KR100888645B1 - Film type antenna for wireless communication equipment - Google Patents

Abstract

Disclosed is a film antenna for a wireless communication device. The dielectric film consists of a thin film of insulating material. The signal line is formed on the dielectric film in the form of a metal thin film, and one end is electrically connected to the transmission output circuit of the wireless communication device to receive RF current, and the other end radiates the RF current to free space. The first ground line and the second ground line are respectively formed on the dielectric film in the form of a metal thin film, and are formed parallel to the signal line by being spaced apart by a predetermined first interval on one side and the other side of the signal line. The third grounding line and the fourth grounding line are formed on the dielectric film, respectively, and are made of a metal thin film having a 'c' shape, and the inner side line among the inner side lines and the outer side lines parallel to each other is the first grounding line and the second grounding line. The signal line is spaced apart from the signal line by a first interval, and the end of the inner line is spaced apart from the end of the first ground line and the second ground line by a predetermined second interval. In addition, each of the third ground line and the fourth ground line is bent in a 'c' shape at a point separated from the other end of the signal line by one quarter of the frequency band used, and the third ground line and the fourth ground line respectively. The length of the outer line of the antenna is 1/4 of the band frequency wavelength used, and the area from one end of the signal line to the outer line of the third ground line and the end of the outer line of the fourth ground line is an equiplanar waveguide. Form all. According to the present invention, it is possible to eliminate the assembly process of each part, mass production is possible, thereby reducing the manufacturing cost.

Description

Film type antenna for wireless communication equipment

The present invention relates to a film-type antenna for a wireless communication device, and more particularly to a small film-type antenna that can be embedded in a wireless communication device.

At present, methods for embedding the antenna inside the case of the wireless communication device have been proposed due to inconvenience in using the antenna attached to the outside of the case of the wireless communication device. Existing external antennas used are sleeve dipole antennas using coaxial cables.

1 is a cross-sectional view showing the configuration of a conventional sleeve dipole antenna.

Referring to FIG. 1, a conventional sleeve dipole antenna includes a coaxial cable 110, a sleeve 120, a housing 130, and a connector 140. The center conductor 150 of the coaxial cable 110 is exposed to the outside by a quarter length of the frequency band used, the outer conductor of the coaxial cable 110 is sleeve 120 at the point where the center conductor 150 is exposed. Is electrically connected to the top of the Sleeve 120 is made of a conductive material, the length of the sleeve 120 is 1/4 of the band frequency wavelength used. The housing 130 accommodates the coaxial cable 110 and the sleeve 120, and the connector 140 is a means for electrically and physically connecting the sleeve dipole antenna to a mobile communication device, a wireless device, and the like. This prior art sleeve dipole antenna generally has a gain of 2 dBi or less.

However, such a conventional sleeve dipole antenna has a problem of low gain, and is not suitable for embedding in a wireless communication device which is miniaturized and light in terms of size, thickness, and weight. In addition, since a complicated manufacturing process is required, it is not suitable for mass production, and there is a problem that it is difficult to obtain uniform characteristics due to a deviation in antenna characteristics due to a complicated manufacturing process.

Due to this problem, a method of forming an antenna having the same function as the sleeve dipole antenna as shown in FIG. 1 has also been proposed. However, even in the case of the antenna formed on the printed circuit board, a separate connector is required to connect the antenna to the PCB main body of the wireless communication device, and in the case of the printed circuit board, there is a problem in that the arrangement position of the antenna is limited.

The technical problem to be achieved by the present invention is to provide a film-type antenna for a wireless communication device, the manufacturing process is simple, compact, and the freedom of the long position.

In order to achieve the above technical problem, a preferred embodiment of the film-type antenna for a wireless communication device according to the present invention, a dielectric film made of a thin film of insulating material; A signal line formed on the dielectric film, one end of which is electrically connected to a transmission output circuit of a wireless communication device to receive RF current and the other end of which a metal thin film type signal line radiates the RF current into a free space; A first ground line formed on the dielectric film, the first ground line being formed in parallel with the signal line by being spaced apart by a predetermined first interval on one side of the signal line; A second ground line formed on the dielectric film, the second ground line having a metal thin film shape formed on the other side of the signal line and being spaced apart by the first interval in parallel with the signal line; The inner line is formed on the dielectric film, and is formed of a metal thin film having a 'c' shape, and the inner line of the inner line and the outer line parallel to each other is spaced apart from the signal line by the first interval in the longitudinal direction of the first ground line. A third ground line spaced apart from the end of the first ground line by a predetermined second interval; And a metal thin film having a 'c' shape, formed on the dielectric film, and the inner line of the inner line and the outer line parallel to each other by the signal line and the first interval in the longitudinal direction of the second ground line. And a fourth ground line spaced apart from each other by an end of the inner line, the second ground line being spaced apart from the end of the second ground line by the second interval, wherein each of the third ground line and the fourth ground line is the signal line. It is bent in a 'c' shape at a quarter of the use band frequency wavelength from the other end of the furnace, and the length of the outer line of each of the third and fourth ground lines is 1 of the use band frequency wavelength. / 4, and the area from one end of the signal line to the outer line of the third ground line and the end of the outer line of the fourth ground line is in the form of a coplanar waveguide (CPW) type. To form a whole.

According to the film-type antenna for a wireless communication device according to the present invention, it is possible to eliminate the assembly process of each component in the manufacture of the antenna, mass production is possible, thereby reducing the overall manufacturing cost. In addition, since it is manufactured in the form of a structurally flexible thin film, it can be miniaturized in terms of size and thickness, and can be easily inserted into a gap between circuit components or a board inside a case of a wireless communication device. Furthermore, by discontinuously cutting the middle portions of both side ground lines in an isoplane waveguide line, the use frequency bandwidth can be widened to a wider bandwidth.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of a film-type antenna for a wireless communication device according to the present invention.

2 is a plan view of a film-type antenna for a wireless communication device according to the present invention, Figure 3 is a cross-sectional view of the film-type antenna for a wireless communication device according to the present invention shown in FIG. It is sectional drawing.

2 and 3, the film-type antenna 200 for a wireless communication device according to the present invention includes a dielectric film 250, a signal line 260, a first ground line 270, and a second ground line 275. ), A third ground line 280 and a fourth ground line 285.

The dielectric film 250 is a thin film having a relative dielectric constant of epsilon _r of an insulator material having no conductivity, and determines the shape of the film antenna 200. The signal line 260 and the ground lines 270 to 285 in the form of a metal thin film are formed on the dielectric film 250 by a plating and etching process. The signal line 260 is made of a conductive thin metal line, and the length of the portion 240 in which the ground lines 270, 275, 280, and 285 do not exist on both sides forms a radiation portion at a quarter of the frequency band used. .

The first ground line 270 and the second ground line 275 start from a point spaced a predetermined distance from one end of the signal line 260, which is a connection portion that is fed to the transmission output circuit of the wireless communication device. 260 and s arranged in parallel. The third ground line 280 and the fourth ground line 285 are symmetrical with the signal line 260 at intervals in the length direction of the first ground line 270 and the second ground line 275. Are arranged on both sides of the Thus, the frequency of use of the antenna is formed by forming discontinuous points 290 and 295 between the first ground line 270 and the third ground line 280 and between the second ground line 275 and the fourth ground line 285. You can broaden your bandwidth to more broadband. In this case, the third ground line 280 and the fourth ground line 285 are disposed in parallel with the signal line 260 at an interval of s.

Meanwhile, the third ground line 280 and the fourth ground line 285 are manufactured in the same shape and have a '-' shape at a point separated by 1/4 of the band frequency wavelength from the other end of the signal line 260. Is bent into. In this case, the lengths of the outer lines of the third ground line 280 and the fourth ground line 285 that are bent in a 'c' shape are one fourth of the frequency band used. As such, the outer lines of the third ground line 280 and the fourth ground line 285 having a 'c' shape function as a sleeve. The first ground line 270 to the fourth ground line 285 are made of a conductive thin metal line and are grounded to the same ground terminal.

The film-type antenna 200 according to the present invention having the above configuration has an outer side of the third ground line 280 from one end of the signal line 260, which is a connection portion fed to the transmission output circuit of the mobile communication device. An area region between the end of the side line and the end of the outer line of the fourth ground line 285 forms a feed part 210 in the form of a coplanar waveguide (CPW). As such, when the feed part 210 having the planar waveguide line is formed, the antenna can be directly connected to the circuit board of the wireless communication device by flip chip bonding or soldering without a separate connector. The characteristic impedance of the isoplanar waveguide line is the relative dielectric constant (ε _r ) and thickness (h) of the dielectric film 250 used, and the thickness (t) and width (W) of the conductor used as the signal line 260. Determined by For example, the dielectric constant ε _r = 2.6 of the dielectric film 250, the interval s = 1 mm between the signal line 260 and the ground lines 270 and 275, the thickness h of the dielectric film 250 h = 0.6 mm, and the signal line When the thickness t of the furnace 260 is 18 μm and the band frequency f is 800 MHz, the width of the signal line 260 is W = 0.085 in order for the isotropic waveguide line to have a characteristic impedance of 50 Ω, which is the characteristic impedance of a commercial coaxial cable. What is necessary is just to set it to mm. At this time, if a dielectric sheet made of a material having a high dielectric constant is used, the circuit can be miniaturized.

On the other hand, a region in which all of the first grounding line 270 to the fourth grounding line 285 overlaps constitutes the first sleeve 220. Therefore, the RF current supplied to one end of the signal line 260 is the first sleeve ( Reflected at the end point of 220 and branched from the signal line 260 to the first ground line 270 and the second ground line 275, which is again the third ground line 280 and the fourth ground line 285 The first current path is formed to flow into the outer line of the flow toward the feeder 210. In addition, the area from the end points of the first ground line 270 and the second ground line 275 to the start point of the portion 240 where the ground line does not exist on both sides of the signal line 260 is the second sleeve 230. ). Therefore, the RF current flowing in the signal line 260 is branched again at the starting point of the portion 240 in which the ground line does not exist on both sides of the signal line 260, so that the third ground line 280 and the fourth ground line ( 285 is introduced into the outer lines of the third ground line 280 and the fourth ground line 285 to form a second current path flowing toward the feed section 210. Since the current flowing through the first current path and the current flowing through the second current path have a phase difference of 180 °, they are canceled and extinguished with each other, thereby improving the reflection coefficient characteristics of the antenna. The RF current directed toward the other end of the 260 is radiated into the free space at the end of the radiating part 240 which is a portion where the ground line does not exist on both sides of the signal line 260.

4A and 4B show a vertical polarization elevation angle pattern and a vertical polarization azimuth pattern of a film-type antenna according to the present invention designed as an internal antenna of an indoor fixed telephone of a wireless subscriber network (WLL) wireless telephone used in the 800 MHz band, respectively. One drawing.

4A and 4B, the film antenna according to the present invention has a beam peak of -1.60 dBi at -165.00 deg, a beam width of -3.00 deg at 64.57 deg, and a right lobe of -78.00 deg in the vertical polarization elevation pattern. At -25.27dB, the left lobe is -11.64dB at 90.00deg, and the fore and aft ratio is 0.04dB at -171.00deg. In the case of the vertically polarized azimuth pattern, the beam peak is 0.06 dBi at 104.00 deg and the front and rear ratio is 0.13 dB at 173.00 deg.

Although the preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific preferred embodiments described above, and the present invention belongs to the present invention without departing from the gist of the present invention as claimed in the claims. Various modifications can be made by those skilled in the art, and such changes are within the scope of the claims.

1 is a cross-sectional view showing the configuration of a conventional film antenna,

2 is a plan view of a film antenna according to the present invention;

3 is a cross-sectional view showing a cross-sectional view of the film-type antenna according to the present invention shown in Figure 2 based on the line A-A ',

4A and 4B show a vertical polarization elevation angle pattern and a vertical polarization azimuth pattern of a film-type antenna according to the present invention designed as an internal antenna of an indoor fixed telephone of a wireless subscriber network (WLL) wireless telephone used in the 800 MHz band, respectively. One drawing.

Claims (2)

A dielectric film made of a thin film of an insulating material; A signal line formed on the dielectric film, one end of which is electrically connected to a transmission output circuit of a wireless communication device to receive RF current and the other end of which a metal thin film type signal line radiates the RF current into a free space; A first ground line formed on the dielectric film, the first ground line being formed in parallel with the signal line by being spaced apart by a predetermined first interval on one side of the signal line; A second ground line formed on the dielectric film, the second ground line having a metal thin film shape formed on the other side of the signal line and being spaced apart by the first interval in parallel with the signal line; The inner line is formed on the dielectric film, and is formed of a metal thin film having a 'c' shape, and the inner line of the inner line and the outer line parallel to each other is spaced apart from the signal line by the first interval in the longitudinal direction of the first ground line. A third ground line spaced apart from the end of the first ground line by a predetermined second interval; And The inner line is formed on the dielectric film, and is formed of a metal thin film having a 'c' shape, and the inner line of the inner line and the outer line parallel to each other is spaced apart from the signal line by the first interval in the longitudinal direction of the second ground line. And an end of the inner line, the fourth ground line being spaced apart from the end of the second ground line by the second interval. Each of the third ground line and the fourth ground line is bent in a 'c' shape at a point separated from the other end of the signal line by one quarter of a frequency band used, The length of the outer line of each of the third ground line and the fourth ground line is one fourth of the frequency band used, The area from one end of the signal line to the outer line of the third ground line and the end of the outer line of the fourth ground line forms a feed part in the form of a coplanar waveguide (CPW). Film type antenna for wireless communication device. The method of claim 1, And the power supply unit is directly connected to the circuit board of the wireless communication device by flip chip bonding or soldering.

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