KR20030015663A - Broadband sleeve antenna using loading coil - Google Patents

Abstract

By adding a loading coil to the inner conductor located inside the dielectric core of the sleeve antenna to extend the antenna bandwidth, the PCS band (1750-1870 [MHz]) and the IMT-2000 band (1920-2200) Not only can [MHz]) be used as one antenna, but also a sleeve antenna capable of satisfying conditions such as miniaturization of antenna, wideband, and minimization of production cost.

Description

Broadband sleeve antenna using loading coil

The present invention relates to a sleeve antenna, and more particularly, to a sleeve antenna for electrically connecting a loading coil to an inner conductor of the sleeve to stabilize the change of antenna impedance according to the widening of the antenna and the change of frequency.

In the case of mobile communication, the type of antenna used is a patch type and a monopole, and the sleeve antenna is a type of monopole antenna used for mobile communication.

Such a conventional sleeve antenna should have a bandwidth of about 22.7 [%] (VSWR <2) when using the PCS band (1750-1870 [MHz]) and the IMT-2000 band (1920-2200 [MHz]) as one antenna. It does not satisfy the condition.

In addition, the current antenna market requires miniaturization of products, miniaturization of production costs, and minimization of production costs. However, in order to meet miniaturization and widening of products, the structure of the antenna becomes complicated, so there is a problem in minimizing production costs. have.

Accordingly, an object of the present invention is to provide a bandwidth of about 22.7 [%] (VSWR <2) when using the PCS band (1750-1870 [MHz]) and the IMT-2000 band (1920-2200 [MHz]) as one antenna. The present invention provides a sleeve antenna capable of satisfying the requirement of having a sleeve.

It is another object of the present invention to provide a sleeve antenna that can meet the requirements of the antenna market, such as miniaturization, broadband, and production cost, as a broadband antenna capable of adding another communication band.

Still other objects and features of the present invention will become apparent from the embodiments described below.

1 is a perspective view showing a sleeve antenna according to an embodiment of the present invention.

FIG. 2 is a test table showing a reflection coefficient S ₁₁ of a frequency of a broadband sleeve antenna using a loading coil at standing wave ratio 2 or less.

Figure 3 is a test table showing the reflection coefficient (S ₁₁ ) for the frequency of the broadband sleeve antenna using the loading coil at standing wave ratio 1.5 or less.

4 is a test table showing the standing wave ratio (VSWR) for the frequency of the broadband sleeve antenna using the loading coil.

5 is a test table showing antenna impedance with respect to the frequency of a broadband sleeve antenna using a loading coil.

6 is a cross-sectional view showing an example in which the internal cross-sectional profile of the dielectric is formed into an uneven shape.

7 shows a sleeve antenna in which the sleeve is overlapped and double applied.

8 shows examples of applying a loading coil to a copier.

9 shows examples of applying various types of tube load to the upper end of the copier.

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

10: copier 20: sleeve

30: loading coil 40: feeder

50: ground plane

According to the sleeve antenna of the present invention, an outer conductor surrounds an outer surface of a dielectric core having an inner space and is connected to an outer conductor of a feeder line through a ground plane, and the inner center conductor and the radiator of the feeder line are electrically connected to an inner space of the dielectric core. A connecting sleeve inner conductor is located, and the loading coil is electrically connected in series with the sleeve inner conductor in the inner space of the dielectric core.

In one embodiment, preferably, the first and second inner conductors are connected to both ends of the loading coil, and the inner conductor may be connected to at least one end of the loading coil.

The dielectric core may be cylindrical or simply cylindrical in profile with an inner cross-sectional profile.

In another embodiment, another dielectric core and outer conductor are laminated outside the sleeve outer conductor, and in another embodiment the copier is separated into two parts and electrically connected via another loading coil, preferably the other loading coil It can be wrapped by a sleeve consisting of a dielectric core and an outer conductor.

In addition, a tube load of various shapes may be installed at the upper end of the copier.

Hereinafter, the configuration and operation of the present invention with reference to the accompanying drawings in detail as follows.

1 shows a sleeve antenna according to an embodiment of the present invention.

As shown, the lower end of the radiator 10 is connected with the upper end of the first inner conductor 23 of the sleeve 20, and the lower end of the first inner conductor 23 is a loading coil 30. It is connected to the upper end of the, the lower end of the loading coil 30 is connected to the upper end of the second inner conductor 24 of the sleeve (20). In addition, the lower end portion of the second inner conductor 24 is connected to the inner center conductor 41 of the feed line 40.

In this embodiment, the first and second inner conductors 23 and 24 are connected to both ends of the loading coil 30 as an example. However, at least one inner conductor and the loading coil may be connected to each other. .

In addition, the outer conductor 21 of the sleeve 20 is connected to the outer conductor 42 of the feed line 40 through a ground plane (50).

A dielectric 22 is interposed between the inner and outer conductors of the sleeve 20 to act as an insulator in direct current, and alternatingly to control the capacitance of the capacitive element. The shape of the dielectric 22 may be cylindrical as shown in FIG. 1 or a cylindrical shape having a profile of an inner cross-section having an uneven shape as shown in FIG. 6 to improve antenna characteristics.

As described above, according to the broadband sleeve antenna using the loading coil, the loading coil serves as an extension coil to reduce the natural frequency of the antenna and is combined with the capacity of the sleeve to provide a standing voltage ratio (VSWR) in the frequency band used. By improving the characteristics of the antenna, the frequency band of the antenna is extended, and the change of the antenna impedance according to the change of the frequency is reduced, thereby improving the operation characteristics of the antenna.

In other words, the conventional sleeve antenna used in one communication band has a narrow bandwidth when the standing wave ratio is 2 or less (VSWR &lt; 2). Therefore, when the PCS band and the IMT-2000 band are used as one antenna. If the antenna bandwidth condition of about 22.7 [%] (VSWR <2) cannot be satisfied, and the antenna for multi-frequency used in two communication bands has the standing wave ratio characteristic as W-shape, There is a problem that the variation in antenna impedance is large.

However, this problem is eliminated in the broadband sleeve antenna using the loading coil according to the present invention.

2 to 5 are test tables of reflection coefficient (S ₁₁ ), frequency of standing wave ratio (VSWR) and frequency of antenna impedance (impedance) with respect to frequency of the broadband sleeve antenna using the loading coil, respectively, according to the present invention. Indicates.

For example, Figures 2 to 4 show the results of measuring the sleeve antenna of the present invention having the following specifications.

Overall length of broadband sleeve antenna using loading coil (length from feed point to top of copier): 48 mm,

Sleeve length: 20mm,

Diameter of copier: 5mm,

Sleeve inner conductor diameter: 3mm,

Diameter of sleeve outer conductor: 13.7mm

Loading coil: 1mm diameter wire, 5mm outer diameter, 3 turns spring shape

Dielectric: cylindrically made from polyethylene

As shown in FIG. 2, at a standing wave ratio of 2 or less (reflection coefficient of -10 dB or less), the lowest frequency mark 3 is 1232 MHz, the maximum frequency mark 2 is 2343 MHz, and the bandwidth is 1111 MHz (62.1% of bandwidth) to operate as a broadband antenna. Done.

In addition, Figure 3 shows the bandwidth in the standing wave ratio 1.5 or less (reflection coefficient -14 dB or less) used as a reference for the practical antenna, the lowest frequency mark 3 is 1709MHz, the maximum frequency mark 2 is 2173MHz, the bandwidth is 464MHz ( Since it operates as a broadband antenna of 23.9% of bandwidth, the PCS band and the IMT-2000 band can be put into one antenna.

5 shows the result of testing the antenna impedance change between the lowest frequency 1232MHz and the maximum frequency 2343MHz, and it can be seen that the antenna operates with a fairly stable impedance without any particular problem in impedance matching with the 50Ω or 75Ω system.

As can be seen from the above test results, the antenna according to the present invention is not only theoretical conditions for the case of using the PCS band and the IMT-2000 band as one antenna, but also the practical antenna It can be seen that the condition as an antenna is satisfied even when the condition of (standing wave ratio is 1.5 or less) is applied.

Furthermore, in Fig. 2, mark 4 shows a GPS communication band at 1580 MHz, and the standing wave ratio is about 1.573 (-13.06 dB), so the frequency bandwidth side (not considering the side of the polarization plane) can accommodate the GPS communication band even if the bandwidth is used. It can be seen that there is a margin of about 300MHz or more.

In addition, as shown in Figs. 7 to 9, by modifying the antenna of the present invention appropriately according to the frequency band and the use, the miniaturization of the antenna by increasing the effective length, the bandwidth associated with the antenna, the standing wave ratio (reflection coefficient) And antenna impedances.

For example, as shown in FIG. 7, the antenna bandwidth can be increased by constituting the sleeve in double, and it is possible to stabilize the antenna impedance in the frequency band.

In addition, as shown in FIG. 8, a loading coil, a simple sleeve, or a sleeve to which the loading coil is applied may be added to a portion of the radiator, and as shown in FIG. By installing the top loading, the effective frequency can be increased and the natural frequency can be lowered, thereby minimizing the antenna and improving the antenna characteristics.

Although the above has been described with reference to the preferred embodiments of the present invention, various changes and modifications are possible at the level of those skilled in the art. Such modifications and variations will naturally belong to the present invention without departing from the spirit of the present invention.

As described above, the broadband sleeve antenna using the loading coil according to the present invention is not only applicable to the PCS and the communication device of the IMT-2000 communication band by wideband transmission and reception, but also accommodates the GPS communication band in terms of bandwidth of the antenna. And an additional communication band can be accommodated.

In addition, the simple structure of the antenna can reduce the costs associated with the design and manufacture of the antenna.

In addition, since the external structure of the antenna for radiating electromagnetic waves is the same as the conventional sleeve antenna, when installed perpendicular to the ground plane acts as an antenna of the same directing characteristics as the conventional sleeve antenna, and installs a loading coil inside the sleeve And by modifying the structure of the dielectric inside the sleeve to stabilize the broadband and antenna impedance, it is possible to use a communication device in a variety of different frequency bands without installing a separate antenna for each communication band.

Claims (7)

A dielectric core provided with an inner space; A sleeve outer conductor surrounding an outer surface of the dielectric core and connected to an outer conductor of a feed line through a ground plane; A sleeve inner conductor located in the inner space and electrically connecting the inner center conductor of the feeder and the copier; And a loading coil electrically connected in series with the sleeve inner conductor in the inner space. The broadband sleeve antenna of claim 1, wherein first and second sleeve inner conductors are connected to both ends of the loading coil. The broadband sleeve antenna using a loading coil according to claim 1, wherein the dielectric core has a cylindrical shape in which an profile of an inner cross section is formed in an uneven shape. 2. The broadband sleeve antenna of claim 1, wherein another dielectric core and an outer conductor are stacked outside the sleeve outer conductor. The broadband sleeve antenna of claim 1, wherein the copier is divided into two parts and electrically connected to each other via another loading coil. 6. The broadband sleeve antenna of claim 5, wherein the other loading coil is wrapped by a sleeve comprising a different dielectric core and an outer conductor. The broadband sleeve antenna using a loading coil, characterized in that the tubular load is installed on the upper end of the copier.