JP3189050B2 - Mobile station antenna device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Summary] The present invention relates to a mobile station antenna apparatus applicable to a mobile satellite communication system, and aims to provide a high-gain antenna having a conical beam characteristic having a substantially constant directivity in an elevation direction. , A part of a curve of a parabola symmetrical with respect to the Y axis of the Y coordinate is rotated by a rotation axis inclined by α ° from the Y axis with respect to an elevation angle of (90 ° −α °) to form a conical rotation parabola. Form a surface,
The conical paraboloid of revolution or the rotational plane corrected therefrom is used as a main reflecting mirror, and a primary radiator that performs beam scanning on the main reflecting mirror is arranged at a focal position of the main reflecting mirror (1). did.

[Industrial applications]

The present invention relates to a mobile station antenna device applicable to a mobile satellite communication system.

In a mobile satellite communication system, communication between mobile stations or between a mobile station and a fixed station is performed using a geostationary satellite. The elevation angle of a satellite viewed from a mobile station is about 40 in Japan.
It becomes ゜. The azimuth is 360 ° because the moving direction of the mobile station changes. Therefore, it is necessary that the antenna of the mobile station be configured to satisfy such a condition.

[Conventional technology]

Mobile station antenna devices in a mobile satellite communication system can be broadly classified into a non-tracking type and a tracking type.

The former non-tracking type is omnidirectional in the azimuth direction and needs to have a cone beam characteristic having directivity in the elevation direction.For example, the elevation angle is 30 ° to 60 ° by a helical antenna.
Within the range of ゜, a cone beam with a beam width of 15 ゜ to 30 ゜ is obtained.

The latter tracking type includes a mechanical tracking method, an electronic tracking method, and a mixed method in which mechanical tracking and electronic tracking are mixed as a tracking control method. The mechanical tracking method is a so-called pencil beam antenna having a relatively sharp beam. Is driven mechanically, and a high-gain antenna device can be obtained. The electron tracking system generally uses a fade array antenna.A flat phased array antenna with 19 element antennas, a digital phase shifter with line switching, and a 16 element antenna are hemispherical. 2. Description of the Related Art Digital beamforming antennas and the like arranged on a surface are known. The mixing method is a method in which mechanical tracking and electronic tracking are mixed. For example, a configuration in which an eight-element spiral array antenna is mechanically rotated in a horizontal plane is known. The elevation angle is electronic tracking, and the azimuth is mechanical tracking. It is what becomes.

[Problems to be solved by the invention]

The aforementioned non-tracking type antenna has an advantage that the configuration is relatively simple, but since it is a beam having directivity in all directions at a predetermined elevation angle, its gain is as low as about 6 to 8 dB. There are drawbacks.

A mechanical tracking antenna can mechanically track a pencil beam antenna, so it can be a high-gain antenna. However, the disadvantage is that the drive mechanism becomes large and the tracking speed cannot be increased. There is.

In the case of a flat array, the electron tracking antenna has a relatively small elevation angle of about 40 °, so that it is necessary to largely shift the beam with respect to the vertical plane of the flat array. However, there is a disadvantage that the antenna cross polarization characteristic is deteriorated, and the gain is about ten and several dB. Therefore, it is difficult to increase the gain. In the case of a hemispherical array, by exciting the element antenna in the direction in which the beam is directed, it is possible to avoid deterioration in characteristics that occur at the time of side-looking as in the case of the flat array. Since element antennas are not excited, the number of element antennas must be increased in order to obtain a desired gain, and there is a disadvantage that the control system becomes complicated.
In addition, in order to increase the gain, it is necessary to increase the radius of the hemisphere, and there is a disadvantage that the size is increased.

In addition, high-speed tracking is difficult due to the limitation of the tracking speed when mechanically tracking an antenna of the mixed type, and the drawback is that the size of the high-gain antenna and the drive mechanism become large. is there.

SUMMARY OF THE INVENTION An object of the present invention is to provide a high-gain antenna having a conical beam characteristic having a directivity in a substantially constant elevation direction.

[Means for solving the problem]

The mobile station antenna apparatus of the present invention has a conical rotating parabolic main reflecting mirror capable of scanning a beam in all directions at a desired elevation angle, and will be described with reference to FIG.

Partial curve W of a parabola symmetrical with respect to the Y axis of X and Y coordinates
1, W2 is rotated by a rotation axis inclined by α ° from the Y axis with respect to an elevation angle of (90 ° −α °) to form a conical paraboloid of revolution, and this conical paraboloid of revolution or correction thereof The rotating surface thus formed is used as a main reflecting mirror 1, and a primary radiator 2 for performing beam scanning on the main reflecting mirror 1 is arranged at a focal position of the main reflecting mirror 1.

In addition, a conical spheroidal or hyperbolic surface in which one focal point is the same as the focal position of the main reflecting mirror 1 or a rotating surface obtained by correcting them is used as a sub-reflecting mirror. The primary radiator to be performed is arranged at the other focal position of the sub-reflector.

Further, the primary radiator 2 is constituted by a phased array antenna composed of a plurality of element antennas and a phase shifter,
The excitation phase of the element antenna located in the direction perpendicular to the beam scanning direction is adjusted so as to correct the aberration caused by the curvature of the opening surface of the main reflecting mirror 1.

[Action]

The main reflecting mirror 1 is a conical rotating parabola constituted by rotating some curves W1 and W2 of a parabola symmetrical with respect to the Y-axis of the X and Y coordinates with a rotation axis of α ゜ with respect to the Y-axis. The main reflecting mirror 1 having a parabolic surface is shown in the lower left corner, and a conical part obtained by rotating another part of the parabola curve W2. Parabolic reflex mirror 1
Has the configuration shown at the lower right.

When the primary radiator 2 is disposed at the focal point of the conical rotation paraboloid and a part of the main reflecting mirror 1 is irradiated with a beam from the primary radiator 2, the beam is reflected in a direction parallel to the Y axis. Therefore, if the conical rotation paraboloid is arranged so that the rotation axis is at a vertical position and the main reflection mirror 1 is used, the beam is reflected from the main reflection mirror 1 at an elevation angle of 90 ° -α °. . When the beam irradiating position of the primary radiator 2 on the main reflecting mirror 1 is changed, the elevation angle is constant and only the azimuth angle is changed.

Therefore, when the beam is scanned mechanically or electronically by the primary radiator 2, the beam can be scanned in all directions at a constant elevation angle. In this case, since the beam is not a cone beam having directivity in all directions, a high gain can be achieved. Even when the beam scanning is performed mechanically, since the small and light primary radiator 2 is mechanically driven, high-speed driving is also facilitated, and a transmitting / receiving antenna having a constant elevation angle can be configured.

Further, a sub-reflector having a spheroidal or hyperboloidal surface is disposed between the main reflector 1 and the primary radiator 2 so that the primary radiator 2
With this configuration, the primary radiator 2 can be easily arranged, and the beam can be scanned in all azimuth directions while keeping the elevation angle of 90 ° -α ° constant.

When the primary radiator 2 is composed of a plurality of element antennas and a phase shifter, beam scanning can be performed electronically, and by adjusting the excitation phase of the element antenna, the aperture of the main reflector 1 can be adjusted. Aberrations caused by the curvature of the surface can be corrected. For example, in the case of the main reflecting mirror 1 having a conical paraboloid of revolution formed by rotating a part of the curve W1 of a parabola, the excitation phases of the element antennas located near both ends in the direction perpendicular to the beam scanning direction are advanced. In the case of the main reflecting mirror 1 having a conical paraboloid of revolution formed by rotating a curve W2 of a part of a parabola, the excitation phase is delayed by contrary to the above case. Aberration correction can be performed.

〔Example〕

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 2 is a schematic side view of the first embodiment of the present invention,
11 is a main reflector, 12 is a primary radiator, and 13 is a rotation drive unit. In this case, when the parabola shown in FIG. 1 is represented by y = (x ² / 4f) -f, the main reflecting mirror 11 inclines a part of the curve W1 of the parabola by α ゜ with respect to the Y axis. It uses a conical paraboloid of revolution formed by rotation about a rotation axis. In this case, the focus of the main reflector is X, Y
It will be located at the origin of the coordinates.

The primary radiator 12, which is disposed at the focal point of the main reflecting mirror 11 and irradiates a beam on the reflecting surface of the main reflecting mirror 11, can be a radiator of a hoso type or a microstrip type,
The beam is scanned by being rotated by a driving unit 13 composed of a motor or the like. That is, the beam 14 from the primary radiator 12
Is reflected as a beam 15 by the reflecting surface of the main reflecting mirror 11, and the primary radiator 12 is rotated by the driving unit 13, so that the beam is emitted according to the locus of the dotted line 16 with a constant elevation angle.

In this case, the main reflecting mirror 11 having a conical paraboloid of revolution is arranged with the rotation axis (see FIG. 1) for forming the conical paraboloid of revolution being vertical, and therefore, the primary radiator arranged at the focal point
The beam 14 from 12 is emitted by the main mirror 11 in the direction of 90 ° -α °, and is emitted in the same direction of 90 ° -α ° on all reflecting surfaces of the main mirror 11. Therefore, an antenna with a constant elevation angle can be configured.

This antenna is mounted on a mobile station, and satellite communication is performed by controlling and tracking the drive unit 13 so that the beam 15 from the main reflector 11 is directed in the direction in which the communication satellite is viewed from the mobile station. Can be. Further, since the primary radiator 12 can be made small and lightweight, high-speed tracking is also possible. As described later, it is also possible to electrically perform beam scanning using a phased array antenna. in this case,
The driving unit 13 uses a configuration that mechanically fixes the excitation phase of the element antenna.

In addition, the main reflecting mirror 11 may be a rotating surface corrected by a mirror surface correcting technique in order to improve the aperture efficiency.

FIG. 3 is a schematic sectional view of a second embodiment of the present invention,
21 is a main reflector, 22 is a primary radiator, and 23 is a rotation drive unit.

In this embodiment, when the parabolic line shown in FIG. 1 is represented by y = (x ² / 4f) -f, a part of the curve W2 of the parabolic line is represented by α with respect to the Y axis.゜ This uses a conical paraboloid of revolution formed by rotation on an inclined axis of rotation, and the curves W1 and W2 are located at opposite positions to the axis of rotation. As shown in the lower left and lower right of FIG. 1, the shape becomes a shape close to a flat plate and a bowl shape. Also, in this embodiment, the focal point is located at the origin of the X and Y coordinates, as in the previous embodiment.

Further, a primary radiator 22 is arranged at the focal point of the main reflecting mirror 21 and rotated by a driving unit 23 such as a motor, so that the primary radiator 22
Scans the reflection surface of the main reflecting mirror 21 with the beam 24 from the main reflecting mirror 21, the beam 15 from the main reflecting mirror 21 has an elevation angle of 90 ° −α °, and this beam 15 is
Is rotated, as shown by the dotted line 26, it is possible to form a beam having a constant elevation angle and an omnidirectional angle.

Therefore, it can be mounted on the mobile station and tracked by the communication satellite by the drive unit 23 to perform satellite communication. Further, similarly to the above-described embodiment, it is possible to use the main reflecting mirror 21 in which the conical paraboloid of revolution is corrected by the mirror surface correcting technique, and the primary radiator 22 is constituted by a phased array antenna to electrically scan. It is also possible to adopt a configuration in which: Also, this embodiment is different from the first embodiment in that the primary radiator 22 is provided with a main reflecting mirror.
There is an advantage that the height can be reduced because it can be arranged in the inside 21.

FIG. 4 is an explanatory view of a third embodiment of the present invention, in which 31 is a main reflecting mirror, 32 is a primary radiator, 33 is a sub-reflecting mirror, and 34 is a common part between the main reflecting mirror 31 and the sub-reflecting mirror 33. , 35 indicates a beam from the primary radiator 32, and 36 indicates a beam from the main reflecting mirror 31.

The main reflecting mirror 31 in this embodiment has the same configuration as the main reflecting mirror 11 in the first embodiment, and the sub-reflecting mirror 33 has one focal point located at the focal point of the main reflecting mirror 11. Ellipse shown by dotted line
This uses a spheroid formed by rotating a part of the curve of 37, and shows a case where both the focal point of the main reflecting mirror 31 and the two focal points of the sub-reflecting mirror 33 are present on the rotation axis. Sub-reflector
At the other focal point of 33, a primary radiator that performs beam scanning on the sub-reflector 33 is arranged. As the support means for the sub-reflector 33, various configurations can be used. For example, the support means can be supported on the main reflector 31 by a dielectric cylinder or a dielectric conical cylinder that transmits radio waves. .

The beam 35 from the primary radiator 32 is reflected by the sub-reflecting mirror 33, enters the main reflecting mirror 31, and emits a beam 36 having an elevation angle of 90 ° -α °. This beam 36 is the primary radiator 32
By scanning the beam 34 from, the beam 36 is scanned in all azimuth angles with a constant elevation angle.

Also in this embodiment, it is possible to correct the mirror surfaces of the main reflecting mirror 31 and the sub-reflecting mirror 33, and it is also possible to use a hyperboloid of revolution instead of the spheroid as the sub-reflecting mirror 33. It is possible.

FIG. 5 is an explanatory view of a fourth embodiment of the present invention, in which 41 is a main reflecting mirror, 42 is a primary radiator, 43 is a sub-reflecting mirror, and 44 is a common part between the main reflecting mirror 41 and the sub-reflecting mirror 43. , 45 indicates a beam from the primary radiator 42, and 46 indicates a beam from the main reflecting mirror 41.

This embodiment is based on the offset Gregorian antenna shown in FIG. 6. The Gregorian antenna has a paraboloid of revolution as a main reflector and one focal point at the same position as the focal position of the main reflector. And a spheroidal sub-reflector in which a primary radiator is disposed at the other focal point. The configuration using a part of the main reflecting mirror and the sub-reflecting mirror,
An offset Gregorian antenna shown in FIG. 6 is shown, 41a is a main reflector, 42a is a primary radiator, 43a is a sub-reflector, and 44a is the other focal point of the main reflector 41a and the sub-reflector 43a.

The main reflector of this offset Gregorian antenna
41a has a paraboloid formed by rotating the parabola with a horizontal rotation axis passing through the focal point of the parabola.In this case, the rotation axis 47 inclined by α By rotating the cross-sectional curve of the Gregorian antenna, the configuration shown in FIG. 5 is obtained. Therefore, the focal point 44 of the main reflecting mirror 41 does not exist on the rotation axis 47, and only one focal point of the sub-reflecting mirror 42 exists on the rotating axis 47, and the primary radiator 42 is located at this focal position. It is something to arrange.

With such a configuration, the beam 45 from the primary radiator 42
Of the main reflecting mirror 41 by scanning the
Is emitted at an elevation angle of 90 ° -α °, and can scan all azimuth angles at a constant elevation angle. Also in this embodiment, the sub-reflection mirror 43 can be supported by a dielectric cylinder or the like.

Further, based on an offset Cassegrain antenna having a sub-reflecting mirror as a hyperboloid of revolution, a rotating surface formed by rotating a cross-sectional curve with a rotating axis at which a desired elevation angle can be obtained is provided in the same manner as in the above-described embodiment. A reflecting mirror and a sub-reflecting mirror can be configured.

FIG. 7 is an illustration of a mechanically driven primary radiator, 51 is a conical horn, 52 is a motor, 53 is a rotary joint,
54 is a transmission / reception control unit. The transmission / reception control unit 54 includes a transmission / reception amplification unit and a tracking control unit.

The conical horn 51 has a rotary joint 53
Is connected to the transmission / reception amplification unit of the transmission / reception control unit 54, and is rotated by a motor 52 via a transmission mechanism such as a gear, and is fed from the transmission / reception amplification unit of the transmission / reception control unit 54 to the conical horn 51, The conical horn 51 is rotated by the motor 52 controlled by the tracking control unit of the transmission / reception control unit 54, and electrical tracking control for the communication satellite is performed.

Such a primary radiator can be applied to the above-described first to fourth embodiments, and simply rotates a small and lightweight conical horn, thereby facilitating high-speed tracking. It is of course possible to use not only a conical horn but also a pyramid horn or the like. Further, a microstrip antenna can be used instead of the above-mentioned conical horn 51, and further weight reduction can be achieved.

FIG. 8 is an explanatory diagram of a primary radiator using a phased array, and shows a primary radiator that electrically performs beam scanning.
In the figure, 55-1 to 55-n are element antennas, 56-1.
56-n are phase shifters, 57 is a transmitting / receiving unit, 58 is a beam, 5
9 shows the scanning locus.

The element antennas 55-1 to 55-n are arranged in a line at half-wavelength intervals, and the feeding phase is sequentially set to 90 by the phase shifters 56-1 to 56-n.
調整 If adjusted to shift the phase, the element antennas 55-1 to 55
The radiation angle γ of the beam 58 due to −n is γ = 30 °.

Accordingly, the element antennas 55-1 to 55-n are arranged on the disk 60 as shown in FIG.
By controlling the feeding phase of n by a phase shifter (not shown), the beam can be scanned with respect to the main reflecting mirror or the sub-reflecting mirror.

A phased array antenna that performs beam scanning with a constant elevation angle is also shown in, for example, B-142 `` Vehicle type phased array antenna for satellite communication '' in the collection of papers of the 1989 IEICE Spring National Convention. A phased array antenna that performs such beam scanning can be used as the primary radiator described above.

FIG. 10 is an explanatory diagram of a switching array antenna, in which a plurality of element antennas 61-1 to 61-m are arranged in a ring to constitute a primary radiator. In the same figure, 62-1 to 62-m are switches, 63 is a transmission / reception unit, and 64 is a main reflecting mirror or a sub-reflecting mirror.

The primary radiator is for selecting an element antenna capable of obtaining a desired azimuth angle and feeding power from the transmission / reception unit 63 via a switch, and includes element antennas 61-1 to 61-1 disposed close to the peripheral surface of the cylinder. The case of irradiating the beam in the horizontal direction by -m is shown. In the case of irradiating the beam upward or downward with respect to the horizontal direction, the element antenna 61-1 is provided on the conical peripheral surface whose peripheral surface is inclined upward or downward. 6161-m may be provided.

FIGS. 11 (a) to 11 (c) are explanatory views of an embodiment for correcting aberrations of the main reflecting mirror, and FIG. 11 (a) shows a configuration similar to that of the first embodiment. A primary radiator 72 composed of a phased array antenna is arranged at the focal point of a main reflector 71 of a conical paraboloid of revolution formed by rotating a part of the curve 76, and a beam 74 is electrically scanned to perform main reflection. The beam 75 from the mirror 71 is directed toward the communication satellite, and the beam 75
In the X and Z coordinates, the elevation angle is 90 ° -α °, as shown in FIG. The primary radiator 72 includes a plurality of element antennas 81 as shown in FIG.

In such an antenna, the cross section of the beam 74 from the primary radiator 72 is substantially circular, and therefore, the beam 75 reflected from the main reflecting mirror 71 is also substantially circular in cross section. The opening surface of the main reflecting mirror 71 at that time is indicated by a dotted line 77. When this opening surface is viewed substantially from the front, it is indicated by a dotted line 78. This dotted line 78 indicates that the beam 74 from the primary radiator 72 is
It indicates the range irradiated on the main reflecting mirror 71, and an arrow
79 indicates the direction along the curve 76, and the arrow 80 indicates the scanning direction. Accordingly, since the component of the beam 74 on the arrow 79 is the component on the curve 76, it becomes the component of the beam 75 reflected in the direction of the desired elevation angle 90 ° -α °. However, the component of the beam 74 deviated from the arrow 79 in the direction of the arrow 80 is represented by the curve 76
Since it is not above, an aberration is given to the reflected beam 75 due to it.

Therefore, the primary radiator 72 controls the excitation phase of each element antenna 81 by using a phase shifter (not shown) corresponding to the element antenna 81 to scan the beam 74, and also controls the excitation phase so as to correct the aberration. Is what you do. For example,
In the primary radiator 72 shown in (c), the element antennas 81 arranged in the Y direction are excited with the same phase, and the excitation phases are sequentially changed along the X direction, so that the beam is emitted with respect to the Z axis. Is emitted in the X direction, the beam from the element antenna 81 on the X axis is positioned on the main reflecting mirror 71, for example, on the arrow 79 within the dotted line 78. Since the beam from the element antenna 81 on the Y axis is located on the arrow 80 within the dotted line 78 on the main reflecting mirror 71, an aberration corresponding to the curvature in the direction of the arrow 80 occurs.

In order to correct this aberration, the excitation phase of the element antenna 81 hatched on both ends on the Y axis or the adjacent element antenna 81 including these element antennas 81 is advanced. Ideally, it is desirable to sequentially advance the excitation phase as the element antenna moves away from the X axis in the Y direction.

Similarly, when the direction of the beam is changed to radiate while being inclined in the Y direction with respect to the X axis, the element antenna 81 on the Y axis
Is located on the arrow 79 within the dotted line 78 on the main reflector 71, and the beam from the element antenna 81 on the X axis is
Because it will be located on the arrow 80 within the dotted line 78 on 71
In this case, the element antennas at both ends on the X axis or in the vicinity thereof
The aberration is corrected by advancing the 81 excitation phase.

In the case of the embodiment shown in FIG. 3, since the main reflecting mirror 21 is concave, the aberration that occurs when the primary radiator 22 is configured by the above-described phased array antenna is affected by the above-mentioned main reflecting mirror 71 as a convex surface. Therefore, the correction can be made by delaying the excitation phase of the element antenna.

Such aberration correction can be easily applied to the configuration using the sub-reflector by using the phased array antenna for the primary radiator.

The present invention is not limited to the above-described embodiment, but can be variously modified.For example, a conical paraboloid of revolution may be configured in consideration of the aperture efficiency and side lobes. Can be done.

〔The invention's effect〕

As described above, the present invention rotates a part of the curves W1 and W2 of the paraboloid symmetrical with respect to the Y axis by the rotation axis inclined by α ゜ with respect to the Y axis to form a conical paraboloid of revolution. A surface is formed, and the conical paraboloid of revolution or the rotational surface corrected therefrom is used as the main reflecting mirror 1, and the primary radiator 2 is arranged at the focal position of the main reflecting mirror 1. The beam scanning is performed, and there is an advantage that the antenna gain can be improved by the beam scanning. In addition, since beam scanning can be performed in all azimuth angles with a constant elevation angle, and even when mechanical scanning is performed, only the small and light primary radiator 2 is rotated. Tracking becomes easy.

In addition, since the configuration using the sub-reflector reduces the limitation on the arrangement position of the primary radiator 2, there is an advantage that the setting of the antenna becomes easy.

Also, by using a phased array antenna as the primary radiator 2 and controlling the excitation phase of the element antenna, there is an advantage that the aberration of the aperture surface of the main reflecting mirror 1 can be corrected and the characteristics can be improved.

[Brief description of the drawings]

FIG. 1 is a view for explaining the principle of the present invention, FIG. 2 is a schematic side view of a first embodiment of the present invention, FIG. 3 is a schematic sectional view of a second embodiment of the present invention, and FIG. Explanatory drawing of a third embodiment of the present invention,
FIG. 5 is an explanatory view of a fourth embodiment of the present invention, FIG. 6 is an explanatory view of an offset Gregorian antenna, FIG. 7 is an explanatory view of a mechanically driven primary radiator, and FIG. 8 is a phased array. 9 is an explanatory diagram of a disk-shaped phased array antenna, FIG. 10 is an explanatory diagram of a switching array antenna, and FIGS. 11A to 11C are explanatory diagrams of aberration correction. . Reference numeral 1 denotes a main reflector, 2 denotes a primary radiator, and W1 and W2 denote partial curves of a parabola.

Continuation of the front page (56) References JP-A-53-68958 (JP, A) JP-A-63-144605 (JP, A) JP-A-52-146149 (JP, A) JP-A-64-30304 (JP) JP-A-63-209304 (JP, A) JP-A-61-93704 (JP, A)

Claims (3)

(57) [Claims] 1. A part of a curve of a parabola symmetrical with respect to a Y axis of X and Y coordinates is rotated by a rotation axis inclined by α ° from the Y axis with respect to an elevation angle of (90 ° −α °). To form a conical paraboloid of revolution, the conical paraboloid of revolution or a rotational plane corrected therefrom as a main reflector (1), and a primary radiator for performing beam scanning on the main reflector (1) (2) The mobile station antenna device, wherein the main reflector (1) is arranged at a focal position. 2. A part of a curve of a parabola symmetrical with respect to a Y axis of X and Y coordinates is rotated by a rotation axis inclined by α ° from the Y axis with respect to an elevation angle of (90 ° −α °). To form a conical paraboloid of revolution, and the conical paraboloid of revolution or a rotational plane obtained by correcting the paraboloid of paraboloid is defined as a main reflector (1). A conical spheroid or a hyperboloid of revolution or a rotational surface obtained by correcting them is used as a sub-reflector, and a primary radiator that performs beam scanning on the sub-reflector is located at the other focal position of the sub-reflector. A mobile station antenna device, which is arranged. 3. The primary radiator (2) is constituted by a phased array antenna comprising a plurality of electronic antennas and a phase shifter, and sets an excitation phase of the element antenna positioned in a direction perpendicular to a beam scanning direction. 3. The mobile station antenna device according to claim 1, wherein an adjustment is made so as to correct an aberration caused by a curvature of an opening surface of the main reflecting mirror (1).