first round, and 7 is a concentric circle radius on the second round r ₂ and 8 are concentric circle radii r _{3 on the} third round, and 9 is a concentric circle radius r _m on the mth round.

Next, the operation will be described. Traditional array
The antenna is n on the circumference of the first concentric circle 2.₁Elements
Arrange the antennas 1 and arrange them on the circumference of the second concentric circle 3 (2
× n ₁) Element antennas 1 are arranged,
On the circumference of the center circle 5 (m × n₁) Arrange the element antennas 1
It is a line. At this time, the concentric radius 6 of the first round is r
₁, Then the radius r of the second concentric circle_Two(2 × r₁)
And the concentric radius r of the 3rd round_ThreeTo (3 × r₁), And m
The radius of the concentric circle on the circumference is (m × r_m).

In an array antenna composed of the element antennas 1 arranged in this way, when an equal phase wavefront is formed in a desired angle direction and an excitation amplitude phase for suppressing a side lobe level is set in each element antenna 1, Radiation characteristics are obtained with the main beam in the desired angle direction and sidelobe levels suppressed.

[0005]

In the conventional M-circle concentric circle array antenna, the element antennas are arranged with the concentric radius r _m of the m-th round being m times the concentric radius of the first round.
When the phase that is a phase condition for each element antenna 1 is set in order to direct the main beam in the desired angular direction, the side lobe rises due to the periodicity of concentric circle intervals and the periodic arrangement of element antennas 1 within the same concentric circle. As a result, the radiation characteristics are deteriorated. In particular, there is a problem that the side lobes are not suppressed to a desired level in a desired frequency band when the main beam is directed to an angle away from the front with a large concentric circle interval. Further, when a wide-band element antenna is used, the concentric circle spacing in a high frequency band becomes wider in terms of wavelength ratio, and the element spacing and the periodicity of the concentric circle spacing cause an increase in side lobes and deteriorate radiation characteristics. Therefore, there is a problem that a low side lobe characteristic over a wide band cannot be obtained.

The present invention has been made to solve the above-mentioned problems, and reduces the element spacing and the periodicity of the element array while keeping the concentric circle radial spacing at a constant spacing correlated with the element antenna diameter. It is an object of the present invention to obtain a radiation characteristic having a desired side lobe characteristic over a wide band of frequencies by constructing such an M-circular concentric array antenna.

[0007]

An array antenna according to a first aspect of the present invention is a concentric array antenna in which a plurality of element antennas having a maximum outer dimension element size D are arranged on a plane concentric circle of M circumferences. Let n _{1 be the} number of element antennas arranged at equal intervals on the concentric circle of
1, 2, ..., M), the concentric circle radius r _m is shown in the first embodiment by using D ₂ which is equal to or larger than the maximum external dimension D.
In which the number 7 arranged at equal intervals largest integer n _m pieces of antenna elements satisfying Equation 8 "" calculated by, as shown in the first the same Example coaxially circumference of the second round after which the calculated " is there.

An array antenna according to a second aspect of the invention is a concentric array antenna in which a plurality of element antennas having a maximum outer dimension element size D are arranged on a plane concentric circle of M circumferences. The number of element antennas arranged at intervals is an odd number n ₁ and the m-th round (m = 1, 2, ...
Maximum concentric radius r _m of the · M) by using the maximum external device dimension D or more D ₂ calculated in "Number 7", satisfies the "number 8" coaxially circumference subsequent second lap calculated above It is an array of odd-numbered _nm element antennas arranged at equal intervals.

An array antenna according to a third aspect of the present invention is a concentric array in which a plurality of element antennas having a maximum external element dimension D are calculated as coordinates on a plane concentric circle of M circumferences and the coordinates are projected on an arbitrary curved surface. In the array antenna, the number of element antennas arranged at equal intervals on the concentric circle on the first round is an odd number n ₁ , and the concentric circle radius r _m on the mth round (m = 1, 2, ... Calculated by "Equation 7" using D ₂ which is equal to or larger than the external element size D, and equidistantly the maximum odd _nm element antennas satisfying "Equation 8" are calculated on the concentric circles after the second round calculated above. The element antenna coordinates on the concentric circles to be arranged are calculated, and the element antennas are arranged at the coordinates obtained by projecting the calculated element antenna coordinates on an arbitrary curved surface.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiment 1. First Embodiment FIG. 1 is an element array diagram of an array antenna showing a first embodiment.
3, 4, 5, 6, 7, 8, and 9 are the same as the conventional array antenna.

Next, the operation will be described. Concentration on the first lap
Element elements of the maximum external element dimension D arranged at equal intervals on the circumference
Number of antennas is n₁To be individual. Above maximum external dimensions D
Of D _TwoConcentricity of the mth round (m = 1, 2, ... M) using
Circle radius r_mWas calculated by "Equation 7", and the calculated 2
Concentric radius r from the 1st round to the Mth round_mOn the circumference of the "number
Maximum integer n satisfying 8 "_mHas maximum external element size D
The element antennas 1 to be arranged are arranged at equal intervals.

[0012]

[Equation 7]

[0013]

[Equation 8]

This plurality of arrayed element antennas 1
Is given an excitation amplitude phase that forms the main beam in the desired angular direction and forms a low sidelobe beam such as a Taylor distribution. The combined radiation characteristic of the plurality of element antennas 1 excited by the above excitation amplitude phase is a radiation characteristic having a low side lobe characteristic in which the main beam is directed in a desired angular direction.

The excitation amplitude forming the low sidelobe beam has the same effect in any of the density distribution, the amplitude distribution, and the amplitude density distribution, and the radiation characteristic of the array antenna has the low sidelobe characteristic.

Even when the wide band element antennas are arranged, the element antennas are densely arranged from the central portion of the concentric circles by bringing D ₂ which determines the concentric circle spacing close to the maximum outline element dimension D, so that in the high frequency band. Also prevents the rise of side lobes and forms a radiation pattern having low side lobe characteristics over a wide band.

Further, by appropriately setting D ₂ which is set to be equal to or larger than the maximum external element size D, the array of the element antennas is taken into consideration in consideration of the external size variation of the element antennas, the size of the feeding circuit connected to the element antennas, and the like. It is possible to decide.

Embodiment 2. FIG. 2 is an element array diagram of the array antenna showing the second embodiment. In a concentric array array antenna in which a plurality of element antennas having a maximum external element size D are arrayed on a plane concentric circle of M circumference, The number of element antennas arranged at equal intervals on the concentric circle is an odd number n ₁ , and the concentric radius r _m of the m-th round (m = 1, 2, ... M) is equal to or larger than the maximum external element dimension D. ₂ is used to calculate the "numeral 7", and the maximum odd _nm element antennas satisfying the "numeral 8" are arranged at equal intervals on the concentric circles calculated from the second round onward. To do.

In this arrangement, the plurality of element antennas 1 are provided with excitation amplitude phases that form a main beam in a desired angular direction and a low sidelobe beam such as a Taylor distribution. The combined radiation characteristic of the plurality of element antennas 1 excited by the above excitation amplitude phase is a radiation characteristic having a low side lobe characteristic in which the main beam is directed in a desired angular direction. Also, by making the number of element antennas on the concentric circle an odd number, the randomness of the element arrangement on the cut plane passing through the center of the concentric circles increases, side lobe rise suppression, and even side lobe level beams during conical beam scanning are obtained. Can be formed.

The excitation amplitude forming the low sidelobe beam has the same effect in any of the density distribution, the amplitude distribution and the amplitude density distribution, and the radiation characteristic of the array antenna has the low sidelobe characteristic.

Even in the case of arranging wide band element antennas, the element antennas are densely arranged from the central portion of the concentric circles by bringing D ₂ which determines the concentric circle spacing close to the maximum outer shape element dimension D, so that in a high frequency band. Also prevents the rise of side lobes and forms a radiation pattern having low side lobe characteristics over a wide band.

Further, by appropriately setting D ₂ which is set to be equal to or larger than the maximum external element size D, the array of element antennas is taken into consideration in consideration of the external size variation of the element antenna, the size of the feeding circuit connected to the element antenna, and the like. It is possible to decide.

Embodiment 3. FIG. 3 is an element array diagram of an array antenna showing a third embodiment, in which a plurality of element antennas having a maximum outer shape element dimension D are used to calculate coordinates on a plane concentric circle of M circumference, and the calculated coordinates are arbitrarily set. In the array antenna of concentric circles projected on the curved surface of, the number of element antennas arranged at equal intervals on the concentric circle of the first round is an odd number n.
_The number of concentric circles r _m of the m-th round (m = 1, 2, ... M) is calculated by the above “Mathematical formula 7” using D ₂ which is equal to or larger than the maximum external element size D, and the above calculation is performed. The element antenna coordinates on a plane concentric circle in which the maximum odd number n _m element antennas satisfying the above "equation 8" are arranged at equal intervals on the concentric circles after the second round are calculated, and the calculated element antenna coordinates are calculated as follows. A case where element antennas are arranged at coordinates projected on an arbitrary curved surface will be described.

In this arrangement, a plurality of element antennas 1 arranged on an arbitrary curved surface form an excitation amplitude phase for forming a main beam in a desired angular direction and forming a low sidelobe beam such as Taylor distribution. To be The combined radiation characteristic of the plurality of element antennas 1 excited by the above excitation amplitude phase is a radiation characteristic having a low side lobe characteristic in which the main beam is directed in a desired angular direction. Also, by making the number of element antennas on the concentric circle an odd number, the randomness of the element arrangement on the cut plane passing through the center of the concentric circles increases, side lobe rise suppression, and even side lobe level beams during conical beam scanning are obtained. Can be formed.

The excitation amplitude forming the low sidelobe beam has the same effect in any of the density distribution, the amplitude distribution, and the amplitude density distribution, and the radiation characteristic of the array antenna formed on the arbitrary curved surface extends over a wide band. Has low sidelobe characteristics.

Even when the wide band element antennas are arranged, the element antennas are densely arranged from the central portion of the concentric circles by bringing D ₂ which determines the concentric circle spacing close to the maximum outer shape element dimension D, so that in the high frequency band. Also prevents the rise of side lobes and forms a radiation pattern having low side lobe characteristics over a wide band.

Further, by appropriately setting D ₂ which is set to be equal to or larger than the maximum external element size D, the array of element antennas is arranged in consideration of the external size variation of the element antenna, the size of the feeding circuit connected to the element antenna, and the like. It is possible to decide.

[0028]

According to the first aspect of the invention, the effect of suppressing the generation of high-level side lobes over a wide band can be obtained. Further, it is possible to obtain an effect that the design can be performed in consideration of the variation in the outer dimensions of the element antenna and the dimension of the power feeding circuit connected to the element antenna.

According to the second aspect of the invention, the effect of suppressing the generation of high-level side lobes over a wide band can be obtained. Further, the effect of forming a beam scanning low sidelobe beam that does not depend on the cut surface can be obtained. Further, it is possible to obtain an effect that the design can be performed in consideration of the variation in the outer dimensions of the element antenna and the dimension of the power feeding circuit connected to the element antenna.

According to the third aspect of the invention, the effect of suppressing the generation of high-level side lobes over a wide band can be obtained.
Further, the effect of configuring an array antenna having an arbitrary shape such as the surface of a body of an aircraft or the like can be obtained. Further, the effect of forming a beam scanning low sidelobe beam that does not depend on the cut surface can be obtained. Further, it is possible to obtain an effect that the design can be performed in consideration of the variation in the outer dimensions of the element antenna and the dimension of the power feeding circuit connected to the element antenna.

[Brief description of drawings]

FIG. 1 is an element array diagram of an array antenna showing a first embodiment of the present invention.

FIG. 2 is an element array diagram of an array antenna showing a second embodiment of the present invention.

FIG. 3 is an element array diagram of an array antenna showing a third embodiment of the present invention.

FIG. 4 is an element array diagram of a conventional array antenna.

[Explanation of symbols]

1 element antenna, 2 concentric circle on 1st round, 3 concentric circle on 2nd round, 4 concentric circle on 3rd round, 5 concentric circle on 5m round, 6
Concentric radius of the first round, 7 Concentric radius of the second round, 8
Concentric radius on the 3rd lap, Concentric radius on the 9th m, 10
Arbitrary curved surface.

Claims (3)

[Claims] 1. A concentric array antenna in which a plurality of element antennas having a maximum external element dimension D are arranged on a plane concentric circle of M circumferences, and the number of element antennas arranged at equal intervals on the first concentric circumference. Is n ₁ and the mth round (m
= 1, 2 ... M) using the concentric radius r _m of D ₂ which is equal to or larger than the maximum external element size D, and is given by Calculated on the concentric circle after the second round calculated above, Array antenna, characterized in that arranged at equal intervals largest integer n _m pieces of antenna elements satisfying. 2. A concentric array antenna in which a plurality of element antennas having a maximum external element dimension D are arranged on a plane concentric circle of M circumferences, and the number of element antennas arranged at equal intervals on the concentric circle of the first round. Is an odd number n ₁ and the concentric radius r _m of the m-th round (m = 1, 2 ... M) is expressed by the following formula using the D ₂ which is equal to or larger than the maximum external dimension D. Calculated on the concentric circles after the second lap calculated above, An array antenna characterized in that a maximum odd number of element antennas satisfying the _{above condition} are arranged at equal intervals. 3. A concentric array antenna in which the coordinates of a plurality of element antennas having the maximum outer shape element dimension D are calculated on a plane concentric circle of M circumferences and the coordinates are projected on an arbitrary curved surface in the first circumference. The number of element antennas arranged at equal intervals on the concentric circle is set to an odd number n ₁ , and the mth round (m = 1, 2.
Equation concentric radius r _m with the maximum external device dimension D over D ₂ of · · M) Equation 5] Calculated on the concentric circles after the second round calculated above, The element antenna coordinates on a concentric circle in which a maximum of odd-numbered _nm element antennas satisfying the above are arranged at equal intervals are calculated, and the element antennas are arranged at the coordinates obtained by projecting the calculated element antenna coordinates on an arbitrary curved surface. Characteristic array antenna.