JP6509271B2 - Dual-polarization antenna, antenna unit, and watch - Google Patents

Description

  The present invention relates to a dual polarization transmitting / receiving antenna, an antenna unit, and a watch, and relates to, for example, an antenna for GPS which is mounted on a metal case such as a watch and transmits / receives vertical polarization and horizontal polarization.

For example, in small portable terminals, watches, etc., the case where an antenna is disposed in a housing containing metal is increasing. For example, Patent Literatures 1 and 2 propose a technique for arranging a plate-like inverted F antenna using a metal casing portion of a watch.
However, in the techniques described in Patent Literatures 1 and 2, each antenna is disposed for single polarization, and two polarizations of horizontal polarization and vertical polarization orthogonal to each other are received. It was not possible.
In addition, when an antenna is incorporated in a metal casing, there is a problem that the characteristics as the antenna deteriorate due to the influence of metal such as a battery or the influence of the movement in the case of a watch.

By the way, when transmitting and receiving two polarizations of vertical polarization and horizontal polarization, two feeding points corresponding to both polarizations are required.
A polarization sharing antenna has been proposed as a technique for transmitting and receiving such two polarized waves (see Non-Patent Documents 1 and 2). This polarization sharing antenna can switch between two polarizations of vertical polarization and horizontal polarization at the same frequency, or transmit and receive simultaneously, and is used in the field of satellite communication, remote sensing, and the like.

However, in the conventional polarization sharing antenna, it is necessary to prepare a feed line for each of the two vertical polarization antennas and the horizontal polarization antenna disposed on the same plane.
In addition, in order to simultaneously transmit and receive two antennas, it is necessary to prepare a high frequency circuit for each of the vertically polarized antenna and the horizontally polarized antenna.

JP 2001-185927 A Japanese Patent Application Publication No. 2003-156576

IEICE technical report '92 / 7 Vol. J75-B-IINo. 7 "A Note on Linearly Polarized Shared Planar Antenna (Akinori Matsui, Misaki Haishi)" IEICE technical report. AP2000-118 "Planar antenna with polarization and its radiation characteristics (Megumi Konno, Misaki Haishi)"

  An object of the present invention is to make it possible to transmit and receive vertically polarized waves and horizontally polarized waves with a simpler configuration with less deterioration of characteristics due to a case having a metal surface portion.

(1) In the invention according to claim 1, a metal casing made of metal is short-circuited to the metal casing having one end as the ground conductor plate, and the other end approaches another position of the metal casing. And a main antenna having an antenna element of a predetermined length generating a polarization component by feeding, and a parallel arrangement on the same plane as the antenna element, and feeding the antenna element by electromagnetic coupling, and A dual polarized wave transmitting and receiving antenna comprising: a feeding unit of a predetermined length generating a polarized wave component orthogonal to a polarized wave component by an electromagnetic coupling unit; and a feeding line feeding the feeding unit. .
(2) In the invention according to claim 2, the metal casing has a recess of a predetermined length, and one end of the antenna element is short-circuited with the end face on one side in the length direction of the recess, and the other end The antenna for transmitting and receiving both polarized waves according to claim 1 is disposed close to the end face of the other side of the recess.
(3) In the invention according to claim 3, the main antenna is connected to the other end of the antenna element, disposed close to and in parallel with the other end face in the lengthwise direction of the recess. The dual polarized wave transmitting and receiving antenna according to claim 2, further comprising a bent portion.
(4) In the invention according to claim 4, the metal casing includes a cylindrical peripheral wall, a bottom surface arranged on one end surface of the peripheral wall, and an inward facing flange arranged on the other end surface of the peripheral wall The dual-polarization transmitting and receiving antenna according to claim 2 or 3, further comprising a portion, wherein the recess is circumferentially formed in the inward flange portion.
(5) In the invention according to claim 5, the metal casing has a cylindrical peripheral wall and a bottom surface disposed on one end face of the peripheral wall, and the recess is a periphery of the peripheral wall. The two-polarization transmitting and receiving antenna according to claim 2 or 3, characterized in that it is formed in a direction.
(6) In the invention according to claim 6, the antenna unit is configured as an antenna unit for transmitting and receiving both polarized waves by being incorporated into a recess of a predetermined length formed in a metal casing, In the dual polarized wave transmitting and receiving antenna according to any one of claim 5, the main antenna, the feeding portion, and the feeding line are molded with a dielectric, and the other end of the antenna element is An antenna unit is provided, which is exposed from the dielectric of the antenna unit so as to allow a short circuit connection with a metal housing.
(7) The invention according to claim 7 provides the antenna unit according to claim 6, characterized in that a spring portion is formed on the exposed other end of the antenna element.
(8) In the invention according to claim 8, the dual polarized wave transmitting and receiving antenna according to any one of claims 1 to 5 and at least the antenna disposed in the metal casing A watch comprising: a windshield; a dial; a pointer; and a watch unit having a movement for driving the pointer.

According to the present invention, since the metal casing is used as the ground conductor plate of the antenna element, the characteristic deterioration can be further reduced.
In addition, power is supplied to the antenna element by electromagnetic coupling, and a polarization component orthogonal to the polarization component of the antenna element is generated at the electromagnetic coupling unit to transmit / receive vertical polarization and horizontal polarization with a simpler configuration. be able to.

It is a perspective view showing composition of a dual polarization transmission and reception antenna. It is an explanatory view showing details of an antenna unit. It is explanatory drawing showing the size of each part in the antenna for dual polarization transmission and reception. It is explanatory drawing about the polarized wave radiated | emitted from the antenna for both polarized-wave transmission and reception. It is explanatory drawing about the shape and size of the antenna for both polarized-waves transmission / reception which simulated. It is explanatory drawing which represented the return loss characteristic of the antenna for both polarization transmission-and-reception by simulation. It is explanatory drawing showing the radiation characteristic of the antenna for both polarizations transmission and reception by simulation. It is an external view of the timepiece provided with the antenna for both polarized-waves transmission and reception.

BEST MODE FOR CARRYING OUT THE INVENTION Preferred embodiments of the dual polarized wave transmitting / receiving antenna 1, antenna unit 20 and watch 100 of the present invention will be described in detail below with reference to FIGS.
(1) Outline of Embodiment The present embodiment is an antenna technology for GPS, which has a resonant frequency of 1.575 GHz and is mounted on a metal case such as a watch.
The dual polarized wave transmitting and receiving antenna 1 of the present embodiment uses a metal casing as a ground conductor plate of the main antenna 30, and differs from the main antenna 30 in the feeding antenna unit 50 (EM feeding unit) for feeding by electromagnetic coupling. It functions as an antenna in the radial direction.
Then, since the polarization component generated in the main antenna 30 and the polarization component generated in the EM coupling portion between the main antenna 30 and the feeding antenna unit 50 are orthogonal to each other, the dual polarization transmitting / receiving antenna capable of receiving also as a GPS antenna It is one. For example, when the dual polarized wave transmitting / receiving antenna 1 is disposed on the timepiece 100, it can be practically used as a GPS antenna having the maximum radiation direction of both horizontal and vertical polarized waves in the Z direction orthogonal to the dial plate 101.
In the simulation results, the dual polarized wave transmitting / receiving antenna 1 with a resonant frequency of 1.575 GHz has an antenna size of 35 mm × 2.5 mm × 0.5 mm, and is smaller than a dipole antenna (having a total length of about 95 mm).
Further, according to the dual polarized wave transmitting and receiving antenna 1 of the embodiment, a high efficiency of 66.8% (1.575 GHz) can be obtained.
In addition, by utilizing the metal casing as the ground conductor plate of the main antenna 30, it is possible to reduce the characteristic deterioration due to the internal container and the like.
Furthermore, since the polarization component by the main antenna 30 and the polarization component at the time of the electromagnetic feeding by the feeding antenna unit 50 are generated by one electromagnetic feeding, the size can be further reduced and the configuration is simpler. Transmission and reception of vertical polarization and horizontal polarization.

(2) Details of Embodiment First, the dual polarized wave transmitting / receiving antenna 1 and the antenna unit 20 will be described.
FIG. 1 is a perspective view showing the configuration of the dual polarized wave transmitting and receiving antenna 1 in the first embodiment.
As shown in FIG. 1, the dual polarized wave transmitting / receiving antenna 1 includes a metal case 10 made of metal, and an antenna unit 20 whose unit base is made of a dielectric such as ceramic or resin.
The metal casing 10 is provided with a circumferential wall 11 formed in a cylindrical shape, an inward facing flange portion 15 disposed on one side of the circumferential wall 11, and a bottom surface 12 disposed on the other side of the circumferential wall 11 It has a cylindrical concave housing as For example, various devices such as a watch movement and a portable terminal, circuits, batteries, and the like can be accommodated and disposed in the cylindrical concave accommodation portion.
The inward facing flange portion 15 is in the shape of a bowl facing the center, and is formed of an annular plate portion having the same outer diameter as the peripheral wall 11 and a smaller inner diameter than the peripheral wall 11. The inward facing flange portion 15 is integrally formed with the peripheral wall 11.
Although the inward flange portion 15 is provided in the present embodiment, the thickness of the peripheral wall 11 may be the same as the width of the peripheral wall 11 in the radial direction. In this case, the inward flange portion 15 is unnecessary.

As shown in FIG. 1B, a peripheral wall step 13 (recess) is formed in a part of the inward flange portion 15 at which the antenna unit 20 is set (incorporated). The peripheral wall step portion 13 is formed inside, leaving a side wall 16 having the same thickness as the radial thickness of the peripheral wall 11. The peripheral wall step portion 13 is a recess directed from the inner peripheral surface side to the outer peripheral surface side (side wall 16 side) of the peripheral wall 11 and is a recess directed from the upper end surface of the inward flange portion 15 to the bottom surface 12 side.
A through hole 14 is formed on the bottom surface of the concave portion facing the bottom surface 12 of the peripheral wall step portion 13 at a substantially central portion in a curved length direction (a position corresponding to a feeding point 53 described later in detail). The through hole 14 is a hole through which the feed line 40 from the high frequency circuit passes. The feed line 40 is connected to a feed point 53 of a feed antenna unit 50 described later.
The feed line 40 is connected at one end to the feed line 52 through the through hole 14 and at the other end to a high frequency circuit (not shown).
By incorporating the antenna unit 20 in the direction of the arrow J in the peripheral wall step portion 13, the dual polarized wave transmitting and receiving antenna 1 of FIG. 1A is formed. When the antenna unit 20 is incorporated, it is fixed to the peripheral wall step portion 13 by fixing means such as press fitting, adhesion, or screwing. When bonding the antenna unit 20, it is bonded to the end face in the longitudinal direction of the antenna unit 20 with the surface excluding the area around the shorting portion 33 and the feeding point 53, so that the metal surface to be shorted and the feeding line Make sure that the shorting point etc. is connected.
As described above, by incorporating the antenna unit 20 in the peripheral wall step portion 13 of the metal housing 10, the compact dual polarized antenna 2 for transmitting and receiving polarization can be configured. Also, the antenna unit 20 can be easily arranged and mounted on the metal housing 10.

FIG. 2 shows the details of the antenna unit 20. As shown in FIG.
FIG. 2A is an external perspective view of the antenna unit 20, and FIG. 2B is a perspective side view of the antenna unit 20 as viewed from the center side. In the transparent side view of (b), the external line of the antenna unit 20 is represented by a dotted line so that the internal antenna member can be seen through.
The antenna unit 20 is provided with a main antenna 30 and a feeding antenna unit 50, and is formed in a curved rod shape by molding with a dielectric unit 21 such as ceramic or resin. The antenna unit 20 is formed in accordance with the shape of the peripheral wall step 13 which is the installation destination.
The antenna unit 20 of the present embodiment can be miniaturized by using ceramic for the unit base (dielectric portion 21), and the antenna unit 20 can have high strength.

The main antenna 30 includes an antenna element 31, a bent portion 32, and a short circuit portion 33.
The antenna element 31 is formed of a metal such as copper so that both side surfaces along the longitudinal direction of the plate surface are curved, that is, the same curvature as that of the peripheral wall 11. The antenna element 31 is disposed parallel to the bottom surface 12. As shown in FIG. 2A, the antenna element 31 of the present embodiment is disposed at the end portion on the inner peripheral surface side on the upper surface (the surface opposite to the surface facing the bottom surface 12) of the antenna unit 20. Thus, one plate surface is exposed (exposed) from the dielectric portion 21. However, the antenna unit 20 is formed so that the entire antenna element 31 is buried in the dielectric portion 21. It is also good.

A bent portion 32 bent radially outward is extended at a predetermined distance s from the longitudinal direction end of the antenna unit 20 at an end of the antenna element 31 on one side. When the antenna unit 20 is incorporated into the peripheral wall step portion 13, the bent portion 32 is disposed to face the portion of the inward flange portion 15 that constitutes the end face of the peripheral wall step portion 13. Thereby, loading of capacitance is realized between the bent portion 32 and the end face of the peripheral wall step portion 13, and the antenna can be further miniaturized. That is, since the resonance frequency is lowered by the loading of the capacitance, the antenna can be miniaturized as compared with the antenna of the same resonance frequency.
The predetermined distance s is set to a distance that can obtain the required amount of capacitance according to the degree of miniaturization required.
Although the predetermined distance s = 0.1 mm is set in the present embodiment, the present invention is not limited to this. For example, although depending on the dielectric constant of the dielectric portion 21, in consideration of miniaturization of the antenna, it is preferable that the upper limit be 1.0 mm or less.
In addition, the bending part 32 is not essential, and the bending part 32 is unnecessary when size reduction by loading of a capacitance is not required.

The other end of the antenna element 31 is extended to the end of the antenna unit 20.
At the end face of the antenna unit 20 in the longitudinal direction, a short circuit portion 33 is disposed on the upper side of the end face. The upper end of the short circuit portion 33 is continuous with the other end of the antenna element 31. The short circuiting portion 33 has a function of shorting the antenna element 31 to the metal casing 10 (the side wall of the circumferential wall stepped portion 13) which functions as a ground conductor plate when the antenna unit 20 is incorporated into the circumferential wall stepped portion 13 of the metal casing 10. have. For this reason, in order to ensure the short circuit by the short circuit part 33, spring parts, such as a spring plate, are used. In addition, a short circuit with the metal casing 10 can be formed by forming a portion (this obtains a spring function) away from the end face of the antenna unit 20 in a part of the short circuit portion 33 or by forming a swell or a convex portion. You can be sure.

  Thus, the antenna element 31 extends in the longitudinal direction inside the upper surface of the antenna unit 20, one end is connected to the radially extending bent portion 32, and the other end is formed on the end face of the antenna unit 20. And connected.

The feed antenna unit 50 is T-shaped, and includes a feed unit 51 corresponding to the horizontal bar portion and a feed line 52 corresponding to the vertical bar portion.
The feeding portion 51 is formed to be curved at the same curvature as the antenna element 31 by a metal such as copper. The feeding portion 51 is disposed on the same plane as the antenna element 31, and the inner side in the width direction (radial direction) is disposed opposite to the antenna element 31 at a predetermined distance from the antenna element 31 at the outer side in the radial direction. ing.
The feeding portion 51 of the present embodiment is disposed to correspond to the central portion in the longitudinal direction of the antenna element 31. However, the feeding part 51 does not have to be disposed at the central portion, and may be shifted to the bent part 32 or the shorting part 33 side.
That is, any position in the length direction of the antenna element 31 can be satisfied as long as two conditions of the feeding portion 51 not being in contact with the bent portion 32 and the fact that the feeding portion 51 is not exposed at the end face of the antenna unit 20 near the shorted portion 33 are satisfied. It is possible to arrange in However, the end of the feeding part 51 is from the bending part 32 or the end face of the antenna unit 20 from the end face of the antenna unit 20 so that the end of the feeding part 51 is opposite to the feeding part 51. The distance to the end face is preferably separated by about the length of the feeding portion 51, and the vicinity of the central portion is optimum.

As shown in FIG. 2B, one end of the feed line 52 is connected near the longitudinal center of the feed section 51, and the other end of the feed line 52 is exposed from the dielectric section 21 as a feed point 53. It is in the (exposed) state. Thereby, in a state where the antenna unit 20 is incorporated in the peripheral wall step portion 13 of the metal housing 10, the feed line 40 passing through the through hole 14 formed corresponding to the position of the feed point 53 (see FIG. 1B) ) And the feed line 52 are connected at the feed point 53.
The feed unit 51 is electromagnetically coupled (EM coupled) to the antenna unit 20 by facing the antenna unit 20.
In FIG. 2B, the position of the feeding portion 51 is slightly lowered for the purpose of clarifying the range of the feeding portion 51, but the actual antenna element 31 and the feeding portion 51 are on the same plane. It is arranged. Similarly, the antenna element 31 is also offset from the dotted line showing the outline line.

FIG. 3 shows the size of each part in the dual polarization transmitting / receiving antenna 1.
The dual polarization transmitting / receiving antenna 1 is an antenna size for GPS with a resonance frequency of 1.575 GHz.
The outer diameter of the metal housing 10 is R mm, and, for example, when the metal housing 10 is used as a main case of a watch, it is selected in the range of 15 mm to 25 mm.
As shown in FIG. 3, the antenna unit 20 has a width of 3 mm and a length of 35 Q mm on the inner side. Here, assuming that the relative permittivity of the dielectric portion 21 is εr, Q = √εr. Although the thickness of the antenna unit 20 is 3 mm (not shown), this thickness can be changed suitably.
The length of the antenna element 31 is (35 × Q−0.1) mm, and the width and thickness are 0.5 mm (not shown). The length of -0.1 mm corresponds to a distance of 0.1 mm (= predetermined distance s) between the bent portion 32 and the inward facing flange portion 15 described later.
The bent portion 32 has a length of 2 mm and a width and a thickness of 0.5 mm (not shown).
The feeding part 51 of the feeding antenna part 50 has a length of 5 mm and a width and a thickness of 0.5 mm (not shown).
Although not shown, the feed line 52 is determined in accordance with the thickness of the antenna unit 20 so that the feed point 53 is exposed from the antenna unit 20, and is about 3 mm in this embodiment. Although the width and thickness (or diameter) of the feed line 52 are also arbitrary, they are 0.5 mm × 0.5 mm in the present embodiment.
The distance between the feeding portion 51 and the antenna element 31 is 0.6 mm. Although not shown, the distance between the feed antenna 50 and the side wall 16 is 1.4 mm, but is shifted in the radial direction due to the size of the drawing.

FIG. 4 is an explanatory view of the polarization radiated from the dual polarization transmitting / receiving antenna 1.
As described above, the dual polarized wave transmitting and receiving antenna 1 includes the main antenna 30 and the feeding antenna unit 50.
And as shown in FIG. 4, from the antenna element 31 of the main antenna 30, the polarization component 30z is radiated along the curved length direction (circumferential direction).
On the other hand, a radial polarization component 50z is radiated from the feeding antenna unit 50 in the process of feeding the antenna element 31 oppositely disposed with EM.
As described above, according to the dual polarized wave transmitting and receiving antenna 1, two polarized waves in directions orthogonal to each other are radiated by the main antenna 30 and the feeding antenna unit 50. And by setting the resonance frequency to 1.575 GHz as described later, it can be used as an antenna for GPS.
When the direction orthogonal to the bottom surface 12 of the metal casing 10 (the axial direction of the peripheral wall 11) is taken as the Z-axis direction, the radiation directions of both polarization components 30z and 50z are the Z direction.
As described above, according to the dual polarization transmitting / receiving antenna 1 of the present embodiment, the polarization component 30z by the main antenna 30 and the polarization component 50z orthogonal thereto by the electromagnetic one-point feeding from the feeding antenna 50. Can be radiated, so that the feeding portion and the high frequency circuit can be simplified, and it is possible to obtain a dual polarization transmitting / receiving antenna capable of transmitting / receiving vertical polarization and horizontal polarization with a simpler configuration.

Next, simulation results of the dual polarization transmitting and receiving antenna 1 will be described.
FIG. 5 is an explanatory view of the shape and size of the dual polarization transmitting / receiving antenna 1 which has been simulated.
While the side wall of the metal housing 10 is the cylindrical peripheral wall 11 in the embodiment described above, in the simulation, it was efficiently performed by using the rectangular metal housing 10 as shown in FIG. However, since the dual polarized wave transmitting and receiving antenna 1 of the embodiment described is assumed to be a watch, it is described as a cylindrical shape, but there is also a square watch and it is mounted on various electronic devices such as portable terminals. It is not always necessary to be circular, and it is also possible to use the dual polarized wave transmitting and receiving antenna 1 shown in FIG.

As shown in FIG. 5A, in the dual polarized wave transmitting / receiving antenna 1 to be simulated, the outer diameter shape is different from that of the dual polarized wave transmitting / receiving antenna 1 of the embodiment described in FIG. Although the shape is as close to the embodiment as possible.
That is, the metal casing 10 is a metal with a thickness of 5 mm and is formed in a size of 42 mm × 42 mm × 10 mm.
The inward flange portion 15 has a width of 3.5 mm and a thickness of 0.5 mm.
The antenna element 31 of the main antenna 30 is 34.9 mm in length, and 2 mm in length of the bent portion 32. The bent portion 32 is opposed to the inward facing flange portion 15 at a distance of 0.1 mm.
The opposite side of the bent portion 32 in the antenna element 31 is connected to the inward facing flange portion 15.
The feeding portion 51 has a length of 5 mm, and faces the antenna element 31 at an interval of 0.6 mm at the center in the longitudinal direction of the antenna element 31.
The antenna element 31, the bent portion 32, the feeding portion 51, and the feeding line 52 all have a width of 0.5 mm and a thickness of 0.5 mm.
The relative dielectric constant around the main antenna 30 and the feeding antenna unit 50 is calculated by εr = 1.

The simulation result by this dual polarization transmission / reception antenna 1 will be described with reference to FIGS. 6 and 7.
FIG. 6 shows the return loss characteristics of the dual polarization transmitting / receiving antenna 1 by simulation.
According to the return loss characteristic shown in FIG. 6, the resonance frequency is 1.574 GHz in the dual polarized wave transmitting and receiving antenna 1 of FIG.
The band satisfying return loss ≦ −6 dB is 8 MHz (BW = 8.539 MHz), and the GPS bandwidth (2 MHz) is satisfied.

FIG. 7 shows the radiation characteristics of the dual polarization transmitting / receiving antenna 1 by simulation.
FIG. 7A shows the radiation characteristic of the XY plane, FIG. 7B shows the radiation characteristic of the ZX plane, and FIG. 7C shows the radiation characteristic of the ZY plane.
As shown in FIG. 7A, this dual polarized wave transmitting and receiving antenna 1 has a radiation efficiency of 66.8% at a resonant frequency of 1.575 GHz.
As shown by the dotted line A in FIG. 7 (b), the maximum value M01 of Eθ is 36.00 °, the maximum value M02 of Eφ is 339.00 °, and horizontal and vertical polarizations are + Z (wind direction). The maximum radiation direction of is obtained.
In FIG. 7B, the polarization component 30z (see FIG. 4) from the main antenna 30 contributes to the radiation of the Eφ component, and the polarization component 50z by the feeding antenna unit 50 contributes to the radiation of the Eθ component.

On the other hand, as shown in FIG. 7C, the maximum value M01 of Eθ is 351.00 °, and the maximum value M02 of Eφ is 276.00 °. However, as shown in FIG. 7C, Eφ is approximately the same as the maximum value M02 up to about 320.00 °. Therefore, as indicated by a dotted line B in FIG. 7C, the maximum radiation directions of both horizontal and vertical polarizations are obtained in + Z (windshield direction).
In FIG. 7C, the polarization component 30z from the main antenna 30 contributes to the radiation of the Eθ component, and the polarization component 50z by the feeding antenna unit 50 contributes to the radiation of the Eφ component.

According to the dual polarized wave transmitting and receiving antenna 1 described above, the following effects can be obtained.
(1) In the dual polarized wave transmitting and receiving antenna 1, generally, a metal casing that degrades the antenna characteristics is actively used as a ground conductor plate, whereby metals and electrons accommodated in the metal casing and the inside are It is possible to obtain an antenna that is less susceptible to the effects of antenna characteristics due to components.
(2) According to the dual polarization transmitting / receiving antenna 1, in addition to the polarization component 30z by the main antenna 30, the feeding antenna unit 50 having a feeding (EM feeding) function to the main antenna 30 is used as the second antenna. Thus, a polarization component 50z orthogonal to the polarization component 30z is obtained. As a result, it becomes possible to efficiently receive circularly polarized waves in the resonant frequency band of the dual polarized wave transmitting / receiving antenna 1.
In particular, by setting the resonance frequency of the dual polarized wave transmitting and receiving antenna 1 to 1.575 GHz, it can be used as a GPS antenna.
(3) Capacitance can be loaded and resonance frequency can be lowered by arranging one end of the antenna element 31 opposite to the end face of the peripheral wall step 13 of the inward facing flange 15 functioning as a ground conductor plate for the main antenna 30. . Therefore, the dual polarization transmitting and receiving antenna 1 with the same resonance frequency can be miniaturized.
(4) The antenna unit 20 of the present embodiment can be miniaturized by using ceramic for the unit base (dielectric portion 21), and the antenna unit 20 can have high strength.
(5) According to the antenna unit 20 of the present embodiment, attachment to a metal casing is easy.

In the embodiment described above, the peripheral wall step 13 is formed with the side wall 16 remaining in the inward flange portion 15 and the main antenna 30 is disposed on the opposite side of the side wall 16 to the center side. It is not limited.
That is, the peripheral wall step portion 13 is formed so that the side wall 16 is left on the center side of the inward facing flange portion 15. In this case, a recess is formed from the outer peripheral side to the center side of the inward flange portion 15 (peripheral wall 11), whereby the outer peripheral side is opened. And the main antenna 30 is arrange | positioned on the outer peripheral side which is the opposite side of the side wall 16 by the side of a center. The feed antenna unit 50 is disposed to face the center of the main antenna 30.
Further, the stepped portion may be formed without leaving the peripheral wall. In this case, both the outer peripheral side and the center side of the stepped portion are open. In this case, the main antenna 30 can be disposed on either the center side or the outer side of the stepped portion. The feed antenna unit 50 in this case is disposed opposite to the outer circumference side and the center side corresponding to the arrangement position of the main antenna 30.

Next, a watch equipped with the dual polarized wave transmitting and receiving antenna described in the embodiment and the modification will be described.
FIG. 8 is an external view of a timepiece 100 equipped with the dual polarized wave transmitting / receiving antenna 1.
As shown in FIG. 8, the timepiece 100 is composed of the dual polarization transmitting / receiving antenna 1 described above and a timepiece unit housed in the metal casing 10 of the dual polarization transmitting / receiving antenna 1.
The watch unit includes at least a windshield, a dial 101, a hand 102, and a movement for driving the hand 102.
Further, in the timepiece unit according to the present embodiment, a bezel 103 for covering the antenna unit 20 incorporated / arranged in the metal housing 10 from the upper surface is provided.
According to the timepiece 100 of the present embodiment, since the metal casing 10 is used as the main body case of the timepiece and the metal casing 10 is used as the ground conductor plate, the timepiece unit in which the antenna characteristic is accommodated is used. It is hard to be affected.

The bottom surface 12 of the metal casing 10 (not shown) may have an open / close structure with a back cover.
Moreover, although the metal casing 10 is used as a main body case of the timepiece 100 in the timepiece of this embodiment, the antenna 1 for transmitting and receiving polarization of this embodiment including the metal casing 10 is not limited to this. Alternatively, it may be accommodated in a separately prepared main body case.
Even in this case, since the metal housing 10 is used as the ground conductor plate, the antenna characteristics are not easily influenced by the external main body case.
Further, since the antenna unit 20 is located below the bezel 103, the antenna characteristics are not easily affected even if the metal casing 10 or the watch unit inside thereof is present around the bezel.
In addition, although the case where the bezel 103 was provided was demonstrated in the timepiece 100 of this embodiment, the bezel 103 does not necessarily need to be attached. In this case, it is preferable to dispose a cover that changes to the bezel 103 above the antenna unit 20.

1 Dual-Polarized Transmission / Reception Antenna 10 Metal Case 11 Peripheral Wall 12 Bottom 13 Peripheral Wall Stepped Part 14 Through Hole 15 Inward Flange Part 16 Side Wall 20 Antenna Unit 21 Dielectric Part 30 Main Antenna 30z Polarization Component (Main Antenna)
31 antenna element 32 bent portion 33 short circuit portion 40 feed line 50 feed antenna portion 50 z polarization component (feed antenna portion)
51 feeding part 52 feeding line 53 feeding point 90 feeding line 100 clock 101 dial 102 pointer 103 bezel

Claims (8)

A metal case made of metal,
A main antenna having an antenna element of a predetermined length, one end of which is short-circuited to the metal casing as a ground conductor plate and the other end of which is close to the other position of the metal casing to generate a polarization component by feeding.
A feed of a predetermined length that generates a polarized wave component orthogonal to the polarized wave component of the antenna element is provided in the electromagnetic coupling portion while being oppositely arranged in parallel on the same plane as the antenna element and electromagnetically coupling the antenna element. Department,
A feed line feeding the feed section;
An antenna for transmitting and receiving both polarized waves, characterized in that it comprises: The metal housing has a recess of a predetermined length,
In the antenna element, one end is short-circuited with the end face on one side in the lengthwise direction of the recess, and the other end is disposed close to the end face on the other side of the recess.
The dual polarized transmission / reception antenna according to claim 1, characterized in that: The main antenna is connected to the other end of the antenna element, and further includes a bent portion disposed close to and in parallel with the end surface on the other side in the lengthwise direction of the recess.
3. The dual polarized wave transmitting and receiving antenna according to claim 2, wherein: The metal casing has a cylindrical peripheral wall, a bottom surface disposed on one end surface of the peripheral wall, and an inward facing flange portion disposed on the other end surface of the peripheral wall.
The recess is circumferentially formed on the inward flange portion.
An antenna for transmitting and receiving both polarized waves according to claim 2 or claim 3, characterized in that: The metal housing has a cylindrical peripheral wall and a bottom surface disposed on one end surface of the peripheral wall,
The recess is circumferentially formed on the peripheral wall,
An antenna for transmitting and receiving both polarized waves according to claim 2 or claim 3, characterized in that: An antenna unit constituting an antenna for transmitting and receiving both polarizations by being incorporated in a recess of a predetermined length formed in a metal casing,
The dual antenna according to any one of claims 2 to 5, wherein the main antenna, the feeding portion, and the feeding line are molded with a dielectric.
The other end of the antenna element is exposed from the dielectric of the antenna unit so as to allow a short circuit connection with the metal housing.
An antenna unit characterized by A spring portion is formed on the exposed other end of the antenna element,
The antenna unit according to claim 6, characterized in that: An antenna for transmitting and receiving both polarized waves according to any one of claims 1 to 5;
At least a windshield, a dial, a pointer, and a watch unit provided with a movement for driving the pointer, which are disposed in the metal housing;
A watch characterized by comprising.

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