JP2004015460A - Orthogonal polarization slot array antenna - Google Patents

Abstract

Provided is a slot array antenna that enables two-way simultaneous parallel transmission / reception with a communication partner at the same transmission / reception frequency without using a conventional FDD system or TDD system.
An angle between a longitudinal direction of a slot (5) of a first antenna section (3) and a longitudinal direction of a slot (6) of a second antenna section (4) of adjacent slot array antennas facing in the same direction is a right angle. So that As a result, the polarization planes of both antennas are orthogonal (intersecting), and when one is a transmission antenna and the other is a reception antenna, there is no wraparound from the transmission antenna to the reception antenna, and transmission is performed with the polarization of the reception antenna. Since the received electromagnetic wave is received only by the receiving antenna, the transmitting antenna is coupled to the transmitter, and the receiving antenna can be coupled to the receiver, thereby achieving the object.
[Selection diagram] Fig. 1

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention belongs to the technical field of an antenna used for fixed antenna-type wireless communication such as FWA (Fixed Wireless Access System) or Entrance wireless.
[0002]
[Prior art]
Conventionally, in such wireless communication, transmission and reception are performed using one parabolic antenna, a microstrip antenna, or the like, using an FDD (Frequency Division Duplex) method or a TDD (Time Division Duplex) method.
The FDD system uses different frequencies with the same polarization for transmission and reception. Thus, transmission and reception can be performed concurrently and simultaneously.
The TDD system uses the same polarization and the same frequency for both transmission and reception. Therefore, it is impossible to perform transmission and reception at the same time at a certain moment, but in view of the time length of the information to be transmitted and received, transmission and reception are performed at high speed on the time axis so that they can be regarded as simultaneous parallel transmission and reception in practical use. Switching to that is going on.
[0003]
[Problems to be solved by the invention]
However, in the FDD system, transmission and reception of two different frequencies are performed by one antenna, so that there is a problem that a wide frequency bandwidth is required for the antenna.
Also, in order to simultaneously transmit and receive at different frequencies with one antenna, both the transmitter and the receiver must be combined with the antenna, but at this time, the output of the transmitter only goes to the antenna and receives In order not to go to the transmitter and the signal received by the antenna to go only to the receiver and not to the transmitter, a duplexer (Duplexer) having a sharp frequency selection characteristic is used. There is also the problem of having to use it.
[0004]
In the TDD system, the same frequency is used for both transmission and reception, so that the frequency bandwidth of the antenna is not required to be as wide as in the case of the FDD system. The antenna coupling must be switched in accordance with the transmission and reception, such as coupling to the receiver at the time of reception. Then, in order to make it appear that transmission and reception are simultaneously performed in practice, the switching between the transmitter and receiver antennas is performed in a very short time interval with respect to the time length of information to be transmitted and received. A coupling switch must be performed. That is, high-speed coupling switching must be performed.
[0005]
For such coupling switching, a coupling switch capable of high-speed switching is required, and a high-speed switching driving circuit is required for causing the coupling switching to perform high-speed switching operation. This drive circuit has to perform a switching operation in synchronization with the transmission operation of the transmitter and the reception operation of the receiver, and there is a problem that it becomes very complicated.
[0006]
SUMMARY OF THE INVENTION In view of the above-mentioned problems of the prior art, an object of the present invention is to fix an antenna that does not require a wide band for an antenna, does not use a duplexer, a coupling switch, a high-speed switching driving circuit, and performs transmission and reception simultaneously. It is an object of the present invention to provide an antenna that can be used for a mobile communication system.
[0007]
[Means for Solving the Problems]
The antenna of the first configuration of the present invention that achieves the above object has a configuration in which the slot array antennas adjacent to each other facing in the same direction have the longitudinal direction of the slot of one antenna and the longitudinal direction of the slot of the other antenna. An orthogonally polarized slot array antenna, wherein an angle between the direction and the direction is a right angle.
[0008]
An antenna according to a second configuration of the present invention is the orthogonal polarization slot array antenna according to the first configuration, wherein the slot array antenna is a waveguide type slot array antenna.
[0009]
The antenna according to a third aspect of the present invention is the antenna according to the first aspect, wherein the slot array antenna is provided with a row of slots on the conductor foil on one surface of the dielectric substrate having a double-sided conductor foil, Are orthogonally polarized slot array antennas in which through conductors conducting between the conductor foils are provided in a linear array at predetermined intervals.
[0010]
BEST MODE FOR CARRYING OUT THE INVENTION
The principle of the antenna of the present invention is that, in a slot array antenna, the angle of the plane of polarization of the electromagnetic wave radiated from the antenna and the maximum electromagnetic wave received is determined by the direction of the slot longitudinal direction of the antenna and perpendicular to the plane of polarization determined by the direction of the slot. The radiation or reception of an electromagnetic wave having a polarization plane (also referred to as an orthogonal polarization plane or a cross polarization plane) is extremely small and its ratio (cross polarization discrimination degree) is 50 dB or more. It focuses on the fact that the radiation or reception of the electromagnetic wave that it has is negligible.
[0011]
Accordingly, the two slot array antennas are arranged in the same direction (direction of the communication partner radio station), and the angle between the longitudinal direction of the slot of one antenna and the longitudinal direction of the slot of the other antenna is a right angle. By doing so, the polarization planes of both antennas are orthogonal.
[0012]
Now, if the polarization plane of one (first) antenna is A and the polarization plane of the other (second) antenna is B, and the polarization plane A and the polarization plane B are orthogonal, the frequencies are the same. However, the first antenna does not emit or receive B-polarized electromagnetic waves, and the second antenna does not emit or receive A-polarized electromagnetic waves.
[0013]
Therefore, even if two antennas are arranged as described above, it is practically impossible that an electromagnetic wave radiated from one antenna is received by an adjacent antenna. That is, there is no wraparound.
[0014]
Accordingly, in the fixed antenna communication system, the transmitting antenna of one of the radio stations facing each other and the receiving antenna of the other radio station are A-polarized, and the receiving antenna of the one radio station and the other If the transmitting antenna of the station is fixed at B polarization, bidirectional transmission and reception at a single frequency (the same transmission and reception frequency) can be literally simultaneously performed between both radio stations.
[0015]
Thus, when one of the adjacent slot array antennas of the present invention is used as a transmitting antenna and the other is used as a receiving antenna, one frequency is used for each antenna irrespective of whether the transmitting and receiving frequencies are the same or different. , FDD type antennas are not required to have a wide band for using two frequencies. Further, since the transmitting antenna is coupled to the transmitter and the receiving antenna is coupled to the receiver, a duplexer is not required as in the FDD system, and a coupling switch and a high-speed switching driving circuit as in the TDD system are also required. It is unnecessary.
[0016]
The antenna of the present invention only needs to form a right angle between the adjacent slot array antennas in the longitudinal direction of the slot. Typically, the antenna is symmetrically inclined by 45 degrees with respect to the direction of the slot row. The angle between the two is a right angle, but the angle is not limited to this, and the inclination can be set to infinity, such as 30 degrees and 60 degrees, and 40 degrees and 50 degrees.
Further, the shape of the slot is not particularly limited as long as it is a shape capable of recognizing the direction for grasping the angle of the polarization plane.
[0017]
Also, as for the combination of the slot arrangement, a single slot may be arranged in a row, for example, a set of two adjacent slots may be arranged in a row, The number of proximity may be more than one, and the modes of proximity may be parallel or serial. Furthermore, in forming a row of slots, different combinations may be alternately repeated, and any combination may be widely used.
The power supply structure to the slot is typically a waveguide type or a dielectric substrate type, but is not limited thereto.
[0018]
【Example】
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram showing a configuration of a first exemplary embodiment of the present invention. (A) is a front view seen from the transmission and reception direction, and (b) is a sectional view thereof. This embodiment is an example in which a waveguide type slot array antenna is used as the slot array antenna as can be seen from FIG.
It has a structure in which a slot plate 1 provided with slots 5 and 6 is attached to a base body 2 provided with a number of waveguides 7 arranged in parallel. The first antenna unit 3 and the second antenna unit 4 are adjacent to each other with the straight line C as a boundary. Since the longitudinal directions of the slot 5 of the first antenna section 3 and the slot 6 of the second antenna section 4 are each symmetrically inclined by 45 degrees with respect to the straight line C, the angle between the slots of both antennas is exactly 90. Degrees or right angles.
[0019]
Accordingly, the plane of polarization by the first antenna unit 3 and the plane of polarization by the second antenna unit 4 are orthogonal (cross). Therefore, if, for example, the first antenna unit 3 is used as a transmitting antenna and the second antenna unit 4 is used as a receiving antenna, the electromagnetic wave radiated from the first antenna unit 3 is not received by the second antenna unit 4. In other words, there is no so-called wraparound reception, and an electromagnetic wave transmitted from the partner radio station on the same polarization plane as the second antenna section 4 is not received by the first antenna section 3.
Therefore, two-way simultaneous parallel transmission / reception at one frequency becomes possible.
[0020]
In the example of FIG. 1, the slot 5 of the first antenna unit 3 and the slot 6 of the second antenna unit 4 are each at 45 degrees with respect to the straight line C. May form a right angle, and may be, for example, an angle of 40 degrees and 50 degrees or 35 degrees and 55 degrees.
[0021]
Also, in the present embodiment, long slots and short slots in series are alternately arranged along the axis of the waveguide in the present embodiment. I'm not caught. It is only necessary that the polarization planes of the first antenna unit 3 and the second antenna unit 4 are orthogonal to each other.
[0022]
FIG. 2 is a diagram showing the configuration of the second embodiment of the present invention. This is an example in which a dielectric substrate type slot array antenna in which a slot is provided in a copper foil on one surface of a dielectric substrate having copper foil printed on both surfaces is used as the slot array antenna.
(A) is a front view seen from the transmission and reception direction, and (b) is a sectional view thereof.
Copper foil 9 and copper foil 11 are printed on both sides of dielectric substrate 10, and slots 15 and 16 are cut in copper foil 9 on one side. Then, through holes 12 are provided at predetermined intervals along a dotted line 17 between the vertical slot rows, and conduction between the copper foil 9 and the copper foil 11 is established. This row of through holes 12 performs the same function as the boundary wall 8 in FIG. 1 and forms the waveguide 18.
[0023]
In FIG. 2, eight columns in the left half of the upper right slot 15 constitute the first antenna unit 13, and eight columns in the right half of the right down slot 16 constitute the second antenna unit 14. I have. Since the directions of the slots 15 and 16 are each symmetrically inclined by 45 degrees with respect to the straight line C, the angle between the slots 15 and 16 is a right angle.
[0024]
This angle does not need to be symmetrical, as in the case of the first embodiment, as long as the angle between both slots is only a right angle.
Also, the form and arrangement of the slots are not particularly limited, as in the first embodiment.
[0025]
【The invention's effect】
As described above, the orthogonally polarized slot array antenna according to the present invention has a structure in which the adjacent slot array antennas facing in the same direction have the longitudinal direction of the slot of one antenna and the longitudinal direction of the slot of the other antenna. Since the angle between the antenna and the direction is set to be a right angle, the polarization plane of one antenna and the polarization plane of the other antenna are orthogonal (intersecting), and the cross polarization discrimination of the slot array antenna is high. Electromagnetic waves radiated from the antenna do not sneak into the other antenna, and electromagnetic waves transmitted from the wireless station of the communication partner with the same polarization as the polarization plane of the other antenna are received only by the other antenna. One antenna couples to the transmitter and the other antenna couples to the receiver only, since it is tuned and not received by one antenna. Two-way simultaneous parallel transmission / reception with the communication partner becomes possible, and the broadband characteristics of the antenna are not required unlike the conventional FDD system, and a duplexer is not required. There is a very remarkable advantage that a drive circuit is not required.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration of a waveguide type orthogonal polarization slot array antenna according to a first embodiment of the present invention.
FIG. 2 is a diagram illustrating a configuration of a dielectric substrate type orthogonal polarization slot array antenna according to a second embodiment of the present invention.
[Explanation of symbols]
REFERENCE SIGNS LIST 1 slot plate 2 base body 3 first antenna unit 4 second antenna unit 5 slot 6 slot 7 waveguide 8 boundary wall 9 copper foil 10 dielectric substrate 11 copper foil 12 through hole 13 first antenna unit 14 second antenna unit 15 Slot 16 Slot 17 Dotted line 18 Waveguide

Claims (3)

Orthogonally polarized waves, wherein the angle between the longitudinal direction of the slot of one antenna and the longitudinal direction of the slot of the other antenna of the adjacent slot array antennas facing in the same direction is a right angle. Slot array antenna. 2. The orthogonally polarized slot array antenna according to claim 1, wherein the slot array antenna is a waveguide type slot array antenna. In the slot array antenna, a row of slots is provided in a conductive foil on one surface of a dielectric substrate of a double-sided conductive foil, and through conductors which conduct between the conductive foils on both sides are provided between the row of slots in a linear array at a predetermined interval. 2. The orthogonally polarized slot array antenna according to claim 1, wherein

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