KR100951157B1 - High Efficiency Wide Band-Width/2 Frequency Patch Antenna - Google Patents

Abstract

The present invention relates to a high-efficiency broadband / 2 frequency patch antenna, wherein a patch antenna is etched differently in a horizontal / vertical length to be resonated at different frequencies on a dielectric substrate to form an antenna that resonates at two specific frequencies, and the feed point is horizontal It is composed of distribution / feeding line that feeds by feeding the signal coming in from the port to the radiator by placing the line dielectric board with the air gap of a certain interval under the dielectric board. As a result, an antenna characteristic of resonating at two frequencies may be obtained by one patch having a different width and length, and a resonance band may also be twice as wide as a conventional method. In addition, it is possible to obtain two resonance frequencies, to maximize the field divergence effect, and to increase the efficiency of the antenna by minimizing the dielectric loss due to the low dielectric constant of the air layer. According to the present invention, since the number of radiators formed on the dielectric substrate is implemented in plural numbers, the gain can be increased and the beam angle can be narrowed, thereby implementing a broadband / 2 frequency high efficiency high gain directional antenna. In addition, by controlling the radiation pattern of the antenna by adjusting the area of the dielectric substrate and the radiator, it is possible to implement an ultra-low back lobe and side lobe antenna, it can be used as an antenna for a high efficiency broadband repeater and base station.

High-Efficiency Patch Antenna, Wideband, Two-Frequency, Ultra-Low Backlobe, High Gain Directional Antenna, Air Layer

Description

High Efficiency Wide Band-Width / 2 Frequency Patch Antenna

The present invention relates to a high efficiency broadband / 2 frequency patch antenna for miniaturizing a transmitter of a base station by applying to a repeater antenna and a base station antenna of a mobile phone and to use it as a base station antenna such as a wireless LAN.

Conventional patch antenna is formed on the dielectric substrate by a technique such as etching to form a radiator in proportion to the antenna frequency of copper foil to feed the signal to the radiator, it is configured to emit an electric field through the dielectric substrate. The radiation of the electric field occurs between the ground plate underneath the substrate of the dielectric substrate and the radiator present on the dielectric substrate, so that the dielectric and dielectric losses of the dielectric substrate are greatly affected by the radiation of the electric field and magnetic field due to the radiation of the electric field and the magnetic field occurring at the dielectric substrate. It has had an effect. In addition, since the size of the patch etched on the dielectric substrate is proportional to the resonance frequency, the resonance frequency and the band are determined according to the size of the pattern-printed patch, making it difficult to obtain broadband characteristics.

Currently, the material mainly used for patch antenna is FR-4 substrate made of epoxy and Teflon and ceramic composite material. These substrate materials are patched because dielectric loss occurs because several different components are mixed together. When the antenna is implemented, the gain of the antenna is lowered and the radiation efficiency is lowered due to the loss of the dielectric substrate. When implementing a 2.4GHz band wireless LAN or WCDMA mobile phone antenna using a general FR-4 board, the gain obtained when the antenna is fabricated by forming 2 * 2 (4) radiators on a 100 * 100mm board is 6 It is typical to achieve ~ 7dBi, radiation efficiency of around 30-40%, and a -10dB frequency band of 5%.

As communication services are diversified and complicated, there are cases where multiple frequencies must be used at the same time. In this case, it is necessary to cope with a multi-frequency communicator with one antenna.

In addition, when the efficiency of the antenna is low, the burden on the transmitter is increased, and the cost of manufacturing a communication device is very high because a high output HPA is required. In the present invention, by solving the problem caused by the low efficiency of the antenna to implement the high efficiency antenna to reduce the output of the transmitter while the purpose of reducing the manufacturing cost of the communicator.

In case of the existing antenna that implements the radiator by etching on the dielectric substrate, the dielectric loss of the dielectric substrate lowers the efficiency of the antenna to 30-40%, resulting in low gain and deterioration of the radiation characteristics of the electric field, resulting in poor back and side lobes. Causes a problem. In addition, since the resonant frequency and the non-frequency band are determined by the size of the etched radiator, it is difficult to obtain a wideband characteristic of resonating several frequencies simultaneously.

The efficiency of the patch antenna formed on the dielectric substrate is due to the dielectric loss of the dielectric substrate. The higher the dielectric constant, the smaller the size of the patch antenna is, but the lower the gain due to the dielectric loss. To this end, the thickness of the dielectric substrate forming the patch antenna is made into a thin film, and a radiator is formed on the thin film by etching or the like, and a gap is placed under the thin film to maintain a space therebetween. A thin film dielectric substrate is arranged, and a feed line for feeding a radiator is pattern-printed on the layer under the ground plate to form an entire antenna. As a result, the dielectric loss generated in the patch antenna using the existing dielectric substrate is replaced with air in the present invention, so that the dielectric loss is hardly generated, thereby increasing the efficiency of the antenna to the maximum. In addition, the dielectric substrate on which the radiator is printed is patterned, and the electric field generated from the radiator and the radiator keeps the direction of the electric field constant along with the ground plate after the air gap, thereby helping to increase the gain and lower the back lobe.

In order to resonate at two frequencies with one radiator, the feed point on the radiator with different horizontal / vertical lengths on the dielectric substrate is fed diagonally to obtain the characteristic of resonating at the two frequencies to have broadband characteristics.

As a result, in the present invention, the dielectric loss generated by the patch antenna using a dielectric substrate having a dielectric constant of about 4.5 to 10 is replaced by air having a dielectric constant of almost 1, thereby reducing the dielectric loss. You can increase the maximum. As a result, in the case of a 2 × 2 patch antenna using a conventional FR-4 substrate, the efficiency is only about 30 to 40%, the frequency band is 5% and the gain is 6 to 7 dBi. By implementing the 2 × 2 patch antenna and using the air gap between the radiator substrate layer and the line layer, the efficiency can be obtained more than 85%, and the frequency non-band at two frequencies can be wider than 19%. It was found that lowering the back lobe by more than 10dBi and -22dB more than the main lobe.

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

1 is a view showing an embodiment according to the present invention. In the embodiment, the validity of the present invention is proved by designing and fabricating an antenna for a repeater corresponding to a frequency of a currently serving WCDMA region. In an embodiment, the radiator 11 of copper foil is implemented by an etching technique on the thin film dielectric substrate 10, and each of the four radiators is determined by etching L and W having a length that resonates at two frequencies, and then The feed point 12 is made at an oblique position. The radiator substrate layer is fabricated and the line dielectric substrate 20 is arranged after having a constant air layer d. Copper foils are formed on the upper surface 21 of the dielectric substrate 20 in contact with the gap d to be coupled to the ground 22 and the through hole 23 of the line dielectric substrate 20. As a result, an air layer having a distance d is formed between the radiator 11 of the radiator substrate layer and the ground plate 21 of the line layer, and an electric field is diverged therebetween, resulting in dielectric loss in the patch antenna formed on the existing dielectric substrate. The part disappears and high efficiency radiation is achieved. In addition, the dielectric substrate 10 in which the radiator 11 is etched, together with the ground plate 21 below a predetermined distance d serves to uniformly spread the electric field radiated from the radiator, thereby gaining due to the uneven stretching of the electric field. This rises and increases the ratio of the back lobe to the main lobe.

To feed a plurality of radiators 11 pattern-printed on the radiator substrate layer 10, a ground coplaner line is formed on the back of the line layer 20, and the input signal coming from the port 24 is ground coplayed. The feed point of the patch antenna after splitting in half through the n-line 25 and the T divider 26 and again transmitting a signal through the line 28 and in a quarter through the T divider 29. Taken to (27) and connected to the feed point 12 of the radiator layer through the feed pin (31). In addition to the T divider, such a divider enables a wider bandwidth of the antenna by using a divider having a wider bandwidth by using a Wilkins divide or the like.

In order to correct an error occurring during the actual substrate etching fabrication process, an open stub 30 is inserted, and after the fabrication, the open stub is adjusted to allow fine adjustment.

In order to maintain a predetermined distance d between the radiator substrate layer 10 and the line layer 20, each of the substrate 10 and 20 is connected to the radiator substrate layer 10 and the line by soldering a support connecting pin 35 to the outside of the substrate 10 and 20. It is attached to the supporting connecting hole 14 of the layer 20 to maintain the spacing. In order to maintain this gap, the gap can be easily maintained by making and inserting a slide for support using a plastic or metal material in addition to the support connecting pin 35.

In the above method, the procedure and results of the design of the mobile phone base station antenna of the WCDMA band using the FR-4 substrate are illustrated. The radiator layer dielectric substrate 10 was made of an FR-4 substrate having a thickness of 0.8 mm, and the line layer dielectric substrate was also formed of four radiators 11 on a 150 * 150 mm substrate size using a material of the same specification. An air gap of 4 mm is connected between the radiator layer substrate 10 and the line layer substrate 20 with a support connecting pin 35 having a diameter of 1 mm, and the signal coming from the port 24 is coplanar line 25 ( 28) and the T dividers (26, 29) through the four distribution and connected to the feed point (27) and through the feed pin 31 connected to the feed point (12) of the radiator to produce an antenna.

The results of the antenna characteristics were confirmed through computer simulations, and the results shown in Tables 1 and 2 were obtained. As shown in Table 1, in the 2GHz WCDMA band, S11 was -10dB, and the frequency non-band was 380MHz, which was more than 19%, gain was obtained more than 10dBi as shown in Table 2, and radiation efficiency was more than 85%. The FB Ratio was also excellent -22 dB. The three-dimensional radiation characteristics and the two-dimensional characteristics of the designed antenna can be seen in FIG. 5, and the shape of the electric field radiated from the radiator for each frequency can be seen in FIG. 6.

By using the above method, the number of radiators can be reduced to make an antenna even with one radiator. As shown in FIG. When the antenna was fabricated by connecting the point with the feed pin, gain could be obtained about 8dBi and efficiency was more than 85%.

In addition, in order to fabricate a higher gain antenna, as shown in FIG. 3, 4 * 4 (16) radiators are formed on a FR-4 substrate having a size of 300 * 300mm as shown in FIG. Incoming signal from the ground coplaner line and T divider is divided into 1/2, 1/4, and 1/16 through the feed point of each radiator, and feed point of radiator layer and feed point Connect with solder. This allows the antenna radiated from the 16 radiators to gain about 16dBi. To get higher gain, increase the number of radiators to 8 * 8, 16 * 16, etc., and the gain can realize more than 16dBi antenna.

Antenna S11 Characteristics min (Ghz) to max (Ghz) Width (Mhz) -10 dB 1.898 (Ghz) to 2.278 (Ghz) 380 (Mhz) -15 dB 1.930 (Ghz) ~ 2.230 (Ghz) 300 (Mhz)

Antenna Gain and Efficiency by Frequency, F-B Ratio Total. efficiency Gain F-B Ratio Phi = 0 Phi = 90 1.97Ghz 0.87 10.18 dB -22.8 dB -22.8 dB 2.16Ghz 0.86 10.92 dB -22.8 dB -23.4 dB

By applying the high-efficiency antenna according to the present invention to a repeater antenna and a base station antenna of a mobile phone, the transmitter of the base station can be miniaturized, and can be used as a high efficiency broadband / 2 frequency patch antenna for a base station such as a wireless LAN.

1: Top, bottom, perspective view of a 2 × 2 radiator patch antenna

2: 1 radiator patch antenna top, bottom view, perspective view

3: Top, bottom, perspective view of a 4 × 4 radiator patch antenna

4: S11 characteristics of a 2 × 2 radiator patch antenna

5: 3D and 2D radiation pattern simulation results of the 2 × 2 radiator patch antenna

6: Frequency Radiation of Frequency by 2 × 2 Radiator Patch Antenna

<Detailed Description of Details>

10: dielectric substrate for radiator, 11: radiator, 12: feed point, 13: cutting surface

14: connection hole for board support

20: track dielectric board, 21: ground board, 22: ground board

23: connection through hole, 24: connection port, 25, 28, 29-1: ground coplaner line

26, 29: T divider, 27: feed point

30: open stub, 31: feed point connecting pin, 35: board support connecting pin

Claims (9)

In the patch antenna, Forming one or more square radiators 11 each having a length L or W corresponding to a resonance frequency on the radiator dielectric substrate 10 by a printing or etching technique; Setting a feed point (12) in the diagonal direction to the radiator; A ground plate 21 is formed on the top surface 21 of the line dielectric substrate 20; A lower surface 22 of the line dielectric substrate 20 includes lines 25 and 28 and a distributor 29 for distributing and connecting signals coming from the port 24; The line dielectric substrate 20 and the radiator dielectric substrate 10 have a constant spacing d; A high efficiency broadband / 2 frequency patch antenna, characterized in that between the feed point 27 of the line layer 20 and the feed point 12 of the radiator layer 10 is connected to the pin 31 for the connection. The method of claim 1, It is characterized by setting the feed point 12 on the radiator dielectric substrate 10 on the square radiator 11 fabricated by an etching technique in the diagonal direction or the diagonal vicinity of the vertex where L or W are combined. High efficiency broadband / 2 frequency patch antenna. The method of claim 1, Characterized in that it is implemented as a coplanar line (25, 28, 29-1) or a microstrip line in order to connect from the input port 24 to the feed point 27 of each radiator on the line dielectric substrate 20 High efficiency broadband / 2 frequency patch antenna. The method of claim 1, A high efficiency broadband / 2 frequency patch antenna, characterized in that a plurality of radiators 11 are formed on the radiator dielectric substrate 10 by printing or etching, such as one or more and four or eight. The method of claim 1, The ground plate 22 around the ground coplanar lines 25, 26, 28, and 29 of the lower surface 22 of the line dielectric substrate 20 and the ground plate 21 on the top surface of the line dielectric substrate 20 High-efficiency broadband / 2 frequency patch antenna, characterized in that the through-holes 23 are processed at a predetermined interval. The method of claim 1, A high efficiency broadband / 2 frequency patch antenna, characterized in that the support connecting pin (35) is fixed while maintaining a predetermined distance d between the radiator dielectric substrate (10) and the line dielectric substrate (20). The method of claim 1, High-efficiency broadband / characterized in that to form a T divider (26, 29) or Wilkins divide, etc. to divide half or quarter of the incoming signal from the port 24 of the dielectric substrate 20 for the line 2 frequency patch antenna. The method of claim 1, High efficiency broadband / 2 frequency patch antenna, characterized in that the support is fixed by a stand of plastic or metal material to maintain a predetermined distance d between the radiator dielectric substrate 10 and the line dielectric substrate 20. The method of claim 1, A high efficiency broadband / 2 frequency patch antenna, characterized in that the matching is controlled by putting an open stub (30), or a short stub on the line before going from the port (24) on the line dielectric substrate (20) to the distributor (26).

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