KR101541374B1 - Dual Polarization Dipole Antenna for Multi-Band and System including the same - Google Patents

Abstract

The present invention relates to a multiband dipole antenna and system, and in particular, to a multiband dipole antenna and system, which comprises a substrate, a first antenna pattern formed on a first substrate region of the substrate, a second antenna pattern formed on a second substrate region of the substrate, A dipole antenna and a system including the dipole antenna are provided. At this time, the first antenna pattern and the second antenna pattern are formed on the same substrate.

Description

[0001] The present invention relates to a multi-band dipole antenna and a multi-band dipole antenna.

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to an antenna that is a radio wave transmitting / receiving device used in a base station and a mobile communication repeater, and more particularly, to a multi-band dipole antenna and a system that are easy to produce and install and manage.

As the popularity of personal mobile phones and the spread of smartphones and tablet PCs are increasing, the usage of radio waves for calls and wireless internet is surging. This sudden increase in usage causes a need for communication in various environments, communication speed, and call quality. Particularly, it is required to have a proper communication quality not only in a room such as a building but also in an outdoor area, a shade area where the distance from the existing base station and the mobile communication repeater is long or the propagation is not easily transmitted by the feature. In order to meet such needs, each communication company additionally installs a base station and a mobile communication repeater in the shaded area.

Meanwhile, an antenna is a main component of the base station and the mobile communication repeater. Antenna is a key device for transmitting and receiving radio waves. As mentioned above, it is required to be light and small in order to suitably apply to various and limited installation environments. In order to provide an antenna that is simple and easy to manufacture and maintain, it is required to design a proper form of a radiating element constituting an antenna, a function, a setting of a propagation direction, a circuit and a mechanism structure.

The present invention has been proposed in order to satisfy the above-mentioned demand, and it is an object of the present invention to provide a multi-band dipole antenna and a system which are easy to manufacture, install and manage.

According to an aspect of the present invention, there is provided a plasma display panel including a substrate having a first substrate region and a second substrate region spaced apart from each other, a first antenna pattern formed on a first substrate region of the substrate, Band dipole antenna including a first antenna pattern and a second antenna pattern formed in a region.

The first antenna pattern may be disposed on a first substrate region disposed at a central portion of the substrate. The first antenna pattern may be disposed on a front surface of the first substrate region. Alternatively, a portion of the first antenna pattern may be disposed on the front surface of the first substrate region, and the remaining portion may be disposed on the rear surface of the first substrate region to provide a dual polarization structure. The first antenna pattern may be formed as a beam pattern.

The second antenna pattern may be disposed on a second substrate region disposed on an outer side of the substrate outside the first antenna pattern, a part of the second antenna pattern may be disposed on a front surface of the second substrate, And may be provided in a dual polarization structure.

The first substrate region and the second substrate region may have the same material or different materials. At least one of the first substrate region and the second substrate region may be formed in a polygonal or circular shape.

The first antenna pattern transmits / receives a frequency of a relatively high frequency band, and the second antenna pattern transmits / receives a frequency of a relatively low frequency band.

The substrate may include a first substrate and a second substrate. The first substrate includes the first substrate region. The second substrate is separated from the first substrate and formed at the same position as the first substrate, and includes the second substrate region formed in a shape surrounding the first substrate. At this time, the first substrate and the second substrate may be printed circuit boards or metal materials.

The present invention is also characterized in that it comprises the above-described multi-band dipole antenna, a first feeder for feeding the first antenna pattern, a second feeder for feeding the second antenna pattern, A reflector, and a support for supporting the multi-band dipole antenna on the reflector.

At this time, the first antenna pattern and the first feeding part, and the second antenna pattern and the second antenna pattern may be connected to each other via a cable or a balun.

The present invention also provides a multi-band dipole antenna comprising a substrate, a plurality of antenna units formed concentrically with respect to the substrate central axis and spaced apart from each other.

And at least one of the substrate portions on which the plurality of antenna units are respectively formed may be separated.

As described above, the present invention providing a multi-band dipole antenna and system facilitates the fabrication, installation, and management of an antenna covering a multi-band.

1 is an exploded view of a multi-band dipole antenna system in accordance with an embodiment of the present invention.
FIG. 2 is an assembly view of a multi-band dipole antenna system according to an embodiment of the present invention; FIG.
3 is a more detailed view of a multi-band dipole antenna according to an embodiment of the present invention.
FIGS. 4 to 8 illustrate a multi-band dipole antenna according to another embodiment of the present invention; FIG.
9 illustrates a balun removed multiband dipole antenna system of the present invention.
10 is a view for explaining another embodiment of a multiband dipole antenna according to the present invention.
11 is a view for explaining another embodiment of the multiband dipole antenna of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, only parts necessary for understanding the embodiments of the present invention will be described, and the description of other parts will be omitted so as not to obscure the gist of the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor is not limited to the meaning of the terms in order to describe his invention in the best way. It should be interpreted as meaning and concept consistent with the technical idea of the present invention. Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely preferred embodiments of the present invention and do not represent all the technical ideas of the present invention, so that various equivalents And variations are possible.

The multi-band dipole antenna system of the present invention can form a multi-band antenna pattern on one substrate. In the following description, a pattern supporting the first frequency band in the multi-band antenna pattern will be referred to as a first antenna pattern, and a pattern supporting the second frequency band will be described as a second antenna pattern or radiating element modules. The first antenna pattern formed on the inner side of the substrate may be a pattern supporting a relatively high frequency band and the second antenna pattern formed on the outer side of the substrate may be a pattern supporting a relatively low frequency band.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a diagram schematically illustrating a configuration of a multi-band dipole antenna system 1 according to an embodiment of the present invention; FIG. 1 is an exploded perspective view of a multiband dipole antenna system 1 of the present invention, and FIG. 2 is a view showing a coupling diagram of a balun removal multiband dipole antenna system 10 of the present invention .

Referring to FIGS. 1 and 2, a multi-band dipole antenna system 10 of the present invention includes a reflector 50, a multi-band dipole antenna 20 having antenna patterns supporting different frequency bands, The feeder 300 and the support table 260 for supplying power to the power supply unit 20. The multi-band dipole antenna system 10 may further include a fixing unit 400 for fixing the feeder 300 to the reflector 50. [ The multiband dipole antenna system 10 includes a first antenna unit 100 having a first antenna pattern for supporting a first frequency band and a second antenna unit 200 having a second antenna pattern for supporting a second frequency band. ).

Although not shown here, a feeder circuit for feeding the first antenna unit 100 and a feeder circuit for feeding the second antenna unit 200 may be provided on the rear surface or the front surface of the reflector 50. The power feeding circuit is connected to the first antenna unit 100 and is connected to a first feeding circuit and a second antenna unit 200 capable of supporting transmission and reception of signals corresponding to the first frequency band, And a second feeding circuit capable of supporting transmission and reception of signals. The height of the support member 160 can be variously formed according to the designer's intention.

The multi-band dipole antenna system 1 of the present invention having such a structure is configured such that the first antenna unit 100 supporting a relatively high frequency band is provided inside the multi-band dipole antenna 20, Band dipole antenna 20 may be provided at the outer periphery of the multiband dipole antenna 20. [ The multi-band dipole antenna system 10 of the present invention can support frequency transmission and reception by forming antenna patterns of different frequency bands on the same plane. Accordingly, the multi-band dipole antenna system 10 of the present invention can more easily manufacture an antenna capable of covering multiple bands, thereby improving mass productivity and facilitating installation and management of the antenna.

On the other hand, at least one of the annular second antenna unit 200 and the first antenna unit 100 having a symmetrical pattern shape is printed on the front and back surfaces of the substrate 10 with an antenna pattern supporting transmission / . In the second antenna unit 200 of the annular shape, the radiating element module corresponding to the second antenna pattern 201 is connected to the second feeder 320 through the second cable 250. The feeder 300 for fixing the second cable 250 and connecting the antennas having polarization characteristics may be disposed on the reflection plate 50 corresponding to the central region of the second antenna unit 200. [ In the present invention, an example of using a printed circuit board as the substrate 10 is disclosed.

The feeder 300 may be disposed under the first antenna unit 100 and may be connected to the second antenna unit 200 through the second cable 250 to provide dual polarization characteristics. The feeder 300 may include a first feeder 310 for feeding the first antenna unit 100 and a second feeder 320 for feeding the second antenna unit 200. The first feeder 310 and the first antenna unit 100 may be connected through the first cable 150. The second feeder 320 corresponds to the center of the second antenna unit 200 so that the second cables 250 reach the radiating element modules 201 provided in the second antenna unit 200 at the same distance As shown in FIG.

The first cable 150 may be provided to connect the center of the first feeder 310 and the center of the first antenna unit 100. The first cable 150 may support impedance matching of the first antenna pattern provided in the first antenna unit 100. [

The second cable 250 may be provided with a plurality of cables connected to the corners of the second power feeder 320. The second cable 250 may be provided in a number corresponding to the number of the radiating element modules 201 of the second antenna unit 200. That is, when the second antenna unit 200 includes four radiating element modules 201, four second cable 250 are provided so that each radiating element module 201 is connected to one side of the feeder 300 . At this time, the second cable 250 is connected to the central contact of the specific radiating element module 201 to support the impedance matching of the radiating element module 201. Accordingly, the second antenna unit 200 of the present invention may have a separate pattern associated with the second cable 250, in which the balun structure is removed.

In the embodiment of the present invention, the first and second cables 150 and 250 are used as the power feeder 300, but a balun may be used.

45 편파 특성을 가지도록 배치될 수 있다. 한편 제1 안테나 유닛(100)은 교차된 복수의 다이폴 안테나들이 전면뿐만 아니라 후면에도 인쇄되어 마련된다. 이때 후면에 형성되는 제1 안테나 패턴들은 일정 축 방향을 중심으로 상호 대칭되는 형태로 인쇄될 수 있다.The first antenna unit 100 is formed by printing a first antenna pattern supporting a dual polarization characteristic on the front and back sides of a certain region of the substrate 10, respectively. In particular, the first antenna unit 100 may be configured such that the "C" -shaped polarization characteristic dipole antenna patterns cross each other in X-shape, but are electrically isolated from each other at the intersections. At this time, the plurality of first antenna patterns are arranged to be rotated 90 degrees with each other

45 polarization characteristic. On the other hand, the first antenna unit 100 is provided by printing a plurality of intersecting dipole antennas on the rear surface as well as on the front surface. At this time, the first antenna patterns formed on the back surface may be printed symmetrically with respect to a certain axial direction.

The second antenna unit 200 may include a second antenna pattern 201 formed by connecting a part of a pattern on the front and back sides of the edge region of the substrate 10 when the antenna unit 200 is formed in an annular shape in the edge region of the substrate 10, A pattern is printed and formed. Hereinafter, the radiating element module will be described with reference to FIG. The second antenna unit 200 is configured to be symmetrical with respect to the center of the radiating element modules 201 formed on the substrate 10, and one side is disposed on the front side and the other side is disposed on the rear side do. The second antenna unit 200 can perform the 180-degree phase-inverted signal emission by partially disposing the radiating element modules 201 on the front and rear sides. The second antenna unit 200 has an annular shape, and the first antenna unit 100 may be disposed at the annular center of the same surface.

Meanwhile, the second antenna unit 200 provides a structure in which the radiating element modules 201 positioned in the diagonal direction are connected through the second cable 250 and the feeder 300. As a result, the second antenna unit 200 has a polarization characteristic of "C" shape based on the feed lines formed in the radiating element modules 201 and the second cable 250 and the feed unit 300 that are symmetrically symmetrical .

The first cable 150 and the second cable 250 may be connected to the antenna pattern of the balun removed form. At this time, the choke supporter may be further attached to one side of the first cable 150 and the second cable 250 for improving the signal characteristics.

The reflection plate 50 supports the multiband dipole antenna 20 provided with the first antenna unit 100 and the second antenna unit 200 and the supporting function of the feeder 300 being seated and fixed, Thereby providing signal reflection characteristics of the first antenna unit 100 and the second antenna unit 200. [ The reflection plate 50 may be subjected to a surface treatment for improving the reflection function. A signal transmitter for transmitting signals to be transmitted / received via the second antenna unit 200 and a signal transmitter, for example, a signal transmitter / receiver connected to the signal line, may be provided on the front surface or the rear surface of the reflection plate 50 .

On one side of the reflector 50, a plurality of reflector holes 263 to which a plurality of supports 260 can be coupled may be formed. The reflector hole 263 is a hole into which a side of the supporter 260 separating the multiband dipole antenna 20 from the reflector 50 is fixed. The reflector holes 263 may be in the number corresponding to the number of supports 260 to be fastened to the multiband dipole antenna 20, for example, 2, 3, 4, . Here, the number of the support table 260 and the number of the reflection plate holes 263 may be similar to each other, but they may be different from each other.

The support bracket 260 supports the first antenna unit 100 at a predetermined distance from the surface of the reflector 50 and suppresses the flow of the multi-band dipole antenna 20, 50 to be supported firmly. The predetermined distance formed by the length of the support member 260 may vary depending on the frequency band supported by the first antenna pattern 85 and the second antenna pattern 201 formed on the multiband dipole antenna 20. The first antenna unit 100 may be provided at one side thereof with substrate holes 261 through which the support members 260 can be inserted so as to pass through the front and rear surfaces of the substrate 10, respectively. The number of the substrate holes 261 may also be changed according to the number of the supports 260.

FIG. 3 is a diagram illustrating the configuration of the multi-band dipole antenna 20 in more detail in FIGS. 1 and 2. FIG.

Referring to FIG. 3, the multiband dipole antenna 20 of the present invention may include a first antenna unit 100 and a second antenna unit 200 provided on a substrate 10 of the same plane. The substrate 10 may include a first substrate region 11 and a second substrate region 12.

The first antenna unit 100 includes a first substrate region 11, a first antenna pattern 85, a ground unit 15, an eleventh feeder 22, a twelfth feeder 21, and the like. The first dipole 11 and the second dipole 12 of the first antenna pattern 85 are connected to the first front antenna pattern 80 and the first substrate area 11, Pattern 90 may be included.

The first dipole 11, the second dipole 12, the eleventh dipole antenna 11, the second dipole antenna 11, the second dipole antenna 11, A feeder line 22, a twelfth feeder line 21, and the like are formed. Where the dielectric may have Teflon or a plastic insulator structure. The first substrate area 11 is provided with a support table 260 for fixing the first substrate area 11 to the reflector 50. The first substrate area 11 includes at least one substrate hole 261 are formed. The first substrate region 11 may be formed in a polygonal shape such as an elliptical shape, a circular shape, a triangular shape, a square shape, or an octagonal shape.

The first substrate region 11 may be surrounded by the second substrate region 12. The first substrate region 11 may be disposed on the same plane as the second substrate region 12. [ The first substrate region 11 may be formed of the same material as the second substrate region 12, or may be formed of another material. The size of the first substrate region 11 can be adjusted according to the size of the frequency region supported by the first front antenna pattern 80 formed.

The first dipole 11 forms a taper type matching circuit in which the widths of both ends of the "C" -shaped antenna pattern are gradually reduced to form a balun, and the first dipole 11 is formed by thinly printing a metal material on one surface of the first substrate area 11 do. The second dipole 12 is formed in the same shape as the first dipole 11 and at a position shifted by 90 degrees about the center of the first substrate region 11 with respect to the longitudinal direction of the first dipole 11, As shown in FIG. The metal may include at least one metal having electrical conductivity such as copper, silver, nickel, and alloys thereof. The first dipole 11 and the second dipole 12 may be disposed on the upper and lower portions of the first substrate region 11 in an X-shaped crossing shape.

As described above, the first antenna unit 100 according to the present invention is manufactured in the form of a built-in balun in the first substrate region 11, thereby reducing the volume required for antenna design and providing improved directivity and electrical characteristics of the radio wave .

Meanwhile, in the first antenna unit 100 of the present invention, the patterns of the dual polarization dipole antennas may be disposed on the front and rear surfaces of the first substrate region 11, respectively. For example, the first front antenna pattern 80 may be disposed on the front surface of the first substrate region 11, and the first counter antenna pattern 90 may be disposed on the rear surface of the first substrate region 11 . At this time, the first counter antenna pattern 90 has the same shape as the first front antenna pattern 80, but the first front antenna pattern 80 is formed in the same shape as the first front antenna pattern 80, It can be formed in a non-formed form.

The grounding portion 15 may be formed on one surface of the first substrate region 11 and may be formed at a portion where the first dipole 11 and the second dipole 12 overlap. For example, the grounding portion 15 is formed in a rectangular thin metal shape at the central portion where the first dipole 11 and the second dipole 12 overlap. The plurality of via holes 16 formed in the ground portion 15 are formed as holes penetrating both side surfaces of the first substrate region 11 and are formed so as to be electrically connected to the opposite surface. The plurality of via holes 16 improve the grounding ability.

The eleventh feeder line 22 is formed by printing on one surface of the first substrate region 11 as a metal line connecting the end of the first dipole 11. [ The twelfth feeder line 21 is formed of a metal line connecting the end of the second dipole 12 and has both ends close to each other with respect to the eleventh feeder line 22, One via hole is formed. Since the first dipole 11 and the second dipole 12 form an angle of 90 degrees in an X-shape on one surface of the first substrate region 11, the first dipole 11 and the second dipole 12 The eleventh feeder line 22 and the twelfth feeder line 21 formed at one end are also orthogonal to each other.

The second antenna unit 200 is spaced apart and fixed with the first antenna unit 100 at regular intervals based on the at least one support 260 on the reflection plate 50. The feeder 300 is placed on the reflector 50 and the first feeder 310 of the feeder 300 is connected to the first antenna unit 100 through the first cable 150, And the second cable 250 is electrically connected between the feeder 320 and the second antenna unit 200. Accordingly, the radiating element modules corresponding to the second antenna pattern 201 of the first antenna unit 100 and the second antenna unit 200 of the present invention can be supplied with the second cable 250 from which the balun is removed Structure can be provided.

The second antenna unit 200 provides a structure in which a plurality of radiating element modules 201 are disposed on the annular second substrate region 12 with respect to the first antenna unit 100 disposed at the center. Accordingly, the second antenna unit 200 of the present invention may be arranged such that a frequency band covers the first antenna unit 100 at the center. In the second antenna unit 200 of the present invention, the radiating element modules 201 are partially arranged on the front and rear surfaces of the substrate, so that the radiating element modules 201 radiate signals with a phase difference of 180 degrees. As a result, the second antenna unit 200 of the present invention provides better signal symmetry, thereby minimizing the occurrence of PIMD (Passive Intermodulation Distortion).

The second antenna unit 200 of the present invention includes four radiating element modules 201, 210, 220, 230, and 240 formed on the front and rear surfaces of the second substrate region 12 and the second substrate region 12, .

The second substrate region 12 is a structure that provides a surface on which the four radiating element modules 210, 220, 230, and 240 are mounted. The second substrate region 12 is formed continuously with the first substrate region 11 and may be formed of a nonconductive material. When the first substrate region 11 is eliminated at the center with reference to the drawing, the second substrate region 12 may have an octagonal ring shape. Thus, each of the radiating element modules can be provided in the form of a hook bent in the corner area of the octagonal ring and bent in the central direction at the center of the side area. However, the second substrate region 12 of the present invention is not limited to the above-described octagonal ring shape but may be formed in at least one of various shapes, and may have a structure symmetrical with respect to a center point or a central axis .

On the other hand, contact holes passing through front and rear surfaces may be provided on the second substrate region 12. These contact holes may be formed at the center points of the respective radiating element modules 210, 220, 230 and 240. These contact holes can serve as a core wire hole through which the second cables 250 are connected to feed a signal. The second cables 250 are inserted into the contact holes and are fixed on the second substrate region 12 through the soldering process to form the contacts 213, 223, 233, and 243. The contacts 213, 223, 233 and 243 are located at the center points of the radiating element modules 210, 220, 230 and 240 and are electrically connected to the respective radiating element modules 210, 220, 230 and 240 . As a result, the second cables 250 are connected to the contact holes to form the contact points 213, 223, 233 and 243, and the contact points 213, 223, 233 and 243 are connected to the radiating element modules 210, 220, 230, and 240, respectively. Accordingly, the second antenna unit 200 of the present invention is configured such that the second cables 250 and the respective radiating element modules 210, 220, 230, and 240 are connected to the contact points 213, 223, 233, and 243 It is possible to provide an interconnected structure.

Also, on the second substrate region 12, at least one substrate hole 261 passing through the front and rear surfaces of the substrate may be provided. A plurality of the substrate holes 261 may be provided on the second substrate region 12 and the second antenna unit 200 may be fixedly supported by the support member 260 fixed to the reflector 50 at one side thereof At least two places can be provided. Although the eight substrate holes 261 are provided on the second substrate region 12 in the drawing, the present invention is not limited thereto. In addition, the present invention is not limited thereto. Also, in the eight substrate holes 261, And a support table 260 may be provided only in some of the substrate holes 261 as needed. For example, at least two or more substrate holes 261, for example, four support holes 260 may be provided. At this time, the substrate holes 261 in which the supporter 260 is installed can be selected in positions mutually symmetrical for rigid support.

The four radiating element modules 210, 220, 230 and 240 include a first radiating element module 210, a second radiating element module 220, a third radiating element module 230, a fourth radiating element module 240 ). Each of the four radiating element modules 210, 220, 230, and 240 may be formed by printing a metal foil on the front and rear surfaces of the second substrate region 12, respectively. The thickness, width, and length of the metal foil to be printed can be adjusted according to the frequency band supported by the second antenna unit 200 of the present invention.

Meanwhile, the first radiating element module 210 and the fourth radiating element module 240 may be disposed symmetrically with respect to the horizontal center line of the drawing. Similarly, the second radiating element module 220 and the third radiating element module 230 may be arranged in a symmetrical structure with respect to the horizontal center line.

The first radiating element module 210 includes an eleventh dipole 211 and a twelfth dipole 212 and a first contact 213. Here, the eleventh dipole 211 is disposed on the front surface of the second substrate region 12 and the twelfth dipole 212 is disposed on the rear surface of the second substrate region 12 with respect to the front surface of the drawing. The eleventh dipoles 211 and the twelfth dipoles can be designed with a hook shape. The thickness, the length and the width of the eleventh dipole 211 and the twelfth dipole 212 can be adjusted according to the frequency band supported by the second antenna unit 200. Meanwhile, the first radiating element module 210 may have a symmetrical structure with respect to the first contact 213. In particular, the first radiating element module 210 has a front-back symmetry structure of the second substrate region 12 with respect to the first contact 213. For example, the eleventh dipole 211 is disposed on the front surface of the second substrate region 12 and is electrically connected to the first contact 213, the twelfth dipole 212 is symmetrical with the eleventh dipole 211, And is electrically connected to the first contact 213 while being disposed on the rear surface of the substrate region 12. [ Accordingly, the eleventh dipoles 211 and the twelfth dipoles 212 are arranged symmetrically with the phase difference being 180 degrees across the front and rear sides. The first contact 213 may be formed by soldering to the above-described contact hole. The first contact 213 may be electrically connected to the first cable 251 during the soldering process.

The second radiating element module 220 includes a twenty-first dipole 221 and a twenty-second dipole 222, and a second contact 223. The third radiating element module 230 is disposed in a diagonal direction with respect to the first radiating element module 210 and rotated to the right by 90 degrees with respect to the second radiating element module 220. The third radiating element module 230 includes a thirty first dipole 231 and a thirty second dipole 232, and a third contact 233. The fourth radiating element module 240 is positioned diagonally to the second radiating element module 220 and is disposed at a position rotated 90 degrees to the right with respect to the third radiating element module 230. The fourth radiating element module 240 includes a 41st dipole 241 and a 42nd dipole 242 and a fourth contact 243. The dipoles of the above-described radiating element modules have shapes similar to those of the eleventh dipole 211 and the twelfth dipole 212, and the directions disposed on the front and rear surfaces may be similar or opposite. Each of the dipoles has a feeding part 300 whose impedance matching is made primarily by the second cable 250 connected to the contacts 213, 223, 233 and 243 and the other end of the second cable 250 is connected, The secondary matching can be performed by the crossover feeder provided in the antenna. The cross feeder may include a drilled hole through which both ends of a feed line for electrically connecting cable connection portions can be connected.

As described above, in the second antenna unit 200 of the present invention, the second cable 250, from which a separate balun is removed, is connected to the contact point, and the antenna pattern is disposed using both front and rear surfaces of the substrate, And electrical characteristics can be improved.

As described above, the multiband dipole antenna system 10 of the present invention supports the first antenna unit 100 and the second antenna unit 200 on the same surface while maintaining good frequency characteristics. Particularly, the present invention is characterized in that the first substrate region 11 of the first antenna unit 100 and the second substrate region 12 of the second antenna unit 200 are physically connected to form an antenna pattern, Modules. Accordingly, the present invention can more easily form an antenna pattern for multi-band support, and can also provide an easier working environment by working on a single substrate in terms of antenna installation and management.

FIGS. 4 to 8 are views showing still another example of the balun-type multiband dipole antenna 20 according to the embodiment. FIG. 9 is a view illustrating the coupling of a balun-type multiband dipole antenna system according to an embodiment of the present invention.

4 and 9, the multi-band dipole antenna 20 of the present invention includes a rectangular substrate 10, a first antenna pattern 85, and a second antenna pattern 201 corresponding to the radiating element module. . The substrate 10 includes a first substrate region 11 formed with a first antenna pattern 85 and a rectangular shape and a second substrate region 11 formed with a second antenna pattern 201, And may include a substrate region 12. The first antenna pattern 85 may be provided with contact holes connected to the feeding part at the center as shown in FIG. The first antenna pattern 85 may be formed by printing a pattern on only the front surface of the first substrate region 11 having a rectangular shape. The first antenna pattern 85 may be pattern-printed as a metal foil in a circular shape as shown in FIG. On the other hand, the first antenna pattern 85 may be formed to have a plurality of empty regions symmetrically formed so that the length of the pattern covers the high frequency band.

A second antenna pattern 201 is formed on the second substrate region 12 having a rectangular band shape formed in connection with the first substrate region 11. The second antenna pattern 201 may be configured as a plurality of radiating element modules as described above. Each of the radiating element modules is formed to be symmetrical in a diagonal direction with a "C" -shaped pattern in the second substrate region 12 having a rectangular band shape, and a part of patterns may be arranged on the front and rear surfaces, .

5 and 9, the multiband dipole antenna 20 of the present invention includes a circular substrate 10, a first antenna pattern 85, and a second antenna pattern 201 corresponding to the radiating element module . The circular substrate 10 is formed with a first antenna pattern 85 and an octagonal first substrate region 11 and a second antenna pattern 201. The outer shape of the first substrate region 11 is circular, And a second substrate region 12 provided in an octagonal band shape. The first antenna pattern 85 may be provided with contact holes connected to the feeding part at the center as shown in FIG. The first antenna pattern 85 may be formed by printing a pattern on only the front surface of the first substrate area 11. [ The first antenna pattern 85 may be provided in a pattern symmetrical with respect to the longitudinal and longitudinal axes. The first antenna pattern 85 may be formed in a large rectangular pattern shape with a small square pattern as shown in FIG.

A second antenna pattern 201 is formed on the second substrate region 12 formed in a continuous manner with the first substrate region 11. [ The second antenna pattern 201 may be configured as a plurality of radiating element modules as described above. Each of the radiating element modules is formed in a "C" -shaped pattern, and a part of the patterns may be disposed on the front and rear surfaces of the radiating element modules, respectively. In particular, the radiating element modules may be arranged side by side in the shape of the rim of the circular second substrate region 12. To this end, each radiating element module may include a curved portion corresponding to the rim of the circular second substrate region 12.

6 and 9, the multi-band dipole antenna 20 of the present invention includes a circular substrate 10, a first antenna pattern 85, and a second antenna pattern 201 including a radiating element module . The circular substrate 10 includes a first substrate region 11 having a first antenna pattern 85 having a circular pattern and an octagonal rim and a second antenna pattern 201 having a rectangular shape, But the inner shape may include a second substrate region 12 provided in an octagonal band shape. The first antenna pattern 85 having a circular shape may be provided with contact holes connected to the feed part at the center as shown in the figure. The first antenna pattern 85 may be formed by printing a pattern on only the front surface of the first substrate area 11. [

A second antenna pattern 201 is formed in a strip-shaped second substrate region 12 formed in an octagonal shape with the first substrate region 11. The second antenna pattern 201 may be configured as a plurality of radiating element modules as described above, and each radiating element module may be formed in a "C" -shaped pattern. The second antenna pattern 201 may be disposed on the front and rear surfaces of the radiating element modules such that a part of the radiating element patterns are opposed to each other. In particular, the radiating element modules may include a curved portion so as to be arranged in parallel with the rim shape of the circular second substrate region 12. [

7 and 9, the multi-band dipole antenna 20 of the present invention includes a second antenna pattern 201 including an octagonal substrate 10, a first antenna pattern 85, and a radiating element module . The octagonal substrate 10 may have a first antenna pattern 85 of a circular pattern in a central fixed region and a second antenna pattern 201 may be formed on an octagonal rim. The first antenna pattern 85 having a circular shape may be provided with contact holes connected to the feed part at the center as shown in the figure. The first antenna pattern 85 may be formed by printing a pattern only on the central front surface of the octagonal substrate 10.

The second antenna pattern 201 may be configured as a plurality of radiating element modules, and each radiating element module may be formed in a "C" -shaped pattern. The second antenna pattern 201 may be disposed on the front and rear surfaces of the radiating element modules such that a part of the radiating element patterns are opposed to each other.

8 and 9, the multiband dipole antenna 20 of the present invention includes a second antenna pattern 201 including a rectangular substrate 10, a first antenna pattern 85, and a radiating element module . The rectangular substrate 10 includes a first substrate region 11 having a rectangular first antenna pattern 85 and an octagonal rim and a second antenna pattern 201 formed on the outer side thereof, But the inner shape may include a second substrate region 12 provided in an octagonal band shape. As shown in the figure, the first antenna pattern 85 having a rectangular shape may be provided with contact holes connected to the feed part at the center. The first antenna pattern 85 may be formed by printing a pattern on only the front surface of the first substrate area 11. [

A second antenna pattern 201 is formed in a strip-shaped second substrate area 12 in which an octagon-shaped first substrate area 11 is contiguous with a rim. The second antenna pattern 201 may be configured as a plurality of radiating element modules as described above, and each radiating element module may be formed in a "C" -shaped pattern. The second antenna pattern 201 may be disposed on the front and rear surfaces of the radiating element modules such that a part of the radiating element patterns are opposed to each other. In particular, the radiating element modules may be arranged symmetrically with respect to the corner area of the quadrangle so as to be arranged in parallel with the rim shape of the second substrate area 12 of the quadrangle.

In the above description, the shape of the substrate 10 in the multiband dipole antenna 20 of the present invention is rectangular, octagonal, circular, etc., but the present invention is not limited thereto. That is, the multiband dipole antenna 20 of the present invention may be provided in various shapes such as a triangle, a pentagon, a star shape, or various gear shapes, which can form each antenna pattern to be symmetrical with respect to a certain direction with respect to a central axis And the area where the first internal antenna pattern is provided may also be provided in various shapes.

Also, the second antenna pattern 201 in the structure of the multi-band dipole antenna 20 is configured as a dual polarization type, but the first antenna pattern 85 has a single polarization type. However, the present invention is not limited thereto. 3, at least one of the first antenna pattern 85 and the second antenna pattern 201 is formed on the front and rear surfaces of the substrate by a double polarized dipole type pattern As shown in FIG. Alternatively, the first antenna pattern 85 and the second antenna pattern 201 may be formed on a single surface of the substrate according to a designer's intention, thereby forming a single polarization dipole type pattern.

10 is a view for explaining an antenna configuration for a multi-band of the multi-band dipole antenna 20 of the present invention.

10, the multiband dipole antenna 20 of the present invention includes a substrate 10, a first antenna unit 100 supporting a first frequency band, a second antenna unit 200 supporting a second frequency band , And a third antenna unit 500 supporting a third frequency band.

The first antenna unit 100 may include a first substrate region 11 corresponding to a central region of the substrate 10 and a first antenna pattern 85 formed on the first substrate region 11. [ The first substrate region 11 occupies a central predetermined region of the substrate 10 and the size of the first antenna unit 100 may be varied according to a target frequency characteristic. The first antenna unit 100 may include a beam pattern symmetrically arranged in a predetermined direction on the central axis of the first substrate region 11 as the first antenna pattern 85. The first antenna pattern 85 may be disposed only on the front surface area of the first substrate area 11 or partially on the front surface and the rear surface. The first antenna pattern 85 partially disposed on the front and rear surfaces may be formed in a pattern symmetrical with respect to the plane of the first substrate area 11. [

The second antenna unit 200 may include a second substrate region 12 corresponding to a rim region of the substrate 10 and a second antenna pattern 201 disposed on the second substrate region 12 have. The second antenna pattern 201 may be disposed along the strip regions of the second substrate region 12 provided in a strip shape. The second antenna pattern 201 disposed at this time may include the radiating element modules arranged to be symmetrical to the front and rear surfaces with respect to the contact point as in the above-described examples.

The third antenna unit 500 includes a third substrate region 13 provided between the first substrate region 11 and the second substrate region 12, a third antenna pattern 202 disposed in the third substrate region 13, ). The third substrate region 13 may be provided in a strip shape disposed inside the second substrate region 12. [ The outside of the third substrate region 13 faces the inside of the second substrate region 12 and the inside of the third substrate region 13 faces the outside of the first substrate region 11 . The shape of the third antenna pattern 202 may be similar to the shape of the second antenna pattern 201 and may be provided in a relatively small pattern. The frequency band supported by the third antenna pattern 202 may be relatively higher than the frequency band of the second antenna pattern 201 due to a different size pattern.

Meanwhile, a multiband dipole antenna or a multiband dipole antenna of the present invention may have a larger number of antenna units. That is, the fourth antenna unit may be provided in a strip shape. In other words, the multi-band dipole antenna of the present invention may include a substrate and a plurality of antenna units formed in a plurality of concentric circles with respect to the center axis of the substrate.

Also, the multi-band dipole antenna according to any of Figs. 1 to 10 discloses an example in which the first, second, or third antenna unit is formed on the same surface of the printed circuit board, but the present invention is not limited thereto. For example, as shown in FIG. 11, the first and second antenna units may be separately formed.

11 is a view for explaining another embodiment of the multiband dipole antenna of the present invention.

Referring to FIG. 11, the multiband dipole antenna 20 of the present invention includes a first antenna unit 100 supporting a first frequency band and a second antenna unit supporting a second frequency band, And the substrate for implementing the second antenna unit 100, 200 are separated from each other. That is, the first antenna unit 100 and the second antenna unit 200 are separated from each other and have a structure in which a first antenna pattern 385 and a second antenna pattern are formed on the same plane.

In this case, the first antenna unit 100 has a structure in which the first antenna pattern 385 is connected to the balun 350 and the balun 350 and the first antenna pattern 385 are integrally formed. For example, the substrate on which the first antenna pattern 385 is formed is formed by a molding method using a metal material such as aluminum, copper, or the like. The first antenna pattern 385 has a structure connected to the balun 350. The balun 350 and the first antenna pattern 385 may be integrally formed through molding.

The second antenna unit 200 is formed in a ring shape so as to surround the first antenna unit 100 by being spaced apart from the first antenna unit 100. That is, the first antenna unit 100 is positioned in the hole 299 formed in the center portion of the second antenna unit 200. The second antenna unit 200 has a structure in which a second antenna pattern is formed on a printed circuit board. The second antenna unit 200 is implemented in the same manner as the second antenna unit according to FIG. 3, but a detailed description thereof will be omitted.

In the present invention, the first antenna unit 100 is implemented as a mold type. However, the second antenna unit 200 may be implemented as a printed circuit board. In the present invention, the second antenna unit 200 is an example of a printed circuit board type. However, it is needless to say that the second antenna unit 200 may be implemented as a mold type like the first antenna unit 100.

In addition, although the first and second antenna units 100 and 200 are formed separately from each other, the present invention is not limited thereto. That is, when three or more antenna units are disposed on the same plane, at least one of the substrates on which three or more antenna units are formed may be formed separately. For example, when three antenna units are disposed on the same plane, the second and third antenna units may be implemented on one substrate and separated into a first antenna unit and implemented on another substrate.

The multi-band dipole antenna 20 of the present invention and the system 10 supporting the multi-band dipole antenna of the present invention can simplify the antenna structure by forming an antenna structure supporting multiple bands on one substrate. Accordingly, the present invention can obtain various effects according to the simplification, that is, ease of manufacture and ease of installation and management.

It should be noted that the embodiments of the present invention disclosed in the present specification and drawings are only illustrative of specific examples for the purpose of understanding and are not intended to limit the scope of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

1: Multi-band dipole antenna system
20: Multi-band dipole antenna
11, 12, 13: substrate area
10: substrate
50: reflector
85: first antenna pattern
100: first antenna unit
150, 250: Cable
200: second antenna unit
201, 210, 220, 230, 240: a second antenna pattern
260: Support
300, 310, 320:

Claims (16)

A substrate having a first substrate region and a second substrate region spaced apart from each other;
A first antenna pattern formed on a first substrate region of the substrate;
And a second antenna pattern formed on a second substrate region of the substrate,
Wherein the first antenna pattern is disposed on the first substrate region formed at the central portion of the substrate and the second antenna pattern is disposed on a second substrate region formed on the outer portion of the substrate outside the first antenna pattern, Band dipole antenna. delete The method according to claim 1,
Wherein the first antenna pattern is disposed on a front surface of the first substrate region. The method according to claim 1,
Wherein a portion of the first antenna pattern is disposed on a front surface of the first substrate region and a remaining portion of the first antenna pattern is disposed on a rear surface of the first substrate region to provide a dual polarization structure. The method according to claim 1,
Wherein the first antenna pattern is formed as a beam pattern. delete The method according to claim 1,
Wherein the second antenna pattern is partially disposed on a front surface of the second substrate and a remaining portion of the second antenna pattern is disposed on a rear surface of the substrate region to provide a dual polarization structure. The method according to claim 1,
Wherein the first substrate region and the second substrate region are formed of the same material or different materials. The method according to claim 1,
Wherein at least one of the first substrate region and the second substrate region is formed in a polygonal or circular shape. The method according to claim 1,
Wherein the first antenna pattern transmits / receives a frequency of a relatively high frequency band, and the second antenna pattern transmits / receives a frequency of a relatively low frequency band. 2. The method of claim 1,
A first substrate having the first substrate region;
A second substrate separated from the first substrate and formed at the same position as the first substrate and having the second substrate region formed to surround the first substrate;
Band dipole antenna. 12. The method of claim 11,
Wherein the first substrate and the second substrate are made of a printed circuit board or a metal material. A multi-band dipole antenna according to any one of claims 1, 3, 4, 5, 7, 8, 9, 10, 11, and 12;
A first feeder for feeding the first antenna pattern and a second feeder for feeding power to the second antenna pattern;
A reflection plate disposed under the multiband dipole antenna;
A support for supporting the multi-band dipole antenna on the reflector;
Band dipole antenna system. 14. The method of claim 13,
The first antenna pattern and the first feeding part, and the second antenna pattern and the second antenna pattern are connected to each other through a cable or a balun. Board;
And a plurality of antenna units formed concentrically with respect to the central axis of the substrate and spaced apart from each other,
Wherein a center of the plurality of antenna units is a central axis of the substrate. 16. The method of claim 15,
Wherein at least one of the substrate portions from which the plurality of antenna units are respectively formed is separated.

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