KR20050065958A - Multi-resonance antenna - Google Patents

Abstract

According to the present invention, in a multi-resonant antenna for implementing broadband characteristics, dipole antennas having one or more adjacent resonance frequencies are arranged in an array form, and dipole antennas having respective resonance frequencies can be collectively combined to implement broadband characteristics.

Description

Multi-Resonance Antenna

The present invention relates to a multi-resonant antenna that implements a wideband characteristic by arranging dipole antennas having a plurality of adjacent resonant frequencies in an array form.

With the development of mobile communication and wireless communication, there is an increasing demand for an antenna having a very wide bandwidth that can be used in multimedia communication, software defined radio (SDR), ultra wideband (UWB) communication, and the like. The wideband antenna as described above can cover various wireless services such as PCS (Personal Communication Service), IMT-2000 (International Mobile Telecommunication 2000), Bluetooth, etc. with one antenna, which is advantageous in terms of cost and space efficiency. It can be said that

Among the various antennas used in mobile communication and wireless communication, printed antennas are light and inexpensive, have mass production, and are easy to integrate with other high frequency circuits. In particular, printed dipole antennas offer much wider bandwidth than microstrip antennas, less excitation of surface waves, and less spurious radiation from feed lines.

The feeding of the printed dipole antenna is mainly performed by feeding a coplanar strip (CPS) together with the dipole on one side of the dielectric substrate, or by placing the dipoles and the strips on both sides of the dielectric substrate. Mainly used.

Hereinafter, a single resonant antenna will be described with reference to the accompanying drawings.

1 is a view showing the structure of a conventional single resonant antenna, Figure 2 is a view showing the bandwidth characteristics of a conventional single resonant antenna.

Referring to FIG. 1, a single resonant antenna is manufactured in a rectangular package by stacking a plurality of stacked substrates.

The single resonant antenna includes a radiation electrode substrate 140 for propagating signals, a feeder substrate 100 for applying a radio wave signal having a predetermined phase difference to the radiation electrode substrate 140, and a radiation line with the feeder substrate 100. A slot substrate 120 disposed between the electrode substrate 140 and transmitting the radio wave signal transmitted from the feed line 105 to the radiation electrode substrate 140, and a ground of the signal transmitted to the feed line substrate 100. And a dielectric substrate 110 and 130 inserted between the ground substrate (not shown), the radiation electrode substrate 140, the slot substrate 120, the feeder substrate 100, and the ground substrate (not shown).

It is electrically coupled to each other so as to penetrate through the dielectric substrates 110 and 130, the slot substrate 120, and the radiation electrode substrate 140 of the feed line 105 formed on the feed line substrate 100.

The slot substrate 120 has a slot for transmitting a radio signal on the radiation electrode substrate 140. Therefore, the slot substrate 120 transmits the radio wave signal to the radiation electrode substrate 140 through the slot.

Using the single resonant antenna as described above, it is possible to obtain a bandwidth as shown in FIG. In other words, if a single resonant antenna is used, only one resonant frequency is generated, thus the bandwidth is quite narrow.

That is, the bandwidth of the dipole antenna as described above is generally 15 to 20%, there is a problem that the bandwidth is very narrow to provide various mobile communication and wireless communication services.

The following technique is used to increase the bandwidth of the dipole antenna to solve the above problems.

First, in order to increase the bandwidth of the dipole, the shape of the dipole arm is modified into a triangular shape such as a bowtie antenna, and one arm has a slightly shorter structure than the other arm. have. However, the printed dipole antenna according to the above technique also has a problem of obtaining a bandwidth of only about 37%.

Second, the dipole antenna includes a spacer between the grounding conductor plate and the radiating plate, and has a structure in which twin-lines connected to the dipole are located on both sides of the substrate to feed the dipole. . However, the printed dipole antenna presented in the above technique also has a limit of about 25% of its bandwidth.

Third, broadband design guidelines are presented to obtain the maximum bandwidth, reflectors on the back of the radiating element to form a unidirectional radiation pattern, and on each arm of the dipole directly from the 50Ω coaxial line. A power feeding structure is formed. According to the above technique, when VSWR? Along with the influence of the reflector, there is a serious problem of forming an additional resonance and forming unnecessary radiation, thereby degrading the characteristics of the antenna.

Accordingly, an object of the present invention is to provide a multi-resonant antenna to implement a wideband characteristic by arranging dipole antennas having a plurality of adjacent resonant frequencies in an array form.

According to an aspect of the present invention for achieving the above object, in the multi-resonant antenna to implement a wideband characteristics, there is provided a multi-resonant antenna, characterized in that the dipole antenna having one or more adjacent resonant frequencies arranged in an array form do.

The resonant antenna in which the dipole antennas are arranged in an array form includes: a radiation electrode substrate provided with one or more radiators, the feeder substrate including a plurality of feed lines for supplying a radio wave signal to the radiation electrode substrate; And a dielectric substrate disposed between the feeder substrate and the radiation electrode substrate to be inserted between the slot substrate, the radiation electrode substrate, the feeder substrate, and the slot substrate, respectively, to transmit a radio signal supplied from the feeder line to the radiation electrode substrate.

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

3 is a view showing a multi-resonant antenna according to an embodiment of the present invention, Figure 4 is a view showing the bandwidth characteristics of a multi-resonant antenna according to an embodiment of the present invention.

Referring to FIG. 3, a multi-resonant antenna is manufactured by stacking a plurality of stacked substrates in a rectangular package.

The resonant antenna may include a radiation electrode substrate 340 for propagating a signal, a feeder substrate 300 for applying a radio wave signal having a predetermined phase difference to the radiation electrode substrate 340, the feeder substrate 300, and a radiation electrode substrate ( A slot substrate 320 disposed between the 340 and transmitting the radio wave signal transmitted from the feed line 305 on the radiation electrode substrate 340, and a ground substrate for grounding the signal transmitted to the feed line substrate 300. (Not shown), the radiation electrode substrate 340, the slot substrate 320, the feeder substrate 300 and the dielectric substrate 310, 330 inserted between the ground substrate (not shown), respectively.

There are a plurality of feed lines 305 on the feed line substrate 300 to provide a plurality of resonant frequencies.

The slot substrate 320 has a slot 315 corresponding to the number of feed lines on the feed line substrate 300.

The radiator 345 corresponding to the number of slots of the slot substrate 320 is present in the radiation electrode substrate 340. That is, the radiator 345 is present in the radiation electrode substrate 340 according to several frequency bands.

As described above, in the resonant antenna, dipole antennas having a plurality of adjacent resonant frequencies are arranged in an array form.

The operation of the resonant antenna configured as described above will be described.

The propagation signal through the feed line 305 on the feed line substrate 300 is transmitted to the slot 315 of the slot substrate 320. At this time, the radio wave signal transmitted from each feed line 305 is transmitted to the corresponding slot 315.

Then, the slot substrate 320 transmits each radio signal transmitted from the feeder substrate 300 to the radiation electrode substrate 340, and the radiation electrode substrate 340 transmits the radio signal to each radiator 345. Radiate through.

Then, the bandwidth as shown in Figure 4 is generated.

That is, by arranging dipole antennas having a plurality of adjacent resonant frequencies in an array form, the dipole antennas having the respective resonant frequencies are collectively combined to increase their bandwidth.

Therefore, it is possible to implement broadband characteristics that are difficult to achieve with conventional single-element dipole antennas.

The present invention is not limited to the above-described embodiments, and various changes can be made by those skilled in the art without departing from the gist of the present invention as claimed in the following claims.

As described above, according to the present invention, by arranging dipole antennas having a plurality of adjacent resonant frequencies in an array form, the dipole antennas having the respective resonant frequencies may be combined to provide a multi-resonant antenna capable of realizing broadband characteristics.

1 is a view showing the structure of a conventional single resonant antenna;

2 is a view showing the bandwidth characteristics of a conventional single resonant antenna.

3 is a view showing a multi-resonant antenna according to an embodiment of the present invention.

4 is a diagram illustrating bandwidth characteristics of a resonant antenna according to an exemplary embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

300: feeder board 305: feeder

310, 330: dielectric substrate 320: slot substrate

325: slot 340: radiation electrode substrate

Claims (2)

In the resonant antenna to implement the broadband characteristics, And a dipole antenna having at least one adjacent resonance frequency in an array form. The method of claim 1, The resonant antenna in which the dipole antennas are arranged in an array form A radiation electrode substrate provided with one or more radiators to emit one or more radio signals; A feed line substrate including a plurality of feed lines for supplying a radio wave signal to the radiation electrode substrate; A slot substrate disposed between the feed line substrate and the radiation electrode substrate to transmit a radio signal supplied from the feed line to the radiation electrode substrate; And a dielectric substrate inserted between the radiation electrode substrate, the feeder substrate, and the slot substrate, respectively.