The present disclosure relates to a preferable antenna device used in a small communication terminal such as a tag of a radio frequency identifier (RFID).
An RFID is an automatic recognition system that reads and writes individual information stored in a tag in a non-contact manner by using radio wave.
Reading and writing of an RFID tag of the individual information are performed by a reader and writer.
The tag of the RFID is referred to as various names such as the RFID tag, an IC tag, and a wireless tag, but the tag will be referred to as the RFID tag in the present specification.
In general, since the RFID tag radiates a linear polarized wave, a circularly polarized wave is used for the reader and writer in order to increase tolerance depending on a position of the RFID tag.
However, in a case where the circularly polarized wave is also used for an RFID tag side when the RFID tag and the reader and writer are opposed to each other, there is no polarization matching loss such that it is advantageous in a communication distance and a received electric power.
For example, as the antenna device that is used in the RFID tag, there are ones described in Japanese Patent No. 5636930 and Japanese Patent Unexamined Publication No. 2005-079970.
An antenna device described in Japanese Patent No. 5636930 includes a ground plate, two radiation conductor parts, each of two radiation conductor parts includes a feed part insulated and formed on the ground plate, a shorting part connected to the ground plate, and a conductor section which is connected to the feed part and the shorting part, in parallel with the ground plate, and separated and extended with a predetermined interval from the ground plate, and a feeder circuit that supplies electric power to the two radiation conductor parts with an opposite phase, in which the two radiation conductor parts are arranged in a point symmetry with respect to the ground plate by a center point of the ground plate as a point symmetry.
The antenna device described in Japanese Patent Unexamined Publication No. 2005-079970 includes a first radiation conductor plate opposite to a ground conductor plane approximately in parallel with each other, a second radiation conductor plate adjacent to the first radiation conductor plate by being disposed so as to be opposed approximately in parallel to the ground conductor plane via a slit (gap), a feeding conductor plate connected to a feeding circuit by extending approximately at a right angle from an outer edge not opposite to the slit of the first radiation conductor plate, a first short-circuit conductor plate connected to the ground conductor plan by extending approximately at the right angle from the outer edge not opposite to the slit of the first radiation conductor plate, and a second short-circuit conductor plate connected to the ground conductor plan by extending approximately at the right angle from the outer edge not opposite to the slit of the second radiation conductor plate, in which the first and second radiation conductor plates are brought close to each other in an approximately line symmetric positional relationship with the slit as a symmetry axis.
As described above, in a case where an RFID tag and a reader and writer are opposed to each other, it is advantageous in a communication distance and a reception electric power when a circularly polarized wave is also used for an RFID tag side.
However, there is a problem that it is difficult to implement a highly sensitive and a small antenna device having circular polarization characteristics.
An object of the present disclosure is to provide an antenna device which has circular polarization characteristics and high sensitivity in which miniaturization which can be used for small communication terminals such as RFID tags is achieved, and which is easily created.
The antenna device of the present disclosure includes a flat plate GND conductor plate; a first plate conductor that is disposed approximately in parallel to the GND conductor plate, and of which one end is grounded to the GND conductor plate, and the other end that is opposed to the one end is opened; and a second plate conductor that has approximately the same shape as that of the first plate conductor, of which one end is grounded to the GND conductor plate, of which the other end that is opposed to the one end is opened, that is disposed at a position obtained by rotating the first plate conductor approximately 180 degrees about an intersection line passing through an approximately central point of the GND conductor plate as an axis on the same plane as the first plate conductor on the GND conductor plate, and that has a ground portion at which the grounding is performed and an open portion at which the opening is performed at positions obtained by rotating the ground portion and the open portion of the first plate conductor approximately 180 degrees about the axis, in which the first plate conductor and the second plate conductor have a gap with approximately equal intervals between sides adjacent to each other, the gap is formed by a side other than the one end and the other end on a surface of the first plate conductor approximately in parallel to the GND conductor plate and a side other than the one end and the other end on a surface of the second plate conductor approximately in parallel to the GND conductor plate, a series of lengths from the other end that is an open end of the first plate conductor to the other end that is an open end of the second plate conductor, through the one end of the first plate conductor that is grounded, a position on the GND conductor plate on which the first plate conductor is grounded, a position on the GND conductor plate on which the second plate conductor is grounded, and the one end of the second plate conductor that is grounded, are almost equal to an electric length of approximately ½ wavelength of a frequency to be used, electric power is supplied from any one of the first plate conductor and the second plate conductor, and circularly polarized wave is radiated from a surface of the GND conductor plate not including the first plate conductor and the second plate conductor to a surface of the GND conductor plate including the first plate conductor and the second plate conductor.
According to the configuration, a configuration is adopted in which the first plate conductor is disposed approximately in parallel to the GND conductor plate, the second plate conductor formed with approximately the same shape as that of the first plate conductor is disposed approximately in parallel to the GND conductor plate while providing a gap with approximately equal intervals between sides adjacent to the first plate conductor, in the first plate conductor, of which one end is short-circuited to the GND conductor plate, of which the other end is opened, and in the second plate conductor of which one end of a side opposite to the first plate conductor is short-circuited and the other end is opened. Power supplying is performed from one of the first plate conductor and the second plate conductor, and the gap is formed by a side other than the one end and the other end on a surface of the first plate conductor approximately in parallel to the GND conductor plate and a side other than the one end and the other end on a surface of the second plate conductor approximately in parallel to the GND conductor plate.
Furthermore, in the first plate conductor and the second plate conductor, a series of physical lengths from the other end that is an open end of the first plate conductor to the other end that is an open end of the second plate conductor, through the one end of the first plate conductor that is grounded, a position on the GND conductor plate on which the first plate conductor is grounded, a position on the GND conductor plate on which the second plate conductor is grounded, and the one end of the second plate conductor that is grounded, are almost equal to an electric length of the approximately ½ wavelength of a frequency to be used.
In such a configuration, for example, when power supplying is performed in the vicinity of the short-circuited end of the second plate conductor, a current flows from the power supplying point toward an open end side on the second plate conductor, reaches an open end of the second plate conductor, and flows toward a short-circuited end side of the second plate conductor on the GND conductor plate, and when reaching the short-circuited end of the second plate conductor, the current flows from an open end to a short-circuited end side on the first plate conductor.
As described above, in a case where the electric power is supplied from the vicinity of the short-circuited end of the second plate conductor, the current flows through three paths of a current path on the second plate conductor->a current path on the GND conductor plate->a current path on the first plate conductor.
Since a series of physical lengths in the first plate conductor and the second plate conductor are almost equal to the electric length of the approximately ½ wavelength of the frequency to be used, it is possible to use an antenna of circularly polarized wave characteristics of the approximately ½ wavelength.
In addition, by implementing the antenna of approximately ½ wavelength, high sensitivity is achieved.
In addition, by arranging the first and second plate conductors on the same surface, it is possible to achieve miniaturization which can also be used in small communication terminals such as the RFID tag.
In addition, since it is a simple configuration of the GND conductor plate, and the first and second plate conductor, it is possible to easily create the antenna.
As an aspect of the antenna device of the present disclosure, for example, a distance from the ground portion of the first plate conductor to an edge of the GND conductor plate near the ground portion of the first plate conductor and a distance from the ground portion of the second plate conductor that is positioned at a rotationally symmetric position by the axis with respect to the ground portion of the first plate conductor to the edge of the GND conductor plate near the ground portion of the second plate conductor are almost equal to each other.
According to the configuration, it is possible to efficiently radiate the circularly polarized wave.
As an aspect of the antenna device of the present disclosure, for example, each of the first plate conductor and the second plate conductor has a plane shape of an approximately L shape.
According to the configuration, since physical lengths of each of the first plate conductor and the second plate conductor are short, the miniaturization is achieved.
As an aspect of the antenna device of the present disclosure, for example, each of the first plate conductor and the second plate conductor has a plane shape of an approximately rectangular shape.
According to the configuration, the circularly polarized wave characteristics are obtained and the high sensitivity is achieved.
In addition, it is possible to achieve miniaturization which can also be used in small communication terminals such as the RFID tag and it is possible to easily create the antenna device.
The antenna device of the present disclosure has the circular polarization characteristics and high sensitivity, miniaturization which can be used for the small communication terminals such as the RFID tags is achieved, and is easily created.
Hereinafter, a preferred embodiment of implementing the present disclosure will be described in detail with reference to the drawings.
In the figure, antenna device 1A according to the present embodiment includes flat plate GND conductor plate 2, first plate conductor 3, and second plate conductor 4.
Each of first plate conductor 3 and second plate conductor 4 has an approximately L shape flat plate, both of which are approximately parallel to each other on GND conductor plate 2, and are arranged to be adjacent to each other while providing gap (slit) 5 with approximately equal intervals between sides adjacent to each other.
A shape and arrangement of first plate conductor 3 and second plate conductor 4 will be described in more detail.
The first plate conductor 3 is disposed in parallel to GND conductor plate 2, of which one end 3a is grounded to GND conductor plate 2, and of which the other end 3b that is opposed to one end 3a is opened.
A shape of second plate conductor 4 is approximately the same as that of first plate conductor 3, of which one end 4a is grounded to GND conductor plate 2 and connected to a power supplying point 6, of which the other end 4b which is opposed to one end 4a is opened and disposed at a position in which first plate conductor 3 rotates by approximately 180 degrees about an intersection line passing through approximately central point C of GND conductor plate 2 as axis I on the same plane as (that is, at the same height as that of first plate conductor 3) first plate conductor 3 on GND conductor plate 2, and ground portion 20 and open portion 21 are provided at positions which ground portion 22 and open portion 23 rotate by approximately 180 degrees about axis I.
One end 4a of second plate conductor 4 is formed with three branch portions 4a1 to 4a3, central branch portion 4a2 is connected to power supplying point 6 provided on GND conductor plate 2, and both branch portions 4a1 and 4a3 are short-circuited to a ground pattern (not shown) of GND conductor plate 2.
An air layer is formed between GND conductor plate 2 and first plate conductor 3 and between GND conductor plate 2 and second plate conductor 4.
A dielectric may also be implemented between GND conductor plate 2 and first plate conductor 3 and between GND conductor plate 2 and second plate conductor 4.
As described above, first plate conductor 3 and second plate conductor 4 have approximately the same shape and size, and are arranged in a mutually opposite direction.
By such an arrangement, a shape of gap 5 between first plate conductor 3 and second plate conductor 4 becomes approximately an S shape.
For example, nickel silver (alloy composed of copper, zinc, and nickel) is used in first plate conductor 3 and second plate conductor 4.
In addition, for example, the copper foil for a circuit substrate (not shown) is used in GND conductor plate 2.
A combined length of first plate conductor 3 and second plate conductor 4 is almost equal to an electric length of an approximately ½ wavelength of a frequency to be used.
As illustrated in this figure, the combined length of first plate conductor 3 and second plate conductor 4 is a series of lengths of length La from the other end 3b (position indicated by circled numeral 1) that is an open end of first plate conductor 3 to the apex (position indicated by circled numeral 2) of the corner of one end 3a of first plate conductor 3 that is grounded, length Lb from the apex (position indicated by circled numeral 2) of the corner of one end 3a of first plate conductor 3 to the tip end (position indicated by circled numeral 3) in contact with GND conductor plate 2 of one end 3a of first plate conductor 3, length Lc from the tip end (position indicated by circled numeral 3) in contact with GND conductor plate 2 of one end 3a of first plate conductor 3 to the tip end (position indicated by circled numeral 4) in contact with GND conductor plate 2 of one end 4a of second plate conductor 4, length Ld from the tip end (position indicated by circled numeral 4) in contact with GND conductor plate 2 of one end 4a of second plate conductor 4 to the apex (position indicated by circled numeral 5) of the corner of one end 4a of second plate conductor 4, and length Le from the apex (position indicated by circled numeral 5) of the corner of one end 4a of second plate conductor 4 to the other end 4b (position indicated by circled numeral 6) of second plate conductor 4.
The series of lengths is almost equal to an electric length of the approximately ½ wavelength of the frequency to be used.
That is, La+Lb+Lc+Ld+Le≅λ<½ is satisfied.
However, it is desirable that lengths La, Lc, and Le be as close as possible.
In addition, lengths Lb and Ld are implemented sufficiently smaller than lengths La, Lc, and Le.
In addition, a positional relationship between GND conductor plate 2 and first plate conductor 3 and second plate conductor 4 is as follows.
That is, as illustrated in
In addition, distance Lcsd from ground portion 22 of first plate conductor 3 to an edge of GND conductor plate 2 near ground portion 22 of first plate conductor 3 and distance Lbsd from ground portion 20 of second plate conductor 4 that is a rotationally symmetric position by axis I with respect to ground portion 22 of first plate conductor 3 to an edge of GND conductor plate 2 near ground portion 20 of second plate conductor 4 are almost equal to each other.
In addition, for example, each of distances between GND conductor plate 2 and first plate conductor 3 and between GND conductor plate 2 and second plate conductor. 4 is approximately 1/100 wavelength to 1/50 wavelength.
In addition, for example, when miniaturization of antenna device 1A of the present embodiment is considered, a width of gap 5 between first plate conductor 3 and second plate conductor 4 is approximately 1/50 wavelength.
Antenna device 1A according to the present embodiment, electric power is supplied in the vicinity of the short-circuited end (one end 4a) of second plate conductor 4.
That is, as illustrated in
The electric power may be supplied in the vicinity of the short-circuited end (one end 3a) of first plate conductor 3.
By supplying the electric power from the vicinity of a short-circuited end of second plate conductor 4, circularly polarized wave is radiated in a direction orthogonal to GND conductor plate 2 from a surface (this is called as “back surface”) of GND conductor plate 2 not including first plate conductor 3 and second plate conductor 4 to a surface (this is called as “front surface”) of GND conductor plate 2 including first plate conductor 3 and second plate conductor 4.
That is, the circularly polarized wave is radiated in a direction indicated by arrow R in
Particularly, since a positional relationship between GND conductor plate 2 and first plate conductor 3 and second plate conductor 4 is set as described above, it is possible to efficiently radiate the circularly polarized wave.
That is, for example, since distance Lcsd and distance Lbsd are almost equal to each other by setting a frequency using distance Lcod and distance Lbod to 1/10 wavelength or more, it is possible to efficiently radiate the circularly polarized wave.
As illustrated in this figure, when the electric power is supplied from the vicinity of the short-circuited end from second plate conductor 4, an electric field occurs from all end portions except one end 3a of first plate conductor 3 short-circuited to GND conductor plate 2 and from all end portions except one end 4a of second plate conductor 4.
Particularly, the electric field of central portion 50 in which first plate conductor 3 and second plate conductor 4 are close to each other is a combination of an end portion electric field, and occurs between gap 5.
The electric field in an oblique transverse direction occurs in central portion 50, but it is possible to neglect the electric field because it is very small.
In addition, the electric field also occurs from end portions 51 and 52 of sides opposite to sides in which first plate conductor 3 and second plate conductor 4 are opposed to each other, but it is also possible to neglect the electric field because it is very small.
The electric field of radio wave radiated from antenna device 1A becomes the circularly polarized wave by end portion electric field (vertical electric field mode M2) occurs between gap 5 of first plate conductor 3 and second plate conductor 4 and by end portion electric field (horizontal electric field mode M1) occurred in each of the other end 3b that is opened of first plate conductor 3 and the other end 4b that is opened of second plate conductor 4.
Arrow 70 illustrated in
The arrow illustrated in the figure indicates a flow of a current.
In this case, arrows indicated by solid lines indicate flows on first plate conductor 3 and second plate conductor 4, and arrows indicated by dotted lines indicate flows on GND conductor plate 2.
As illustrated in
As illustrated in
As illustrated in
As described above, the electric power is supplied from the vicinity of the short-circuited end of second plate conductor 4, the current flows on three paths (1) to (3) of current paths on second plate conductor 4 (1)->a current path on GND conductor plate 2 (2)->a current path on first plate conductor 3 (3).
Since the total of these paths (1) to (3) is almost equal to the electric length of the approximately ½ wavelength of the frequency to be used, the total can be used as an antenna of circularly polarized wave characteristics of the approximately ½ wavelength.
In addition, by arranging the first and second plate conductors 3 and 4 on the same plane surface, it is possible to achieve miniaturization to be used for a small communication terminal such as an RFID tag, or by implementing the antenna of the approximately ½ wavelength, it is possible to achieve high sensitivity.
Furthermore, since the GND conductor plate and the first and second plate conductors 3 and 4 have a simple structure, it is possible to easily create them.
As illustrated in this figure, an eight-character radiation pattern is obtained, and maximum 2.9 (dBic) is obtained as a circularly polarized wave gain (dBic).
A range indicated by solid lines 80 and 81 is a half value width.
In a case where antenna device 1A according to the present embodiment is used in the RFID tag, the frequency to be used is 920 MHz.
In addition, angle ANG1 (see
As described above, since a configuration is adopted in which antenna device 1A according to the present embodiment includes flat plate GND conductor plate 2, first plate conductor 3, and second plate conductor 4, first plate conductor 3 is disposed approximately in parallel to GND conductor plate 2, of which one end 3a is short-circuited to GND conductor plate 2, and of which the other end 3b is opened, second plate conductor 4 is formed with approximately the same shape as that of first plate conductor 3, of which one end 4a on a side opposite to first plate conductor 3 is short-circuited, of which the other end 4b is opened, a series of physical lengths from the other end 3b of first plate conductor 3 to the other end 4b of second plate conductor 4, through one end 3a of first plate conductor 3, a position on GND conductor plate 2 on which first plate conductor 3 is grounded, a position on GND conductor plate 2 on which second plate conductor 4 is grounded, and one end 4a of second plate conductor 4 disposed approximately in parallel to GND conductor plate 2, while providing gap 5 with approximately equal intervals between sides adjacent to first plate conductor 3, are almost equal to the electric length of the approximately ½ wavelength of the frequency to be used, and the electric power is supplied from the vicinity of the short-circuited end (one end 4a) of second plate conductor 4, it is possible to obtain the antenna device which has the circularly polarized wave characteristics and high sensitivity and in which the miniaturization which can also be used for the small communication terminal such as the RFID tag is achieved, and it is possible to obtain the antenna device which can be easily created.
The disclosure described in the above-described Japanese Patent No. 5636930 is obviously different from the configuration of the present disclosure in that two power supplying points are provided and they are in opposite phases to each other.
In addition, the above-described Japanese Patent Unexamined Publication No. 2005-079970 is obviously different from the configuration of the present disclosure in that the GND short-circuited position is on the same side surface.
In antenna device 1A according to the present embodiment, as a form in which first plate conductor 3 is short-circuited to GND conductor plate 2, an end portion of first plate conductor 3 is bent at the right angle in a longitudinal direction such that the tip end thereof is connected. However, an extended portion in which the end portion of first plate conductor 3 is bent at the right angle in a width direction is provided such that the tip end may be connected.
An example thereof will be described below.
The same reference numerals are assigned to members in common with
As illustrated in
Projection piece 3Bc of first plate conductor 3B is bent at the right angle in the longitudinal direction of first plate conductor 3B.
Projection piece 4Bc of second plate conductor 4B is bent at the right angle in the longitudinal direction of second plate conductor 4B similar to projection piece 3Bc of first plate conductor 3B.
Power supplying in antenna device 1B of the first modification example is performed from the vicinity of the short-circuited end of second plate conductor 4B.
Projection piece 4Ba1 for supplying the electric power other than projection piece 4Bc is provided in one end 4Ba of second plate conductor 4B.
This projection piece 4Ba1 is connected to power supplying point 6 provided on GND conductor plate 2.
First plate conductor 3B has projection piece 3Bc on one side surface side. However, first plate conductor 3B may also have the same projection piece on the other side surface side.
In addition, second plate conductor 4B also has projection piece 4Bc on one side surface side. However, second plate conductor 4B may also have the same projection piece on the other side surface side.
Even short-circuiting with respect to GND conductor plate 2 of first plate conductor 3B and short-circuiting with respect to GND conductor plate 2 of second plate conductor 4B in antenna device 1B of the first modification example are performed on a side surface of each end portion, the same effect as that of the above-described antenna device 1A is obtained.
In addition, angle ANG1 in first plate conductor 3B and angle ANG2 in second plate conductor 4B may not be the right angle similar to the above-described antenna device 1A.
As illustrated in this figure, a radiation pattern is the eight-character shaped radiation pattern, and maximum 2.9 (dBic) is obtained as the maximum circular polarization gain (dBic).
Next, the second modification example of the above-described antenna device 1A will be described.
The same reference numerals are assigned to members in common with
As illustrated in
First plate conductor 3C is disposed approximately in parallel to GND conductor plate 2.
One end 3Ca of first plate conductor 3C is short-circuited to a ground pattern (not shown) of GND conductor plate 2 and the other end 3Cb is opened.
Second plate conductor 4C is disposed approximately in parallel to the same plane as first plate conductor 3C and to GND conductor plate 2.
One end 4Ca opposite to first plate conductor 3C of second plate conductor 4C is short-circuited to the ground pattern (not shown) of GND conductor plate 2 and the other end 4Cb is opened.
A shape of gap 5C between first plate conductor 3C and second plate conductor 4C is a straight line shape.
Power supplying in antenna device 1C of the second modification example is performed from the vicinity of the short-circuited end of one of first plate conductor 3C and second plate conductor 4C.
For example, in a case where the electric power is supplied from a second plate conductor 4C side, a shape of one end 4Ca of second plate conductor 4C is the same shape as that of one end 4a illustrated in
A series of lengths from the other end 3Cb that is an open end of first plate conductor 3C to the other end 4Cb that is an open end of second plate conductor 4C through one end 3Ca of first plate conductor 3C that is grounded, a position on GND conductor plate 2 on which first plate conductor 3C is grounded, a position on GND conductor plate 2 on which second plate conductor 4C is grounded, and one end 4Ca of second plate conductor 4C that is grounded, are almost equal to the electric length of the approximately ½ wavelength of the frequency to be used.
Antenna device 1C according to the second modification example having such a configuration also obtains the same effect as that of the above-described antenna device 1A.
Next, a third modification example of the above-described antenna device 1A will be described.
The same reference numerals are assigned to members in common with
As illustrated in
Other than this point, antenna device 1D has the same structure as antenna device 1A.
In addition, similar to antenna device 1C of the second modification example, the electric power is supplied from the vicinity of the short-circuited end one of first plate conductor 3D and second plate conductor 4D.
For example, in a case where the electric power is supplied from a second plate conductor 4D side, one end 4Da of second plate conductor 4D is the same shape as that of one end 4a illustrated in
The series of lengths from the other end 3Db that is an open end of first plate conductor 3D to the other end 4Db that is an open end of second plate conductor 4D, through one end 3Da of first plate conductor 3D that is grounded, a position on GND conductor plate 2 on which first plate conductor 3D is grounded, a position on GND conductor plate 2 on which second plate conductor 4D is grounded, and one end 4Da of second plate conductor 4D that is grounded are almost equal to the electric length of the approximately ½ wavelength of the frequency to be used.
Angle ANG1 in first plate conductor 3D and angle ANG2 in second plate conductor 4D may also not be the right angle similar to the above-described antenna device 1A.
Even in antenna device 1D of the third modification example of such a configuration, the same effect as the above-described antenna device 1A is obtained.
Application terminal 60 of the RFID tag illustrated in this figure includes housing case 61, circuit substrate 62, EH (energy harvest) antenna ground plate (corresponding to GND conductor plate 2) 63, cushion member 64, EH antennas 65 and 66 (corresponding to first plate conductor 3 and second plate conductor 4), RFID communication antenna 67, and housing cover 68.
For example, housing case 61 and housing cover 68 are configured with synthetic resin and ABS resin.
For example, cushion member 64 is configured with a foam material.
For example, a print pattern by copper foil or nickel silver is used in RFID communication antenna 67.
One end 66a of EH antenna 66 corresponding to second plate conductor 4 is formed with three branch portions, the central branch portion is connected to the power supplying point (not shown) provided on EH antenna ground plate 63 corresponding to GND conductor plate 2, and branch portions of both sides are short-circuited to a ground pattern (not shown) of EH antenna ground plate 63.
The power supplying point (not shown) provided on EH antenna ground plate 63 is connected to an RF output terminal (not shown) on circuit substrate 62 by a wire.
Since this application terminal 60 uses antenna device 1A, application terminal 60 has the circularly polarized wave characteristics and high sensitivity such that it is possible to achieve miniaturization and easily create the application terminal.
Antenna device 1B of
So far, although one embodiment of the present disclosure and its modification examples (first to third) have been described in detail, It will be apparent to those skilled in the art that various changes and modifications can be made without departing from the spirit and scope of the present disclosure.
The antenna device according to the present disclosure can be applied to the small communication terminal, energy harvest, and the like such as the tag of the RFID.
Number | Date | Country | Kind |
---|---|---|---|
2016-245400 | Dec 2016 | JP | national |
2017-107966 | May 2017 | JP | national |