JPH04253402A - Patch antenna array - Google Patents

Abstract

PURPOSE:To accurately and easily change the beam width of the patch antenna array by changing the number of patch antennas to be excited by switching the ON/OFF of a diode, to search and exactly orient the counter antenna in a short time when installing a portable antenna or the like by using this patch antenna array. CONSTITUTION:This patch antenna array formed on a dielectric substrate is equipped with plural patch antennas 1a-1e serially connected by strip lines 2, diodes 4a and 4b arranged among the patch antennas 1a-1e so as to enable the connection/disconnection of high frequencies by being turned on/off, and diode control means to control the excitation of the patch antennas 1b-1e by turning the diodes 4a and 4b on/off.

Description

[Detailed description of the invention]

0001

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a patch antenna array, and more particularly to a patch antenna array whose antenna beam width can be easily changed.

0002

2. Description of the Related Art When installing a portable antenna or an easily installed antenna, it is necessary to point the antenna toward an artificial satellite or an opposing antenna in a short time.

Conventionally, as a first method for this purpose, when the opposing antenna is visible, there has been a method of making a hole in the reflector and determining the directivity toward the opposing antenna from behind the antenna.

[0004] A second method is to first change the beam width of the antenna to a wide beam width to roughly limit the pointing range, and in the next step, change the beam width to the normal narrow beam width.
There are ways to improve pointing accuracy. When using this method, the primary radiator of the reflector was mechanically moved to shift the focal point of the antenna from its normal position and widen the beam width.

[0005]

The first method described above, the visual inspection method, cannot be used when the opposing antenna cannot be seen, such as when an antenna is mounted on an artificial satellite. Furthermore, the second method of shifting the focus position of the antenna has the drawback that it is difficult to set it accurately, and furthermore, in the case of a large diameter antenna, the work is difficult.

[0006] An object of the present invention is to provide an antenna with good beam width changing work and setting accuracy, and with which the beam width can be easily set.

[0007]

[Means for Solving the Problems] A patch antenna array according to the present invention includes a plurality of patch antennas connected in cascade by strip lines, and a plurality of patch antennas disposed between the patch antennas in a patch antenna array formed on a dielectric substrate. The patch antenna includes a diode that can connect and disconnect high frequency waves by turning on and off the diode, and a diode control means that turns on and off the diode to control excitation of the patch antenna.

[0008]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, the present invention will be explained with reference to the drawings.

FIG. 1(a) is a front view of a first embodiment of the present invention, and FIG. 1(b) is a side view thereof. Moreover, FIG. 2 is a characteristic explanatory diagram of the first embodiment.

This patch antenna array consists of a plurality of patch antennas 1 (1a in this embodiment) on a dielectric substrate 3 on which a ground conductor 5 is arranged.
~1e). In this antenna array,
The high frequency is fed from a power feeding section 8 provided at one point of the patch antenna 1a. The other patch antennas 1b to 1e are
The patch antenna 1a is connected in cascade through a strip line 2 and a polarization matching adjustment unit 7 for polarization matching, which is configured by the strip line. Also, between the patch antenna 1a and the patch antennas 1b and 1c, and between the patch antenna 1a and the patch antennas 1d and 1e, the PI
N diodes 4 (4a and 4b) are arranged. The cathode side of the PIN diode 4 is the patch antenna 1a.
It is connected to the. A bias line 6 is provided at the cathode and anode of the PIN diode 4 to block high frequencies and pass direct current. This patch antenna array is designed for the arrangement and connection of patch antennas 1 so that the beam width of the antenna is narrow when all patch antennas 1a to 1e are excited, and the beam width is wide when only patch antenna 1a is excited. The length of the strip line 2 and the length of the polarization matching adjustment section 7 are set.

In this configuration, A is the terminal of the bias line 6 to which the cathode of the PIN diode 4 is connected.
When a negative voltage is applied to the point and a relatively positive voltage is applied to point B, which is the terminal of the bias line 6 to which the anode of the PIN diode 4 is connected, the PIN diode 4 becomes conductive and all five patch antennas 1 are electromagnetically coupled and excited. At this time, the antenna aperture area of the patch antenna array becomes wider, and the beam width w1 becomes narrower, as shown by the radiation pattern α in FIG. On the other hand, when a negative voltage is applied to point B and a relatively positive voltage is applied to point A, the PIN diode 4 blocks the high frequency passing through the strip line 2, and only the patch antenna 1a in the center is excited. Therefore, the antenna aperture area of the patch antenna array becomes narrower, and the antenna beam w2 becomes wider as shown in the radiation pattern β in FIG.

That is, in the patch antenna array shown in FIG. 1, by turning on and off the PIN diodes, the number of excited patch antennas changes and the antenna aperture area changes, so the beam width can be changed. Note that the PIN diode 4 electrically turns on and off the high frequency.
A diode with other characteristics may be used as long as it is an element that turns off.

FIG. 3 is a side view of a second embodiment of the invention.

The reflector antenna 9 according to this embodiment has a reflector 10 and the patch antenna array 11 described in the first embodiment, which serves as a primary radiator. PIN
When the diode 4 is turned on, the beam width of the patch antenna array 11 becomes narrower as described above, and as a result, the beam width of the reflector antenna 9 becomes wider. Also, P.I.
When the N diode 4 is turned off, the beam width of the primary radiator is widened and the effective aperture area of the reflector antenna 9 is widened, so that the beam width of the reflector antenna 9 is narrowed.

In this way, by using the patch antenna array 11 described above as the reflector antenna 9, the beam width can be easily changed by turning on and off the PIN diode 4 without moving the position of the primary radiator.

FIG. 4 is a plan view of a third embodiment of the present invention, and FIG. 5 is a diagram illustrating its characteristics.

Patch antennas 41a to 41i in this patch antenna array are formed on a dielectric substrate 43 having a ground conductor disposed on the back surface, similarly to the first embodiment. In addition, elements with the same names and having the same function as those in the first embodiment, a strip line 42 and a PIN diode 44 (
44a to 44d), bias line 46, polarization matching adjustment section 4
7 and a power supply section 48, and are similarly connected. However, patch antennas 41a to 41e are arranged on the X axis of the patch antenna array, and patch antennas 41f to 41e are arranged on the X axis of the patch antenna array.
41i and the commonly used patch antenna 41a are arranged on the Y axis orthogonal thereto. Also, PIN
Diode 44a connects patch antennas 41b and 41c
PIN diode 44b is placed at a position to turn on/off patch antennas 41d and 41e, PIN diode 44c is placed at a position to turn on/off patch antennas 41f and 41g, and PIN diode 44d is placed at a position to turn on/off patch antennas 41h and 41i. ing. The voltage from the terminal A1 point is applied to the anodes of PIN diodes 44a and 44b, which are connected to the patch antenna 41a via the bias line 46, and the PIN diode 44c.
, 44d. Also, terminal B1
The voltage from the point is applied to the cathode of PIN diode 44a and
is supplied to the anode of c. Furthermore, the voltage from the terminal B2 point is applied to the patch antenna 41 via the bias line 46.
It is supplied to the cathode of PIN diode 44a and the anode of PIN diode 44c, which are connected to d, 41e and 41h, 41i, respectively.

In this configuration, when the patch antennas 41a to 41e on the X axis are fed and excited, the beam width in the XZ axis (the Z axis is an axis perpendicular to the X and Y axes) becomes narrower.
When the patch antennas 41a, 41f to 41i on the Y axis are fed and excited, the beam width in the YZ axis plane becomes narrower.

Now, when terminals B1 and B2 are set to the same potential and a positive voltage is applied to terminal A1, the PIN diodes 44a and 44b are turned on, and the patch antennas 41a to 41 on the X axis are turned on.
Only 41e is excited. Then, as shown by the beam contour line γ in FIG. 5, the beam width in the XZ plane is narrow, and the beam width in the Y
An elliptical beam with a wide beam width in the Z plane is created. Conversely, when a negative voltage is applied to the terminal A, the PIN diodes 44c and 44d are turned on, and only the patch antennas 41a, 41f to 41i on the X axis on the Y axis are excited. Then, as shown by the beam contour lines δ in FIG. 5, an elliptical beam with a narrow beam width in the YZ plane and a wide beam width in the XZ plane is produced. In this way, the beam width in the orthogonal plane (AZ=azimuth, EL=elevation) of the antenna changes depending on whether the PIN diode 44 is turned on or off.

When the patch antenna array shown in this second embodiment is used as the primary radiator of the reflector antenna, first, in order to determine the position of the AZ plane of the antenna,
If we form an elliptical beam that is narrow in the Z plane and wide in the EL plane,
Even if the opposing antenna is misaligned on the EL plane, move the antenna to AZ.
If you rotate to the plane, you can find the opposing antenna. Next, by switching the beam to narrow the beam in the EL plane and rotating the antenna in the EL plane, it is possible to easily find the opposing antenna.

[0021]

As explained above, in the patch antenna array according to the present invention, patch antennas are connected in cascade by strip lines, and a diode for turning on/off high frequency is arranged in the middle. Further, by switching the diodes on and off, the number of excited patch antennas can be changed, thereby making it possible to easily change the beam width of the patch antenna array with high precision. Also,
By using this patch antenna array, when installing a portable antenna or the like, it becomes possible to quickly find an opposing antenna and direct it accurately.

[Brief explanation of the drawing]

FIG. 1(a) is a front view of a first embodiment of the present invention, and FIG. 1(b) is a side view.

FIG. 2 is a characteristic explanatory diagram of the first embodiment.

FIG. 3 is a side view of a second embodiment of the invention.

FIG. 4 is a plan view of a third embodiment according to the invention.

FIG. 5 is a characteristic explanatory diagram of a third embodiment.

[Explanation of symbols]

1 (1a to 1e), 41 (41a to 41i) Patch antenna 2, 42 Strip line 3, 43 Dielectric substrate 4 (4a, 4b), 44 (44a to 44d) P
IN diode 5 Ground conductor 6, 46 Bias line 7, 47 Polarization matching adjustment section 8, 48 Power feeding section 9 Reflector antenna 10 Reflector 11 Patch antenna array

Claims (3)

[Claims] 1. In a patch antenna array formed on a dielectric substrate, a plurality of patch antennas are connected in cascade by strip lines, and a plurality of patch antennas are arranged between the patch antennas, and high frequencies can be connected and disconnected by turning on and off the patch antennas. What is claimed is: 1. A patch antenna array comprising: a diode; and diode control means for controlling excitation of the patch antenna by turning on and off the diode. 2. A plurality of the patch antennas are arranged in rows on orthogonal surfaces on the dielectric substrate, and the diode control means is configured to control one of the orthogonal patch antenna rows arranged in the rows. A patch antenna array characterized in that either one of the patch antenna rows is excited. 3. A reflector antenna comprising the patch antenna array according to claim 1 or 2 as a primary radiator.