Japanese Patent Application Tokugan No. 2004-186812 is hereby incorporated by reference.
This invention relates to an antenna generating circularly polarized waves, in particular, to a circularly polarized loop antenna generating circularly polarized waves from a loop-shaped conductor whose length is equal to 1 wavelength of the transmitted and received signals.
Loop antennas comprising loop-shaped conductors, curl antennas comprising curl-shaped conductors, and other types of antennas have been designed in the past as antennas for generating circularly polarized waves.
Disclosed loop antennas include an antenna comprising a C-type loop element obtained by cutting out a predetermined gap in a portion of a loop-shaped conductor, whose length is approximately equal to 1 wavelength of the radiated circularly polarized waves, a linear I-shaped conductor one end of which is connected to the C-type loop element and the other end of which serves as a feed point, a ground plane disposed in parallel to the C-type loop element, and a feed conductor, which is connected to the feed point and transmits electric power to the feed point (for example, see Patent document 1).
In addition, disclosed curl antennas include an antenna comprising a spiral-shaped curl section with a turns number in the range of from about 1 to about 1.5, in which a wire conductor is formed by joining semi-circles of different shape and whose length is approximately equal to 1 wavelength of the radiated circularly polarized waves, and a shaft section, one end of which is connected to the beginning of the curl section and the other end of which is connected to a power supply conductor (for example, see Patent document 2).
Problem to be Solved by the Invention
However, the strength of the loop antenna described in Patent document 1 was low because it was a C-type loop antenna with a section of the loop-shaped conductor cut out with a predetermined gap, i.e. it was not a closed shape.
Additionally, the curl antenna described in Patent document 2 had low strength because it was not a closed-shaped antenna, in the same manner as the above-mentioned C-type loop antenna, and moreover, because it was curled, the shape required to obtain the prescribed characteristics was not easy to maintain.
Therefore, it is an object of the present invention to build an easy-to-fabricate and relatively strong circularly polarized loop antenna of a simple construction.
Means for Solving Problem
This invention provides a circularly polarized loop antenna comprising a loop section made up of a conductor, the length of a single turn of which is approximately equal to 1 wavelength of the transmitted and received signals, and a feed section performing input/output of signals to/from the loop section, wherein the feed section comprises a coupling section which has one end connected to the loop section and the other end to a feed point, and which extends from the point of connection to the loop section along the loop section for a length approximately equal to ¼ of the wavelength.
Because in this configuration the loop section has a length approximately equal to 1 wavelength of the transmitted and received signals and the coupling section has a length equal to ¼ of the wavelength, in accordance with the principle described below, there are essentially two standing waves generated in the loop section.
As illustrated in
First of all, when the switch 53 is turned off, the connection point 500 is released, with the connection point 500 operating as a node and generating a current standing wave in the semi-infinite line 51 and coupling line 52, as illustrated in
Here, the location of 1 wavelength (λ) of the transmitted signal from the point of connection 500 of the semi-infinite line 51 to the coupling line 52 corresponds, quite naturally, to a node of the current standing wave Iw1. For this reason, a similar current standing wave is generated if the semi-infinite line 51 is cut at a point corresponding to 1 wavelength (λ) from the connection point 500 and connected to the connection point 500. Thus, a construction, in which the severed line 51′ is imparted a circular configuration and a coupling line 52 is disposed therealong, corresponds to the circularly polarized loop antenna of the present invention. In other words, a current standing wave identical to the current standing wave Iw1 illustrated in
On the other hand, when the switch 53 is turned on, the connection point 500 is shorted to the ground, with the connection point 500 operating as an antinode and generating a current standing wave Iw2 in the semi-infinite line 51 and coupling line 52, as illustrated in
Here, the position of 1 wavelength (λ) of the transmitted signal from the point of connection 500 of the semi-infinite line 51 to the coupling line 52 corresponds, quite naturally, to an antinode of the current standing wave Iw2. For this reason, a similar current standing wave Iw2 is generated if the semi-infinite line 51 is cut at a point corresponding to the length of 1 wavelength (λ) from the connection point 500 and connected to the connection point 500. Thus, the construction, in which the severed line 51′ is imparted a circular configuration and a coupling line 52 is disposed therealong, also corresponds to the circularly polarized loop antenna of the present invention. In other words, a current standing wave identical to the current standing wave Iw2 illustrated in
In this manner, with a single feed point, the thus configured circularly polarized loop antenna of the present invention forms two virtual feed points spaced at an interval of ¼ of the wavelength along the loop section, with respective standing waves generated by these two virtual feed points. This actually corresponds to the construction of an ideal circularly polarized loop antenna 1, as illustrated in
In addition, the loop antenna of this invention is characterized by the fact that the coupling section is arranged on the inner periphery of the loop section.
In this configuration, a one-layer electrode pattern etc. is used to implement an antenna configuration, where the coupling section is arranged on the inner periphery of the loop section, as a result of which the loop section and the coupling section are arranged within the same plane and, at the same time, the coupling section is connected to the point of connection to external circuitry disposed in the central location of the loop section.
In addition, the loop antenna of this invention is characterized by the fact that the coupling section is arranged on the side of the loop section facing the reflective plate.
Because in this configuration the coupling section is arranged on the side facing the principal direction of radiation of circularly polarized waves from the loop section, the effects exerted by the coupling section on the radiation characteristics are suppressed.
In addition, the loop antenna of this invention is characterized by the fact that the coupling section is arranged on the outer periphery of the loop section.
In this configuration, by arranging the coupling section on the outer periphery of the loop section, the impedance of the loop antenna is decreased from at least 150Ω to about 50Ω.
In addition, the loop antenna of the present invention is characterized by the fact that the feed section comprises a matching section performing impedance matching on signals supplied to the coupling section or signals outputted from the coupling section.
In this configuration, the loop antenna has the desired radiation characteristics and even if its impedance is different from external connect circuitry, e.g. transmit signal generating circuitry or receive signal processing circuitry, etc., impedance matching is carried out by the matching section.
Effects of the Invention
Based on this invention, an ideal 1-wavelength loop antenna can be built by providing it with a loop-shaped conductor of a closed shape, whose length is approximately equal to 1 wavelength (λ) of the transmitted and received signals, and a coupling section extending in parallel to the loop-shaped conductor for a length approximately equal to ¼ of the wavelength, and by connecting one end of the coupling section to the loop-shaped conductor and the other end to a feed point. This makes it possible to build an easy-to fabricate and relatively strong circularly polarized loop antenna with a superior axial ratio and a simple construction.
In addition, in accordance with this invention, arranging the coupling section on the inner periphery of the loop section permits implementation of a loop antenna on a one-layer electrode pattern substrate. This makes it possible to build a simple loop antenna providing the effects described above.
In addition, this invention improves radiation characteristics by arranging the coupling section on the side of the loop section facing the reflective plate. In other words, a loop antenna can be built that has better radiation characteristics.
In addition, in accordance with this invention, arranging the coupling section on the outer periphery of the loop section makes it possible to adjust the impedance of the loop antenna to about 50Ω and enables it to be directly connected to 50-Ω transmission lines typically used in communication systems as well as to be directly used with 50-Ω electric components and measurement devices, which permits easy and inexpensive antenna assembly, tuning and inspection.
In addition, in accordance with this invention, connecting the coupling section to external circuitry through a matching section suppresses signal transmission losses in the process of input/output between the loop antenna and the external circuitry and makes it possible to build a circularly polarized loop antenna possessing highly efficient transmission-reception characteristics.
The circularly polarized loop antenna of a first embodiment of the present invention will be explained by referring to drawings.
As shown in
Additionally, a reflective plane 2, which is made up of a conductor formed to have a surface area that is at least greater than the surface area of the loop section 11, is located in a position spaced a predetermined distance from the circumferential plane of the loop section 11 towards the second feed conductor 14 (vertically downwards in the figure), with a through hole formed in the reflective plate 2 and the second feed conductor 14 passing through the through hole and connected via the reflective plate 2 to the external circuitry located opposite the loop section 11. Here, in the present embodiment, the coupling section 12, first feed conductor 13, and second feed conductor 14 correspond to the “feed section” of the present invention.
Because in the thus configured circularly polarized loop antenna the loop section 11 has a length approximately equal to 1 wavelength of the transmitted and received signals and the coupling section 12 has a length equal to ¼ of the wavelength, in accordance with the principle described below, there are essentially two standing waves generated in the loop section 11.
Because the loop section 11 has a length approximately equal to 1 wavelength (λ) of the transmitted and received signals, with respect to the standing wave, it can be viewed as an equivalent of a semi-infinite line ending in the connection point 201. In addition, the coupling section 12 can be viewed as a feed line having one end at the connection point 201, extending along the semi-infinite line (loop section 11) for a length equal to ¼ of the wavelength of the transmitted and received signals, and having its other end at the feed point.
In the thus constructed antenna, two standing waves are generated depending on the state of the connection point 201, with the waves having a mutual phase difference corresponding to the length of λ/4. In other words, if the connection point 201 is grounded, the current standing wave illustrated in FIG. 20 is generated, and if the connection point 201 is released (not grounded), then the current standing wave illustrated in
When these states are applied to a loop-shaped antenna, namely, the circularly polarized loop antenna 1, grounding the connection point 201 generates the current standing wave illustrated in
As a result, the circularly polarized loop antenna 1 functions as an ideal circularly polarized loop antenna. In other words, the configuration of the present embodiment permits implementation of an ideal circularly polarized loop antenna of a simple construction possessing a superior axial ratio.
In addition, because in the configuration of the present embodiment the loop section 11 has a closed-loop shape, it has higher strength against external pressures in comparison with the C-type loop shape, which has a cutout portion, and the curl shape, which has different diameters at the initial point and final point. In addition, because the loop section 11 has a closed-loop shape and the coupling section has a matching shape, the antenna is easy to fabricate. Therefore, using the configuration of the present embodiment makes it possible to build a high-strength, easy-to-fabricate loop antenna.
Loop antenna simulation results obtained using the configuration of the present embodiment are explained next.
As shown in
It should be noted that, in the loop antenna used to obtain the simulation results illustrated in
As shown in
A Smith chart obtained using a loop antenna of such a configuration is shown in
In addition, as shown in
As described above, using the configuration of the present embodiment makes it possible to build a high-strength, easy-to-fabricate loop antenna possessing superior axial ratio characteristics and directivity.
It should be noted that in the construction of the present embodiment, in which the coupling section is disposed on the inner periphery (towards the center) of the loop section, the loop section 11, the coupling section 12, and the first feed conductor 13 can be formed using a single layer on one of the faces of a single substrate and the loop antenna can be thus fabricated more easily.
The loop antenna of a second embodiment is explained next by referring to drawings.
As shown in
The axial ratio characteristics, radiation characteristics, and a Smith chart of a 1410-MHz signal (circularly polarized waves) produced by the thus configured loop antenna are shown in
As shown in
It should be noted that in the present embodiment connection to external circuitry can be implemented without problems by using an impedance matching circuit such as the ones illustrated in
The loop antenna of the third embodiment is explained next by referring to drawings.
As shown in
The radiation characteristics and a Smith chart of a 1585.75-MHz signal (circularly polarized waves) produced by the thus configured loop antenna are shown in
As shown in
It should be noted that while in the construction illustrated in the present embodiment the first feed conductor 13 extends normally to the reflective plate 2 and the second feed conductor 14 is arranged so as to extend in parallel to the reflective plate 2, the impedance is reduced to about 50Ω simply by arranging the coupling section 12 on the outer periphery of the loop section 11. For this reason, the antenna may be constructed as shown in
The loop antenna illustrated in
Also, it should be noted that while all the embodiments described above illustrate a right-hand polarized loop antenna comprising a coupling section extending in the counterclockwise direction with respect to the feed point, a similar configuration can be applied, and the above-described effects can be obtained, in a left-hand polarized loop antenna comprising a coupling section extending in the clockwise direction with respect to the feed point.
This invention can be used for an antenna generating circularly polarized waves, in particular, a circularly polarized loop antenna generating circularly polarized waves from a loop conductor whose length is equal to 1 wavelength of the transmitted and received signals.
Number | Date | Country | Kind |
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JP2004-186812 | Jun 2004 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP05/10619 | 6/9/2005 | WO | 12/21/2006 |