KR20230052168A - Dielectric resonator antenna and antenna device - Google Patents

Abstract

An embodiment of the present invention, according to the present invention, a dielectric resonator includes: a dielectric material block; a first feed unit disposed in the dielectric material block and having a first height measured from a lower surface of the dielectric material block; and a second feed unit disposed in the dielectric material block and having a second height measured from the lower surface of the dielectric material block, wherein the first feed unit and the second feed unit are disposed to be symmetrical to each other with reference to a center region. Therefore, it is possible to prevent antenna performance degradation while reducing an antenna size.

Description

Dielectric resonator antenna and antenna device {DIELECTRIC RESONATOR ANTENNA AND ANTENNA DEVICE}

The present disclosure relates to dielectric resonator antennas and antenna devices.

The development of wireless communication systems has greatly changed our lifestyle over the past 20 years. Advanced mobile systems with gigabit per second data rates are required to support potential wireless applications such as multimedia devices, Internet of Things and intelligent transportation systems. This is impossible to realize due to the limited bandwidth in the current 4G communication system. To overcome bandwidth limitations, the International Telecommunication Union has licensed the spectrum of millimeter wave (mmWave) for a range of potential fifth generation (5G) applications. Since then, there has been a lot of interest in research on mmWave antennas in both academia and industry.

Recently, the size of mmWave 5G antenna modules for mobile devices is required to be miniaturized. As mobile devices such as mobile phones become slimmer, the size of an antenna module tends to decrease.

As such, as the size of the antenna module decreases, antenna performance such as antenna gain and bandwidth, and isolation between a low frequency band and a high frequency band may deteriorate.

Embodiments are intended to provide an antenna and an antenna device capable of preventing antenna performance degradation while reducing an antenna size.

However, problems to be solved by the embodiments are not limited to the above-described problems and may be variously extended in the range of technical ideas included in the embodiments.

The dielectric resonator antenna according to the embodiment includes a dielectric block, a first feed part located on the dielectric block and having a first height from the bottom surface of the dielectric block, and a first feed unit located on the dielectric block and having the first height and height from the bottom surface of the dielectric block. A second feed part having a different second height may be included, and the first feed part and the second feed part may be symmetrically disposed with respect to the central part.

The dielectric resonator antenna may further include a shielding via positioned in the dielectric block and positioned between the first feed part and the second feed part.

The via may overlap the central portion.

The bottom surface of the dielectric block may include a first side extending in a first direction and a second side extending in a second direction different from the first direction, and the first straight line extends between the first side and the second direction. It can overlap with the part where the sides intersect.

The first feed part and the second feed part may be vias located in the dielectric block.

The first feed part and the second feed part may be feed strips positioned outside the dielectric block.

The first straight line may be parallel to the first side or the second side.

The dielectric resonator antenna may further include a third feed part positioned on the dielectric block and having the first height from the bottom surface and a fourth feed part positioned on the dielectric block and having the second height from the bottom surface.

The third feed part and the fourth feed part may overlap with a second straight line passing through the center of the bottom surface, the third feed part and the center have the first distance, and the fourth feed part and The second interval may be provided between the centers.

The dielectric block may extend in a first direction, a second direction different from the first direction, and a third direction perpendicular to the first direction and the second direction, and the bottom surface may extend in the first direction and the second direction. It may include two parallel first sides and two second sides parallel to the second direction, and the first straight line and the second straight line may overlap a point where the first and second sides intersect. there is.

The first straight line and the second straight line may be parallel to the first direction or the second direction.

The first straight line and the second straight line may overlap centers of the first and second sides.

The dielectric block may include a first dielectric block, a second dielectric block, and a third dielectric block stacked from the bottom surface, and the first feed unit may be located in the first dielectric block and the second dielectric block. And, the second feed unit may be located in the first dielectric block.

The dielectric block may further include a first dielectric layer positioned between the first dielectric block and the second dielectric block, and a second dielectric layer positioned between the second dielectric block and the third dielectric block. Permittivity of the first dielectric layer and the second dielectric layer may be lower than that of the first dielectric block, the second dielectric block, and the third dielectric block.

A dielectric resonator antenna according to another embodiment includes a dielectric block, a first feed unit located on the dielectric block and having a first height from the bottom surface of the dielectric block, located on the dielectric block, and the first height from the bottom surface. A second feed part having a second height different from , and a shield via located in the dielectric block, overlapping the center of the bottom surface, and spaced apart at substantially the same interval as the first feed part and the second feed part. can do.

A third height of the shield via measured from the bottom surface of the dielectric block may be greater than or equal to the second height.

The bottom surface of the dielectric block may include a first side extending in a first direction and a second side extending in a second direction different from the first direction, and the first feed part and the second feed part may include the bottom It may overlap with a negative straight line, and the straight line may be parallel to the first side or the second side.

The straight line may overlap a portion where the first side and the second side intersect.

The dielectric resonator antenna may further include a third feed part located on the dielectric block and having the first height from the bottom surface and a fourth feed part located on the dielectric block and having the second height from the bottom surface, The shielding vias may be spaced apart from each other at the same interval as the third feed part and the fourth feed part.

The bottom surface of the dielectric block may include a first side extending in a first direction and a second side extending in a second direction different from the first direction, and the first feed part and the second feed part may include the bottom may overlap with the first straight line of the negative, the third feed part and the fourth feed part may overlap with the second straight line of the bottom part, and the first straight line and the second straight line are the first side or the first straight line. It can be parallel to 2 sides.

The first straight line and the second straight line may be a diagonal line overlapping a portion where the first side and the second side intersect.

An antenna device according to an embodiment includes a dielectric block, a first feed unit located on the dielectric block and having a first height from the bottom surface of the dielectric block, and a first feed unit located on the dielectric block and different from the first height from the bottom surface. It may include a second feed part having a height of 2, a ground plane positioned under the dielectric block, and a pattern part formed on the ground plane and positioned between the first feed part and the second feed part.

The antenna device may further include shield vias located in the dielectric block and spaced at substantially the same interval as the first feed part and the second feed part, and the pattern part may overlap the shield via.

The pattern part may include an extension part extending between the first feed part and the second feed part from a center overlapping the shield via.

The pattern part is connected to a first pattern part including an extension part extending between the first feed part and the second feed part from the center overlapping the shield via, and the first pattern part, and the first feed part and A second pattern part surrounding the second feed part may be included.

The second pattern part may include a portion extending outward from the bottom surface of the dielectric block.

The antenna device may further include a third feed part located on the dielectric block and having the first height from the bottom surface and a fourth feed part located on the dielectric block and having the second height from the bottom surface, The pattern unit includes a first expansion unit extending between the first feed unit and the second feed unit from the center overlapping the shielding via, a second expansion unit extending between the first feed unit and the third feed unit, and the third feed unit. A third expansion unit extending between the second feed unit and the fourth feed unit, and a fourth expansion unit extending between the third feed unit and the fourth feed unit may be included.

According to embodiments, it is possible to provide an antenna and an antenna device capable of preventing antenna performance deterioration while reducing the size of the antenna.

However, it is obvious that the effects of the embodiments are not limited to the above-described effects, and can be variously extended without departing from the spirit and scope of the present invention.

1 is a perspective view of a dielectric resonator antenna according to one embodiment.
2a and 2b are plan views of the dielectric resonator antenna of FIG. 1;
3 is a perspective view of a dielectric resonator antenna according to another embodiment.
4a and 4b are plan views of the dielectric resonator antenna of FIG. 3;
5 is a perspective view of a dielectric resonator antenna according to another embodiment.
6A and 6B are plan views of the dielectric resonator antenna of FIG. 5;
7 is a perspective view of a dielectric resonator antenna according to another embodiment.
8A and 8B are plan views of the dielectric resonator antenna of FIG. 7 .
9 is a perspective view of a dielectric resonator antenna according to another embodiment.
10A and 10B are plan views of the dielectric resonator antenna of FIG. 9 .
11 is a perspective view of a dielectric resonator antenna according to another embodiment.
12a and 12b are plan views of the dielectric resonator antenna of FIG. 11;
13 is a perspective view of a dielectric resonator antenna according to another embodiment.
14a and 14b are plan views of the dielectric resonator antenna of FIG. 13;
15 is a perspective view of a dielectric resonator antenna according to another embodiment.
16A and 16B are plan views of the dielectric resonator antenna of FIG. 15;
17 is a perspective view of a dielectric resonator antenna according to another embodiment.
18 is a plan view of the dielectric resonator antenna of FIG. 17;
19 is a perspective view of a dielectric resonator antenna according to another embodiment.
20 is a plan view of the dielectric resonator antenna of FIG. 19;
21 is a perspective view of a dielectric resonator antenna according to another embodiment.
22 is a perspective view of a dielectric resonator antenna according to another embodiment.
23 is a perspective view of a dielectric resonator antenna according to another embodiment.
24 is a perspective view of a dielectric resonator antenna according to another embodiment.
25 is a perspective view of a dielectric resonator antenna according to another embodiment.
26 is a perspective view of a dielectric resonator antenna according to another embodiment.
27 is a perspective view of a dielectric resonator antenna according to another embodiment.
28 is a perspective view of a dielectric resonator antenna according to another embodiment.
29 is a perspective view of a dielectric resonator antenna according to another embodiment.
30 is a perspective view of a dielectric resonator antenna according to another embodiment.
31 is a perspective view of an antenna device according to another embodiment.
32 is a cross-sectional view of the antenna device of FIG. 31;
33 is a plan view of the antenna device of FIG. 31;
34A to 34E are perspective views illustrating a method of manufacturing an antenna device according to an embodiment.
35 is a plan view of a portion of an antenna device according to another embodiment.
36 is a plan view of a portion of an antenna device according to another embodiment.
37 is a plan view of a portion of an antenna device according to another embodiment.
38 is a plan view of a portion of an antenna device according to another embodiment.
39 is a plan view of a portion of an antenna device according to another embodiment.
40 is a plan view of a portion of an antenna device according to another embodiment.
41 is a plan view of a portion of an antenna device according to another embodiment.
42 is a plan view of a portion of an antenna device according to another embodiment.
43 is a plan view of a portion of an antenna device according to another embodiment.
44 is a layout view of an antenna device according to another embodiment.
45 is a layout view of an antenna device according to another embodiment.
46 is a layout view of an antenna device according to another embodiment.
47 is a layout view of an antenna device according to another embodiment.
48 is a layout view of an antenna device according to another embodiment.
49 is a layout view of an antenna device according to another embodiment.
50 is a layout view of an antenna device according to another embodiment.
51 is a layout view of an antenna device according to another embodiment.
52 is a layout view of an antenna device according to another embodiment.
53 is a layout view of an antenna device according to another embodiment.
54 is a simplified diagram illustrating an electronic device including an antenna device according to an embodiment.
55 to 57 are graphs showing the results of one experimental example.
58 to 61 are views showing the results of another experimental example.

Hereinafter, various embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. This invention may be embodied in many different forms and is not limited to the embodiments set forth herein.

In order to clearly describe the present invention, parts irrelevant to the description are omitted, and the same reference numerals are assigned to the same or similar components throughout the specification.

In addition, the accompanying drawings are only for easy understanding of the embodiments disclosed in this specification, the technical idea disclosed in this specification is not limited by the accompanying drawings, and all changes included in the spirit and technical scope of the present invention , it should be understood to include equivalents or substitutes.

In addition, since the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of explanation, the present invention is not necessarily limited to the shown bar. In the drawings, the thickness is shown enlarged to clearly express the various layers and regions. And in the drawings, for convenience of explanation, the thicknesses of some layers and regions are exaggerated.

In addition, when a part such as a layer, film, region, plate, etc. is said to be "on" or "on" another part, this includes not only the case where it is "directly on" the other part, but also the case where another part is in the middle. . Conversely, when a part is said to be "directly on" another part, it means that there is no other part in between. In addition, being "above" or "on" a reference part means being located above or below the reference part, and does not necessarily mean being located "above" or "on" in the opposite direction of gravity. .

In addition, throughout the specification, when a certain component is said to "include", it means that it may further include other components without excluding other components unless otherwise stated.

In addition, throughout the specification, when it is referred to as "planar image", it means when the target part is viewed from above, and when it is referred to as "cross-sectional image", it means when a cross section of the target part cut vertically is viewed from the side.

Also, throughout the specification, when it is said to be "connected", this does not mean that two or more components are directly connected, but that two or more components are indirectly connected through another component, or physically connected. It may mean not only being, but also being electrically connected, or being referred to by different names depending on location or function, but being integral.

Throughout the specification, patterns, vias, planes, lines, and electrical connection structures refer to metal materials (eg, copper (Cu), aluminum (Al), silver (Ag), tin (Sn), gold (Au), nickel (Ni), lead (Pb), titanium (Ti), or a conductive material such as an alloy thereof), and chemical vapor deposition (CVD) ), PVD (Physical Vapor Deposition), sputtering, subtractive, additive, SAP (Semi-Additive Process), MSAP (Modified Semi-Additive Process), etc. It may be, but is not limited thereto.

Throughout the specification, the dielectric layer and/or the insulating layer is a thermosetting resin such as FR4, liquid crystal polymer (LCP), low temperature co-fired ceramic (LTCC), epoxy resin, thermoplastic resin such as polyimide, or these resins are inorganic fillers. In addition, resin impregnated in core material such as glass fiber (Glass Fiber, Glass Cloth, Glass Fabric), prepreg, ABF (Ajinomoto Build-up Film), FR-4, BT (Bismaleimide Triazine), photosensitive insulation ( Photo Imagable Dielectric (PID) resin, general Copper Clad Laminate (CCL), or a glass or ceramic-based insulating material may be implemented.

Throughout the specification, Radio Frequency (RF) signals are Wi-Fi (IEEE 802.11 family, etc.), WiMAX (IEEE 802.16 family, etc.), IEEE 802.20, long term evolution (LTE), Ev-DO, HSPA+ , HSDPA+, HSUPA+, EDGE, GSM, GPS, GPRS, CDMA, TDMA, DECT, Bluetooth, 3G, 4G, 5G and any other wireless and wired protocols designated thereafter, but not limited to It doesn't work.

Hereinafter, various embodiments and modifications will be described in detail with reference to the drawings.

A dielectric resonator antenna 100a according to an exemplary embodiment will be described with reference to FIGS. 1, 2A, and 2B. 1 is a perspective view of a dielectric resonator antenna according to an exemplary embodiment, and FIGS. 2A and 2B are plan views of the dielectric resonator antenna of FIG. 1 .

Referring to FIGS. 1 and 2A , a dielectric resonator antenna (DRA) 100a according to an embodiment has a first direction DR1, a second direction DR2, and a first direction DR1 that are different from each other. and a dielectric block 111 having an extended shape along a third direction DR3 perpendicular to the second direction DR2, a first feed via 11 positioned inside the dielectric block 111, and a second It may include a feed via 12 and a plurality of connectors 1 and 1a located under the dielectric block 111, that is, attached to a bottom surface of the dielectric block 111. A portion 1a of the plurality of connection parts 1 and 1a may overlap the first feed via 11 and the second feed via 12 .

The dielectric block 111 may have, for example, a rectangular parallelepiped shape, and the dielectric block 111 may have a via hole into which the first feed via 11 and the second feed via 12 are inserted.

The dielectric block 111 includes a plurality of first sides Ea parallel to the first direction DR1, a plurality of second sides Eb parallel to the first direction DR1, and a plurality of sides parallel to the third direction DR3. A third side (Ec) may be included. The dielectric block 111 may have a first length (a) along the first direction (DR1), have a second length (b) along the second direction (DR2), and along the third direction (DR3). It may have a rectangular parallelepiped shape having a third length (c).

The first feed via 11 and the second feed via 12 may be positioned within a portion of the dielectric block 111 along the third direction DR3 .

A first height h1 of the first feed via 11 measured from the bottom surface of the dielectric block 111 along the third direction DR3 is higher than the second height h2 of the second feed via 12 can

When an electric signal is applied to the first feed via 11 and the second feed via 12, a resonance of a certain frequency occurs inside the dielectric block 111, and an RF signal is transmitted and received according to the resonance frequency of the antenna 100a. can

The dielectric resonator antenna 100a may transmit and receive an RF signal of a first bandwidth through the first feed via 11, and transmit and receive an RF signal of a second bandwidth different from the first bandwidth through the second feed via 12. can do. A center frequency of the first bandwidth may be lower than a center frequency of the second bandwidth. For example, the center frequency of the first bandwidth may be about 24 GHz or about 28 GHz, and the center frequency of the second bandwidth may be about 39 GHz.

The first feed via 11 and the second feed via 12 pass through the center C of the bottom surface of the dielectric block 111 and are arranged on a first imaginary straight line L1 parallel to the first direction DR1. The first feed via 11 and the second feed via 12 may be symmetrically arranged with respect to the center C of the bottom surface of the dielectric block 111 .

The first feed via 11 and the second feed via 12 may be disposed adjacent to the center of two second sides Eb facing each other along the first direction DR1, and the dielectric block 111 The first distance d1 between the central part C of the bottom surface and the first feed via 11 may be substantially the same as the second distance d2 between the central part C and the second feed via 12. .

Referring to FIG. 2B , when the first feed via 11 and the second feed via 12 are disposed symmetrically to each other along the first straight line L1, the first feed via 11 and the second feed via ( 12), not only the first positions 11x and 12x where the centers of the first feed via 11 and the second feed via 12 are disposed on the first straight line L1, but also the first positions 11x and 12x Second positions (11y, 12y) and third positions (11z, 12z) located on both sides of and the edge portions of the first feed via 11 and the second feed via 12 are disposed on the first straight line L1 ) may be placed.

Therefore, the center (C) of the bottom surface of the dielectric block 111 in which the first feed via 11 and the second feed via 12 are symmetrical to each other means the exact center point of the bottom surface of the dielectric block 111 Rather, the central portion C is a symmetrical central portion C1 that is symmetrical to each other when the first feed via 11 and the second feed via 12 are disposed at the first positions 11x and 12x, the first When the feed via 11 and the second feed via 12 are disposed at the second positions 11y and 12y, the symmetric center C2 is symmetrical to each other, the first feed via 11 and the second feed via ( 12) may be a predetermined area that may include both symmetrical center portions C3 that are symmetrical to each other when disposed at the third positions 11z and 12z.

As such, the first feed via 11 and the second feed via 12 are adjacent to the edge of the second side Eb facing each other along the first direction DR1 and are adjacent to the bottom surface of the dielectric block 111. By arranging them symmetrically and spaced apart from each other with respect to the center (C), the electric field generated by the electrical signal applied to the first feed via 11 in the dielectric block 111 is distributed The length and second feed The distribution length of the electric field generated by the electrical signal applied to the via 12 can be increased, respectively, without increasing the size of the dielectric block 111, the bandwidth of the RF signal of the first bandwidth and the RF signal of the second bandwidth can be widened, and an RF signal of a first bandwidth transmitted and received by an electrical signal applied to the first feed via 11 and an RF signal of a second bandwidth transmitted and received by an electrical signal applied to the second feed via 12 interference between them can be reduced.

According to the dielectric resonator antenna 100a according to the present embodiment, the first feed via 11 and the second feed via having different heights are formed in the dielectric block 111, and the central portion C of the bottom surface of the dielectric block 111 ) By placing them in a straight line spaced apart from each other so as to be symmetrical to each other and adjacent to the edge of the bottom surface of the dielectric block 111, RF signals of different bands can be transmitted and received using one dielectric block 111. And, it is possible to widen the bandwidth of the RF signal of the first bandwidth and the RF signal of the second bandwidth, and increase the gain of the antenna 100a by reducing interference between the RF signal of the first bandwidth and the RF signal of the second bandwidth. .

A dielectric resonator antenna 100b according to another embodiment will be described with reference to FIGS. 3, 4A and 4B. 3 is a perspective view of a dielectric resonator antenna according to another exemplary embodiment, and FIGS. 4A and 4B are plan views of the dielectric resonator antenna of FIG. 3 .

Referring to FIGS. 3 and 4A , the dielectric resonator antenna 100b according to this embodiment is similar to the dielectric resonator antenna 100a according to the embodiment previously described with reference to FIGS. 1 , 2A and 2B . A detailed description of the same component is omitted.

Referring to FIGS. 3 and 4A, the dielectric resonator antenna 100b according to this embodiment is similar to the dielectric resonator antenna 100a according to the above-described embodiment, the dielectric block 111, the inside of the dielectric block 111 The first feed via 11 and the second feed via 12 located on the bottom of the dielectric block 111, that is, a plurality of connection parts 1 attached to the bottom surface of the dielectric block 111 , 1a).

The first feed via 11 and the second feed via 12 may be positioned within a portion of the dielectric block 111 along the third direction DR3 .

A first height h1 of the first feed via 11 measured from the bottom surface of the dielectric block 111 along the third direction DR3 is higher than the second height h2 of the second feed via 12 can

The dielectric resonator antenna 100b may transmit and receive an RF signal of a first bandwidth through the first feed via 11, and transmit and receive an RF signal of a second bandwidth different from the first bandwidth through the second feed via 12 can do. A center frequency of the first bandwidth may be lower than a center frequency of the second bandwidth.

However, the dielectric resonator antenna 100b according to this embodiment is different from the dielectric resonator antenna 100a according to the above-described embodiment, the first feed via 11 and the second feed via 12 are dielectric block 111 It may be disposed on a second imaginary straight line L2, which is a diagonal line passing through the central portion C of the bottom surface of.

The first feed via 11 and the second feed via 12 are two edges where a first side Ea parallel to the first direction DR1 and a second side Eb parallel to the second direction DR2 meet each other. can be placed adjacent to.

The third distance d3 between the center part C of the bottom surface of the dielectric block 111 and the first feed via 11 is the fourth distance d4 between the center part C and the second feed via 12 can be almost the same as

Referring to FIG. 4B , when the first feed via 11 and the second feed via 12 are disposed symmetrically to each other along the second straight line L2, the first feed via 11 and the second feed via ( 12) is the first position (11x, 12x) as well as the first position (11x, 12x) in which the centers of the first feed via 11 and the second feed via 12 are disposed on the second straight line L2 The second positions (11y, 12y) and the third positions (11z, 12z) are located on both sides of and the edge portions of the first feed via 11 and the second feed via 12 are disposed on the second straight line L2 ) may be placed.

Therefore, the center (C) of the bottom surface of the dielectric block 111 in which the first feed via 11 and the second feed via 12 are symmetrical to each other means the exact center point of the bottom surface of the dielectric block 111 Rather, the central portion C is a symmetrical central portion C1 that is symmetrical to each other when the first feed via 11 and the second feed via 12 are disposed at the first positions 11x and 12x, the first When the feed via 11 and the second feed via 12 are disposed at the second positions 11y and 12y, the symmetric center C2 is symmetrical to each other, the first feed via 11 and the second feed via ( 12) may be a predetermined area that may include both symmetrical center portions C3 that are symmetrical to each other when disposed at the third positions 11z and 12z.

As such, in the first feed via 11 and the second feed via 12, the first side Ea parallel to the first direction DR1 and the second side Eb parallel to the second direction DR2 are mutually The first feed via 11 and the second feed via 11 and the second The interval between the feed vias 12 may be further widened.

Therefore, interference between the RF signal of the first bandwidth transmitted and received by the electrical signal applied to the first feed via 11 and the RF signal of the second bandwidth transmitted and received by the electrical signal applied to the second feed via 12 can reduce In addition, within the dielectric block 111, the electric field generated by the electric signal applied to the first feed via 11 is distributed and the electric field generated by the electric signal applied to the second feed via 12 is distributed It is possible to increase the lengths of the first and second bandwidth RF signals without increasing the size of the dielectric block 111.

According to the dielectric resonator antenna 100b according to the present embodiment, the first feed via 11 and the second feed via 12 having different heights are formed in the dielectric block 111 at the bottom surface of the dielectric block 111. RF signals of different bands can be transmitted and received using one dielectric block 111 by disposing them spaced apart from each other on the diagonals passing through the center C so as to be symmetrical to each other with respect to the center C, and the first The bandwidths of the RF signal of the second bandwidth and the RF signal of the second bandwidth may be widened, and the gain of the antenna 100b may be increased by reducing interference between the RF signal of the first bandwidth and the RF signal of the second bandwidth.

Many features of the antenna according to the embodiment described above are all applicable to the antenna according to the present embodiment.

A dielectric resonator antenna 100c according to another embodiment will be described with reference to FIGS. 5, 6A, and 6B. 5 is a perspective view of a dielectric resonator antenna according to another exemplary embodiment, and FIGS. 6A and 6B are plan views of the dielectric resonator antenna of FIG. 5 .

Referring to FIGS. 5, 6A, and 6B, the dielectric resonator antenna 100c according to this embodiment is similar to the dielectric resonator antenna 100a according to the embodiment previously described with reference to FIGS. 1, 2A, and 2B. . A detailed description of the same component is omitted.

5 and 6A, the dielectric resonator antenna 100c according to this embodiment is similar to the dielectric resonator antenna 100a according to the above-described embodiment, the dielectric block 111, the inside of the dielectric block 111 The first feed via 11 and the second feed via 12 located on the bottom of the dielectric block 111, that is, a plurality of connection parts 1 attached to the bottom surface of the dielectric block 111 , 1a).

The first feed via 11 and the second feed via 12 may be positioned within a portion of the dielectric block 111 along the third direction DR3 .

A first height h1 of the first feed via 11 measured from the bottom surface of the dielectric block 111 along the third direction DR3 is higher than the second height h2 of the second feed via 12 can

The dielectric resonator antenna 100b may transmit and receive an RF signal of a first bandwidth through the first feed via 11, and transmit and receive an RF signal of a second bandwidth different from the first bandwidth through the second feed via 12 can do. A center frequency of the first bandwidth may be lower than a center frequency of the second bandwidth.

The first feed via 11 and the second feed via 12 may be disposed adjacent to the center of two second sides Eb facing each other along the first direction DR1, and the dielectric block 111 Passing through the center portion (C) of the bottom surface of and disposed on an imaginary first straight line (L1) parallel to the first direction (DR1), the center portion (C) of the bottom surface of the dielectric block 111 and the first feed via The first distance d1 between ( 11 ) may be substantially the same as the second distance ( d2 ) between the central portion (C) and the second feed via 12 .

However, unlike the dielectric resonator antenna 100a according to the above-described embodiment, the dielectric resonator antenna 100c according to the present embodiment has a shielding via 13 overlapping the central portion C of the bottom surface of the dielectric block 111. may further include.

The shield via 13 is located between the first feed via 11 and the second feed via 12, and the shield via 13 is spaced at substantially the same distance from the first feed via 11 and the second feed via 12. , and the third height h3 of the shield via 13 measured from the bottom surface of the dielectric block 111 is lower than the first height h1 of the first feed via 11, It may be equal to or higher than the second height h2 of the 2 feed vias 12 . However, it is not limited thereto, and the third height h3 of the shield via 13 may be equal to or higher than the second height h2 of the second feed via 12 .

Referring to FIG. 6B, the center C of the bottom surface of the dielectric block 111 in which the first feed vias 11 and the second feed vias 12 are symmetrical to each other is the top of the bottom surface of the dielectric block 111. It does not mean the central point, but the center C is a symmetric center C1 that is symmetrical to each other when the first feed via 11 and the second feed via 12 are disposed at the first positions 11x and 12x ), a symmetric center C2 symmetrical to each other when the first feed via 11 and the second feed via 12 are disposed at the second positions 11y and 12y, the first feed via 11 and the second feed via 11 When the 2-feed via 12 is disposed at the third positions 11z and 12z, it may be a predetermined area that may include both symmetrical center portions C3 that are symmetrical to each other. In addition, the shield via 13 may be located in the central portion C of the bottom surface of the dielectric block 111 including the central portions C1 , C2 , and C3 .

As such, the dielectric resonator antenna 100c according to the present embodiment is located between the first feed via 11 and the second feed via 12, and is substantially separated from the first feed via 11 and the second feed via 12. By further including shield vias 13 spaced at the same interval and having a third height h3 equal to or higher than the second height h2 of the second feed via 12, the first feed via 11 Interference between an RF signal of the first bandwidth transmitted and received by the electrical signal applied to ) and an RF signal of the second bandwidth transmitted and received by the electrical signal applied to the second feed via 12 may be further reduced.

In addition, according to the dielectric resonator antenna 100c according to the present embodiment, the first feed via 11 and the second feed via 12 having different heights are formed in the dielectric block 111 at the bottom of the dielectric block 111. RF of different bands using one dielectric block 111 by placing them in a straight line spaced apart from each other so that they are symmetrical with respect to the center of the surface (C) and adjacent to the edge of the bottom surface of the dielectric block 111. The antenna 100c can transmit and receive signals, widen the bandwidths of the RF signal of the first bandwidth and the RF signal of the second bandwidth, and reduce interference between the RF signal of the first bandwidth and the RF signal of the second bandwidth. can increase profits.

Many features of the antennas according to the above-described embodiments are all applicable to the antenna according to the present embodiment.

A dielectric resonator antenna 100d according to another embodiment will be described with reference to FIGS. 7, 8A, and 8B. 7 is a perspective view of a dielectric resonator antenna according to another embodiment, and FIGS. 8A and 8B are plan views of the dielectric resonator antenna of FIG. 7 .

Referring to FIGS. 7, 8A, and 8B, the dielectric resonator antenna 100d according to this embodiment is similar to the dielectric resonator antenna 100b according to the embodiment previously described with reference to FIGS. 3, 4A, and 4B. . A detailed description of the same component is omitted.

Referring to FIGS. 7 and 8A , the dielectric resonator antenna 100d according to this embodiment is similar to the dielectric resonator antenna 100b according to the above-described embodiment, the dielectric block 111 and the inside of the dielectric block 111 The first feed via 11 and the second feed via 12 located on the bottom of the dielectric block 111, that is, a plurality of connection parts 1 attached to the bottom surface of the dielectric block 111 , 1a).

The first feed via 11 and the second feed via 12 may be positioned within a portion of the dielectric block 111 along the third direction DR3 .

A first height h1 of the first feed via 11 measured from the bottom surface of the dielectric block 111 along the third direction DR3 is higher than the second height h2 of the second feed via 12 can

The dielectric resonator antenna 100b may transmit and receive an RF signal of a first bandwidth through the first feed via 11, and transmit and receive an RF signal of a second bandwidth different from the first bandwidth through the second feed via 12 can do. A center frequency of the first bandwidth may be lower than a center frequency of the second bandwidth.

The first feed via 11 and the second feed via 12 may overlap an imaginary second straight line L2, which is a diagonal line passing through the center C of the bottom surface of the dielectric block 111, and The via 11 and the second feed via 12 are adjacent to two corners where a first side Ea parallel to the first direction DR1 and a second side Eb parallel to the second direction DR2 meet each other. The third distance d3 between the center portion C of the bottom surface of the dielectric block 111 and the first feed via 11 is the first distance d3 between the center portion C and the second feed via 12. It may be almost the same as the 4 interval (d4).

However, unlike the dielectric resonator antenna 100b according to the above-described embodiment, the dielectric resonator antenna 100d according to the present embodiment has a shield via 13 overlapping the center C of the bottom surface of the dielectric block 111. may further include.

The shield via 13 is located between the first feed via 11 and the second feed via 12, and the shield via 13 is spaced at substantially the same distance from the first feed via 11 and the second feed via 12. , and the third height h3 of the shield via 13 measured from the bottom surface of the dielectric block 111 is lower than the first height h1 of the first feed via 11, It may be equal to or higher than the second height h2 of the 2 feed vias 12 . However, it is not limited thereto, and the third height h3 of the shield via 13 may be equal to or higher than the second height h2 of the second feed via 12 .

Referring to FIG. 8B, the center C of the bottom surface of the dielectric block 111 in which the first feed via 11 and the second feed via 12 are symmetrical to each other is the top of the bottom surface of the dielectric block 111. It does not mean the central point, but the center C is a symmetric center C1 that is symmetrical to each other when the first feed via 11 and the second feed via 12 are disposed at the first positions 11x and 12x ), a symmetric center C2 symmetrical to each other when the first feed via 11 and the second feed via 12 are disposed at the second positions 11y and 12y, the first feed via 11 and the second feed via 11 When the 2-feed via 12 is disposed at the third positions 11z and 12z, it may be a predetermined area that may include both symmetrical center portions C3 that are symmetrical to each other. In addition, the shield via 13 may be located in the central portion C of the bottom surface of the dielectric block 111 including the central portions C1 , C2 , and C3 .

As such, the dielectric resonator antenna 100d according to the present embodiment is located between the first feed via 11 and the second feed via 12, and is substantially separated from the first feed via 11 and the second feed via 12. By further including shield vias 13 spaced at the same interval and having a third height h3 equal to or higher than the second height h2 of the second feed via 12, the first feed via 11 Interference between an RF signal of the first bandwidth transmitted and received by the electrical signal applied to ) and an RF signal of the second bandwidth transmitted and received by the electrical signal applied to the second feed via 12 may be further reduced.

In addition, according to the dielectric resonator antenna 100d according to the present embodiment, the first feed via 11 and the second feed via 12 having different heights are placed in the dielectric block 111 at the bottom of the dielectric block 111. RF signals of different bands are transmitted using one dielectric block 111 by disposing the center (C) of the surface at a distance from each other on a diagonal passing through the center (C) so as to be symmetrical with respect to the center (C). It is possible to transmit and receive, widen the bandwidth of the RF signal of the first bandwidth and the RF signal of the second bandwidth, and reduce the interference between the RF signal of the first bandwidth and the RF signal of the second bandwidth to increase the gain of the antenna 100d. can be raised

Many features of the antennas according to the above-described embodiments are all applicable to the antenna according to the present embodiment.

A dielectric resonator antenna 100e according to another embodiment will be described with reference to FIGS. 9, 10A, and 10B. 9 is a perspective view of a dielectric resonator antenna according to another exemplary embodiment, and FIGS. 10A and 10B are plan views of the dielectric resonator antenna of FIG. 9 .

Referring to FIGS. 9, 10A and 10B, the dielectric resonator antenna 100e according to this embodiment is similar to the dielectric resonator antenna 100a according to the embodiment previously described with reference to FIGS. 1, 2A and 2B. . A detailed description of the same component is omitted.

9 and 10a, the dielectric resonator antenna 100e according to the present embodiment includes a plurality of feed vias 11a, 11b, 12a, and 12b located inside the dielectric block 111 and the dielectric block 111 ) It may include a plurality of connection parts (1, 1a) attached to the bottom surface.

Unlike the dielectric resonator antenna 100a according to the above-described embodiment, the dielectric resonator antenna 100e according to the present embodiment includes the first feed via 11a and the second feed via ( 11b), the third feed via 12a, and the fourth feed via 12b including feed vias 11a, 11b, 12a, and 12b.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b may be located within a portion of the dielectric block 111 along the third direction DR3. can

The first feed via 11a and the second feed via 11b may have a first height h1 measured from the bottom surface of the dielectric block 111 along the third direction DR3, and the third feed via 12a and the fourth feed via 12b may have a second height h2, and the first height h1 may be higher than the second height h2.

The dielectric resonator antenna 100e may transmit and receive a first polarized RF signal of a first bandwidth through the first feed via 11a, and transmit and receive a second polarized RF signal of the first bandwidth through the second feed via 11b. can transmit and receive. Similarly, the dielectric resonator antenna 100e may transmit and receive a first polarized RF signal of a second bandwidth through the third feed via 12a and receive a second polarized RF signal of the second bandwidth through the fourth feed via 12b. It can transmit and receive polarized RF signals.

A center frequency of the first bandwidth may be lower than a center frequency of the second bandwidth, the first polarization may be horizontal polarization, and the second polarization may be vertical polarization.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are in the first direction DR1 and the second direction DR2 of the dielectric block 111. ) and can be disposed adjacent to the center of four sides parallel to each other, and the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are dielectric blocks It may pass through the central portion C of the bottom surface of (111) and overlap an imaginary first straight line L1 and a third straight line L3 parallel to the first and second directions DR1 and DR2. The first feed vias 11a, the second feed vias 11b, the third feed vias 12a, and the fourth feed vias 12b are left, right, up, down, left, and right with respect to the center C of the bottom surface of the dielectric block 111. Can be placed in four positions.

A first distance d1 is provided between the center portion C of the bottom surface of the dielectric block 111 and the first feed via 11a and between the center portion C and the second feed via 11b, and the center portion C and the third feed via 12a and between the central portion C and the fourth feed via 12b have a second distance d2, and the first distance d1 and the second distance d2 may be substantially the same. there is.

The first feed via 11a and the fourth feed via 12b are disposed symmetrically with respect to the center C of the bottom surface along the first direction DR1, and the second feed via 11b and the second feed via 11b The three feed vias 12a may be arranged symmetrically with respect to the center C of the bottom surface along the second direction DR2 .

Referring to FIG. 10B , when the first feed via 11a and the fourth feed via 12b are disposed symmetrically to each other along the first straight line L1, the first feed via 11a and the fourth feed via ( 12b) is the first positions 11ax and 12bx as well as the first positions 11ax and 12bx where the centers of the first feed via 11a and the fourth feed via 12b are disposed on the first straight line L1 The second positions 11ay and 12by and the third positions 11az and 12bz are located on both sides of and the edge portions of the first feed via 11a and the fourth feed via 12b are disposed on the first straight line L1 ) may be placed. At the same time, when the second feed via 11b and the third feed via 12a are disposed symmetrically to each other along the third straight line L3, the second feed via 11b and the third feed via 12a , both sides of the fourth positions 11bx and 12ax as well as the fourth positions 11bx and 12ax where the centers of the second and third feed vias 11b and 12a are disposed on the third straight line L3 , and the edge portions of the second feed via 11b and the third feed via 12a are disposed on the third straight line L3 at the fifth position (11by, 12ay) and the sixth position (11bz, 12az) It could be.

Therefore, the center (C) of the bottom surface of the dielectric block 111 in which the first feed via 11a and the fourth feed via 12b are symmetrical to each other means the exact center point of the bottom surface of the dielectric block 111 Rather, the central part C is symmetrical central part C1 that is symmetrical to each other when the first feed via 11a and the fourth feed via 12b are disposed at the first positions 11ax and 12bx, the first When the feed via 11a and the fourth feed via 12b are disposed at the second positions 11ay and 12by, the symmetrical center C21 is symmetrical to each other, the first feed via 11a and the fourth feed via ( When 12b) is disposed at the third positions 11az and 12bz, the symmetric center C31 symmetric with each other, the second feed via 11b and the third feed via 12a are at the fifth position 11by and 12ay A symmetrical center C22 symmetrical to each other when disposed in, and a symmetrical symmetrical center C22 symmetrical to each other when the second feed via 11b and the third feed via 12a are disposed at the sixth positions 11bz and 12az. It may be a predetermined area that may include all of the central portion C32.

In this way, the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are connected to the first side Ea parallel to the first direction DR1. Imaginary planes adjacent to the second side Eb parallel to the second direction DR2 and passing through the center C of the bottom surface of the dielectric block 111 parallel to the first direction DR1 and the second direction DR2. By arranging the first straight line L1 and the third straight line L3 to be symmetrical and spaced apart from each other with respect to the center C of the bottom surface of the dielectric block 111, the first feed via 11a, A distance between the second feed via 11b, the third feed via 12a, and the fourth feed via 12b may be widened.

Accordingly, the first and second polarized RF signals of the first bandwidth transmitted and received by the electrical signals applied to the first feed via 11a and the second feed via 11b and the third feed via 12a and the fourth Interference between the first polarized wave and the second polarized wave RF signal of the second bandwidth transmitted and received by the electrical signal applied to the feed via 12b can be reduced, and transmitted and received by the electrical signal applied to the first feed via 11a It is possible to reduce interference between the first polarized RF signal of the first bandwidth and the second polarized RF signal of the first bandwidth transmitted and received by the electric signal applied to the second feed via 11b, and the third feed via 12a To reduce interference between the first polarized RF signal of the second bandwidth transmitted and received by the electrical signal applied to the ) and the second polarized RF signal of the second bandwidth transmitted and received by the electrical signal applied to the fourth feed via 12b can

In addition, within the dielectric block 111, the electric field generated by the electric signal applied to the first feed via 11a and the second feed via 11b is distributed, and the third feed via 12a and the fourth feed via 12a. The distribution length of the electric field generated by the electric signal applied to the via 12b can be increased, respectively, so that the size of the dielectric block 111 is not increased, and the first polarization and the second polarization RF signals of the first bandwidth and the second polarization The bandwidths of the first polarization and second polarization RF signals of 2 bandwidths may be widened.

According to the dielectric resonator antenna 100e according to the present embodiment, the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b in the dielectric block 111 ) are formed at different heights, and the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are based on the center (C) of the bottom surface RF signals of different bands are transmitted and received using one dielectric block 111 by disposing the first straight line L1 and the third straight line L3 passing through the center C so as to be symmetrical with each other and spaced apart from each other. It is possible to widen the bandwidth of the first polarized wave and the second polarized wave RF signal of the first bandwidth and the first polarized wave and the second polarized wave RF signal of the second bandwidth, and the first polarized wave and the second polarized wave RF of the first bandwidth. The gain of the antenna 100e may be increased by reducing interference between the signal and the first polarization and second polarization RF signals of the second bandwidth.

Many features of the antenna according to the embodiment described above are all applicable to the antenna according to the present embodiment.

A dielectric resonator antenna 100f according to another embodiment will be described with reference to FIGS. 11, 12A and 12B. 11 is a perspective view of a dielectric resonator antenna according to another embodiment, and FIGS. 12A and 12B are plan views of the dielectric resonator antenna of FIG. 11 .

Referring to FIGS. 11, 12A, and 12B, the dielectric resonator antenna 100f according to this embodiment is similar to the dielectric resonator antenna 100e according to the embodiment previously described with reference to FIGS. 9, 10A, and 10B. . A detailed description of the same component is omitted.

11 and 12a, the dielectric resonator antenna 100f according to the present embodiment includes a plurality of feed vias 11a, 11b, 12a, and 12b located inside the dielectric block 111 and the dielectric block 111 ) It may include a plurality of connection parts (1, 1a) attached to the bottom surface.

The first feed via 11a and the second feed via 11b may have a first height h1 measured from the bottom surface of the dielectric block 111 along the third direction DR3, and the third feed via 12a and the fourth feed via 12b may have a second height h2, and the first height h1 may be higher than the second height h2.

The dielectric resonator antenna 100f may transmit and receive a first polarized RF signal of a first bandwidth through the first feed via 11a, and transmit and receive a second polarized RF signal of the first bandwidth through the second feed via 11b. can transmit and receive. Similarly, the dielectric resonator antenna 100e may transmit and receive a first polarized RF signal of a second bandwidth through the third feed via 12a and receive a second polarized RF signal of the second bandwidth through the fourth feed via 12b. It can transmit and receive polarized RF signals.

A center frequency of the first bandwidth may be lower than a center frequency of the second bandwidth, the first polarization may be horizontal polarization, and the second polarization may be vertical polarization.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b pass through the central portion C of the bottom surface of the dielectric block 111 and form two It may overlap the second straight line L2 and the fourth straight line L4, which are diagonal lines passing through corners formed by the intersection of one side Ea and two second sides Eb. The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b have four corners based on the center C of the bottom surface of the dielectric block 111 It can be arranged symmetrically on the part.

A third distance d3 is provided between the center portion C of the bottom surface of the dielectric block 111 and the first feed via 11a and between the center portion C and the second feed via 11b, and the center portion C and the third feed via 12a and between the central portion C and the fourth feed via 12b have a fourth distance d4, and the third distance d3 and the fourth distance d4 may be substantially the same. there is.

The first feed via 11a and the fourth feed via 12b are arranged symmetrically with respect to the center C of the bottom surface, and the second feed via 11b and the third feed via 12a are They may be arranged symmetrically with respect to the center (C) of the surface.

Referring to FIG. 12B , when the first feed via 11a and the fourth feed via 12b are disposed symmetrically to each other along the second straight line L2, the first feed via 11a and the fourth feed via ( 12b) is the first positions 11ax and 12bx as well as the first positions 11ax and 12bx in which the centers of the first feed via 11a and the fourth feed via 12b are disposed on the second straight line L2 The second positions 11ay and 12by and the third positions 11az and 12bz are located on both sides of and the edges of the first feed via 11a and the fourth feed via 12b are disposed on the second straight line L2 ) may be placed. At the same time, when the second feed via 11b and the third feed via 12a are disposed symmetrically to each other along the fourth straight line L4, the second feed via 11b and the third feed via 12a , both sides of the fourth positions 11bx and 12ax as well as the fourth positions 11bx and 12ax where the centers of the second and third feed vias 11b and 12a are disposed on the fourth straight line L4 , and the edge portions of the second feed via 11b and the third feed via 12a are disposed on the fourth straight line L4 at fifth positions 11by and 12ay and at sixth positions 11bz and 12az It could be.

Therefore, the center (C) of the bottom surface of the dielectric block 111 in which the first feed via 11a and the fourth feed via 12b are symmetrical to each other means the exact center point of the bottom surface of the dielectric block 111 Rather, the central part C is symmetrical central part C1 that is symmetrical to each other when the first feed via 11a and the fourth feed via 12b are disposed at the first positions 11ax and 12bx, the first When the feed via 11a and the fourth feed via 12b are disposed at the second positions 11ay and 12by, the symmetrical center C21 is symmetrical to each other, the first feed via 11a and the fourth feed via ( When 12b) is disposed at the third positions 11az and 12bz, the symmetric center C31 symmetric with each other, the second feed via 11b and the third feed via 12a are at the fifth position 11by and 12ay A symmetrical center C22 symmetrical to each other when disposed in, and a symmetrical symmetrical center C22 symmetrical to each other when the second feed via 11b and the third feed via 12a are disposed at the sixth positions 11bz and 12az. It may be a predetermined area that may include all of the central portion C32.

In this way, the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are connected to the first side Ea parallel to the first direction DR1. The dielectric block 111 is adjacent to the four corners formed by the intersection of the second side Eb parallel to the second direction DR2 and is symmetrical with respect to the center C of the bottom surface of the dielectric block 111. The first feed via ( 11a), the second feed via 11b, the third feed via 12a, and the fourth feed via 12b may be further widened.

Accordingly, the first and second polarized RF signals of the first bandwidth transmitted and received by the electrical signals applied to the first feed via 11a and the second feed via 11b and the third feed via 12a and the fourth Interference between the first and second polarized RF signals of the second bandwidth transmitted and received by the electric signal applied to the feed via 12b may be reduced. In addition, within the dielectric block 111, the electric field generated by the electric signal applied to the first feed via 11a and the second feed via 11b is distributed, and the third feed via 12a and the fourth feed via 12a. The distribution length of the electric field generated by the electric signal applied to the via 12b can be increased, respectively, so that the size of the dielectric block 111 is not increased, and the first polarization and the second polarization RF signals of the first bandwidth and the second polarization The bandwidths of the first polarization and second polarization RF signals of 2 bandwidths may be widened.

According to the dielectric resonator antenna 100f according to the present embodiment, the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b in the dielectric block 111 ) are formed at different heights, and the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are based on the center (C) of the bottom surface RF of different bands using one dielectric block 111 by disposing the second straight line L2 and the fourth straight line L4, which are two diagonal lines passing through the center C, so as to be symmetrical to each other, spaced apart from each other. It is possible to transmit and receive signals, and to widen the bandwidth of the first polarization and second polarization RF signals of the first bandwidth and the first polarization and second polarization RF signals of the second bandwidth, and the first polarization and the second polarization of the first bandwidth. The gain of the antenna 100f may be increased by reducing interference between the two-polarized RF signal and the first and second polarized RF signals of the second bandwidth.

Many features of the antenna according to the embodiment described above are all applicable to the antenna according to the present embodiment.

A dielectric resonator antenna 100g according to another embodiment will be described with reference to FIGS. 13, 14A and 14B. 13 is a perspective view of a dielectric resonator antenna according to another embodiment, and FIGS. 14A and 1BB are plan views of the dielectric resonator antenna of FIG. 13 .

Referring to FIGS. 13, 14a and 14b, the dielectric resonator antenna 100g according to this embodiment is similar to the dielectric resonator antenna 100e according to the embodiment previously described with reference to FIGS. 9, 10a and 10b. . A detailed description of the same component is omitted.

13 and 14a, the dielectric resonator antenna 100g according to the present embodiment includes a plurality of feed vias 11a, 11b, 12a, and 12b located inside the dielectric block 111 and the dielectric block 111 ) It may include a plurality of connection parts (1, 1a) attached to the bottom surface.

The first feed via 11a and the second feed via 11b may have a first height h1 measured from the bottom surface of the dielectric block 111 along the third direction DR3, and the third feed via 12a and the fourth feed via 12b may have a second height h2, and the first height h1 may be higher than the second height h2.

The dielectric resonator antenna 100g may transmit and receive a first polarized RF signal of a first bandwidth through the first feed via 11a, and transmit and receive a second polarized RF signal of the first bandwidth through the second feed via 11b. can transmit and receive. Similarly, the dielectric resonator antenna 100g may transmit and receive a first polarized RF signal of a second bandwidth through the third feed via 12a, and receive a second polarized RF signal of the second bandwidth through the fourth feed via 12b. It can transmit and receive polarized RF signals.

A center frequency of the first bandwidth may be lower than a center frequency of the second bandwidth, the first polarization may be horizontal polarization, and the second polarization may be vertical polarization.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are in the first direction DR1 and the second direction DR2 of the dielectric block 111. ) and can be disposed adjacent to the center of four sides parallel to each other, and the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are dielectric blocks It may pass through the central portion C of the bottom surface of (111) and overlap an imaginary first straight line L1 and a third straight line L3 parallel to the first and second directions DR1 and DR2. The first feed vias 11a, the second feed vias 11b, the third feed vias 12a, and the fourth feed vias 12b are left, right, up, down, left, and right with respect to the center C of the bottom surface of the dielectric block 111. Can be placed in four positions.

A first distance d1 is provided between the center portion C of the bottom surface of the dielectric block 111 and the first feed via 11a and between the center portion C and the second feed via 11b, and the center portion C and the third feed via 12a and between the central portion C and the fourth feed via 12b have a second distance d2, and the first distance d1 and the second distance d2 may be substantially the same. there is.

The first feed via 11a and the fourth feed via 12b are disposed symmetrically with respect to the center C of the bottom surface along the first direction DR1, and the second feed via 11b and the second feed via 11b The three feed vias 12a may be arranged symmetrically with respect to the center C of the bottom surface along the second direction DR2 .

In this way, the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are connected to the first side Ea parallel to the first direction DR1. The center portion of the bottom surface of the dielectric block 111 is adjacent to the second side Eb parallel to the second direction DR2 and is symmetrical with respect to the center portion C of the bottom surface of the dielectric block 111 ( C), first feed vias 11a by arranging imaginary first straight lines L1 and third straight lines L3 parallel to the first and second directions DR1 and DR2 so as to be spaced apart from each other, A distance between the second feed via 11b, the third feed via 12a, and the fourth feed via 12b may be widened.

Accordingly, the first and second polarized RF signals of the first bandwidth transmitted and received by the electrical signals applied to the first feed via 11a and the second feed via 11b and the third feed via 12a and the fourth Interference between the first and second polarized RF signals of the second bandwidth transmitted and received by the electric signal applied to the feed via 12b may be reduced. In addition, within the dielectric block 111, the electric field generated by the electric signal applied to the first feed via 11a and the second feed via 11b is distributed, and the third feed via 12a and the fourth feed via 12a. The distribution length of the electric field generated by the electric signal applied to the via 12b can be increased, respectively, so that the size of the dielectric block 111 is not increased, and the first polarization and the second polarization RF signals of the first bandwidth and the second polarization The bandwidths of the first polarization and second polarization RF signals of 2 bandwidths may be widened.

However, unlike the dielectric resonator antenna 100e according to the above-described embodiment, the dielectric resonator antenna 100g according to the present embodiment has a shield via 13 overlapping the center portion C of the bottom surface of the dielectric block 111. may further include.

The shield via 13 is located between the first feed via 11a and the fourth feed via 12b and between the second feed via 11b and the third feed via 12a. The feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are spaced at substantially the same intervals and measured from the bottom surface of the dielectric block 111. The third height h3 of the shield via 13 is lower than the first height h1 of the first feed via 11a and the second feed via 11b, and the third feed via 12a and the fourth feed via It may be equal to or higher than the second height h2 of (12b).

Referring to FIG. 14B, similarly as described above with reference to FIG. 10B, the center portion C of the bottom surface of the dielectric block 111 in which the first feed via 11a and the fourth feed via 12b are symmetrical to each other does not mean the exact center point of the bottom surface of the dielectric block 111, but in the center C, the first feed via 11a and the fourth feed via 12b are disposed at the first positions 11ax and 12bx A symmetrical center C1 symmetrical to each other when the first feed via 11a and the fourth feed via 12b are symmetrical to each other when disposed at the second positions 11ay and 12by (C21) ), a symmetric center C31 symmetrical to each other when the first feed via 11a and the fourth feed via 12b are disposed at the third positions 11az and 12bz, and the second feed via 11b and the second feed via 11b When the 3 feed vias 12a are disposed at the fifth positions 11by and 12ay, the symmetric center C22 is symmetrical to each other, and the second and third feed vias 11b and 12a are at the sixth position It may be a predetermined area that may include both symmetrical center portions C32 that are symmetrical to each other when disposed at (11bz, 12az). In addition, the shielding via 13 may be located in the central portion C of the bottom surface of the dielectric block 111 including the central portions C1 , C21 , C31 , C22 , and C32 .

As such, the dielectric resonator antenna 100g according to the present embodiment is located between the first feed via 11a and the fourth feed via 12b and between the second feed via 11b and the third feed via 12a, The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are spaced at substantially the same intervals, and the third feed via 12a and the 4 By further including a shield via 13 having a third height h3 equal to or higher than the second height h2 of the feed via 12b, the first feed via 11a and the second feed via 11b The first and second polarized RF signals of the first bandwidth transmitted and received by electrical signals applied to and the second bandwidth transmitted and received by electrical signals applied to the third feed via 12a and the fourth feed via 12b Interference between the first polarized wave and the second polarized wave RF signal of may be further reduced.

According to the dielectric resonator antenna 100g according to the present embodiment, the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b in the dielectric block 111 ) are formed at different heights, and the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are based on the center (C) of the bottom surface RF signals of different bands are transmitted and received using one dielectric block 111 by disposing the first straight line L1 and the third straight line L3 passing through the center C so as to be symmetrical with each other and spaced apart from each other. It is possible to widen the bandwidth of the first polarized wave and the second polarized wave RF signal of the first bandwidth and the first polarized wave and the second polarized wave RF signal of the second bandwidth, and the first polarized wave and the second polarized wave RF of the first bandwidth. The gain of the antenna 100e may be increased by reducing interference between the signal and the first polarization and second polarization RF signals of the second bandwidth.

In addition, the dielectric resonator antenna 100g according to the present embodiment further includes a shielding via 13 to transmit and receive electrical signals applied to the first feed via 11a and the second feed via 11b. Between the first and second polarized RF signals of the second bandwidth transmitted and received by the electric signals applied to the third and fourth feed vias 12a and 12b and the first polarized and second polarized RF signals of the second bandwidth interference can be further reduced.

Many features of the antenna according to the embodiment described above are all applicable to the antenna according to the present embodiment.

A dielectric resonator antenna 100h according to another embodiment will be described with reference to FIGS. 15, 16A and 16B. 15 is a perspective view of a dielectric resonator antenna according to another embodiment, and FIGS. 16A and 16B are plan views of the dielectric resonator antenna of FIG. 15 .

15, 16a and 16b, the dielectric resonator antenna 100h according to this embodiment is similar to the dielectric resonator antenna 100f according to the embodiment previously described with reference to FIGS. 11, 12a and 12b. . A detailed description of the same component is omitted.

15 and 16a, the dielectric resonator antenna 100h according to the present embodiment includes a plurality of feed vias 11a, 11b, 12a, and 12b located inside the dielectric block 111 and the dielectric block 111 ) It may include a plurality of connection parts (1, 1a) attached to the bottom surface.

The first feed via 11a and the second feed via 11b may have a first height h1 measured from the bottom surface of the dielectric block 111 along the third direction DR3, and the third feed via 12a and the fourth feed via 12b may have a second height h2, and the first height h1 may be higher than the second height h2.

The dielectric resonator antenna 100h may transmit and receive a first polarized RF signal of a first bandwidth through the first feed via 11a and receive a second polarized RF signal of the first bandwidth through the second feed via 11b. can transmit and receive. Similarly, the dielectric resonator antenna 100h may transmit and receive a first polarized RF signal of a second bandwidth through the third feed via 12a and receive a second polarized RF signal of the second bandwidth through the fourth feed via 12b. It can transmit and receive polarized RF signals.

A center frequency of the first bandwidth may be lower than a center frequency of the second bandwidth, the first polarization may be horizontal polarization, and the second polarization may be vertical polarization.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b pass through the center C of the bottom surface of the dielectric block 111, and two It may be located on a second straight line L2 and a fourth straight line L4, which are diagonal lines passing through corners formed by the intersection of the first side Ea and the two second sides Eb. The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b have four corners based on the center C of the bottom surface of the dielectric block 111 It can be arranged symmetrically on the part.

A third distance d3 is provided between the center portion C of the bottom surface of the dielectric block 111 and the first feed via 11a and between the center portion C and the second feed via 11b, and the center portion C and the third feed via 12a and between the central portion C and the fourth feed via 12b have a fourth distance d4, and the third distance d3 and the fourth distance d4 may be substantially the same. there is.

The first feed via 11a and the fourth feed via 12b are arranged symmetrically with respect to the center C of the bottom surface, and the second feed via 11b and the third feed via 12a are They may be arranged symmetrically with respect to the center (C) of the surface.

In this way, the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are connected to the first side Ea parallel to the first direction DR1. The center (C) is adjacent to the four corners formed by the intersection of the second side (Eb) parallel to the second direction (DR2) and is symmetrical with respect to the center (C) of the bottom surface of the dielectric block 111. The first feed via 11a and the second feed via ( 11b), the interval between the third feed via 12a and the fourth feed via 12b may be further widened.

Accordingly, the first and second polarized RF signals of the first bandwidth transmitted and received by the electrical signals applied to the first feed via 11a and the second feed via 11b and the third feed via 12a and the fourth Interference between the first and second polarized RF signals of the second bandwidth transmitted and received by the electric signal applied to the feed via 12b may be reduced. In addition, within the dielectric block 111, the electric field generated by the electric signal applied to the first feed via 11a and the second feed via 11b is distributed, and the third feed via 12a and the fourth feed via 12a. The distribution length of the electric field generated by the electric signal applied to the via 12b can be increased, respectively, so that the size of the dielectric block 111 is not increased, and the first polarization and the second polarization RF signals of the first bandwidth and the second polarization The bandwidths of the first polarization and second polarization RF signals of 2 bandwidths may be widened.

However, unlike the dielectric resonator antenna 100f according to the above-described embodiment, the dielectric resonator antenna 100h according to the present embodiment has a shield via 13 overlapping the center C of the bottom surface of the dielectric block 111. may further include.

The shield via 13 is located between the first feed via 11a and the fourth feed via 12b and between the second feed via 11b and the third feed via 12a. The feed vias 11a, the second feed vias 11b, the third feed vias 12a, and the fourth feed vias 12b are spaced at substantially the same intervals and measured from the bottom surface of the dielectric block 111. The third height h3 of the shield via 13 is lower than the first height h1 of the first feed via 11a and the second feed via 11b, and the third feed via 12a and the fourth feed via It may be equal to or higher than the second height h2 of (12b).

Referring to FIG. 16B, similarly as described above with reference to FIG. 12B, the center portion C of the bottom surface of the dielectric block 111 in which the first feed via 11a and the fourth feed via 12b are symmetrical to each other does not mean the exact center point of the bottom surface of the dielectric block 111, but in the center C, the first feed via 11a and the fourth feed via 12b are disposed at the first positions 11ax and 12bx A symmetrical center C1 symmetrical to each other when the first feed via 11a and the fourth feed via 12b are symmetrical to each other when disposed at the second positions 11ay and 12by (C21) ), a symmetric center C31 symmetrical to each other when the first feed via 11a and the fourth feed via 12b are disposed at the third positions 11az and 12bz, and the second feed via 11b and the second feed via 11b When the 3 feed vias 12a are disposed at the fifth positions 11by and 12ay, the symmetric center C22 is symmetrical to each other, and the second and third feed vias 11b and 12a are at the sixth position It may be a predetermined area that may include both symmetrical center portions C32 that are symmetrical to each other when disposed at (11bz, 12az). In addition, the shielding via 13 may be located in the central portion C of the bottom surface of the dielectric block 111 including the central portions C1 , C21 , C31 , C22 , and C32 .

As such, the dielectric resonator antenna 100h according to the present embodiment is located between the first feed via 11a and the fourth feed via 12b and between the second feed via 11b and the third feed via 12a, The first feed vias 11a, the second feed vias 11b, the third feed vias 12a, and the fourth feed vias 12b are spaced apart from each other, and the third feed vias 12a and 4 By further including a shield via 13 having a third height h3 equal to or higher than the second height h2 of the feed via 12b, the first feed via 11a and the second feed via 11b The first and second polarized RF signals of the first bandwidth transmitted and received by electrical signals applied to and the second bandwidth transmitted and received by electrical signals applied to the third feed via 12a and the fourth feed via 12b Interference between the first polarized wave and the second polarized wave RF signal of may be further reduced.

According to the dielectric resonator antenna 100h according to the present embodiment, the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b in the dielectric block 111 ) are formed at different heights, and the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are based on the center (C) of the bottom surface RF of different bands using one dielectric block 111 by disposing the second straight line L2 and the fourth straight line L4, which are two diagonal lines passing through the center C, so as to be symmetrical to each other, spaced apart from each other. It is possible to transmit and receive signals, and to widen the bandwidth of the first polarization and second polarization RF signals of the first bandwidth and the first polarization and second polarization RF signals of the second bandwidth, and the first polarization and the second polarization of the first bandwidth. The gain of the antenna 100h may be increased by reducing interference between the two-polarized RF signal and the first and second polarized RF signals of the second bandwidth.

In addition, the dielectric resonator antenna 100h according to the present embodiment further includes a shielding via 13 to transmit and receive electrical signals applied to the first feed via 11a and the second feed via 11b. Between the first and second polarized RF signals of the second bandwidth transmitted and received by the electric signals applied to the third and fourth feed vias 12a and 12b and the first polarized and second polarized RF signals of the second bandwidth interference can be further reduced.

Many features of the antenna according to the embodiment described above are all applicable to the antenna according to the present embodiment.

A dielectric resonator antenna 100i according to another embodiment will be described with reference to FIGS. 17 and 18 . 17 is a perspective view of a dielectric resonator antenna according to another embodiment, and FIG. 18 is a plan view of the dielectric resonator antenna of FIG. 17 .

17 and 18, the dielectric resonator antenna 100i according to the present embodiment has a first side Ea parallel to the first direction DR1 and a second direction DR2 of the dielectric block 111. The first feed strip 21a, the second feed strip 21b, and the second feed strip 21b extend from the bottom surface of the dielectric block 111 in the third direction DR3 along the four corners formed by the intersection of the second sides Eb. It may include a plurality of connection parts 1 and 1a attached to the bottom surface of the three feed strips 22a, the fourth feed strip 22b and the dielectric block 111.

The first feed strip 21a and the second feed strip 21b may have a first height h1 measured from the bottom surface of the dielectric block 111, and the third feed strip 22a and the fourth feed strip (22b) may have a second height (h2), the first height (h1) may be higher than the second height (h2).

The dielectric resonator antenna 100i may transmit and receive a first polarized RF signal of a first bandwidth through a first feed strip 21a and receive a second polarized RF signal of a first bandwidth through a second feed strip 21b. can transmit and receive. Similarly, the dielectric resonator antenna 100i may transmit and receive the first polarized RF signal of the second bandwidth through the third feed strip 22a, and the second polarized RF signal of the second bandwidth through the fourth feed strip 22b. It can transmit and receive polarized RF signals.

A center frequency of the first bandwidth may be lower than a center frequency of the second bandwidth, the first polarization may be horizontal polarization, and the second polarization may be vertical polarization.

The first feed strip (21a), the second feed strip (21b), the third feed strip (22a), and the fourth feed strip (22b) pass through the central portion (C) of the bottom surface of the dielectric block (111) and pass through the two first feed strips. It may overlap with two diagonal lines passing through corners formed by the intersection of one side Ea and two second sides Eb. The first feed strip 21a, the second feed strip 21b, the third feed strip 22a, and the fourth feed strip 22b have four corners based on the center C of the bottom surface of the dielectric block 111. It can be arranged symmetrically on the part.

The first feed strip 21a, the second feed strip 21b, the third feed strip 22a, and the fourth feed strip 22b have the same distance from the center C of the bottom surface of the dielectric block 111. can have

The first feed strip 21a and the fourth feed strip 22b are disposed symmetrically with respect to the center C of the bottom surface, and the second feed strip 21b and the third feed strip 22a are disposed on the bottom surface. They may be arranged symmetrically with respect to the center (C) of the surface.

In this way, the first feed strip 21a, the second feed strip 21b, the third feed strip 22a, and the fourth feed strip 22b are connected to the first side Ea parallel to the first direction DR1. The bottom of the dielectric block 111 is located at four corners formed by the intersection of the second side Eb parallel to the second direction DR2 and is symmetrical with respect to the center C of the bottom surface of the dielectric block 111. The first feed strip 21a, the second feed strip 21b, and the third feed strip do not increase the size of the dielectric block 111 by arranging them spaced apart from each other on two diagonal lines passing through the center C of the surface. (22a), the interval between the fourth feed strip (22b) can be widened.

Accordingly, the first and second polarized RF signals of the first bandwidth transmitted and received by the electric signals applied to the first feed strip 21a and the second feed strip 21b and the third feed strip 22a and the fourth feed strip 22a are transmitted and received. Interference between the first and second polarized RF signals of the second bandwidth transmitted and received by the electric signal applied to the feed strip 22b may be reduced. In addition, in the dielectric block 111, the electric field generated by the electric signal applied to the first feed strip 21a and the second feed strip 21b is distributed, and the third feed strip 22a and the fourth feed strip 22a. The distribution length of the electric field generated by the electric signal applied to the strip 22b can be increased, respectively, so that the size of the dielectric block 111 is not increased, and the first polarized wave and the second polarized wave RF signal of the first bandwidth are separated from each other. The bandwidths of the first polarization and second polarization RF signals of 2 bandwidths may be widened.

According to the dielectric resonator antenna 100i according to this embodiment, the first feed strip 21a, the second feed strip 21b, the third feed strip 22a, and the fourth feed strip 22b are formed on the dielectric block 111. ) is formed with different heights, and the first feed strip 21a, the second feed strip 21b, the third feed strip 22a, and the fourth feed strip 22b pass through the center C of the bottom surface. One dielectric block ( 111) can be used to transmit and receive RF signals of different bands, and the bandwidths of the first polarized and second polarized RF signals of the first bandwidth and the first and second polarized waves of the second bandwidth can be widened, , It is possible to increase the gain of the antenna 100i by reducing interference between the first and second polarized RF signals of the first bandwidth and the first and second polarization RF signals of the second bandwidth.

Many features of the antenna according to the embodiment described above are all applicable to the antenna according to the present embodiment.

A dielectric resonator antenna 100j according to another embodiment will be described with reference to FIGS. 19 and 20 . 19 is a perspective view of a dielectric resonator antenna according to another embodiment, and FIG. 20 is a plan view of the dielectric resonator antenna of FIG. 19 .

Referring to FIGS. 19 and 20 , the dielectric resonator antenna 100j according to this embodiment is similar to the dielectric resonator antenna 100i according to the embodiment previously described with reference to FIGS. 17 and 18 . A detailed description of the same component is omitted.

In the dielectric resonator antenna 100j according to the present embodiment, the first side Ea parallel to the first direction DR1 and the second side Eb parallel to the second direction DR2 of the dielectric block 111 intersect. The first feed strip 21a, the second feed strip 21b, the third feed strip 22a, the fourth feed strip 21a, the second feed strip 21b, and the fourth feed strip 21a extend from the bottom surface of the dielectric block 111 along the four corners formed in the third direction DR3. It may include a plurality of connection parts (1, 1a) attached to the bottom surface of the feed strip (22b) and the dielectric block (111).

The first feed strip 21a and the second feed strip 21b may have a first height h1 measured from the bottom surface of the dielectric block 111, and the third feed strip 22a and the fourth feed strip (22b) may have a second height (h2), the first height (h1) may be higher than the second height (h2).

The dielectric resonator antenna 100j may transmit and receive a first polarized RF signal of a first bandwidth through a first feed strip 21a and receive a second polarized RF signal of a first bandwidth through a second feed strip 21b. can transmit and receive. Similarly, the dielectric resonator antenna 100j may transmit and receive the first polarized RF signal of the second bandwidth through the third feed strip 22a, and the second polarized RF signal of the second bandwidth through the fourth feed strip 22b. It can transmit and receive polarized RF signals.

A center frequency of the first bandwidth may be lower than a center frequency of the second bandwidth, the first polarization may be horizontal polarization, and the second polarization may be vertical polarization.

The first feed strip 21a, the second feed strip 21b, the third feed strip 22a, and the fourth feed strip 22b are connected to the first side Ea parallel to the first direction DR1 and the second feed strip 21b. It is located at the four corners formed by the intersection of the second side Eb parallel to the direction DR2 and passes through the center C of the bottom surface of the dielectric block 111, and the second straight line L2 and the fourth straight line L4, which are two diagonal lines, ) and arranged symmetrically with respect to the center (C) of the bottom surface of the dielectric block 111 so as to be spaced apart from each other, the first feed strip 21a without increasing the size of the dielectric block 111 , The interval between the second feed strip 21b, the third feed strip 22a, and the fourth feed strip 22b may be widened.

Accordingly, the first and second polarized RF signals of the first bandwidth transmitted and received by the electric signals applied to the first feed strip 21a and the second feed strip 21b and the third feed strip 22a and the fourth feed strip 22a are transmitted and received. Interference between the first and second polarized RF signals of the second bandwidth transmitted and received by the electric signal applied to the feed strip 22b may be reduced. In addition, in the dielectric block 111, the electric field generated by the electric signal applied to the first feed strip 21a and the second feed strip 21b is distributed, and the third feed strip 22a and the fourth feed strip 22a. The distribution length of the electric field generated by the electric signal applied to the strip 22b can be increased, respectively, so that the size of the dielectric block 111 is not increased, and the first polarized wave and the second polarized wave RF signal of the first bandwidth are separated from each other. The bandwidths of the first polarization and second polarization RF signals of 2 bandwidths may be widened.

However, unlike the dielectric resonator antenna 100i according to the above-described embodiment, the dielectric resonator antenna 100j according to the present embodiment has a shield via 13 overlapping the center portion C of the bottom surface of the dielectric block 111. may further include.

The shield via 13 is located between the first feed strip 21a and the fourth feed strip 22b and between the second feed strip 21b and the third feed strip 22a, and the shield via 13 is The feed strip 21a, the second feed strip 21b, the third feed strip 22a, and the fourth feed strip 22b are spaced apart from each other, and the shielding measured from the bottom surface of the dielectric block 111 The third height h3 of the via 13 is lower than the first height h1 of the first feed strip 21a and the second feed strip 21b, and the third feed strip 22a and the fourth feed strip ( It may be equal to or higher than the second height h2 of 22b).

As such, the dielectric resonator antenna 100j according to this embodiment is located between the first feed strip 21a and the fourth feed strip 22b and between the second feed strip 21b and the third feed strip 22a, The first feed strip 21a, the second feed strip 21b, the third feed strip 22a, and the fourth feed strip 22b are spaced at substantially the same intervals, and the third feed strip 22a and the fourth feed strip Applying to the first feed strip 21a and the second feed strip 21b by further including a shield via 13 having a third height h3 that is equal to or higher than the second height h2 of the strip 22b. The first and second polarized RF signals of the first bandwidth transmitted and received by the electrical signal and the second bandwidth of the second bandwidth transmitted and received by the electrical signal applied to the third feed strip 22a and the fourth feed strip 22b Interference between the first polarization and second polarization RF signals can be further reduced.

According to the dielectric resonator antenna 100j according to this embodiment, the first feed strip 21a, the second feed strip 21b, the third feed strip 22a, and the fourth feed strip 22b are formed on the dielectric block 111. ) of different heights, and the first feed strip 21a, the second feed strip 21b, the third feed strip 22a, and the fourth feed strip 22b are based on the center C of the bottom surface. By placing them spaced apart from each other at the four corners of the dielectric block 111 so as to be symmetrical to each other and overlapping the two diagonal lines passing through the center (C), RF signals of different bands can be transmitted and received using one dielectric block 111. The first polarized wave and the second polarized wave RF signal of the first bandwidth and the first polarized wave and the second polarized wave RF signal of the second bandwidth may be widened, and the first polarized wave and the second polarized wave RF signal of the first bandwidth may be widened. It is possible to increase the gain of the antenna 100j by reducing interference between the first polarized wave and the second polarized wave RF signal of the second bandwidth.

In addition, the dielectric resonator antenna 100j according to the present embodiment further includes a shielding via 13, so that the first feed strip 21a and the second feed strip 21b are transmitted and received by electrical signals applied to the first feed strip 21a and the second feed strip 21b. Between the first and second polarized RF signals of the second bandwidth transmitted and received by the electrical signals applied to the third and fourth feed strips 22a and 22b and the first polarized and second polarized RF signals of the second bandwidth. interference can be further reduced.

Many features of the antenna according to the embodiment described above are all applicable to the antenna according to the present embodiment.

Referring to FIG. 21, a dielectric resonator antenna 100k according to another embodiment will be described. 21 is a perspective view of a dielectric resonator antenna according to another embodiment.

Referring to FIG. 21 , a dielectric resonator antenna 100k according to this embodiment is similar to the dielectric resonator antenna 100a according to the embodiment described with reference to FIGS. 1 and 2 . A detailed description of the same component is omitted.

The dielectric resonator antenna 100k according to the present embodiment includes a dielectric block 111, a first feed via 11 and a second feed via 12 located inside the dielectric block 111, and a dielectric block 111 It may include a plurality of connection parts (1, 1a) located below, that is, attached to the bottom surface of the dielectric block 111.

The dielectric block 111 may include a first dielectric block 110 , a second dielectric block 120 , and a third dielectric block 130 sequentially disposed along the third direction DR3 . The dielectric constants of the first dielectric block 110, the second dielectric block 120, and the third dielectric block 130 may be the same, but differently, the first dielectric block 110, the second dielectric block 120, the The dielectric constants of the three dielectric blocks 130 may be different from each other. For example, the permittivity of the first dielectric block 110 and the third dielectric block 130 may be higher than that of the second dielectric block 120, but is not limited thereto. The permittivity of the second dielectric block 120 and the third dielectric block 130 can be changed.

The first dielectric block 110 , the second dielectric block 120 , and the third dielectric block 130 may have the same planar shape so as to overlap each other along the third direction DR3 . When the first dielectric block 110, the second dielectric block 120, and the third dielectric block 130 are stacked and bonded to each other along the third direction DR3, each of the side surfaces, that is, the four pairs of side surfaces, respectively It can be smoothly connected to each other without a step so as to be located on the same plane (coplanar).

The dielectric block 111 including the first dielectric block 110, the second dielectric block 120, and the third dielectric block 130 may have, for example, a rectangular parallelepiped shape, and the dielectric block 111 has a It may have via holes into which the first feed via 11 and the second feed via 12 are inserted.

The first feed via 11 and the second feed via 12 may be located within a portion of the dielectric block 111 along the third direction DR3, and the first feed via 11 may be located in the first dielectric block ( 110) and the second dielectric block 120, and the second feed via 12 may be located in the first dielectric block 110. A first height h1 of the first feed via 11 measured from the bottom surface of the dielectric block 111 along the third direction DR3 is higher than the second height h2 of the second feed via 12 can

The dielectric resonator antenna 100k may transmit and receive an RF signal of a first bandwidth through the first feed via 11, and transmit and receive an RF signal of a second bandwidth different from the first bandwidth through the second feed via 12 can do. A center frequency of the first bandwidth may be lower than a center frequency of the second bandwidth.

The first feed via 11 and the second feed via 12 may be disposed adjacent to the center of two second sides Eb facing each other along the first direction DR1, and the dielectric block 111 It can be disposed on a first imaginary straight line L1 parallel to the first direction DR1 passing through the center C of the bottom surface of, and the first feed via 11 and the second feed via 12 are dielectric blocks (111) may have substantially the same distance from the center (C) of the bottom surface.

As such, the dielectric resonator antenna 100k according to this embodiment has a first dielectric block of the dielectric blocks 111 including the first dielectric block 110, the second dielectric block 120, and the third dielectric block 130. 110 and a first feed via 11 positioned on the second dielectric block 120 and a second feed via 12 positioned on the first dielectric block 110, the first feed via 11 and the second feed via 12, based on the center C of the bottom surface of the dielectric block 111, are symmetrical to each other with the same interval and adjacent to the edge of the bottom surface of the dielectric block 111, By spaced apart arrangement, RF signals of different bands can be transmitted and received using the same dielectric block 111, the bandwidths of the RF signal of the first bandwidth and the RF signal of the second bandwidth can be widened, and the RF of the first bandwidth The gain of the antenna 100k may be increased by reducing interference between the signal and the RF signal of the second bandwidth.

Many features of the antennas according to the above-described embodiments are all applicable to the antenna according to the present embodiment.

Referring to FIG. 22, a dielectric resonator antenna 100l according to another embodiment will be described. 22 is a perspective view of a dielectric resonator antenna according to another embodiment.

Referring to FIG. 22 , the dielectric resonator antenna 100l according to this embodiment is similar to the dielectric resonator antenna 100k according to the above-described embodiment. A detailed description of the same component is omitted.

The dielectric resonator antenna 100l according to the present embodiment includes a dielectric block 111, a first feed via 11 and a second feed via 12 located inside the dielectric block 111, and a dielectric block 111 It may include a plurality of connection parts (1, 1a) located below, that is, attached to the bottom surface of the dielectric block 111.

The dielectric block 111 may include a first dielectric block 110 , a second dielectric block 120 , and a third dielectric block 130 sequentially disposed along the third direction DR3 . The dielectric constants of the first dielectric block 110, the second dielectric block 120, and the third dielectric block 130 may be the same, but differently, the first dielectric block 110, the second dielectric block 120, the The dielectric constants of the three dielectric blocks 130 may be different from each other.

The first feed via 11 may be located in the first dielectric block 110 and the second dielectric block 120, and the second feed via 12 may be located in the first dielectric block 110, A first height h1 of the first feed via 11 measured from the bottom surface of the dielectric block 111 along the third direction DR3 is higher than the second height h2 of the second feed via 12 can

The dielectric resonator antenna 100l may transmit and receive an RF signal of a first bandwidth through the first feed via 11, and transmit and receive an RF signal of a second bandwidth different from the first bandwidth through the second feed via 12 can do. A center frequency of the first bandwidth may be lower than a center frequency of the second bandwidth.

However, the dielectric resonator antenna 100l according to this embodiment is different from the dielectric resonator antenna 100k according to the above-described embodiment, the first feed via 11 and the second feed via 12 are dielectric block 111 It may be disposed on a second imaginary straight line L2, which is a diagonal line passing through the central portion C of the bottom surface of.

The first feed via 11 and the second feed via 12 are two edges where a first side Ea parallel to the first direction DR1 and a second side Eb parallel to the second direction DR2 meet each other. can be placed adjacent to.

The first feed via 11 and the second feed via 12 may have substantially the same distance from each other from the center C of the bottom surface of the dielectric block 111 .

As such, in the first feed via 11 and the second feed via 12, the first side Ea parallel to the first direction DR1 and the second side Eb parallel to the second direction DR2 are mutually The first feed via 11 and the second feed via (12) The interval between them can be widened further.

Therefore, interference between the RF signal of the first bandwidth transmitted and received by the electrical signal applied to the first feed via 11 and the RF signal of the second bandwidth transmitted and received by the electrical signal applied to the second feed via 12 can reduce In addition, within the dielectric block 111, the electric field generated by the electric signal applied to the first feed via 11 is distributed and the electric field generated by the electric signal applied to the second feed via 12 is distributed It is possible to increase the lengths of the first and second bandwidth RF signals without increasing the size of the dielectric block 111.

As such, the dielectric resonator antenna 100l according to this embodiment has a first dielectric block of the dielectric blocks 111 including the first dielectric block 110, the second dielectric block 120, and the third dielectric block 130. 110 and a first feed via 11 positioned on the second dielectric block 120 and a second feed via 12 positioned on the first dielectric block 110, the first feed via 11 and the second feed via 12 are symmetrical to each other with respect to the center C of the bottom surface of the dielectric block 111, and the first side Ea parallel to the first direction DR1 and the second direction DR2 ) and parallel second sides (Eb) are spaced apart from each other so that they are adjacent to the two corners where they meet each other, so that RF signals of different bands can be transmitted and received using the same dielectric block 111, and RF signals of the first bandwidth It is possible to widen the bandwidth of the RF signal of the second bandwidth and to increase the gain of the antenna 100k by reducing interference between the RF signal of the first bandwidth and the RF signal of the second bandwidth.

Many features of the antennas according to the above-described embodiments are all applicable to the antenna according to the present embodiment.

Referring to FIG. 23, a dielectric resonator antenna 100m according to another embodiment will be described. 23 is a perspective view of a dielectric resonator antenna according to another embodiment.

Referring to FIG. 23, the dielectric resonator antenna 100m according to the present embodiment includes a plurality of feed vias 11a, 11b, 12a, and 12b located inside the dielectric block 111 and the bottom of the dielectric block 111. It may include a plurality of connection parts (1, 1a) attached to the surface.

The dielectric block 111 may include a first dielectric block 110 , a second dielectric block 120 , and a third dielectric block 130 sequentially disposed along the third direction DR3 . The dielectric constants of the first dielectric block 110, the second dielectric block 120, and the third dielectric block 130 may be the same, but differently, the first dielectric block 110, the second dielectric block 120, the The dielectric constants of the three dielectric blocks 130 may be different from each other.

The first feed via 11a and the second feed via 11b may be positioned in the first dielectric block 110 and the second dielectric block 120, and the third feed via 12a and the fourth feed via ( 12b) may be located in the first dielectric block 110, and the first feed via 11a and the second feed via 11b measured from the bottom surface of the dielectric block 111 along the third direction DR3 The first height h1 of may be higher than the second height h2 of the third and fourth feed vias 12a and 12b.

The dielectric resonator antenna 100m may transmit and receive a first polarized RF signal of a first bandwidth through a first feed via 11a, and transmit and receive a second polarized RF signal of a first bandwidth through a second feed via 11b. A first polarized RF signal of a second bandwidth can be transmitted and received through the third feed via 12a, and a second polarized wave RF signal of a second bandwidth can be transmitted and received through the fourth feed via 12b. can

A center frequency of the first bandwidth may be lower than a center frequency of the second bandwidth, the first polarization may be horizontal polarization, and the second polarization may be vertical polarization.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b pass through the central portion C of the bottom surface of the dielectric block 111 and form two It may be disposed on a second straight line L2 and a fourth straight line L4, which are diagonal lines passing through corners formed by the intersection of one side Ea and two second sides Eb. The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b have four corners based on the center C of the bottom surface of the dielectric block 111 It can be arranged symmetrically on the part.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are spaced at substantially the same distance from the center C of the bottom surface of the dielectric block 111. The first feed via 11a and the fourth feed via 12b are arranged symmetrically with respect to the center C of the bottom surface, and the second feed via 11b and the third feed via ( 12a) may be arranged symmetrically with respect to the center (C) of the bottom surface.

In this way, the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are connected to the first side Ea parallel to the first direction DR1. The center (C) is adjacent to the four corners formed by the intersection of the second side (Eb) parallel to the second direction (DR2) and is symmetrical with respect to the center (C) of the bottom surface of the dielectric block 111. The first feed via 11a and the second feed via ( 11b), the interval between the third feed via 12a and the fourth feed via 12b may be further widened.

Accordingly, the first and second polarized RF signals of the first bandwidth transmitted and received by the electrical signals applied to the first feed via 11a and the second feed via 11b and the third feed via 12a and the fourth Interference between the first and second polarized RF signals of the second bandwidth transmitted and received by the electric signal applied to the feed via 12b may be reduced. In addition, within the dielectric block 111, the electric field generated by the electric signal applied to the first feed via 11a and the second feed via 11b is distributed, and the third feed via 12a and the fourth feed via 12a. The distribution length of the electric field generated by the electric signal applied to the via 12b can be increased, respectively, so that the size of the dielectric block 111 is not increased, and the first polarization and the second polarization RF signals of the first bandwidth and the second polarization The bandwidths of the first polarization and second polarization RF signals of 2 bandwidths may be widened.

The dielectric resonator antenna 100m according to this embodiment is a first dielectric block 110 of a dielectric block 111 including a first dielectric block 110, a second dielectric block 120, and a third dielectric block 130. ) And the first feed via 11a and the second feed via 11b located on the second dielectric block 120 and the third feed via 12a and the fourth feed via located on the first dielectric block 110 (12b), including the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b, based on the center portion C of the bottom surface RF signals of different bands are transmitted using the same dielectric block 111 by disposing the second straight line L2 and the fourth straight line L4, which are two diagonal lines passing through the center C, to be symmetrical to each other and spaced apart from each other. Can transmit and receive, can widen the bandwidth of the RF signal of the first bandwidth and the RF signal of the second bandwidth, reduce the interference between the RF signal of the first bandwidth and the RF signal of the second bandwidth to increase the gain of the antenna (100m) can be raised

Many features of the antenna according to the embodiment described above are all applicable to the antenna according to the present embodiment.

Referring to FIG. 24, a dielectric resonator antenna 100n according to another embodiment will be described. 24 is a perspective view of a dielectric resonator antenna according to another embodiment.

Referring to FIG. 24 , the dielectric resonator antenna 100n according to this embodiment is similar to the dielectric resonator antenna 100m according to the embodiment previously described with reference to FIG. 23 . A detailed description of the same component is omitted.

The dielectric resonator antenna 100n according to the present embodiment includes a plurality of feed vias 11a, 11b, 12a, and 12b located inside the dielectric block 111 and a plurality of feed vias 11a, 11b, 12a, and 12b attached to the bottom surface of the dielectric block 111. It may include the connection parts (1, 1a) of.

The dielectric resonator antenna 100n may transmit and receive a first polarized RF signal of a first bandwidth through the first feed via 11a and receive a second polarized RF signal of the first bandwidth through the second feed via 11b. A first polarized RF signal of a second bandwidth can be transmitted and received through the third feed via 12a, and a second polarized wave RF signal of a second bandwidth can be transmitted and received through the fourth feed via 12b. can

A center frequency of the first bandwidth may be lower than a center frequency of the second bandwidth, the first polarization may be horizontal polarization, and the second polarization may be vertical polarization.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b pass through the central portion C of the bottom surface of the dielectric block 111 and form two It may be disposed on a second straight line L2 and a fourth straight line L4, which are diagonal lines passing through corners formed by the intersection of one side Ea and two second sides Eb. The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b have four corners based on the center C of the bottom surface of the dielectric block 111 It can be arranged symmetrically on the part.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are spaced at substantially the same distance from the center C of the bottom surface of the dielectric block 111. The first feed via 11a and the fourth feed via 12b are arranged symmetrically with respect to the center C of the bottom surface, and the second feed via 11b and the third feed via ( 12a) may be arranged symmetrically with respect to the center (C) of the bottom surface.

However, the dielectric resonator antenna 100n according to the present embodiment is different from the dielectric resonator antenna 100m according to the above-described embodiment, the first feed via 11a and the second feed via 11b have a first dielectric block ( 110) and the second dielectric block 120, as well as a portion of the third dielectric block 130, the third feed via 12a and the fourth feed via 12b are the first dielectric block 110 can be located in The fourth height h4 of the first feed via 11a and the second feed via 11b measured from the bottom surface of the dielectric block 111 along the third direction DR3 is the third feed via 12a and It may be higher than the second height h2 of the fourth feed via 12b.

As such, by adjusting the heights of the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b, the RF signal transmitted and received by the dielectric resonator antenna 100n The frequency band of can be adjusted.

The dielectric resonator antenna 100n according to the present embodiment includes a first dielectric block 110 of a dielectric block 111 including a first dielectric block 110, a second dielectric block 120, and a third dielectric block 130. ) and the first feed vias 11a located on parts of the second dielectric block 120 and the third dielectric block 130 and the third located on the second feed vias 11b and the first dielectric block 110. Including the feed via 12a and the fourth feed via 12b, the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b, The same dielectric block (111) It is possible to transmit and receive RF signals of different bands by using, it is possible to widen the bandwidth of the RF signal of the first bandwidth and the RF signal of the second bandwidth, and between the RF signal of the first bandwidth and the RF signal of the second bandwidth The gain of the antenna 100n may be increased by reducing interference.

Many features of the antenna according to the embodiment described above are all applicable to the antenna according to the present embodiment.

Referring to FIG. 25, a dielectric resonator antenna 100o according to another embodiment will be described. 25 is a perspective view of a dielectric resonator antenna according to another embodiment.

Referring to FIG. 25 , the dielectric resonator antenna 100o according to this embodiment is similar to the dielectric resonator antenna 100m according to the embodiment previously described with reference to FIG. 23 . A detailed description of the same component is omitted.

Referring to FIG. 25, the dielectric resonator antenna 100o according to the present embodiment includes a plurality of feed vias 11a, 11b, 12a, and 12b located inside the dielectric block 111 and the bottom of the dielectric block 111. It may include a plurality of connection parts (1, 1a) attached to the surface.

The first feed via 11a and the second feed via 11b may be positioned in the first dielectric block 110 and the second dielectric block 120, and the third feed via 12a and the fourth feed via ( 12b) may be located in the first dielectric block 110, and the first feed via 11a and the second feed via 11b measured from the bottom surface of the dielectric block 111 along the third direction DR3 The first height h1 of may be higher than the second height h2 of the third and fourth feed vias 12a and 12b.

The dielectric resonator antenna 100o may transmit and receive a first polarized RF signal of a first bandwidth through the first feed via 11a, and transmit and receive a second polarized RF signal of the first bandwidth through the second feed via 11b. A first polarized RF signal of a second bandwidth can be transmitted and received through the third feed via 12a, and a second polarized wave RF signal of a second bandwidth can be transmitted and received through the fourth feed via 12b. can

A center frequency of the first bandwidth may be lower than a center frequency of the second bandwidth, the first polarization may be horizontal polarization, and the second polarization may be vertical polarization.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are connected to the first side Ea parallel to the first direction DR1 and the second Adjacent to the four corners formed by the intersection of the second side Eb parallel to the direction DR2, and symmetrical to each other based on the center C of the bottom surface of the dielectric block 111 of the bottom surface of the dielectric block 111 The first feed via 11a without increasing the size of the dielectric block 111 by arranging the second straight line L2 and the fourth straight line L4, which are two diagonal lines passing through the center C, so as to be spaced apart from each other. ), the intervals between the second feed via 11b, the third feed via 12a, and the fourth feed via 12b may be further widened.

Accordingly, the first and second polarized RF signals of the first bandwidth transmitted and received by the electrical signals applied to the first feed via 11a and the second feed via 11b and the third feed via 12a and the fourth Interference between the first and second polarized RF signals of the second bandwidth transmitted and received by the electric signal applied to the feed via 12b may be reduced. In addition, within the dielectric block 111, the distribution length of the electric field generated by the electrical signal applied to the first feed via 11a and the second feed via 11b and the third feed via 12a and the fourth feed via 12a The distribution length of the electric field generated by the electric signal applied to the via 12b can be increased, respectively, so that the size of the dielectric block 111 is not increased, and the first polarization and the second polarization RF signals of the first bandwidth and the second polarization The bandwidths of the first polarization and second polarization RF signals of 2 bandwidths may be widened.

However, unlike the dielectric resonator antenna 100m according to the above-described embodiment, the dielectric resonator antenna 100o according to the present embodiment has a shield via 13 overlapping the center portion C of the bottom surface of the dielectric block 111. may further include.

The shield via 13 is located between the first feed via 11a and the fourth feed via 12b and between the second feed via 11b and the third feed via 12a. The vias 11a, the second feed vias 11b, the third feed vias 12a, and the fourth feed vias 12b are spaced at substantially the same intervals and measured from the bottom surface of the dielectric block 111. The third height h3 of (13) is lower than the first height h1 of the first feed via 11a and the second feed via 11b, and the third feed via 12a and the fourth feed via 12b ) may be equal to or higher than the second height h2.

As such, the dielectric resonator antenna 100o according to the present embodiment is located between the first feed via 11a and the fourth feed via 12b and between the second feed via 11b and the third feed via 12a, The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are spaced apart at substantially the same intervals, and the third feed via 12a and the fourth feed via 12a By further including a shielding via 13 having a third height h3 equal to or higher than the second height h2 of the via 12b, applied to the first feed via 11a and the second feed via 11b The first and second polarized RF signals of the first bandwidth transmitted and received by the electrical signal and the second bandwidth of the second bandwidth transmitted and received by the electrical signal applied to the third feed via 12a and the fourth feed via 12b Interference between the first polarization and second polarization RF signals can be further reduced.

The dielectric resonator antenna 100o according to the present embodiment includes a first dielectric block 110 of a dielectric block 111 including a first dielectric block 110, a second dielectric block 120, and a third dielectric block 130. ) And the first feed via 11a and the second feed via 11b located on the second dielectric block 120 and the third feed via 12a and the fourth feed via located on the first dielectric block 110 (12b), including the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b, based on the center portion C of the bottom surface RF signals of different bands are transmitted using the same dielectric block 111 by disposing the second straight line L2 and the fourth straight line L4, which are two diagonal lines passing through the center C, to be symmetrical to each other and spaced apart from each other. Can transmit and receive, can widen the bandwidth of the RF signal of the first bandwidth and the RF signal of the second bandwidth, reduce the interference between the RF signal of the first bandwidth and the RF signal of the second bandwidth to increase the gain of the antenna (100m) can be raised

In addition, the dielectric resonator antenna 100o according to the present embodiment further includes a shielding via 13, so that the first signal transmitted and received by the electrical signal applied to the first feed via 11a and the second feed via 11b Between the first and second polarized RF signals of the second bandwidth transmitted and received by the electric signals applied to the third and fourth feed vias 12a and 12b and the first polarized and second polarized RF signals of the second bandwidth interference can be further reduced.

Many features of the antenna according to the embodiment described above are all applicable to the antenna according to the present embodiment.

A dielectric resonator antenna 100p according to another embodiment will be described with reference to FIG. 26 . 26 is a perspective view of a dielectric resonator antenna according to another embodiment.

Referring to FIG. 26 , the dielectric resonator antenna 100p according to this embodiment is similar to the dielectric resonator antenna 100l according to the embodiment previously described with reference to FIG. 22 . A detailed description of the same component is omitted.

The dielectric resonator antenna 100p according to the present embodiment includes a dielectric block 111, a first feed via 11 and a second feed via 12 located inside the dielectric block 111, and a dielectric block 111 It may include a plurality of connection parts (1, 1a) located below, that is, attached to the bottom surface of the dielectric block 111.

The first feed via 11 may be located in the first dielectric block 110 and the second dielectric block 120, and the second feed via 12 may be located in the first dielectric block 110, A first height h1 of the first feed via 11 measured from the bottom surface of the dielectric block 111 along the third direction DR3 is higher than the second height h2 of the second feed via 12 can

The first feed via 11 and the second feed via 12 are two edges where a first side Ea parallel to the first direction DR1 and a second side Eb parallel to the second direction DR2 meet each other. It may be disposed on a diagonal imaginary second straight line (L2) passing through the center (C) of the bottom surface of the dielectric block 111 adjacent to, and almost each other from the center (C) of the bottom surface of the dielectric block 111 may have the same spacing.

As such, in the first feed via 11 and the second feed via 12, the first side Ea parallel to the first direction DR1 and the second side Eb parallel to the second direction DR2 are mutually The first feed via 11 and the second feed via (12) The interval between them can be widened further.

Therefore, interference between the RF signal of the first bandwidth transmitted and received by the electrical signal applied to the first feed via 11 and the RF signal of the second bandwidth transmitted and received by the electrical signal applied to the second feed via 12 can reduce In addition, within the dielectric block 111, the electric field generated by the electric signal applied to the first feed via 11 is distributed and the electric field generated by the electric signal applied to the second feed via 12 is distributed It is possible to increase the lengths of the first and second bandwidth RF signals without increasing the size of the dielectric block 111.

Unlike the dielectric resonator antenna 100l according to the above-described embodiment, the dielectric resonator antenna 100p according to the present embodiment is disposed between the first dielectric block 110 and the second dielectric block 120 of the dielectric block 111. A second antenna patch 41 positioned between the first antenna patch 31 and the second dielectric block 120 and the third dielectric block 130 may be further included.

The first antenna patch 31 is spaced apart from and coupled to the second feed via 12, so that power can be supplied in a capacitive coupled feed method, and the second antenna patch 41 is coupled to the first feed via ( 11) by being spaced apart and coupled, power may be supplied in a capacitive coupling power supply method. The dielectric resonator antenna 100p according to the present embodiment may further include a first antenna patch 31 and a second antenna patch 41, thereby increasing a bandwidth of an RF signal to be transmitted and received.

Along the third direction DR3, the first feed via 11 and the second feed via 12 do not overlap the first antenna patch 31 and the second antenna patch 41, whereby the first feed via The generation of resonance of a certain frequency inside the dielectric block 111 may not be disturbed by the electric signal supplied to (11) and the second feed via 12.

The size and shape of the first antenna patch 31 and the second antenna patch 41 can be changed, and the size and shape of the first antenna patch 31 and the second antenna patch 41 and the feed via 11, 12) and the antenna patches 31 and 41, the degree of freedom in antenna design can be improved.

Many features of the antennas according to the above-described embodiments are all applicable to the antenna according to the present embodiment.

Referring to FIG. 27, a dielectric resonator antenna 100q according to another embodiment will be described. 27 is a perspective view of a dielectric resonator antenna according to another embodiment.

Referring to FIG. 27 , the dielectric resonator antenna 100q according to this embodiment is similar to the dielectric resonator antenna 100m according to the embodiment previously described with reference to FIG. 23 . A detailed description of the same component is omitted.

The dielectric resonator antenna 100q according to the present embodiment includes a plurality of feed vias 11a, 11b, 12a, and 12b located inside the dielectric block 111 and a plurality of feed vias 11a, 11b, 12a, and 12b attached to the bottom surface of the dielectric block 111. It may include the connection parts (1, 1a) of.

The dielectric block 111 may include a first dielectric block 110 , a second dielectric block 120 , and a third dielectric block 130 sequentially disposed along the third direction DR3 .

The first feed via 11a and the second feed via 11b may be positioned in the first dielectric block 110 and the second dielectric block 120, and the third feed via 12a and the fourth feed via ( 12b) may be located in the first dielectric block 110, and the first feed via 11a and the second feed via 11b measured from the bottom surface of the dielectric block 111 along the third direction DR3 The first height h1 of may be higher than the second height h2 of the third and fourth feed vias 12a and 12b.

The dielectric resonator antenna 100q may transmit and receive a first polarized RF signal of a first bandwidth through a first feed via 11a, and transmit and receive a second polarized RF signal of a first bandwidth through a second feed via 11b. A first polarized RF signal of a second bandwidth can be transmitted and received through the third feed via 12a, and a second polarized wave RF signal of a second bandwidth can be transmitted and received through the fourth feed via 12b. can

A center frequency of the first bandwidth may be lower than a center frequency of the second bandwidth, the first polarization may be horizontal polarization, and the second polarization may be vertical polarization.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b have four corners based on the center C of the bottom surface of the dielectric block 111 It can be arranged symmetrically on the part.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are spaced at substantially the same distance from the center C of the bottom surface of the dielectric block 111. The first feed via 11a and the fourth feed via 12b are arranged symmetrically with respect to the center C of the bottom surface, and the second feed via 11b and the third feed via ( 12a) may be arranged symmetrically with respect to the center (C) of the bottom surface.

The dielectric resonator antenna 100q according to the present embodiment includes a first dielectric block 110 of a dielectric block 111 including a first dielectric block 110, a second dielectric block 120, and a third dielectric block 130. ) And the first feed via 11a and the second feed via 11b located on the second dielectric block 120 and the third feed via 12a and the fourth feed via located on the first dielectric block 110 (12b), including the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b, based on the center portion C of the bottom surface RF signals of different bands are transmitted using the same dielectric block 111 by disposing the second straight line L2 and the fourth straight line L4, which are two diagonal lines passing through the center C, to be symmetrical to each other and spaced apart from each other. Can transmit and receive, can widen the bandwidth of the RF signal of the first bandwidth and the RF signal of the second bandwidth, reduce the interference between the RF signal of the first bandwidth and the RF signal of the second bandwidth to increase the gain of the antenna (100m) can be raised

Unlike the dielectric resonator antenna 100m according to the above-described embodiment, the dielectric resonator antenna 100q according to the present embodiment is disposed between the first dielectric block 110 and the second dielectric block 120 of the dielectric block 111. By further including a second antenna patch 41 located between the first antenna patch 31 located and the second dielectric block 120 and the third dielectric block 130, the bandwidth of the RF signal to be transmitted and received can be increased. can

The first and second feed vias 11a and 11b along the third direction DR3 and the third and fourth feed vias 12a and 12b are connected to the first antenna patch 31 and the second feed via 12b. It does not overlap with the antenna patch 41, and thereby electrical signals supplied to the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b It may not interfere with the generation of resonance of a certain frequency inside the dielectric block 111 .

The size and shape of the first antenna patch 31 and the second antenna patch 41 can be changed, and the size and shape of the first antenna patch 31 and the second antenna patch 41 and the feed via 11a, By modifying the spacing between 11b, 12a, and 12b and the antenna patches 31 and 41, the degree of freedom in antenna design can be improved.

Many features of the antenna according to the embodiment described above are all applicable to the antenna according to the present embodiment.

Referring to FIG. 28, a dielectric resonator antenna 100r according to another embodiment will be described. 28 is a perspective view of a dielectric resonator antenna according to another embodiment.

Referring to FIG. 28 , the dielectric resonator antenna 100r according to this embodiment is similar to the dielectric resonator antenna 100n according to the embodiment previously described with reference to FIG. 24 . A detailed description of the same component is omitted.

The dielectric resonator antenna 100r according to the present embodiment includes a plurality of feed vias 11a, 11b, 12a, and 12b positioned inside the dielectric block 111 and a plurality of feed vias 11a, 11b, 12a, and 12b attached to the bottom surface of the dielectric block 111. It may include the connection parts (1, 1a) of.

The dielectric resonator antenna 100n may transmit and receive a first polarized RF signal of a first bandwidth through the first feed via 11a and receive a second polarized RF signal of the first bandwidth through the second feed via 11b. A first polarized RF signal of a second bandwidth can be transmitted and received through the third feed via 12a, and a second polarized wave RF signal of a second bandwidth can be transmitted and received through the fourth feed via 12b. can

A center frequency of the first bandwidth may be lower than a center frequency of the second bandwidth, the first polarization may be horizontal polarization, and the second polarization may be vertical polarization.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b have four corners based on the center C of the bottom surface of the dielectric block 111 It can be arranged symmetrically on the part. The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are spaced at substantially the same distance from the center C of the bottom surface of the dielectric block 111. The first feed via 11a and the fourth feed via 12b are arranged symmetrically with respect to the center C of the bottom surface, and the second feed via 11b and the third feed via ( 12a) may be arranged symmetrically with respect to the center (C) of the bottom surface.

The first feed via 11a and the second feed via 11b may be located not only on the first dielectric block 110 and the second dielectric block 120 but also on a part of the third dielectric block 130, and The feed via 12a and the fourth feed via 12b may be positioned on the first dielectric block 110 . The fourth height h4 of the first feed via 11a and the second feed via 11b measured from the bottom surface of the dielectric block 111 along the third direction DR3 is the third feed via 12a and It may be higher than the second height h2 of the fourth feed via 12b.

The dielectric resonator antenna 100r according to this embodiment includes a first dielectric block 110 of a dielectric block 111 including a first dielectric block 110, a second dielectric block 120, and a third dielectric block 130. ) and the first feed vias 11a located on parts of the second dielectric block 120 and the third dielectric block 130 and the third located on the second feed vias 11b and the first dielectric block 110. Including the feed via 12a and the fourth feed via 12b, the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b, The same dielectric block (111) It is possible to transmit and receive RF signals of different bands by using, it is possible to widen the bandwidth of the RF signal of the first bandwidth and the RF signal of the second bandwidth, and between the RF signal of the first bandwidth and the RF signal of the second bandwidth The gain of the antenna 100n may be increased by reducing interference.

Unlike the dielectric resonator antenna 100n according to the above-described embodiment, the dielectric resonator antenna 100r according to the present embodiment is disposed between the first dielectric block 110 and the second dielectric block 120 of the dielectric block 111. It may further include a first antenna patch 31 positioned between the second dielectric block 120 and the third dielectric block 130, and a second antenna patch 41 positioned between the RF signals transmitted and received through the bandwidth can be increased.

The first and second feed vias 11a and 11b along the third direction DR3 and the third and fourth feed vias 12a and 12b are connected to the first antenna patch 31 and the second feed via 12b. It does not overlap with the antenna patch 41, and thereby electrical signals supplied to the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b It may not interfere with the generation of resonance of a certain frequency inside the dielectric block 111 .

The size and shape of the first antenna patch 31 and the second antenna patch 41 can be changed, and the size and shape of the first antenna patch 31 and the second antenna patch 41 and the feed via 11a, By modifying the spacing between 11b, 12a, and 12b and the antenna patches 31 and 41, the degree of freedom in antenna design can be improved.

Many features of the antenna according to the embodiment described above are all applicable to the antenna according to the present embodiment.

Then, referring to FIG. 29, a dielectric resonator antenna 100s according to another embodiment will be described. 29 is a perspective view of a dielectric resonator antenna according to another embodiment.

Referring to FIG. 29 , the dielectric resonator antenna 100s according to this embodiment is similar to the dielectric resonator antenna 100o according to the embodiment previously described with reference to FIG. 25 . A detailed description of the same component is omitted.

The dielectric resonator antenna 100s according to the present embodiment includes a plurality of feed vias 11a, 11b, 12a, and 12b positioned inside the dielectric block 111 and a plurality of feed vias 11a, 11b, 12a, and 12b attached to the bottom surface of the dielectric block 111. The connection parts 1 and 1a of the dielectric block 111 may include a shielding via 13 overlapping with the central portion C of the bottom surface.

The dielectric resonator antenna 100s according to this embodiment includes a first dielectric block 110 of a dielectric block 111 including a first dielectric block 110, a second dielectric block 120, and a third dielectric block 130. ) And the first feed via 11a and the second feed via 11b located on the second dielectric block 120 and the third feed via 12a and the fourth feed via located on the first dielectric block 110 (12b), including the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b, based on the center portion C of the bottom surface RF signals of different bands are transmitted using the same dielectric block 111 by disposing the second straight line L2 and the fourth straight line L4, which are two diagonal lines passing through the center C, to be symmetrical to each other and spaced apart from each other. Can transmit and receive, can widen the bandwidth of the RF signal of the first bandwidth and the RF signal of the second bandwidth, reduce the interference between the RF signal of the first bandwidth and the RF signal of the second bandwidth to increase the gain of the antenna (100m) can be raised

In addition, the dielectric resonator antenna 100s according to the present embodiment further includes a shielding via 13 to transmit and receive electrical signals applied to the first feed via 11a and the second feed via 11b. Between the first and second polarized RF signals of the second bandwidth transmitted and received by the electric signals applied to the third and fourth feed vias 12a and 12b and the first polarized and second polarized RF signals of the second bandwidth interference can be further reduced.

Unlike the dielectric resonator antenna 100o according to the above-described embodiment, the dielectric resonator antenna 100s according to this embodiment is between the first dielectric block 110 and the second dielectric block 120 of the dielectric block 111. It may further include a first antenna patch 31 positioned between the second dielectric block 120 and the third dielectric block 130, and a second antenna patch 41 positioned between the RF signals transmitted and received through the bandwidth can be increased.

The first and second feed vias 11a and 11b along the third direction DR3 and the third and fourth feed vias 12a and 12b are connected to the first antenna patch 31 and the second feed via 12b. It does not overlap with the antenna patch 41, and thereby electrical signals supplied to the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b It may not interfere with the generation of resonance of a certain frequency inside the dielectric block 111 .

The size and shape of the first antenna patch 31 and the second antenna patch 41 can be changed, and the size and shape of the first antenna patch 31 and the second antenna patch 41 and the feed via 11a, By modifying the spacing between 11b, 12a, and 12b and the antenna patches 31 and 41, the degree of freedom in antenna design can be improved.

Many features of the antenna according to the embodiment described above are all applicable to the antenna according to the present embodiment.

Referring to FIG. 30, a dielectric resonator antenna 100t according to another embodiment will be described. 30 is a perspective view of a dielectric resonator antenna according to another embodiment.

Referring to FIG. 30 , the dielectric resonator antenna 100t according to this embodiment is similar to the dielectric resonator antenna 100m according to the embodiment previously described with reference to FIG. 23 . A detailed description of the same component is omitted.

The dielectric resonator antenna 100t according to the present embodiment includes a plurality of feed vias 11a, 11b, 12a, and 12b located inside the dielectric block 111 and a plurality of feed vias 11a, 11b, 12a, and 12b attached to the bottom surface of the dielectric block 111. It may include the connection parts (1, 1a) of.

The dielectric block 111 may include a first dielectric block 110 and a second dielectric block 120 sequentially disposed along the third direction DR3, and the first feed via 11a and the second feed via The vias 11b may be located at portions of the first dielectric block 110 and the second dielectric block 120, and the third feed vias 12a and the fourth feed vias 12b are the first dielectric block 110 ) can be located. The first heights h1 of the first feed vias 11a and the second feed vias 11b measured from the bottom surface of the dielectric block 111 along the third direction DR3 are the third feed vias 12a and It may be higher than the second height h2 of the fourth feed via 12b.

The permittivity of the dielectric block 111 may be adjusted by changing the permittivity of the first dielectric block 110 and the second dielectric block 120 included in the dielectric block 111 and the thickness of the layer. First and second polarized RF signals of a first bandwidth transmitted and received by electrical signals applied to the feed via 11a and the second feed via 11b, and the third feed via 12a and the fourth feed via 12b ) It is possible to adjust the first polarized wave and the second polarized wave RF signal of the second bandwidth transmitted and received by the electrical signal applied to the ).

A first feed via 11a located in a portion of the first dielectric block 110 and the second dielectric block 120 of the dielectric block 111 including the first dielectric block 110 and the second dielectric block 120 ) and the second feed via 11b and the third feed via 12a and the fourth feed via 12b located in the first dielectric block 110, the first feed via 11a, the second feed The via 11b, the third feed via 12a, and the fourth feed via 12b are symmetrical to each other with respect to the center C of the bottom surface, so that the second straight line (two diagonal lines passing through the center C) ( L2) and the fourth straight line (L4), by spaced apart from each other, it is possible to transmit and receive RF signals of different bands using the same dielectric block 111, and the RF signal of the first bandwidth and the RF signal of the second bandwidth The bandwidth of can be widened, and the gain of the antenna 100t can be increased by reducing interference between the RF signal of the first bandwidth and the RF signal of the second bandwidth.

Many features of the antenna according to the embodiment described above are all applicable to the antenna according to the present embodiment.

Then, the antenna device 200a according to an embodiment will be described with reference to FIGS. 31 to 33 . 31 is a perspective view of an antenna device according to another embodiment, FIG. 32 is a cross-sectional view of the antenna device of FIG. 31 , and FIG. 33 is a plan view of the antenna device of FIG. 31 .

31 to 33, the antenna device 200a according to the embodiment includes an antenna unit 100, a connecting substrate 200 located under the antenna unit 100, and a main unit located under the connecting substrate 200. The circuit unit 300, a Radio Frequency-System in Package (RF-SiP) 400 located under the main circuit unit 300, and passive components 500 connected to the RF-SiP 400 may be included. there is.

The antenna unit 100 of the antenna device 200a includes a plurality of feed vias 11a, 11b, 12a, and 12b located inside the dielectric block 111, the shield via 13, and the dielectric block 111. It may include a plurality of connection parts (1, 1a) attached to the bottom surface.

The dielectric block 111 includes a first dielectric block 110, a second dielectric block 120, a third dielectric block 130, and a first dielectric block 110 sequentially positioned along the third direction DR3. A first dielectric layer 140a positioned between the second dielectric block 120 and a second dielectric layer 140b positioned between the second dielectric block 120 and the third dielectric block 130 may be included.

The first dielectric block 110, the second dielectric block 120, the third dielectric block 130, the first dielectric layer 140a, and the second dielectric layer 140b are identical to overlap each other along the third direction DR3. It may have a planar shape. When the first dielectric block 110, the second dielectric block 120, and the third dielectric block 130 are stacked and bonded to each other along the third direction DR3, each of the side surfaces, that is, the four pairs of side surfaces, respectively It can be smoothly connected to each other without a step so as to be located on the same plane (coplanar).

The dielectric constants of the first dielectric layer 140a and the second dielectric layer 140b may be lower than those of the first dielectric block 110 , the second dielectric block 120 , and the third dielectric block 130 . The first dielectric layer 140a and the second dielectric layer 140b may have adhesive properties.

The dielectric block 111 including the first dielectric block 110, the second dielectric block 120, the third dielectric block 130, the first dielectric layer 140a and the second dielectric layer 140b has a rectangular parallelepiped shape, for example. , and the dielectric block 111 may have via holes into which the feed vias 11a, 11b, 12a, and 12b and the shield via 13 are inserted.

The dielectric constants of the first dielectric block 110, the second dielectric block 120, and the third dielectric block 130 may be the same, but differently, the first dielectric block 110, the second dielectric block 120, the The dielectric constants of the three dielectric blocks 130 may be different from each other.

The first feed via 11a and the second feed via 11b may be positioned on the first dielectric block 110, the second dielectric block 120, and the first dielectric layer 140a, and the third feed via 12a ) and the fourth feed via 12b may be located in the first dielectric block 110, and the first feed via 11a measured from the bottom surface of the dielectric block 111 along the third direction DR3 and The first height h1 of the second feed via 11b may be higher than the second height h2 of the third and fourth feed vias 12a and 12b.

The antenna unit 100 may transmit and receive a first polarized RF signal of a first bandwidth through the first feed via 11a, and transmit and receive a second polarized RF signal of the first bandwidth through the second feed via 11b. A first polarized RF signal of a second bandwidth can be transmitted and received through the third feed via 12a, and a second polarized RF signal of a second bandwidth can be transmitted and received through the fourth feed via 12b. there is.

A center frequency of the first bandwidth may be lower than a center frequency of the second bandwidth, the first polarization may be horizontal polarization, and the second polarization may be vertical polarization.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b pass through the central portion C of the bottom surface of the dielectric block 111 and form two It may be disposed on a second straight line L2 and a fourth straight line L4, which are diagonal lines passing through corners formed by the intersection of one side Ea and two second sides Eb. The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b have four corners based on the center C of the bottom surface of the dielectric block 111 It can be arranged symmetrically on the part.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are spaced at substantially the same distance from the center C of the bottom surface of the dielectric block 111. The first feed via 11a and the fourth feed via 12b are arranged symmetrically with respect to the center C of the bottom surface, and the second feed via 11b and the third feed via ( 12a) may be arranged symmetrically with respect to the center (C) of the bottom surface.

The heights (h1, h2) of the feed vias (11a, 11b, 12a, 12b) for causing resonance inside the dielectric block 111 may be greater than 0.25λ, which is a value obtained by multiplying the operating frequency (λ) by 0.25. Resonance can occur while reducing the input reactance. The first height h1 of the first feed via 11a and the second feed via 11b may be about 0.32λ, and the second height of the third feed via 12a and the fourth feed via 12b ( h2) may be about 0.25λ, but is not limited thereto.

The first feed via 11a and the fourth feed via 12b are arranged symmetrically with respect to the center C of the bottom surface, and the second feed via 11b and the third feed via 12a are They may be arranged symmetrically with respect to the center (C) of the surface.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are connected to the first side Ea parallel to the first direction DR1 and the second Two lines passing through the center (C) are adjacent to the four corners formed by the intersection of the second side (Eb) parallel to the direction (DR2) and are symmetrical with each other with respect to the center (C) of the bottom surface of the dielectric block 111. The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b without increasing the size of the dielectric block 111 by arranging them to be spaced apart from each other on the diagonal ) can be further widened.

Accordingly, the first and second polarized RF signals of the first bandwidth transmitted and received by the electrical signals applied to the first feed via 11a and the second feed via 11b and the third feed via 12a and the fourth Interference between the first and second polarized RF signals of the second bandwidth transmitted and received by the electric signal applied to the feed via 12b may be reduced. In addition, within the dielectric block 111, the electric field generated by the electric signal applied to the first feed via 11a and the second feed via 11b is distributed, and the third feed via 12a and the fourth feed via 12a. The distribution length of the electric field generated by the electric signal applied to the via 12b can be increased, respectively, so that the size of the dielectric block 111 is not increased, and the first polarization and the second polarization RF signals of the first bandwidth and the second polarization The bandwidths of the first polarization and second polarization RF signals of 2 bandwidths may be widened.

The thickness of the third dielectric block 130 of the dielectric block 111 of the antenna unit 100 may be thicker than the thickness of the first dielectric block 110 and the thickness of the second dielectric block 120, but is not limited thereto. .

The antenna unit 100 may be connected to the connecting substrate 200 through a plurality of connection units 1 and 1a, and the feed vias 11a, 11b, 11c and 11d of the antenna unit 100 are connected to the connection units 1a ), it may be connected to the metal layers 202 and 203 capable of transmitting electrical signals other than the ground plane 201.

The connection substrate 200 may include a ground plane 201 and a plurality of metal layers 202 and 203 .

The ground plane 201 may be connected to the shield via 13 . Also, the ground plane 201 may be connected to the first decoupling pattern 210 and the second decoupling pattern 220 .

The first decoupling pattern 210 may be connected to the shield via 13 , and the first decoupling pattern 210 may include the first feed via 11a and the second feed via 11b at a central portion connected to the shield via 13 . ), a second portion 210b extending between the first feed via 11a and the third feed via 12a in the central portion connected to the shield via 13, and the shield via 13 A third portion 210c extending between the second feed via 11b and the fourth feed via 12b from the central portion connected to the third feed via 12a and the third feed via 12a from the central portion connected to the shield via 13 It may have a cross shape to include the fourth portion 210d extending between the 4 feed vias 12b.

The second decoupling pattern 220 is connected to the first decoupling pattern 210 and includes a first portion 220a surrounding the first feed via 11a and a second portion surrounding the second feed via 11b ( 220b), a third portion 220c surrounding the third feed via 12a, and a fourth portion 220d surrounding the fourth feed via 12b.

The second decoupling pattern 220 may extend to the outside of the dielectric block 111, but is not limited thereto.

As such, according to the antenna unit 100 of the antenna device 200a according to the present embodiment, the first feed via 11a, the second feed via 11b, and the third feed via 12a are formed in the dielectric block 111 And the height of the fourth feed via 12b is formed differently, and the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are formed on the bottom surface One dielectric block 111 is used by arranging the second straight line L2 and the fourth straight line L4, which are two diagonal lines passing through the center C, to be symmetrical to each other with respect to the center C of the It is possible to transmit and receive RF signals of different bands, and to widen the bandwidth of the first polarized and second polarized RF signals of the first bandwidth and the first and second polarized waves of the second bandwidth, the first bandwidth The gain of the antenna device 200a may be increased by reducing interference between the first and second polarized RF signals of and the first and second polarized RF signals of the second bandwidth.

In addition, the antenna device 200a according to the present embodiment includes the first decoupling pattern 210 and the second decoupling pattern 220 connected to the ground plane 201 together with the shield via 13 formed in the dielectric block 111. By including, the first and second polarized RF signals of the first bandwidth transmitted and received by the electrical signals applied to the first feed via 11a and the second feed via 11b and the third feed via 12a and 4 It is possible to reduce interference between the first and second polarized wave RF signals of the second bandwidth transmitted and received by the electrical signal applied to the feed via 12b, and by the electrical signal applied to the first feed via 11a. Interference between the transmitted and received first polarized RF signal of the first bandwidth and the second polarized RF signal of the first bandwidth transmitted and received by the electric signal applied to the second feed via 11b may be reduced, and the third feed via ( Interference between the first polarized RF signal of the second bandwidth transmitted and received by the electric signal applied to 12a) and the second polarized RF signal of the second bandwidth transmitted and received by the electric signal applied to the fourth feed via 12b can be reduced

The connection board 200 and the main circuit part 300, and the main circuit part 300 and the RF-SiP 400 are solder balls, pins, lands, pads, or SOPs ( Solder on pad) may be connected to each other through a connection part.

The antenna unit 100 according to the embodiment described with reference to FIGS. 31 to 33 may include any one of the dielectric resonator antennas 100a to 100t according to the above-described embodiments.

Many features of the dielectric resonator antennas 100a to 100t according to the above-described embodiments are all applicable to the antenna device 200a according to the present embodiment.

Then, a method of manufacturing an antenna device according to an embodiment will be described with reference to FIGS. 34A to 34E. 34A to 34E are perspective views illustrating a method of manufacturing an antenna device according to an embodiment.

Referring to FIG. 34A, by preparing the first dielectric plate 110a constituting the first dielectric block 110, third feed vias 12a and A plurality of first through holes 112a and a plurality of second through holes 112b, where the fourth feed vias 12b are to be formed, are formed. At this time, a through hole in which the shield via 13 is to be formed may be formed together.

Referring to FIG. 34B , metal layers are filled in the plurality of first through-holes 112a and the plurality of second through-holes 112b formed in the plurality of regions of the first dielectric plate 110a with plating or the like, thereby forming a plurality of third through-holes 112a. A feed via 12a and a plurality of fourth feed vias 12b are formed.

Referring to FIG. 34C , the second dielectric plate 120a constituting the second dielectric block 120 is stacked on the first dielectric plate 110a. In this case, a first dielectric layer 140a having adhesive strength may be stacked between the first dielectric plate 110a and the second dielectric plate 120a. Then, a plurality of third through-holes in which the first feed vias 11a and the second feed vias 11b are formed in the second dielectric plate 120a, the first dielectric layer 140a, and the first dielectric plate 110a (111a) and the fourth through hole (111b) are formed.

As shown in FIG. 34D, the plurality of third through holes 111a and the plurality of fourth through holes 111b formed in a plurality of regions are filled with a metal layer by plating or the like to form a plurality of first feed vias 11a and A plurality of second feed vias 11b are formed.

As shown in FIG. 34E, the third dielectric plate 130a constituting the third dielectric block 130 is stacked on the second dielectric plate 120a. In this case, a second dielectric layer 140b having adhesive strength may be stacked between the second dielectric plate 120a and the third dielectric plate 130a. After that, a plurality of connection parts 1 and 1a may be formed under the first dielectric plate 110a. In addition, a virtual dividing line SR dividing a plurality of regions including the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b, respectively, is provided. Accordingly, a plurality of antennas may be formed by cutting the third dielectric plate 130a, the second dielectric layer 140b, the second dielectric plate 120a, the first dielectric layer 140a, and the first dielectric plate 110a.

As described above, by forming a plurality of vias 11a, 11b, 12a, and 12b in the dielectric plates 110a and 120a and cutting the dielectric plates 110a, 120a, and 130a to form a plurality of antennas, Similarly, the first dielectric block 110, the second dielectric block 120, the third dielectric block 130, the first dielectric layer 140a, and the second dielectric layer 140b overlap each other along the third direction DR3. It may have the same planar shape so as to When the first dielectric block 110, the second dielectric block 120, and the third dielectric block 130 are stacked and bonded to each other along the third direction DR3, each of the side surfaces, that is, the four pairs of side surfaces, respectively It can be smoothly connected to each other without a step so as to be located on the same plane (coplanar).

Then, with reference to FIG. 35, an antenna device 200b according to another embodiment will be described. 35 is a plan view of a portion of an antenna device according to another embodiment.

Referring to FIG. 35 , the antenna device 200b according to the present embodiment includes a first feed via 11a, a second feed via 11b, a third feed via 12a, and a fourth feed via 11a formed in a dielectric block 111. A feed via 12b, and a first decoupling pattern 210 connected to the shield via 13 and the ground plane 201 are included.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b of the antenna device 200a according to the embodiment described above with reference to FIGS. 31 to 33 ), and many features of the shield via 13 are the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed of the antenna device 200b according to the present embodiment. It is applicable to both the via 12b and the shielding via 13.

The antenna device 200b according to the present embodiment has the same distance from the center C of the bottom surface of the dielectric block 111, and the first side Ea and the second side of the bottom surface of the dielectric block 111 ( Eb) may include a first feed via 11a, a second feed via 11b, a third feed via 12a, and a fourth feed via 12b disposed adjacent to the four corner portions formed by crossing each other. can

In addition, the antenna device 200b according to the present embodiment includes a first portion 210a extending between the first feed via 11a and the second feed via 11b in the central portion connected to the shield via 13, the shield via A second portion 210b extending between the first feed via 11a and the third feed via 12a at the central portion connected to (13), and the second feed via 11b at the central portion connected to the shield via 13 and a fourth portion 210c extending between the third feed via 12b and a fourth portion extending between the third feed via 12a and the fourth feed via 12b from the central portion connected to the shield via 13 ( 210d) may include a first decoupling pattern 210 having a cross shape.

In the antenna device 200b according to the present embodiment, the heights of the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b in the dielectric block 111 is formed differently, and the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are symmetrical to each other with respect to the center C of the bottom surface By arranging the two diagonal lines passing through the center (C) spaced apart from each other to form, it is possible to transmit and receive RF signals of different bands using one dielectric block 111, and the first polarization and the second polarization of the first bandwidth It is possible to widen the bandwidth of the RF signal and the first polarized wave and the second polarized wave RF signal of the second bandwidth, and the first polarized wave and the second polarized wave RF signal of the first bandwidth and the first polarized wave and the second polarized wave RF signal of the second bandwidth. It is possible to increase the gain of the antenna device 200b by reducing interference between the antennas.

Unlike the antenna device 200a according to the embodiment previously described with reference to FIGS. 31 to 33, the antenna device 200b according to the present embodiment may not include the second decoupling pattern 220, but the first decoupling pattern 220 may not be included. The first portion 210a of the pattern 210 extends between the first feed via 11a and the second feed via 11b, and the second portion 210b of the first decoupling pattern 210 extends between the first feed via 11a and the second feed via 11b. It extends between the via 11a and the second feed via 11b, and the third portion 210c of the first decoupling pattern 210 extends between the second feed via 11b and the fourth feed via 12b. and the fourth portion 210d of the first decoupling pattern 210 may extend between the third feed via 12a and the fourth feed via 12b. Therefore, through the first decoupling pattern 210 connected to the ground plane 201 together with the shielding via 13 formed in the dielectric block 111, applied to the first feed via 11a and the second feed via 11b The first and second polarized RF signals of the first bandwidth transmitted and received by the electrical signal and the second bandwidth of the second bandwidth transmitted and received by the electrical signal applied to the third feed via 12a and the fourth feed via 12b It is possible to reduce interference between the first polarized wave and the second polarized wave RF signal, and to the first polarized RF signal of the first bandwidth transmitted and received by the electric signal applied to the first feed via 11a and the second feed via 11b. A first polarized RF signal of a second bandwidth capable of reducing interference between second polarized RF signals of a first bandwidth transmitted and received by an applied electrical signal and transmitted and received by an electrical signal applied to the third feed via 12a Interference between the second polarized RF signal of the second bandwidth transmitted and received by the electric signal applied to the fourth feed via 12b may be reduced.

Many features of the antennas 100a to 100t and 100 according to the above-described embodiments are all applicable to the antenna device 200b according to the present embodiment.

Then, referring to FIG. 36, an antenna device 200c according to another embodiment will be described. 36 is a plan view of a portion of an antenna device according to another embodiment.

Referring to FIG. 36 , the antenna device 200c according to the present embodiment includes a first feed via 11a, a second feed via 11b, a third feed via 12a, and a fourth feed via 11a formed in a dielectric block 111. A feed via 12b, and a first decoupling pattern 210 connected to the shield via 13 and the ground plane 201 are included.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b of the antenna device 200a according to the embodiment described above with reference to FIGS. 31 to 33 ), and many features of the shield via 13 are the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed of the antenna device 200c according to the present embodiment. It is applicable to both the via 12b and the shielding via 13.

The antenna device 200c according to the present embodiment has the same distance from the center C of the bottom surface of the dielectric block 111 and is disposed adjacent to four corner portions of the bottom surface of the dielectric block 111. A first feed via 11a, a second feed via 11b, a third feed via 12a, and a fourth feed via 12b may be included.

In addition, the antenna device 200c according to the present embodiment includes a first portion 210a extending between the first feed via 11a and the second feed via 11b in the central portion connected to the shield via 13, the shield via A second portion 210b extending between the first feed via 11a and the third feed via 12a at the central portion connected to (13), and the second feed via 11b at the central portion connected to the shield via 13 and a fourth portion 210c extending between the third feed via 12b and a fourth portion extending between the third feed via 12a and the fourth feed via 12b from the central portion connected to the shield via 13 ( 210d) may include a first decoupling pattern 210 having a cross shape, and the width of the first decoupling pattern 210 of the antenna device 200c according to this embodiment is the antenna according to the above-described embodiment. It may be wider than the width of the first decoupling pattern 210 of the device 200b.

In the antenna device 200c according to the present embodiment, the heights of the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b in the dielectric block 111 is formed differently, and the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are symmetrical to each other with respect to the center C of the bottom surface By arranging the two diagonal lines passing through the center (C) spaced apart from each other to form, it is possible to transmit and receive RF signals of different bands using one dielectric block 111, and the first polarization and the second polarization of the first bandwidth It is possible to widen the bandwidth of the RF signal and the first polarized wave and the second polarized wave RF signal of the second bandwidth, and the first polarized wave and the second polarized wave RF signal of the first bandwidth and the first polarized wave and the second polarized wave RF signal of the second bandwidth. It is possible to increase the gain of the antenna device 200b by reducing interference between the antennas.

The first portion 210a of the first decoupling pattern 210 extends between the first feed via 11a and the second feed via 11b, and the second portion 210b of the first decoupling pattern 210 has It extends between the first feed via 11a and the third feed via 12a, and the third portion 210c of the first decoupling pattern 210 includes the second feed via 11b and the fourth feed via 12b. The fourth portion 210d of the first decoupling pattern 210 may extend to between the third feed via 12a and the fourth feed via 12b, and the first portion 210d of the antenna device 200c The width of the decoupling pattern 210 may be wider than that of the first decoupling pattern 210 of the antenna device 200b according to the above-described embodiment.

Therefore, through the first decoupling pattern 210 connected to the ground plane 201 together with the shielding via 13 formed in the dielectric block 111, applied to the first feed via 11a and the second feed via 11b The first and second polarized RF signals of the first bandwidth transmitted and received by the electrical signal and the second bandwidth of the second bandwidth transmitted and received by the electrical signal applied to the third feed via 12a and the fourth feed via 12b It is possible to reduce interference between the first polarized wave and the second polarized wave RF signal, and to the first polarized RF signal of the first bandwidth transmitted and received by the electric signal applied to the first feed via 11a and the second feed via 11b. A first polarized RF signal of a second bandwidth capable of reducing interference between second polarized RF signals of a first bandwidth transmitted and received by an applied electrical signal and transmitted and received by an electrical signal applied to the third feed via 12a Interference between the second polarized RF signal of the second bandwidth transmitted and received by the electric signal applied to the fourth feed via 12b may be reduced.

Many features of the antennas 100a to 100t and 100 according to the above-described embodiments are all applicable to the antenna device 200c according to the present embodiment.

Then, referring to FIG. 37, an antenna device 200d according to another embodiment will be described. 37 is a plan view of a portion of an antenna device according to another embodiment.

Referring to FIG. 37 , the antenna device 200d according to the present embodiment includes a first feed via 11a, a second feed via 11b, a third feed via 12a, and a fourth feed via 11a formed in the dielectric block 111. A feed via 12b, and a first decoupling pattern 210 connected to the shield via 13 and the ground plane 201 are included.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b of the antenna device 200a according to the embodiment described above with reference to FIGS. 31 to 33 ), and many features of the shield via 13 are the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed of the antenna device 200d according to the present embodiment. It is applicable to both the via 12b and the shielding via 13.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b of the antenna device 200d according to the present embodiment are formed on the bottom of the dielectric block 111 It may be disposed adjacent to the center of four sides of the bottom surface of the dielectric block 111 with the same distance from the center of the surface (C).

In addition, the first decoupling pattern 210 of the antenna device 200d according to the present embodiment extends from the central portion connected to the shield via 13 toward the four corners of the bottom surface of the dielectric block 111 to the first feed via 11a. ) and the second feed via 11b, a first portion 210a extending between the first feed via 11a and the third feed via 12a in the central portion connected to the shield via 13 210b, a third portion 210c extending between the second feed via 11b and the fourth feed via 12b from the central portion connected to the shield via 13, and the third portion 210c from the central portion connected to the shield via 13. It may have a cross shape to include the fourth portion 210d extending between the 3 feed vias 12a and the 4th feed via 12b.

In the antenna device 200d according to the present embodiment, the heights of the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b in the dielectric block 111 are is formed differently, and the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are symmetrical to each other with respect to the center C of the bottom surface It is possible to transmit and receive RF signals of different bands using one dielectric block 111 by disposing them apart from each other on two straight lines parallel to the two sides Ea and Eb of the bottom surface passing through the center C so as to form , It is possible to widen the bandwidth of the first polarized wave and the second polarized wave RF signal of the first bandwidth and the first polarized wave and the second polarized wave RF signal of the second bandwidth, and the first polarized wave and the second polarized wave RF signal of the first bandwidth and the second The gain of the antenna device 200d may be increased by reducing interference between the first polarization and second polarization RF signals of 2 bandwidths.

In addition, the first portion 210a extending between the first feed via 11a and the second feed via 11b toward the four corners of the bottom surface of the dielectric block 111 from the central portion connected to the shield via 13 , a second portion 210b extending between the first feed via 11a and the third feed via 12a at the central portion connected to the shield via 13, and the second feed via at the central portion connected to the shield via 13 A third portion 210c extending between 11b and the fourth feed via 12b, and a third portion 210c extending between the third feed via 12a and the fourth feed via 12b in the central portion connected to the shield via 13. A first bandwidth transmitted and received by electrical signals applied to the first feed via 11a and the second feed via 11b by including the first decoupling pattern 210 having a cross shape to include the 4 parts 210d Between the first and second polarized RF signals of the second bandwidth transmitted and received by the electrical signals applied to the third and fourth feed vias 12a and 12b. A first polarized RF signal of a first bandwidth that can reduce interference and is transmitted and received by an electrical signal applied to the first feed via 11a and a first polarized RF signal transmitted and received by an electrical signal applied to the second feed via 11b It is possible to reduce interference between the second polarized RF signal of the bandwidth, and applied to the first polarized RF signal of the second bandwidth transmitted and received by the electric signal applied to the third feed via 12a and the fourth feed via 12b. It is possible to reduce interference between second polarization RF signals of a second bandwidth transmitted and received by an electrical signal that is transmitted and received.

Many features of the antennas 100a to 100t and 100 according to the above-described embodiments are all applicable to the antenna device 200d according to the present embodiment.

Then, with reference to FIG. 38, an antenna device 200e according to another embodiment will be described. 38 is a plan view of a portion of an antenna device according to another embodiment.

Referring to FIG. 38 , the antenna device 200e according to the present embodiment includes a first feed via 11a, a second feed via 11b, a third feed via 12a, and a fourth feed via 11a formed in a dielectric block 111. A first decoupling pattern 210 and a second decoupling pattern 220 connected to the feed via 12b, the shield via 13, and the ground plane 201 are included.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b of the antenna device 200a according to the embodiment described above with reference to FIGS. 31 to 33 ), and many features of the shield via 13 are the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed of the antenna device 200e according to the present embodiment. It is applicable to both the via 12b and the shielding via 13.

The antenna device 200e according to the present embodiment has the same distance from the center C of the bottom surface of the dielectric block 111, and the first side Ea and the second side of the bottom surface of the dielectric block 111 ( Eb) may include a first feed via 11a, a second feed via 11b, a third feed via 12a, and a fourth feed via 12b disposed adjacent to the four corner portions formed by crossing each other. can

In addition, the antenna device 200e according to the present embodiment includes a first portion 210a extending between the first feed via 11a and the second feed via 11b in the central portion connected to the shield via 13, the shield via A second portion 210b extending between the first feed via 11a and the third feed via 12a at the central portion connected to (13), and the second feed via 11b at the central portion connected to the shield via 13 and a fourth portion 210c extending between the third feed via 12b and a fourth portion extending between the third feed via 12a and the fourth feed via 12b from the central portion connected to the shield via 13 ( 210d), the first decoupling pattern 210 having a cross shape, and connected to the first decoupling pattern 210, the first feed via 11a and the second feed via together with the first decoupling pattern 210 11b, the third feed via 12a, and the fourth feed via 12b may include a second decoupling pattern 220 forming four quadrangular decoupling patterns surrounding each other.

In the antenna device 200e according to the present embodiment, the heights of the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b in the dielectric block 111 is formed differently, and the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are symmetrical to each other with respect to the center C of the bottom surface By arranging the two diagonal lines passing through the center (C) spaced apart from each other to form, it is possible to transmit and receive RF signals of different bands using one dielectric block 111, and the first polarization and the second polarization of the first bandwidth It is possible to widen the bandwidth of the RF signal and the first polarized wave and the second polarized wave RF signal of the second bandwidth, and the first polarized wave and the second polarized wave RF signal of the first bandwidth and the first polarized wave and the second polarized wave RF signal of the second bandwidth. It is possible to increase the gain of the antenna device 200b by reducing interference between the antennas.

In addition, the first decoupling pattern 210 forming the shape of four rectangles each enclosing the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b. and the second decoupling pattern 220, through the shield via 13, the first decoupling pattern 210, and the second decoupling pattern 220, the first feed via 11a and the second feed via 11b ) The first and second polarization RF signals of the first bandwidth transmitted and received by the electrical signal applied to the third and fourth feed vias 12a and 12b are transmitted and received by electrical signals applied to the second It is possible to reduce interference between the first polarized wave and the second polarized wave RF signal of the bandwidth, and the first polarized wave RF signal of the first bandwidth and the second feed via ( 11b) can reduce interference between second polarized RF signals of the first bandwidth transmitted and received by the electrical signal applied to the third feed via 12a, and the first signal of the second bandwidth transmitted and received by the electrical signal applied to the third feed via 12a Interference between the polarized RF signal and the second polarized RF signal of the second bandwidth transmitted and received by the electric signal applied to the fourth feed via 12b may be reduced.

Many features of the antennas 100a to 100t and 100 according to the above-described embodiments are all applicable to the antenna device 200e according to the present embodiment.

Then, with reference to FIG. 39, an antenna device 200f according to another embodiment will be described. 39 is a plan view of a portion of an antenna device according to another embodiment.

Referring to FIG. 39 , the antenna device 200f according to the present embodiment includes a first feed via 11a, a second feed via 11b, a third feed via 12a, and a fourth feed via 11a formed in a dielectric block 111. A first decoupling pattern 210 and a second decoupling pattern 220 connected to the feed via 12b, the shield via 13, and the ground plane 201 are included.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b of the antenna device 200a according to the embodiment described above with reference to FIGS. 31 to 33 ), and many features of the shield via 13 are the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed of the antenna device 200e according to the present embodiment. It is applicable to both the via 12b and the shielding via 13.

The antenna device 200f according to this embodiment has the same distance from the center C of the bottom surface of the dielectric block 111, and the first side Ea and the second side of the bottom surface of the dielectric block 111 ( Eb) may include a first feed via 11a, a second feed via 11b, a third feed via 12a, and a fourth feed via 12b disposed adjacent to the four corner portions formed by crossing each other. can

In addition, the antenna device 200f according to the present embodiment includes a first portion 210a extending between the first feed via 11a and the second feed via 11b in the central portion connected to the shield via 13, the shield via A second portion 210b extending between the first feed via 11a and the third feed via 12a at the central portion connected to (13), and the second feed via 11b at the central portion connected to the shield via 13 and a fourth portion 210c extending between the third feed via 12b and a fourth portion extending between the third feed via 12a and the fourth feed via 12b from the central portion connected to the shield via 13 ( 210d), the first decoupling pattern 210 having a cross shape, and connected to the first decoupling pattern 210, the first feed via 11a and the second feed via together with the first decoupling pattern 210 11b, the third feed via 12a, and the fourth feed via 12b may include a second decoupling pattern 220 forming four quadrangular decoupling patterns surrounding each other.

In the antenna device 200f according to the present embodiment, the heights of the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b in the dielectric block 111 is formed differently, and the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are symmetrical to each other with respect to the center C of the bottom surface By arranging the two diagonal lines passing through the center (C) spaced apart from each other to form, it is possible to transmit and receive RF signals of different bands using one dielectric block 111, and the first polarization and the second polarization of the first bandwidth It is possible to widen the bandwidth of the RF signal and the first polarized wave and the second polarized wave RF signal of the second bandwidth, and the first polarized wave and the second polarized wave RF signal of the first bandwidth and the first polarized wave and the second polarized wave RF signal of the second bandwidth. It is possible to increase the gain of the antenna device 200b by reducing interference between the antennas.

In addition, the first decoupling pattern 210 forming the shape of four rectangles each enclosing the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b. and the second decoupling pattern 220, through the shield via 13, the first decoupling pattern 210, and the second decoupling pattern 220, the first feed via 11a and the second feed via 11b ) The first and second polarization RF signals of the first bandwidth transmitted and received by the electrical signal applied to the third and fourth feed vias 12a and 12b are transmitted and received by electrical signals applied to the second It is possible to reduce interference between the first polarized wave and the second polarized wave RF signal of the bandwidth, and the first polarized wave RF signal of the first bandwidth and the second feed via ( 11b) can reduce interference between second polarized RF signals of the first bandwidth transmitted and received by the electrical signal applied to the third feed via 12a, and the first signal of the second bandwidth transmitted and received by the electrical signal applied to the third feed via 12a Interference between the polarized RF signal and the second polarized RF signal of the second bandwidth transmitted and received by the electric signal applied to the fourth feed via 12b may be reduced.

In addition, the first side Ea and the second side Eb of the bottom surface of the dielectric block 111 may form an oblique line instead of parallel to the edge of the ground plane 201 . In this way, when the plurality of dielectric blocks 111 are arranged by arranging the first side Ea and the second side Eb of the bottom surface of the dielectric block 111 to form an oblique line with the edge of the ground plane 201 An area of an adjacent part between adjacent dielectric blocks 111 may be arranged to be narrow, thereby reducing interference between RF signals transmitted/received by resonance frequencies in two adjacent dielectric blocks 111 .

Many features of the antennas 100a to 100t and 100 according to the above-described embodiments are all applicable to the antenna device 200f according to the present embodiment.

Then, with reference to FIG. 40, an antenna device 200g according to another embodiment will be described. 40 is a plan view of a portion of an antenna device according to another embodiment.

Referring to FIG. 40 , the antenna device 200g according to the present embodiment includes a first feed via 11a, a second feed via 11b, a third feed via 12a, and a fourth feed via 11a formed in a dielectric block 111. A first decoupling pattern 210 and a second decoupling pattern 220 connected to the feed via 12b, the shield via 13, and the ground plane 201 are included.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b of the antenna device 200a according to the embodiment described above with reference to FIGS. 31 to 33 ), and many features of the shield via 13 are the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed of the antenna device 200g according to the present embodiment. It is applicable to both the via 12b and the shielding via 13.

The antenna device 200g according to this embodiment has the same distance from the center C of the bottom surface of the dielectric block 111 and is disposed adjacent to the center of four sides of the bottom surface of the dielectric block 111. A first feed via 11a, a second feed via 11b, a third feed via 12a, and a fourth feed via 12b may be included.

In addition, the antenna device 200g according to the present embodiment has a first feed via 11a and a second feed via 11b toward the four corners of the dielectric block 111 from the central portion connected to the shield via 13. A first portion 210a extending between, a second portion 210b extending between the first feed via 11a and the third feed via 12a at a central portion connected to the shield via 13, and the shield via 13 A third portion 210c extending between the second feed via 11b and the fourth feed via 12b from the central portion connected to the third feed via 12a and the fourth feed via 12a from the central portion connected to the shield via 13 The first decoupling pattern 210 having an X-shape to include the fourth portion 210d extending between the feed vias 12b and connected to the first decoupling pattern 210 together with the first decoupling pattern 210 The second decoupling pattern 220 forming four diamond-shaped decoupling patterns surrounding the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b. can include

In the antenna device 200g according to the present embodiment, the heights of the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b in the dielectric block 111 is formed differently, and the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are formed at the center of the bottom surface of the dielectric block 111 (C ) Using one dielectric block 111 by arranging them spaced apart from each other on two straight lines parallel to the two sides (Ea, Eb) of the bottom surface of the dielectric block 111 passing through the center (C) so as to be symmetrical to each other based on It is possible to transmit and receive RF signals of different bands, and to widen the bandwidth of the first polarized and second polarized RF signals of the first bandwidth and the first and second polarized waves of the second bandwidth, the first bandwidth The gain of the antenna device 200g may be increased by reducing interference between the first and second polarized RF signals of the second bandwidth and the first and second polarized RF signals of the second bandwidth.

In addition, the antenna device 200g according to this embodiment has four feed vias 11a, 2nd feed vias 11b, 3rd feed vias 12a, and 4th feed vias 12b, respectively. By including the first decoupling pattern 210 and the second decoupling pattern 220 forming a rhombus shape, through the shield via 13, the first decoupling pattern 210, and the second decoupling pattern 220, the first feed The first and second polarized RF signals of the first bandwidth transmitted and received by the electric signals applied to the vias 11a and the second feed vias 11b and the third and fourth feed vias 12a and 12b It is possible to reduce interference between the first polarized wave and the second polarized RF signal of the second bandwidth transmitted and received by the electrical signal applied to the first bandwidth transmitted and received by the electrical signal applied to the first feed via 11a. Interference between the first polarized RF signal and the second polarized RF signal of the first bandwidth transmitted and received by the electric signal applied to the second feed via 11b can be reduced, and the electric signal applied to the third feed via 12a Interference between the first polarized RF signal of the second bandwidth transmitted and received by the signal and the second polarized RF signal of the second bandwidth transmitted and received by the electrical signal applied to the fourth feed via 12b may be reduced.

Many features of the antennas 100a to 100t and 100 according to the above-described embodiments are all applicable to the antenna device 200g according to the present embodiment.

Then, with reference to FIG. 41, an antenna device 200h according to another embodiment will be described. 41 is a plan view of a portion of an antenna device according to another embodiment.

Referring to FIG. 41 , the antenna device 200h according to the present embodiment includes a first feed via 11a, a second feed via 11b, a third feed via 12a, and a fourth feed via 11a formed in a dielectric block 111. A first decoupling pattern 210 and a second decoupling pattern 220 connected to the feed via 12b, the shield via 13, and the ground plane 201 are included.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b of the antenna device 200a according to the embodiment described above with reference to FIGS. 31 to 33 ), and many features of the shield via 13 are the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed of the antenna device 200h according to the present embodiment. It is applicable to both the via 12b and the shielding via 13.

The antenna device 200h according to this embodiment has the same distance from the center C of the bottom surface of the dielectric block 111, and the first side Ea and the second side of the bottom surface of the dielectric block 111 ( Eb) may include a first feed via 11a, a second feed via 11b, a third feed via 12a, and a fourth feed via 12b disposed adjacent to the four corner portions formed by crossing each other. can

In addition, the antenna device 200h according to the present embodiment includes a first portion 210a extending between the first feed via 11a and the second feed via 11b in the central portion connected to the shield via 13, the shield via A second portion 210b extending between the first feed via 11a and the third feed via 12a at the central portion connected to (13), and the second feed via 11b at the central portion connected to the shield via 13 and a fourth portion 210c extending between the third feed via 12b and a fourth portion extending between the third feed via 12a and the fourth feed via 12b from the central portion connected to the shield via 13 ( 210d), the first decoupling pattern 210 having a cross shape and connected to the first decoupling pattern 210, the first feed via 11a, the second feed via 11b, and the third feed via 12a ), and the second decoupling pattern 220 in the form of four circles surrounding the fourth feed via 12b.

In the antenna device 200h according to the present embodiment, the heights of the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b in the dielectric block 111 is formed differently, and the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are symmetrical to each other with respect to the center C of the bottom surface It is possible to transmit and receive RF signals of different bands using one dielectric block 111 by disposing them spaced apart from each other on two diagonal lines passing through the center (C) so as to form, and the first polarization and the second polarization of the first bandwidth It is possible to widen the bandwidth of the polarized RF signal and the first polarized and second polarized RF signals of the second bandwidth, and the first polarized and second polarized RF signals of the first bandwidth and the first and second polarized RF signals of the second bandwidth. The gain of the antenna device 200b may be increased by reducing interference between signals.

The antenna device 200h according to the present embodiment includes a first decoupling pattern (which surrounds the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b). 210) and the second decoupling pattern 220, the first decoupling pattern 210 and the second decoupling pattern 220 connected to the ground plane 201 together with the shield via 13 formed in the dielectric block 111 Through, the first and second polarized RF signals of the first bandwidth transmitted and received by the electric signals applied to the first feed via 11a and the second feed via 11b and the third feed via 12a and 4 It is possible to reduce interference between the first and second polarized wave RF signals of the second bandwidth transmitted and received by the electrical signal applied to the feed via 12b, and by the electrical signal applied to the first feed via 11a. Interference between the transmitted and received first polarized RF signal of the first bandwidth and the second polarized RF signal of the first bandwidth transmitted and received by the electric signal applied to the second feed via 11b may be reduced, and the third feed via ( Interference between the first polarized RF signal of the second bandwidth transmitted and received by the electric signal applied to 12a) and the second polarized RF signal of the second bandwidth transmitted and received by the electric signal applied to the fourth feed via 12b can be reduced

Many features of the antennas 100a to 100t and 100 according to the above-described embodiments are all applicable to the antenna device 200h according to the present embodiment.

Then, with reference to FIG. 42, an antenna device 200i according to another embodiment will be described. 42 is a plan view of a portion of an antenna device according to another embodiment.

Referring to FIG. 42 , the antenna device 200i according to the present embodiment includes a first feed via 11a, a second feed via 11b, a third feed via 12a, and a fourth feed via 11a formed in a dielectric block 111. A first decoupling pattern 210 and a second decoupling pattern 220 connected to the feed via 12b, the shield via 13, and the ground plane 201 are included.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b of the antenna device 200a according to the embodiment described above with reference to FIGS. 31 to 33 ), and many features of the shield via 13 are the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed of the antenna device 200i according to the present embodiment. It is applicable to both the via 12b and the shielding via 13.

The antenna device 200i according to the present embodiment has the same distance from the center C of the bottom surface of the dielectric block 111 and is disposed adjacent to the center portions of the four sides of the bottom surface of the dielectric block 111, and The first feed via 11a, the second feed via 11b, and the third feed via 11a pass through the center C of the bottom surface of the block 111 and are disposed in two straight lines parallel to the four sides of the bottom surface of the dielectric block 111 A feed via 12a and a fourth feed via 12b may be included.

In addition, the antenna device 200i according to the present embodiment has a first feed via 11a and a second feed via ( 11b) a first portion 210a extending between, a second portion 210b extending between the second feed via 11b and the third feed via 12a in a central portion connected to the shield via 13, and a shield via ( 13), a third portion 210c extending between the third feed via 12a and the fourth feed via 12b from the central portion connected to the shield via 13, and the fourth feed via 12b and the fourth feed via 12b from the central portion connected to the shield via 13. Connected to the first decoupling pattern 210 having a cross shape and the first decoupling pattern 210 to include the fourth portion 210d extending between the first feed vias 11a, the first decoupling pattern 210 and The second decoupling pattern 220 forming four circular decoupling patterns surrounding the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b together. ) may be included.

In the antenna device 200i according to the present embodiment, the heights of the first feed vias 11a, the second feed vias 11b, the third feed vias 12a, and the fourth feed vias 12b in the dielectric block 111 are is formed differently, and the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are symmetrical to each other with respect to the center C of the bottom surface It is possible to transmit and receive RF signals of different bands using one dielectric block 111 by disposing them spaced apart from each other on two straight lines passing through the center (C) so as to form, and the first polarization and the second polarization of the first bandwidth It is possible to widen the bandwidth of the polarized RF signal and the first polarized and second polarized RF signals of the second bandwidth, and the first polarized and second polarized RF signals of the first bandwidth and the first and second polarized RF signals of the second bandwidth. The gain of the antenna device 200i may be increased by reducing interference between signals.

In addition, the antenna device 200i according to the present embodiment includes first decoupling that surrounds the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b. By including the pattern 210 and the second decoupling pattern 220, the first decoupling pattern 210 and the second decoupling pattern ( 210), the first and second polarized RF signals of the first bandwidth transmitted and received by the electrical signals applied to the first feed via 11a and the second feed via 11b and the third feed via 12a and interference between the first polarized wave and the second polarized wave RF signal of the second bandwidth transmitted and received by the electric signal applied to the fourth feed via 12b may be reduced, and the electric signal applied to the first feed via 11a It is possible to reduce interference between a first polarized RF signal of a first bandwidth transmitted and received by and a second polarized RF signal of a first bandwidth transmitted and received by an electrical signal applied to the second feed via 11b, and Between the first polarized RF signal of the second bandwidth transmitted and received by the electrical signal applied to the via 12a and the second polarized RF signal of the second bandwidth transmitted and received by the electrical signal applied to the fourth feed via 12b interference can be reduced.

In addition, the first side (Ea) and the second side (Eb) of the bottom surface of the dielectric block 111 of the antenna device (200i) according to the present embodiment are not aligned with the edge of the ground plane 201 but form an oblique line. can In this way, when the plurality of dielectric blocks 111 are arranged by arranging the first side Ea and the second side Eb of the bottom surface of the dielectric block 111 to form an oblique line with the edge of the ground plane 201 An area of an adjacent part between adjacent dielectric blocks 111 may be arranged to be narrow, thereby reducing interference between RF signals transmitted/received by resonance frequencies in two adjacent dielectric blocks 111 .

Many features of the antennas 100a to 100t and 100 according to the above-described embodiments are all applicable to the antenna device 200i according to the present embodiment.

Then, referring to FIG. 43, an antenna device 200j according to another embodiment will be described. 43 is a plan view of a portion of an antenna device according to another embodiment.

Referring to FIG. 43 , the antenna device 200j according to the present embodiment includes a first feed via 11a, a second feed via 11b, a third feed via 12a, and a fourth feed via 11a formed in the dielectric block 111. A first decoupling pattern 210 and a second decoupling pattern 220 connected to the feed via 12b, the shield via 13, and the ground plane 201 are included.

The first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b of the antenna device 200a according to the embodiment described above with reference to FIGS. 31 to 33 ), and many features of the shield via 13 are the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed of the antenna device 200j according to the present embodiment. It is applicable to both the via 12b and the shielding via 13.

The antenna device 200j according to the present embodiment has the same distance from the center C of the bottom surface of the dielectric block 111 and is disposed adjacent to the central parts of the four sides of the bottom surface of the dielectric block 111 A first feed via 11a, a second feed via 11b, a third feed via 12a, and a fourth feed via 12b may be included.

In addition, the antenna device 200j according to the present embodiment has a first feed via 11a and a second feed via ( 11b) a first portion 210a extending between, a second portion 210b extending between the second feed via 11b and the third feed via 12a in a central portion connected to the shield via 13, and a shield via ( 13), a third portion 210c extending between the third feed via 12a and the fourth feed via 12b from the central portion connected to the shield via 13, and the fourth feed via 12b and the fourth feed via 12b from the central portion connected to the shield via 13. The first decoupling pattern 210 having an X-shape to include the fourth portion 210d extending between the first feed vias 11a and connected to the first decoupling pattern 210, the first decoupling pattern 210 A second decoupling pattern forming four circular decoupling patterns surrounding the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b together with 220) may be included.

In the antenna device 200j according to the present embodiment, the heights of the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b in the dielectric block 111 is formed differently, and the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b are symmetrical to each other with respect to the center C of the bottom surface It is possible to transmit and receive RF signals of different bands using one dielectric block 111 by disposing them spaced apart from each other on two straight lines passing through the center (C) so as to form, and the first polarization and the second polarization of the first bandwidth It is possible to widen the bandwidth of the polarized RF signal and the first polarized and second polarized RF signals of the second bandwidth, and the first polarized and second polarized RF signals of the first bandwidth and the first and second polarized RF signals of the second bandwidth. The gain of the antenna device 200b may be increased by reducing interference between signals.

The antenna device 200j according to the present embodiment has four circular shapes surrounding the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b. The decoupling pattern may include a first decoupling pattern 210 and a second decoupling pattern 220 . Therefore, through the first decoupling pattern 210 and the second decoupling pattern 220 connected to the ground plane 201 together with the shielding via 13 formed in the dielectric block 111, the first feed via 11a and the second The first and second polarization RF signals of the first bandwidth transmitted and received by the electrical signal applied to the second feed via 11b and the electrical signals applied to the third feed via 12a and the fourth feed via 12b It is possible to reduce interference between the first polarization and the second polarization RF signal of the second bandwidth transmitted and received by the first polarization RF signal of the first bandwidth transmitted and received by the electrical signal applied to the first feed via 11a and It is possible to reduce interference between second polarized RF signals of the first bandwidth transmitted and received by the electrical signal applied to the second feed via 11b, and transmitted and received by the electrical signal applied to the third feed via 12a. Interference between a first polarized RF signal of 2 bandwidths and a second polarized RF signal of a second bandwidth transmitted and received by an electric signal applied to the fourth feed via 12b may be reduced.

Many features of the antennas 100a to 100t and 100 according to the above-described embodiments are all applicable to the antenna device 200j according to the present embodiment.

Referring to FIG. 44, an antenna device 1000a according to another embodiment will be described. 44 is a layout diagram of an antenna device according to another embodiment.

Referring to FIG. 44 , the antenna device 1000a according to the present embodiment may include a plurality of antennas 10a arranged along the arrangement direction DRa.

The plurality of antennas 10a, like the antennas 100a, 100c, and 100k according to the above-described embodiments, the first feed via 11 disposed adjacent to the central portion of two parallel sides of the dielectric block 111. ) and the second feed via 12 .

Edges of the bottom surface of the dielectric block 111 of the plurality of antennas 10a may be parallel to or substantially perpendicular to the array direction DRa, and the first feed via 11 of the plurality of antennas 10a and The second feed vias 12 face each other along a right angle direction DRb perpendicular to the array direction DRa, pass through the center of the bottom surface of the dielectric block 111, and overlap a straight line parallel to the right angle direction DRb. can

As such, by arranging the first feed via 11 and the second feed via 12 of the plurality of antennas 10a to face each other along the orthogonal direction DRb, the resonance of the RF signals of the antennas 10a The direction may be parallel to the perpendicular direction DRb, thereby preventing RF signals of adjacent antennas 10a from interfering with each other.

Many features of the antennas 100a to 100t and 100 according to the above-described embodiments are all applicable to the antenna device 1000a according to the present embodiment.

Then, referring to FIG. 45, an antenna device 1000b according to another embodiment will be described. 45 is a layout view of an antenna device according to another embodiment.

Referring to FIG. 45 , the antenna device 1000b according to the present embodiment may include a plurality of antennas 10b arranged along the arrangement direction DRa.

The plurality of antennas 10b, like the antennas 100a, 100c, and 100k according to the above-described embodiments, the first feed via 11 disposed adjacent to the central portion of two parallel sides of the dielectric block 111. ) and the second feed via 12 .

Edges of the bottom surface of the dielectric block 111 of the plurality of antennas 10a may be parallel to or substantially perpendicular to the array direction DRa, and the first feed via 11 of the plurality of antennas 10a and The second feed vias 12 may face each other along a direction parallel to the array direction DRa, pass through the center of the bottom surface of the dielectric block 111, and overlap a straight line parallel to the array direction DRa.

As such, by arranging the first feed via 11 and the second feed via 12 of the plurality of antennas 10a to face each other along the direction parallel to the array direction DRa, the RF of each antenna 10a The resonance direction of the signals may be parallel to the array direction DRa, whereby RF signals of adjacent antennas 10a may be enhanced along the antenna array direction DRa.

Many features of the antennas 100a to 100t and 100 according to the above-described embodiments are all applicable to the antenna device 1000b according to the present embodiment.

Referring to FIG. 46, an antenna device 1000c according to another embodiment will be described. 45 is a layout view of an antenna device according to another embodiment.

Referring to FIG. 46 , the antenna device 1000c according to the present embodiment may include a plurality of antennas 10c arranged along the arrangement direction DRa.

The plurality of antennas 10c, like the antennas 100a, 100c, and 100k according to the above-described embodiments, the first feed via 11 disposed adjacent to the central portion of two parallel sides of the dielectric block 111. ) and the second feed via 12 .

Edges of the bottom surface of the dielectric block 111 of the plurality of antennas 10c may form an oblique line with respect to the array direction DRa, and the first feed via 11 and the second feed via 11 of the plurality of antennas 10c The feed vias 12 face each other along a direction forming an oblique line with the array direction DRa, pass through the center of the bottom surface of the dielectric block 111, and overlap a straight line parallel to the direction forming an oblique line with the array direction DRa. there is.

As such, the edges of the bottom surface of the dielectric block 111 of the plurality of antennas 10c are arranged to form an oblique line with respect to the array direction DRa, thereby reducing the area of the adjacent portion between the two adjacent antennas 10c. , interference between two adjacent antennas 10c can be reduced.

Many features of the antennas 100a to 100t and 100 according to the above-described embodiments are all applicable to the antenna device 1000c according to the present embodiment.

Referring to FIG. 47, an antenna device 1000d according to another embodiment will be described. 46 is a layout view of an antenna device according to another embodiment.

Referring to FIG. 47 , the antenna device 1000d according to the present embodiment may include a plurality of antennas 10d arranged along the arrangement direction DRa.

The plurality of antennas 10d, like the antennas 100a, 100c, and 100k according to the above-described embodiments, the first feed via 11 disposed adjacent to the central portion of two parallel sides of the dielectric block 111. ) and the second feed via 12 .

Edges of the bottom surface of the dielectric block 111 of the plurality of antennas 10d may form an oblique line with respect to the array direction DRa, and the first feed via 11 and the second feed via 11 of the plurality of antennas 10c The feed vias 12 face each other along a direction forming an oblique line with the array direction DRa, pass through the center of the bottom surface of the dielectric block 111, and overlap a straight line parallel to the direction forming an oblique line with the array direction DRa. there is.

As such, the edges of the bottom surface of the dielectric block 111 of the plurality of antennas 10d are arranged to form an oblique line with respect to the array direction DRa, thereby reducing the area of the adjacent portion between the two adjacent antennas 10c. , interference between two adjacent antennas 10c can be reduced.

Many features of the antennas 100a to 100t and 100 according to the above-described embodiments are all applicable to the antenna device 1000d according to the present embodiment.

Referring to FIG. 48, an antenna device 1000e according to another embodiment will be described. 48 is a layout view of an antenna device according to another embodiment.

Referring to FIG. 48 , the antenna device 1000e according to the present embodiment may include a plurality of antennas 10e arranged along the arrangement direction DRa.

The plurality of antennas 10e, like the antennas 100b, 100d, 100l, and 100p according to the above-described embodiments, are disposed adjacent to two facing corner portions of the bottom surface of the dielectric block 111. A first feed via 11 and a second feed via 12 may be included.

Edges of the bottom surface of the dielectric block 111 of the plurality of antennas 10e may be parallel to or substantially perpendicular to the array direction DRa, and the first feed via 11 of the plurality of antennas 10e and The second feed vias 12 may face each other along an oblique direction forming an oblique line with the arrangement direction DRa, pass through the center of the bottom surface of the dielectric block 111, and overlap a straight line parallel to the oblique direction.

As such, by arranging the first feed via 11 and the second feed via 12 of the plurality of antennas 10e to face each other along an oblique direction forming an oblique line with the array direction DRa, each antenna 10e The resonance direction of the RF signals of ) may be parallel to an oblique direction forming an oblique line with the array direction DRa, thereby preventing RF signals of adjacent antennas 10e from interfering with each other.

Many features of the antennas 100a to 100t and 100 according to the above-described embodiments are all applicable to the antenna device 1000e according to the present embodiment.

Then, referring to FIG. 49, an antenna device 1000f according to another embodiment will be described. 49 is a layout view of an antenna device according to another embodiment.

Referring to FIG. 49 , an antenna device 1000f according to the present embodiment may include a plurality of antennas 10f arranged along an arrangement direction DRa.

The plurality of antennas 10f, like the antennas 100b, 100d, 100l, and 100p according to the above-described embodiments, are disposed adjacent to two facing corner portions of the bottom surface of the dielectric block 111. The first feed via 11 and the second feed via 12 may be included, and edges of the bottom surface of the dielectric block 111 of the plurality of antennas 10f are parallel to or substantially perpendicular to the arrangement direction DRa. The first feed via 11 and the second feed via 12 face each other along an oblique direction forming an oblique line with the array direction DRa and pass through the center of the bottom surface of the dielectric block 111 in an oblique direction can be overlapped with a straight line parallel to

As such, by arranging the first feed via 11 and the second feed via 12 of the plurality of antennas 10f to face each other along an oblique direction forming an oblique line with the array direction DRa, each antenna 10f The resonance direction of the RF signals of ) may be parallel to an oblique direction forming an oblique line with the array direction DRa, thereby preventing RF signals of adjacent antennas 10f from interfering with each other.

Many features of the antennas 100a to 100t and 100 according to the above-described embodiments are all applicable to the antenna device 1000f according to the present embodiment.

Referring to FIG. 50, an antenna device 1000g according to another embodiment will be described. 50 is a layout diagram of an antenna device according to another embodiment.

Referring to FIG. 50 , the antenna device 1000g according to the present embodiment may include a plurality of antennas 10g arranged along the arrangement direction DRa.

The plurality of antennas 10g, like the antennas 100a, 100c, and 100k according to the above-described embodiments, the first feed via 11 disposed adjacent to the central portion of two parallel sides of the dielectric block 111. ) and the second feed via 12 .

Edges of the bottom surface of the dielectric block 111 of the plurality of antennas 10g may form an oblique line with respect to the array direction DRa, and the first feed via 11 and the second feed via 11 of the plurality of antennas 10g The feed vias 12 may face each other along a right angle direction DRb perpendicular to the array direction DRa, pass through the center of the bottom surface of the dielectric block 111, and overlap a straight line parallel to the right angle direction DRb. .

As such, by arranging the plurality of antennas 10g such that the edges of the bottom surface of the dielectric block 111 of the plurality of antennas 10g form an oblique line with respect to the array direction DRa, a gap between two adjacent antennas 10g is formed. By reducing the area of the adjacent portion of , interference between two adjacent antennas 10g can be reduced.

Many features of the antennas 100a to 100t and 100 according to the above-described embodiments are all applicable to the antenna device 1000g according to the present embodiment.

Referring to FIG. 51, an antenna device 1000h according to another embodiment will be described. 51 is a layout view of an antenna device according to another embodiment.

Referring to FIG. 51 , the antenna device 1000h according to the present embodiment may include a plurality of antennas 10h arranged along the arrangement direction DRa.

The plurality of antennas 10h, like the antennas 100b, 100d, 100l, and 100p according to the above-described embodiments, are disposed adjacent to two facing corner portions of the bottom surface of the dielectric block 111. A first feed via 11 and a second feed via 12 may be included.

Edges of the bottom surface of the dielectric block 111 of the plurality of antennas 10h may form an oblique line with respect to the array direction DRa, and the first feed via 11 and the second feed via 11 of the plurality of antennas 10h The feed vias 12 may face each other along a direction parallel to the array direction DRa, pass through the center of the bottom surface of the dielectric block 111, and overlap a straight line parallel to the direction parallel to the array direction DRa.

As such, the edges of the bottom surface of the dielectric block 111 of the plurality of antennas 10h are arranged to form an oblique line with respect to the array direction DRa, thereby reducing the area of the adjacent portion between the two adjacent antennas 10h. , interference between two adjacent antennas 10h can be reduced.

In addition, by arranging the first feed via 11 and the second feed via 12 of the plurality of antennas 10h to face each other along a direction parallel to the array direction DRa, the RF of each antenna 10h The resonance direction of the signals may be parallel to the array direction DRa, whereby RF signals of adjacent antennas 10h may be enhanced along the antenna array direction DRa.

Many features of the antennas 100a to 100t and 100 according to the above-described embodiments are all applicable to the antenna device 1000h according to the present embodiment.

An antenna device 1000i according to another embodiment will be described with reference to FIG. 52 . 52 is a layout view of an antenna device according to another embodiment.

Referring to FIG. 52 , the antenna device 1000i according to the present embodiment may include a plurality of antennas 10i arranged along the arrangement direction DRa.

The plurality of antennas 10i, like the antennas 100f, 100h, 100m, 100n, 100o, 100q, 100r, 100s, 100t, and 100 according to the above-described embodiments, are on the bottom surface of the dielectric block 111. It may include a first feed via 11a, a second feed via 11b, a third feed via 12a, and a fourth feed via 12b disposed adjacent to four corner portions of .

Edges of the bottom surface of the dielectric block 111 of the plurality of antennas 10i may be parallel to or substantially perpendicular to the array direction DRa, and the first feed vias 11a of the plurality of antennas 10i, The second feed via 11b, the third feed via 12a, and the fourth feed via 12b may overlap two diagonal lines passing through the center of the bottom surface of the dielectric block 111.

Also, the ground plane 201 of the plurality of antennas 10i may include a decoupling pattern 210 .

The distance between the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b of the plurality of antennas 10i can be widened, so that one dielectric RF signals of different bands can be transmitted and received using the block 111, and the bandwidths of the first polarized and second polarized RF signals of the first bandwidth and the first and second polarized waves of the second bandwidth can be widened. The gain of the antenna device 1000i may be increased by reducing interference between the first and second polarized RF signals of the first bandwidth and the first and second polarization RF signals of the second bandwidth.

Many features of the antennas 100a to 100t and 100 according to the above-described embodiments are all applicable to the antenna device 1000i according to the present embodiment.

Referring to FIG. 53, an antenna device 1000j according to another embodiment will be described. 53 is a layout view of an antenna device according to another embodiment.

Referring to FIG. 53 , the antenna device 1000j according to the present embodiment may include a plurality of antennas 10j arranged along the arrangement direction DRa.

The plurality of antennas 10j, like the antennas 100e and 100g according to the above-described embodiments, the first feed via 11a disposed adjacent to the central portion of the four sides of the dielectric block 111, the first feed via 11a, Two feed vias 11b, a third feed via 12a, and a fourth feed via 12b may be included.

Edges of the bottom surface of the dielectric block 111 of the plurality of antennas 10j may form an oblique line with respect to the array direction DRa, and the first feed via 11a of the plurality of antennas 10j, the second The feed via 11b, the third feed via 12a, and the fourth feed via 12b pass through the center of the bottom surface of the dielectric block 111 and overlap a straight line parallel to the direction forming an oblique line with the arrangement direction DRa. can

As such, the edges of the bottom surface of the dielectric block 111 of the plurality of antennas 10j are arranged to form an oblique line with respect to the array direction DRa, thereby reducing the area of the adjacent portion between the two adjacent antennas 10j. , interference between two adjacent antennas 10j can be reduced.

Also, the ground plane 201 of the plurality of antennas 10j may include the decoupling pattern 210 .

The distance between the first feed via 11a, the second feed via 11b, the third feed via 12a, and the fourth feed via 12b of the plurality of antennas 10j can be widened, so that one dielectric RF signals of different bands can be transmitted and received using the block 111, and the bandwidths of the first polarized and second polarized RF signals of the first bandwidth and the first and second polarized waves of the second bandwidth can be widened. The gain of the antenna device 1000j may be increased by reducing interference between the first and second polarized RF signals of the first bandwidth and the first and second polarization RF signals of the second bandwidth.

Many features of the antennas 100a to 100t and 100 according to the above-described embodiments are all applicable to the antenna device 1000j according to the present embodiment.

Referring to FIG. 54, an electronic device including an antenna device according to an embodiment will be described. 54 is a simplified diagram illustrating an electronic device including an antenna device according to an embodiment.

Referring to FIG. 54 , an electronic device 2000 according to an embodiment includes an antenna device 1000, and the antenna device 1000 is disposed in a set 40 of the electronic device 2000.

The electronic device 2000 includes a smart phone, a personal digital assistant, a digital video camera, a digital still camera, a network system, and a computer. ), monitor, tablet, laptop, netbook, television, video game, smart watch, automotive, etc., but Not limited.

The electronic device 2000 may have polygonal sides, and the antenna device 1000 may be disposed adjacent to at least a portion of a plurality of sides of the electronic device 2000 .

A communication module 610 and a baseband circuit 620 may be further disposed in the set 40 . The antenna device may be connected to the communication module 610 and/or the baseband circuit 620 through a coaxial cable 630 .

The communication module 610 includes memory chips such as volatile memory (eg, DRAM), non-volatile memory (eg, ROM), and flash memory to perform digital signal processing; Application processor chips such as central processors (eg, CPU), graphic processors (eg, GPUs), digital signal processors, encryption processors, microprocessors, and microcontrollers; It may include at least some of logic chips such as an analog-to-digital converter and an application-specific IC (ASIC).

The baseband circuit 620 may generate a base signal by performing analog-to-digital conversion, amplification, filtering, and frequency conversion on an analog signal. Base signals input and output from the baseband circuit 620 may be transferred to the antenna device through a cable.

For example, a base signal may be transferred to an IC through an electrical connection structure, a core via, and wiring. The IC may convert the base signal into a millimeter wave (mmWave) band RF signal.

The antenna device 1000 may include any one of the aforementioned antenna devices 1000a to 1000j.

Many of the features of the antenna devices 1000a to 1000j described above are all applicable to the antenna device 1000 of the electronic device 2000.

Then, an experimental example will be described with reference to FIGS. 55 to 57 and Table 1. 55 to 57 are graphs showing the results of one experimental example.

In this experimental example, the antenna device 200a according to the embodiment shown in FIGS. 31 to 33 was formed, and unlike the antenna device 200a, the first case (case 1) not including the shield via 13, the antenna In the second case (case 2) in which one shield via 13 is formed at the center of the dielectric block 111 as in the device 200a, three shield vias are formed at the center of the dielectric block 111 For the third case (case 3), the S-parameters of the RF signal of the first bandwidth and the RF signal of the second bandwidth are measured, and the results are graphed in FIGS. 55 to 57 and shown in Table 1. was

55 shows the result of the first case (case 1), in FIG. 55 a1 represents the result of the RF signal of the first bandwidth, and b1 represents the result of the RF signal of the second bandwidth. 56 shows the results of the second case (case 2), in FIG. 56, a2 represents the result of the RF signal of the first bandwidth, and b2 represents the result of the RF signal of the second bandwidth. 57 shows the result of the third case (case 3), in FIG. 57, a3 represents the result of the RF signal of the first bandwidth, and b3 represents the result of the RF signal of the second bandwidth.

Table 1 shows the RF signal of the first bandwidth and the RF signal of the second bandwidth in the low frequency region of about 28 GHz for the first case (case 1), the second case (case 2), and the third case (case 2). The difference value and the difference value between the RF signal of the first bandwidth and the RF signal of the second bandwidth in the high frequency region of about 39 GHz are shown.

Low frequency band (28 GHz) High frequency band (39 GHz) Case 1 (case 1) 8dB 2dB Case 2 (case 2) 18dB 4dB Case 3 (case 3) 5dB 10dB

54 to 56 together with Table 1, unlike the antenna device 200a, unlike the first case (case 1) that does not include the shield via 13, the dielectric block ( 111), in the second case (case 2) in which one shielding via 13 was formed, the isolation characteristics increased by about two times or more. Three shields located in the center of the dielectric block 111 compared to the second case (case 2) in which one shield via 13 is formed in the center of the dielectric block 111, such as the antenna device 200a. In case 3 in which the vias were formed, the change in isolation characteristics was not large, and it was found that the isolation characteristics in the low frequency band were reduced. , It was found that the isolation characteristics of the antenna can be improved by forming one shielding via 13 located at the center of the dielectric block 111.

Another experimental example will be described with reference to FIGS. 58 to 61 . 58 to 61 are diagrams showing the results of another experimental example.

In this experimental example, the antenna device 200a according to the embodiment shown in FIGS. 31 to 33 is formed, and the current of the dielectric block 111 is observed when the RF signal of the first bandwidth and the RF signal of the second bandwidth are transmitted and received. So, the results are shown in FIGS. 58 to 61. 58 and 59 show the results of the first bandwidth, and FIGS. 60 and 61 show the results of the second bandwidth.

58 to 61, it can be seen that the entire dielectric block 111 resonates when transmitting and receiving an RF signal of a first bandwidth, and when transmitting and receiving an RF signal of a second bandwidth, the first portion of the dielectric block 111 It can be seen that resonance is achieved in the first dielectric block 110 and the third dielectric block 130 so as to be symmetrical to each other. In this way, like the antennas 100a to 100t and 100 according to the embodiments, by forming a feeding part of a first bandwidth and a feeding part of a second bandwidth having different heights in one dielectric block 111, two different bandwidths It was found that resonance was made to transmit and receive RF signals of .

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and it is possible to carry out various modifications within the scope of the claims and the detailed description of the invention and the accompanying drawings, and this is also the present invention. It goes without saying that it falls within the scope of the invention.

100, 100a, 100b, 100c, 100d, 100e, 100f, 100g, 100h, 100i, 100j, 100k, 100l, 100m, 100n, 100o, 100p, 100q, 100r, 100s, 100t: antenna
1000, 1000a, 1000b, 1000c, 1000d, 1000e, 1000f, 1000g, 1000h, 1000i, 1000j, 200a, 200b, 200c, 200d, 200e, 200f, 200g, 200ki, 2000h: antenna, 2000h, device
11, 11a, 11b, 12, 12a, 12b: feed vias
21a, 21b, 22a, 22b: feed strip
111, 110, 120, 130: dielectric block,
140a, 140b: dielectric layer
201: ground plane
210, 220: decoupling pattern
31, 41: antenna patch

Claims (29)

dielectric block,
A first feed unit located in the dielectric block and having a first height from the bottom surface of the dielectric block, and
A second feed part located in the dielectric block and having a second height different from the first height from the bottom surface,
The first feed unit and the second feed unit are symmetrically disposed with respect to the center Dielectric resonator antenna.
In paragraph 1,
A dielectric resonator antenna further comprising a shielding via positioned in the dielectric block and positioned between the first feed part and the second feed part.
In paragraph 2,
The shielding via overlaps the center portion of the dielectric resonator antenna.
In paragraph 1,
The bottom surface of the dielectric block includes a first side extending in a first direction and a second side extending in a second direction different from the first direction,
The dielectric resonator antenna of claim 1 , wherein the first straight line overlaps a portion where the first side and the second side intersect.
In paragraph 4,
The first feed part and the second feed part are vias positioned in the dielectric block.
In paragraph 4,
The first feed part and the second feed part are feed strips positioned outside the dielectric block.
In paragraph 1,
The bottom surface of the dielectric block includes a first side extending in a first direction and a second side extending in a second direction different from the first direction,
The first straight line is a dielectric resonator antenna parallel to the first side or the second side.
In paragraph 1,
Further comprising a third feed part located on the dielectric block and having the first height from the bottom surface and a fourth feed part located on the dielectric block and having the second height from the bottom surface,
The third feed part and the fourth feed part overlap with a second straight line passing through the center of the bottom surface,
The dielectric resonator antenna having the first distance between the third feed part and the center, and having the second distance between the fourth feed part and the center.
In paragraph 8,
The dielectric block extends in a first direction, a second direction different from the first direction, and a third direction perpendicular to the first and second directions,
The bottom surface includes two first sides parallel to the first direction and two second sides parallel to the second direction,
The dielectric resonator antenna of claim 1, wherein the first straight line and the second straight line overlap a point where the first side and the second side intersect.
In paragraph 8,
The dielectric block extends in a first direction, a second direction different from the first direction, and a third direction perpendicular to the first and second directions,
Wherein the first straight line and the second straight line are parallel to the first direction or the second direction.
In paragraph 10,
The bottom surface includes two first sides parallel to the first direction and two second sides parallel to the second direction,
The first straight line and the second straight line overlap the centers of the first side and the second side of the dielectric resonator antenna.
In paragraph 1,
The dielectric block includes a first dielectric block, a second dielectric block, and a third dielectric block stacked from the bottom surface,
The first feed unit is located in the first dielectric block and the second dielectric block,
The second feed unit is a dielectric resonator antenna located in the first dielectric block.
In paragraph 12,
The dielectric block further comprises a first dielectric layer positioned between the first dielectric block and the second dielectric block, and a second dielectric layer positioned between the second dielectric block and the third dielectric block,
The dielectric resonator antenna of claim 1 , wherein dielectric constants of the first dielectric layer and the second dielectric layer are lower than those of the first dielectric block, the second dielectric block, and the third dielectric block.
dielectric block,
A first feed unit located in the dielectric block and having a first height from the bottom surface of the dielectric block;
A second feed unit located in the dielectric block and having a second height different from the first height from the bottom surface, and
A dielectric resonator antenna comprising a shielding via located in the dielectric block, overlapping a central portion of the bottom surface, and spaced at substantially the same interval as the first feed part and the second feed part.
In paragraph 14,
A dielectric resonator antenna wherein a third height of the shield via measured from the bottom surface of the dielectric block is greater than or equal to the second height.
In paragraph 14,
The bottom surface of the dielectric block includes a first side extending in a first direction and a second side extending in a second direction different from the first direction,
The first feed part and the second feed part overlap the straight line of the bottom part,
The straight line is a dielectric resonator antenna parallel to the first side or the second side.
In paragraph 14,
The bottom surface of the dielectric block includes a first side extending in a first direction and a second side extending in a second direction different from the first direction,
The first feed part and the second feed part overlap the straight line of the bottom part,
The dielectric resonator antenna of claim 1, wherein the straight line overlaps a portion where the first side and the second side intersect.
In paragraph 14,
Further comprising a third feed part located on the dielectric block and having the first height from the bottom surface and a fourth feed part located on the dielectric block and having the second height from the bottom surface,
The shielding via is a dielectric resonator antenna spaced at the same interval as the third feed part and the fourth feed part.
In paragraph 18,
The bottom surface of the dielectric block includes a first side extending in a first direction and a second side extending in a second direction different from the first direction,
The first feed part and the second feed part overlap the first straight line of the bottom part,
The third feed part and the fourth feed part overlap the second straight line of the bottom part,
The first straight line and the second straight line are parallel to the first side or the second side of the dielectric resonator antenna.
In paragraph 18,
The bottom surface of the dielectric block includes a first side extending in a first direction and a second side extending in a second direction different from the first direction,
The first feed part and the second feed part overlap the first straight line of the bottom part,
The third feed part and the fourth feed part overlap the second straight line of the bottom part,
The first straight line and the second straight line are diagonal lines overlapping a portion where the first side and the second side cross each other.
In paragraph 14,
The dielectric block includes a first dielectric block, a second dielectric block, and a third dielectric block stacked from the bottom surface,
The first feed unit is located in the first dielectric block and the second dielectric block,
The second feed unit is a dielectric resonator antenna located in the first dielectric block.
In paragraph 21,
The dielectric block further comprises a first dielectric layer positioned between the first dielectric block and the second dielectric block, and a second dielectric layer positioned between the second dielectric block and the third dielectric block,
The dielectric resonator antenna of claim 1 , wherein dielectric constants of the first dielectric layer and the second dielectric layer are lower than those of the first dielectric block, the second dielectric block, and the third dielectric block.
dielectric block,
A first feed unit located in the dielectric block and having a first height from the bottom surface of the dielectric block;
A second feed unit located in the dielectric block and having a second height different from the first height from the bottom surface;
A ground plane located below the dielectric block, and
An antenna device comprising a pattern unit connected to the ground plane and positioned between the first feed unit and the second feed unit.
In paragraph 23,
Further comprising shield vias located in the dielectric block and spaced at substantially the same interval as the first feed part and the second feed part,
The antenna device of claim 1, wherein the pattern portion overlaps the shield via.
In paragraph 23,
The antenna device of claim 1 , wherein the pattern portion includes an extension portion extending between the first feed portion and the second feed portion from a central portion overlapping the shield via.
In paragraph 25,
The pattern part includes a first pattern part including an extension part extending between the first feed part and the second feed part from the center overlapping the shield via, and
An antenna device comprising a second pattern unit connected to the first pattern unit and surrounding the first feed unit and the second feed unit.
In paragraph 26,
The second pattern portion antenna device including a portion extending outward from the bottom surface of the dielectric block.
In paragraph 25,
Further comprising a third feed part located on the dielectric block and having the first height from the bottom surface and a fourth feed part located on the dielectric block and having the second height from the bottom surface,
The pattern part may include a first extension extending between the first feed part and the second feed part from a center overlapping the shielding via, a second extension extending between the first feed part and the third feed part, the An antenna device including a third extension part extending between the second feed part and the fourth feed part, and a fourth extension part extending between the third feed part and the fourth feed part.
In paragraph 28,
The dielectric block includes a first dielectric block, a second dielectric block, and a third dielectric block stacked from the bottom surface,
The first feed part and the third feed part are located in the first dielectric block and the second dielectric block,
The second feed unit and the fourth feed unit are located in the first dielectric block antenna device.

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