JPH03166803A - Microstrip antenna for separately feeding two-frequency circular polarized wave - Google Patents

Abstract

PURPOSE:To reduce the size and weight and facilitate the manufacture and to transmit and receive two circular polarized waves at the same time by arranging two different-size one-side short-circuited microstrip antennas in pairs, i.e., four antennas in total on the same plane. CONSTITUTION:Four radiation conductors 111-114 are provided on a dielectric plate 15 and short-circuited to a ground conductor 14 by short-circuiting conductors 121-124. Feed points 131-134 of the respective radiation conductors are fed from behind. The conductors 111 and 112 are of the same size and has their resonance frequency is adjusted to a transmission frequency, and the conductors 113 and 114 are of the same size and have their resonance frequency is adjusted to a reception frequency. The conductors 111 and 113 are therefore different in size. Further, signals fed to the conductors 111 and 112 in in-phase relation at the time of transmitting are put together by the conductors 111 and 112 into a circular polarized wave, and the constitution of the conductors 113 and 114 for receiving the circular polarized wave is provided for the reception.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a two-frequency separated feed circularly polarized river microstrip antenna used in various wireless communications.

(Prior Art) A microstrip antenna has a planar structure that is sufficiently thin compared to the wavelength used, and is lightweight, so it has a wide range of uses as an antenna for various communications. Furthermore, by forming a phased array antenna using a plurality of these antennas, it becomes possible to electrically change the radio wave beam by controlling the phase amount of the phase shifter connected to each element. The phased array antenna manufactured in this way has the characteristics of being thin, small, and lightweight, making it suitable for applications such as mobile communications.
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As is well known, such a microstrip antenna has a narrow band. For example, if the voltage standing wave ratio is 2 or less, which is a standard that is considered to be practically usable as an antenna, the bandwidth of a microstrinbu antenna that satisfies this standard will depend on the characteristics of the dielectric plate, but It is at most a few percent of the frequency. Therefore, a normal microstrip antenna cannot be used for communications where the transmission frequency and reception frequency exceed this bandwidth. To solve this problem, microstrip antennas with various configurations have been proposed.

Figure 5 shows an example of the configuration of a conventional microstrip antenna designed to widen the band.
) shows a side view taken along line BB' in FIG. In the figure, 5] is a radiation conductor, 52 is a parasitic radiation conductor, 53 and 53' are feeding points, 54 is a ground conductor, 5
5 is a dielectric, and 56 is a power supply line. The feed point 53 is fed with power using a connector provided on the ground conductor 54 and connected to the feed line 5.
Connected to 6. In this configuration example, by adjusting the sizes of the radiation conductor 51 and the parasitic radiation conductor 52, an antenna that resonates in the transmission frequency band or the reception frequency band can be obtained.

FIG. 8 is a configuration diagram of a conventional phased array antenna using the microstrip antenna shown in FIG. In the figure, 81 is each antenna element, 82 is a directional coupler for combining circularly polarized waves, 83 is a phase control unit, and 84 is a directional coupler for combining circularly polarized waves.
85 is a power divider, 86 is a transmitting device,
87 is a receiving device, and 88 is a pseudo load. Phase controller 8
By changing the phase for each antenna element 81 in step 3, the direction of the beam can be electrically controlled.

Further, FIG. 6 shows another example of a conventional configuration capable of simultaneous transmission and reception, in which FIG. 6(a) is a plan view and FIG. 6(b) is a side view. In the figure, 61 is an annular microstrip antenna (receiving radiation conductor), 62 is a circular microstrip antenna (transmission radiation conductor), and both antennas are independently fed with power from the back side. In this configuration, the annular microstrip antenna 61 and the microstrip antenna 62 resonate in the reception and transmission frequency bands, respectively.

On the other hand, circularly polarized antennas commonly used in mobile communications can be realized by feeding power at two points as shown in Figures 5 and 6 above, but they can be realized by feeding power at two points as shown in Figure 7. A point-fed circularly polarized antenna that generates circularly polarized waves at a point is also well known. In FIG. 7, by adding a convex portion 72 on a radiation conductor 71, only one feeding point 73 functions as a circularly polarized antenna.

(Problems to be Solved by the Invention) When attempting to configure a phased array antenna using the above-mentioned conventional technology, first, the broadband microstrip antenna and dual-resonance microstrip antenna shown in FIG. The problem was that it was complicated.

In addition, as shown in Fig. 8, since the power supply part is shared between transmitting and receiving, and the transmitting and receiving phases are controlled by the same phase controller 83, the transmitting and receiving beams do not match due to the difference in frequency. Problems, phase controller 83 and transmitter 86
A guiplexer 85 for separating transmitting and receiving signals is essential between the receiving device 87 and the receiving device 87, and there is a problem that the power feeding section becomes large.

Next, the structure in which the annular microstrip antenna and the circular microstrip antenna shown in FIG. No diplexer or circulator is required. However, since it is made of 2N, the structure is more complex and heavier than that of a single layer structure, and there are problems in that it requires many manufacturing steps and high precision machining.

Furthermore, the single-point fed circularly polarized antenna shown in Figure 7 has a narrower band than a normal microstrip antenna.
Furthermore, since the axial ratio has dependence on frequency, it is unsuitable as an antenna for wideband communication.

The present invention was made to solve the problems of the prior art described above, and an object of the present invention is to provide a microstrip antenna that is small, easy to manufacture, and can separate two frequencies.

(Means for Solving the Problems) A feature of the present invention is to solve the above-mentioned problems, and is characterized in that four radiating conductors are arranged on a dielectric plate arranged on a ground conductor, A portion of the periphery of each of the four radiating conductors is short-circuited to the grounding conductor by a corresponding shorting conductor, and passing through the grounding conductor and the dielectric plate to the respective feeding points of the radiating conductor. The four radiation conductors transmit radio waves of two desired frequencies.
A configuration in which two radiation conductors of two different sizes are arranged so that they can generate circularly polarized waves, each of which is adjusted so that one wave can be used for transmission and the other wave can be used for reception. It is characterized by having the following.

(Example 1) FIG. 1 shows a first example according to the present invention. Here, a rectangular microstrip antenna with one side short-circuited is shown as an example. Figure 1 (a) is a plan view, and Figure 1 (b) is (a
) is a cross-sectional view taken along line AA' in the figure. In the figure, four radiation conductors 111 to 114 are placed on a dielectric plate 15.
are provided, and each radiation conductor is short-circuited to the ground conductor 14 by short-circuit conductors 121 to 124. 131 to 134 are each radiation conductor 111
~114 power supply points, and power is supplied from the back. Radiation conductors 111 and 112 have the same size and have their resonant frequencies matched to the transmission frequency, and radiation conductors 113 and 114 have the same size and have their resonant frequencies matched to the reception frequency. Therefore, the radiation conductors 111 and 113 have different sizes.

Regarding transmission, the radiation conductors 111 and 112 are in the same phase.
The signals fed to the antenna are combined into a circularly polarized wave by the radiation conductors 111 and 112, and it is generally known that this must be within a half wavelength of the frequency used.

The same applies to reception due to the reversibility of the antenna, and it is composed of radiation conductors 113 and 114 for receiving circularly polarized waves. The transmitting radiation conductors 111 and 112 and the receiving radiation conductors 113 and 114 are arranged so as not to interfere with each other. In order to satisfy these conditions, the radiating conductors 111, 112, 113, and 114 are arranged as shown in FIG. A rectangular or square shape is formed on the dielectric 5 by the A-A' plane).

In addition, the radiation conductor 1l1~1 is used for the bandwidth required for transmission and reception.
By limiting the size of 14, the coupling between transmitting and receiving can be ensured without interfering with communication. Feeding point 1
31 and 132 are connected from the back side of the ground conductor 14 to the transmitter via a feeder line and a directional coupler. Since the radiation conductors 111 and 112 each generate linearly polarized waves orthogonal to each other, as shown in the configuration of FIG. Waves can be combined. Right-handed or left-handed polarization is selected depending on the connection direction of the directional coupler.

For reception, circularly polarized waves are received using the same principle through a directional coupler. In addition, when multiple antennas are arranged to form a phased play antenna as shown in Figure 4(b), the radiation characteristics cover a wide angle, and there is no need for a guiplexer or circular rake, and there is no mismatch between the transmitting and receiving beams. It becomes something that does not exist.

Note that the one-sided short-circuited microstrip antenna used in the present invention has already been proposed (IEICE 1988 Comprehensive National Conference Lecture Proceedings Volume 3, Published March 5, 1980, Published by: Institute of Electronics and Communication Engineers, Haneishi et al. “On the radiation characteristics of short-circuited microstrip antenna on one side” 7
(page 43, etc.), the size of the required radiation conductor can be reduced to about half compared to a normal microstrip antenna, thereby making it possible to downsize.

(Embodiment 2) FIG. 2 is a block diagram showing a second embodiment of the present invention. Rectangular one-side short-circuited microstrip radiation conductor 211-2
In addition to the shorting conductors 221 to 224, shorting conductors 281 to 284 are provided as shorting means between the shorting conductor 14 and the grounding conductor 24. In addition to the shorting pin, a shorting plate, solder, or electrolytic plating may be used.

By providing a shorting pin, a microstrip antenna with good impedance matching can be easily realized. Also, if there is an effect of mutual coupling, the axial ratio may deteriorate, but by providing this shorting pin, it is possible to correct the phase, and it is possible to obtain a microstrip antenna with a good axial ratio. .

(Example 3) FIG. 3(a) shows the radiation conductor in Example 1 in a shape where a part of the circle is cut off, but the present invention can also be applied to a radiation conductor with such a shape. is valid.

(Embodiment 4) FIG. 3(b) shows a short circuit pin 3 as a short circuit means in Embodiment 3.
81 to 384 are provided. Even with such a configuration, the present invention is effective.

(Effects of the Invention) As described above, according to the present invention, by arranging a total of four short-circuited microstrip antennas, two of which have different sizes, on one plane, the antennas are small, lightweight, and easy to manufacture. Furthermore, it is possible to realize a microstrip antenna that can transmit and receive circularly polarized waves of two frequencies at the same time.

Furthermore, by using this as one element of a phased array antenna, it is possible to realize a small-sized, two-frequency separated feeding type circularly polarized wave antenna with wide-angle radiation characteristics on the same plane.

By forming the short-circuited side of the microstrip antenna by electrolytic plating or the like, the present invention can be easily manufactured in the conventional printed circuit board manufacturing process.

[Brief explanation of the drawing]

FIGS. 1(a) and 3(b) are a plan view showing one embodiment of the present invention, a sectional view taken along line A-A', FIGS.
) and FIG. 3(b) are plan views showing other embodiments of the present invention, and FIG. 4(a) is a plan view showing another embodiment of the present invention. FIG. 4(b) is a configuration diagram when a transmitting device and a receiving device are connected to the two-frequency separated feeding circularly polarized wave microstrip antenna according to the present invention.
2, 3(a) or 3(b), a structural diagram of a phased array antenna using the two-frequency separated feeding circularly polarized microstrip antenna according to the present invention as an element. Figures 5(a) and (b) are a plan view and a cross-sectional view taken along line B-B'' of a conventional circularly polarized microstrip antenna designed to widen the band; Figures 6(a) and (b)
7(a) and 7(b) are a plan view and a cross-sectional view taken along c-c' of a conventional two-frequency separated feeding circularly polarized wave microstrip antenna, and FIGS. 7(a) and 7(b) are a conventional single point feeding circularly polarized wave microstrip antenna. FIG. 8 is a plan view of the antenna, a cross-sectional view taken along line D-D', and a structural diagram of a phased array antenna using the conventional broadband circularly polarized microstrip antenna shown in FIG. 3 as an element. 111-114... Radiation conductor, 121-124...
・Short-circuit conductor, 131-134... Feeding point, 14・
...Grounding conductor, 15...Dielectric material, 181-1
84... Shorting pin, 211-214... Radiation conductor, 221-224... Shorting conductor, 231-234
... Feeding point, 24... Grounding conductor, 25... Dielectric, 281-284... Shorting conductor, 311-31
4... Radiation conductor, 32T... Transmission side directional coupler, 32R... Receiving side directional coupler, 361 to 364
...Feeding line, 41...Antenna element, 42...
・Directional coupler, 43...phase controller, 44a・
...Power combiner, 44b...Power divider, 46.
...Receiving device, 47... Transmitting device, 411 to 414
... Radiation conductor, 420 ... Receiving side directional coupler,
421...Transmission side directional coupler, 461-464...
・Feeding line, 51... Radiation conductor, 52... Parasitic radiation conductor, 53.53'... Feeding point, 54...
Grounding conductor, 55... dielectric, 56... power supply line,
61... Radiation conductor of the receiving microstrip antenna, 62... Radiation conductor of the transmitting microstrip antenna, 63... Transmission feed point, 64... Ground conductor, 65... Dielectric material, 66...・・Transmission feeder line,
67... Reception power supply point, 68... Reception power supply line,
71... Radiation conductor, 72... Convex portion, 73... Feeding point, 74... Grounding conductor, 75... Dielectric material,
76... Feeding line, 81... Antenna element, 82
... directional coupler, 83 ... phase controller, 84.
...Power distributor, 85...Diplexer, 86
... Transmitting device, 87... Receiving device, 88... Pseudo load. Octopus 1 figure (Q) Octopus 2 figure '443 figure (b) Bacteria figure 4 (cup octopus 4 (2) (b)) 5th A (offering with the elbow vIG ■ ¥17 (illustration a) Octopus figure 8

Claims (4)

[Claims] (1) Four radiating conductors are placed on a dielectric plate placed on a grounding conductor, and a portion of the periphery of each of the four radiating conductors is short-circuited to the grounding conductor by a corresponding shorting conductor. In addition, the four radiation conductors are configured to pass through the ground conductor and the dielectric plate to be supplied with power to the respective feed points of the radiation conductors, and the four radiation conductors transmit radio waves of two desired frequencies. Two radiating conductors of two different sizes are arranged so that they can generate circularly polarized waves, and are arranged so that one wave can be used for transmitting and the other wave can be used for receiving at the same time. What is claimed is: 1. A microstrip antenna for circularly polarized wave feeding with dual frequency separation, characterized in that the antenna has a configuration in which: (2) Each of the four radiation conductors short-circuits the ground conductor and another part adjacent to the part of the radiation conductor short-circuited by the short-circuit conductor at a position different from the short-circuit conductor. A microstrip antenna for two-frequency separated feeding circularly polarized wave according to claim 1, characterized in that the antenna is provided with a short-circuiting means. (3) Claim 2, characterized in that the shorting means is composed of one or more shorting pins.
A microstrip antenna for dual-frequency separated feeding circularly polarized waves as described in 2. (4) The dual frequency circuit according to claim 2, wherein the short circuit means is constructed by applying solder or electrolytic plating to a plurality of through holes provided between the radiation conductor and the ground conductor. Microstrip antenna for separately fed circularly polarized waves.