JP2019186788A - Antenna and communication device - Google Patents

Abstract

To provide a small antenna with a small outer size but thin, and a small communication device using the antenna.SOLUTION: An antenna includes: a first dielectric layer; a base layer made of metal formed on one surface of the first dielectric layer; a mirror image wall layer erected from the base layer; radiation element layer which is the other surface of the first dielectric layer and provided by forming a predetermined gap between the radiation element layer and the mirror image wall layer; and an antenna element which is an upper part of the radiation element layer and disposed in parallel with the radiation element layer.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a small antenna that can be applied to both free space and conductors and a communication device using the same.

The inventor according to the present application has previously proposed a thin and small antenna using metamaterial technology (Patent Documents 1 and 2).
As a result of studying an antenna that can be further reduced in size, the present inventor has reached the present invention.

JP-A-2006-146558 JP 2011-55054 A

  An object of the present invention is to provide a small antenna that is thin but has a small outer mold size, and a small communication device using the antenna.

  The antenna according to the present invention includes a first dielectric layer, a base layer made of metal formed on one surface of the first dielectric layer, and a mirror image wall layer erected from the base layer. A radiating element layer provided on the other surface of the dielectric layer with a predetermined gap formed between the dielectric layer and the upper surface of the radiating element layer; And antenna elements arranged in parallel with each other.

The antenna disclosed in Patent Document 1 is a pair of non-contact type feeding elements that operate as a dipole antenna via a plate-like radiating element layer on both sides via a slit in the center and a dielectric layer on the upper side thereof. Is provided.
As a result, a thin antenna with impedance matching, which can be used not only in free space but also on a conductor, was obtained.
On the other hand, the present invention is characterized in that a mirror image wall layer functioning as a reflector is erected at the position of the slit portion to further reduce the size.
In the present invention, the antenna element may be disposed on the upper surface of the radiating element layer via a second dielectric layer, and a feeding point may be provided on the antenna element and the mirror image wall layer.
In this case, an example in which the antenna element extends in a key shape from the mirror image wall layer and an example in which a predetermined gap is formed between the mirror image wall layer and the antenna element can be considered.

In the present invention, the antenna element includes a mode including a pair of antenna elements that operate as a dipole antenna.
A plurality of mirror image wall layers may be provided upright, and the antenna element may be disposed between the plurality of mirror image wall layers.
Although details will be described later in this case, as shown in FIG. 2, the feeding points F ₁ and F ₂ are formed on the antenna element and the mirror image wall layer, and the feeding points on the pair of antenna elements as shown in FIG. There is an embodiment in which F ₁ and F ₂ are provided.
When the feed points F ₁ and F ₂ are formed on the antenna element and the mirror image wall layer, the heights thereof should be substantially the same.
On the other hand, when the feeding points F ₁ and F ₂ are provided in the pair of antenna elements, the height of the mirror image wall layer may be lower than the feeding point.
Here, the antenna element is arranged in a direction perpendicular to the center line along the standing direction of the mirror image wall layer, and in addition to a predetermined center from a horizontal center line perpendicular to the standing center line of the mirror image wall layer. In the form of being offset by the distance, it is possible to realize a two-frequency shared / wideband type small antenna.

In the present invention, the first dielectric layer and the second dielectric layer may be not only a non-conductive material such as a resin plate but also a spatial layer as long as they act as dielectric layers.
The base layer and the mirror image wall layer are made of metal and may be integrally formed or may be joined separately.
The radiating element layer is made of metal, and may have a curved shape as well as a planar shape as long as the first dielectric layer is sandwiched between the radiating element layer and the base layer.
The radiating element layer may have substantially the same outer shape as that of the base layer, except that a predetermined slit-like gap is provided between the radiating element layer and the mirror image wall layer.
Further, the radiating element layer may be a plurality of radiating element pieces provided with cutouts inside the length direction.
Further, a plurality of radiating element layers may be provided corresponding to a pair of antenna elements.

  In the present invention, the mirror image wall layer acts as a reflecting plate and is intended to map the radiating element layer and the antenna element, and may be not only a plate shape but also a lattice shape, a mesh shape, or the like.

  The antenna according to the present invention becomes a small communication device by combining with the communication module.

The antenna according to the present invention is equivalent to the antenna described in Patent Document 1 in which the radiating element layer and the feeding element are formed symmetrically by providing the mirror image wall layer, and is about half the size of the conventional antenna. It becomes possible.
Moreover, it becomes a small antenna by applying to the structure of patent document 2. FIG.

The structural example of the antenna which concerns on this invention is shown. (A) shows a sectional structure of the antenna, (b) shows an antenna substrate on which an antenna element is arranged, (c) shows a grid substrate on which a radiating element layer is arranged, and (d) shows a metal substrate on which a base layer is arranged. A comparison of impedance characteristics between the antenna (A) shown in FIGS. 1 and 2 and the conventional antenna (B) shown in FIG. 32 according to the present invention is shown. The left graph shows the impedance characteristics in free space, and the right graph shows the impedance characteristics on the metal (on the conductor). X represents a reactance component, and R represents a resistance component. The VSWR characteristics of the antenna (A) shown in FIGS. 1 and 2 and the conventional antenna (B) are shown. The radiation pattern is shown. An example of the structure of a two-frequency compatible antenna in which antenna elements are offset is shown. (A) is a cross-sectional structure, (b) is an antenna substrate, (c) is a grid substrate, and (d) is a metal substrate. An antenna specification table comparing the design is shown. The impedance characteristic in the antenna specification of FIG. 8 is shown. The VSWR characteristic in the antenna specification of FIG. 8 is shown. The radiation pattern in the antenna specification of FIG. 8 is shown. The specification comparison of the offset type antenna (A) according to the present invention and the specification of the conventional antenna (B) is shown. A comparison between the present invention (A) and the conventional (B) in the antenna specification of the resonance frequency 5 GHz _Z type is shown. The impedance characteristic of an offset type antenna is shown. The VSWR characteristic of an offset type antenna is shown. The radiation pattern of an offset type antenna is shown. The example which notched the inner side of the radiation | emission element layer is shown, (a)-(d) is equivalent to FIG. 2, (e) shows a perspective view. The modification of an antenna element is shown. An example of a pair of antenna elements is shown. (A) Impedance characteristics and (b) VSWR characteristics of the antenna shown in FIG. The radiation characteristic of the antenna shown in FIG. 19 is shown. An example in which two mirror image wall layers are erected facing each other is shown. 22 shows (a) impedance characteristics and (b) VSWR characteristics of the antenna shown in FIG. The radiation characteristic of the antenna shown in FIG. 19 is shown. An example in which a pair of antenna elements is arranged between a pair of mirror image wall layers is shown. 25 shows (a) impedance characteristics and (b) VSWR characteristics of the antenna shown in FIG. The radiation characteristic of the antenna shown in FIG. 25 is shown. An example in which one antenna element is arranged between a pair of mirror image wall layers is shown. 28 shows (a) impedance characteristics and (b) VSWR characteristics of the antenna shown in FIG. The radiation characteristic of the antenna shown in FIG. 28 is shown. An example of a conventional antenna structure is shown. The example compared with the antenna of patent document 2 is shown.

An example of the structure of the antenna according to the present invention will be described below with reference to the drawings.
1 and 2 show structural examples of the antenna according to the present invention. For comparison, FIG. 31 shows a structural example of the antenna disclosed in the cited document 1 as a conventional example.
A comparison with the antenna disclosed in the cited document 2 is shown in FIG.
In FIG. 32, M indicates a mirror image plane.
A metal base layer 11 a is disposed on one surface (lower surface) of the first dielectric layer 12, and a mirror image wall layer 11 b erected along the edge of the first dielectric layer 12 from one end thereof. It is.
The base layer 11a and the mirror image wall layer 11b form a substantially L-shaped metal layer 11 in a side view.
On the other surface (upper surface) of the first dielectric layer 12, a slit portion S is provided as a predetermined gap between the first dielectric layer 12 and the mirror image wall layer 11b to form a metal radiating element layer 13.
A second dielectric layer 14 was formed on the top surface of the radiating element layer 13, and an antenna element 15 was disposed thereon.
The antenna element 15 is arranged in a direction perpendicular to the surface of the mirror image wall layer.
The antenna element 15 is a non-contact type and operates as a dipole antenna having the mirror image wall layer 11b as a reflection surface.
A slit portion S is formed as a predetermined gap also between the antenna element 15 and the mirror image wall layer 11b, and the slit width (s) is the slit width (s) of the radiating element layer 13 as shown in FIG. s).
2B shows an antenna substrate in which the antenna element 15 is arranged on the upper surface of the second dielectric layer 14, and FIG. 2C shows a grid substrate in which the radiating element layer 13 is arranged. (D) is a metal substrate representing the base layer 11a.
In this embodiment, to form a feeding point F ₁ to the antenna element 15 to form a feeding point F ₂ to an upper end portion of the mirror image wall layer 11b, configured to feed point F _1, F ₂ is flush It is.

As a conventional example, FIG. 31 shows an example of the structure of the antenna disclosed in Patent Document 1.
A first dielectric layer 112 is formed on a metal plate 111, an s × 2 times slit portion is provided at the center thereof, and a radiating element layer 113 is disposed on both sides thereof.
A second dielectric layer 114 is formed on the radiating element layer 113, and a pair of feeding elements 115 is further provided thereon.
A dipole antenna composed of a pair of feed elements has a length of a × 2 + s × 2.
The antenna according to the present invention will be described below in comparison with this conventional example.

The parameters of the antenna according to the present invention shown in FIG. 2 were set as follows and compared with the conventional antenna of FIG.
The feeding points are F ₁ and F ₂ shown in FIGS. 1, 2A and 31A.
In this embodiment, the feeding point F ₁ at the slit side end of the antenna element 15 and the feeding point F _{2 at} the upper end of the mirror image wall layer 11b are used, and feeding is performed at these two points.
In the conventional example of FIG. 31, the pair of feed elements 115 have feed points F ₁ and F ₂ .
Height H: 4mm
Length L: 29.7mm
Width W: 30mm
Radiation element length g: 29.45 mm
Slit width s: 0.25mm
Antenna element length a: 12 mm
Antenna element width ww: 1mm
First dielectric thickness t ₁ : 3.12 mm, relative dielectric constant ε ₁ : 2.59
Second dielectric thickness t ₂ : 0.74 mm, relative dielectric constant ε ₂ : 2.53
A copper foil having a thickness of 0.018 mm was used for the metal layer (radiating element layer).
In addition, in FIG. 31, said numerical value was input into the calculation formula.

FIG. 3 shows the impedance characteristics, where X represents a reactance component and R represents a resistance component.
FIG. 4 shows the VSWR characteristics.
FIG. 5 shows a radiation pattern.
(A) shows an antenna according to the present invention, and (B) shows a comparative example.
3 and 4, the left graph shows antenna characteristics in free space, and the right graph shows antenna characteristics on metal.
VSWR near 2.45 GHz _Z have taken is aligned approximately 1.
When normalized by the resonance frequency _{2.45GH Z, L = 0.25λ, H} = 0.033λ, a W = 0.25 [lambda.

Next, as shown in FIGS. 6 and 7, the antenna element 15 is offset from the horizontal center line G ₀ of the radiating element layer 13 by the lower side d in FIG.
The setting values of each parameter are shown in the table of FIG.
FIG. 9 shows impedance characteristics, FIG. 10 shows VSWR characteristics, and FIG. 11 shows radiation patterns.
In the table of FIG. 8, the length L of the base layer (metal substrate) is expressed as the substrate length L, and the width W of the substrate corresponding to 31.5 mm, 30.5 mm, 29.75 mm, 29.65 mm. Were set to (a) 24 mm, (b) 27 mm, (c) 30 mm, and (d) 33 mm, respectively.
Further, the length of the antenna element 15 is expressed as the antenna length a in the table of FIG. 8, and the horizontal center line G ₀ of the antenna substrate (center line orthogonal to the standing center line of the mirror image wall layer 11b in the horizontal direction). The offset amount d from the bottom to the bottom was set to 8 mm, 9.5 mm, 11 mm, and 12.5 mm corresponding to (A) to (D).
Looking at the VSWR characteristics shown in impedance characteristic and 10 shown in FIG. 9, the resonance frequency _{f 1} in the vicinity of 2.45 GHz _Z, relative to being determined by the value of the antenna length a and the grid width g, it is understood that the second resonance frequency f ₂ appears shifted by setting the width of the substrate W and the offset amount d.
It can be seen from the radiation patterns in FIG. 11 that there is no significant difference in the radiation patterns in any of (a) to (d).

FIG. 12 shows an example in which the antenna (A) according to the present invention and the conventional antenna (B) are compared by calculation when the substrate width W is 27 mm.
It can be seen that the length is about half that of the conventional one.
13 to _{f 1: 5.25GH Z, f 2} : shows a calculation example of the antenna specification when set to 5.65GH _Z.
(A) is the present invention, and (B) is a conventional example.
FIG. 14 shows the impedance characteristics in that case, FIG. 15 shows the VSWR characteristics, and FIG. 16 shows the radiation pattern.
Also in this case, the length of the antenna is about half that of the conventional example.

The embodiment of the antenna shown in FIG. 17 shows an example in which the inside of the radiating element layer 13a is cut out and formed with a plurality of pieces g ₁ and g ₂ .
This effect shows the same effect as described in Patent Document 1.

FIG. 18 is composed of a ₁ and a _{2 in} which the antenna element 15a extends from the mirror image wall layer 11b in a key shape, and a gap is formed between a ₂ and the mirror image wall layer 11b, and feeding points F ₁ and F ₂ is an example.

FIG. 19 shows an example in which a pair of antenna elements 15b and 15c are arranged on the upper surface of the second dielectric layer 14 to provide feed points F ₁ and F ₂ .
In this case, the height of the mirror image wall layer 11b may be lower than the height of the antenna element 15c as long as it is higher than the radiating element 13c.
H: 4mm, W: 30mm, L: 48.3mm
FIG. 20 shows the impedance characteristics when the grid widths of the radiating elements 13b and 13c are designed as g ₁ : 31 mm, g ₂ : 16 mm, slits S ₁ : 0.5 mm, and slits S: 0.25 mm, and FIG. 21 shows the radiation characteristics. Each is shown.
The impedance is lower than that of the basic type shown in FIG.

In the embodiment shown in FIG. 22, the first mirror image wall layer 11b and the second mirror image wall layer 11c are erected so as to be opposed from both sides of the base layer 11a, and a pair of antenna elements 15b and 15c are interposed therebetween. This is an example of arrangement.
Feed points F ₁ and F ₂ are formed in the antenna elements 15b and 15c, respectively.
The antenna elements 15b and 15c are linear antennas, and are arranged in a straight line on one side in a direction orthogonal to the standing surface of the mirror image wall layer 11b.
In this case, the radiating element layer was divided into 13d and 13e.
H: 4 mm, W: 30 mm, L: 39 mm, g ₁ = g ₂ : 19 mm, s ₁ : 0.5 mm, s ₂ = s ₃ : 0.25 mm.
FIG. 23 shows the impedance characteristics in this case, and FIG. 24 shows the radiation characteristics.
In this case as well, the bandwidth is wider than the basic type.

The antenna shown in FIG. 25 is a case where L: 32.5 mm, g ₅ : 7 mm, and g ₆ : 24.5 mm are designed as compared with FIG. 22, and FIG. 26 shows the impedance characteristics and FIG. 27 shows the radiation characteristics. Show.

In FIG. 28, the antenna element 15d is linearly disposed between the first and second mirror image wall layers 11b and 11c arranged to face each other, and the feeding points F ₁ , F ₁ , This is an example in which F ₂ is provided.
FIG. 29 and FIG. 30 show impedance characteristics and radiation characteristics when designed as H: 4 mm, W: 30 mm, L: 22.6 mm, g: 22.1 mm, and s: 0.25 mm.

11 Metal layer 11a Base layer 11b Mirror image wall layer 12 First dielectric layer 13 Radiating element layer 14 Second dielectric layer 15 Antenna element

Claims (6)

A first dielectric layer;
A base layer made of metal formed on one surface of the first dielectric layer, and a mirror image wall layer erected from the base layer;
A radiation element layer provided on the other surface of the first dielectric layer, with a predetermined gap formed between the first dielectric layer and the mirror image wall layer;
An antenna having an antenna element disposed above and in parallel with the radiating element layer.   The said antenna element is arrange | positioned through the 2nd dielectric material layer on the upper surface of the said radiation | emission element layer, The feed point is provided in the said antenna element and the said mirror image wall layer, The Claim 1 characterized by the above-mentioned. antenna.   The antenna according to claim 2, wherein the antenna element is disposed with a predetermined gap between the antenna element wall layer and the mirror image wall layer.   2. The antenna according to claim 1, wherein the antenna element comprises a pair of antenna elements that operate as a dipole antenna.   5. The antenna according to claim 3, wherein a plurality of the mirror image wall layers are erected, and the antenna element is disposed between the plurality of mirror image wall layers.   A communication apparatus comprising a combination of the antenna according to claim 1 and a communication module.