KR100393017B1 - Microstrip patch array antenna for high frequency transmitter- receiver - Google Patents

Abstract

An antenna of the present invention relates to an antenna capable of transmitting and receiving radio waves in a 10 GHz to 12 GHz frequency band belonging to a KU band among centimeter waves (SHFs). The antenna includes a frit dielectric substrate formed in a quadrangle shape, and is provided on an upper portion of the printed dielectric substrate. It is formed of copper material to receive 10GHz ~ 12GHz frequency signals belonging to the centimeter wave KU-BAND at intervals of, and reduces the beam width of radio waves to form patch elements to benefit long-distance communication using microwave waves. The strip lines are arranged on a printed dielectric substrate having separate strip lines arranged to collect frequencies of the 10 GHz to 12 GHz band received through the patch element, and the print dielectric substrate and the printed dielectric substrate on which the strip lines are arranged are predetermined. The frit dielectric in a state spaced apart from each other The cable 30 is installed on the strip line 21 of the printed dielectric substrate in which the strip lines are arranged so as to transmit and receive radio waves transmitted and received through the patch elements of the substrate. It is easy to manufacture, low weight and small size can be produced by using a flat surface, and the manufacturing cost and installation cost of the antenna are drastically reduced.

Description

Microstrip patch array antenna for high frequency transmitter-receiver

The present invention relates to a planar microstrip patch array antenna capable of transmitting / receiving at a frequency for KU-BAND (10 GHz to 12 GHz), and more particularly, to miniaturize the antenna for easy portability and easy installation. To develop a gain antenna. In addition, the designed antenna has a voltage standing wave ratio (VSWR) indicating efficiency of less than 1.5 and the reception gain (GAIN) relates to a microstrip patch array antenna for high frequency transmission and reception of 32db or more.

Generally, it is one of the flat antennas, and one of the conductive plates bonded to both sides of the insulator is made of a strip (thin steel plate), which is called a microstrip line. Because it is named micro.

The strip and the conductor plate become two feed lines, which become the line, and the strip line is cut from the terminal to the half-wave position, and instead of the transmission line, the microstrip is fed to the coaxial line from the bottom side of the strip instead of the transmission line. The wider the strip, the wider the frequency bandwidth and the easier it is to radiate radio waves, and the microstrip antenna in the forward direction is referred to as a square patch antenna and a circular patch antenna. It is suitable for mass production because it is made in high quality, and it has various features such as low height and flatness so that it is widely used as an array antenna element requiring a large number of small antennas. Remove the antenna 1/4 wavelength behind and place it in proper impedance Belongs and works as a reflector (反射 器), are mainly used in short-wave communication (短波 通信) between International. As the nominal frequency band which is mainly used, the frequency band above 10GHz with increasingly widely used in satellite communications. There is no single frequency range that is clearly determined, but it is a frequency band of 12.5-18 GHz, or 12-14 GHz, depending on the country and institution. Generally referred to as `` K-BAND '', the antenna manufactured by using a printed circuit board with a communication antenna through a conventional KU-BAND is heavy and difficult to miniaturize. When determining the beam width, there is a problem that it is difficult to reduce the size because the strip line and the strip line connected between the patch elements are installed on one printed dielectric substrate, and the size of the printed dielectric substrate cannot be reduced. There was a problem that the installation work takes a lot of time, causing an increase in installation costs due to the increase in labor costs.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above problems, and an object of the present invention is to provide a high-gain antenna having a low cost by miniaturizing the antenna for easy portability and easy installation. It is an object of the present invention to provide a microstrip patch array antenna for transmitting / receiving high frequency signals having a voltage standing wave ratio (VSWR) of 1.5 or less and a gain of 32 dB or more. (Beam width) should be designed to be less than 5 degrees so that it can be advantageously applied for radio transmission and reception in tunnels, highway installation, and long-distance wireless communication between radio base stations. Especially, radio wave straightness (LOS, LINE-OF-SIGHT) Microstrip Patch Array Antenna for Transmitting and Receiving High Frequency Applications as Sensors for Magnetic Fence Another object of the present invention is to provide an antenna capable of transmitting and receiving radio waves in a 10 GHz to 12 GHz frequency band belonging to a KU-BAND. It is formed of the same material so as to receive a frequency signal in the 10GHz ~ 12GHz band belonging to the centimeter wave KU-BAND at a predetermined interval on the printed dielectric substrate, and by reducing the beam width of the radio wave for long-distance communication using microwave wave The patch element is advantageously formed, and the strip line is arranged on a printed dielectric substrate having separate strip lines arranged to collect frequencies of the 10 GHz to 12 GHz band received through the patch element. Position the printed dielectric substrate spaced apart by a predetermined distance Microstrip for high frequency transmission and reception, characterized in that the cable 30 is installed on the strip line 21 of the printed dielectric substrate in which the strip line is arranged to transmit and receive radio waves transmitted and received through the patch element of the frit dielectric substrate in a state. A patch array antenna is also provided. The patch element according to the present invention is characterized in that the strip line 12 is connected so that four of the patch elements are provided. Also, the reception angle (beam width) of the radio wave according to the present invention is 5 degrees ( In addition, the beam width is small according to the present invention, it is characterized in that the sensor for the electromagnetic fence (magnetic fence) as well as the communication between the long-distance base station or the radio wave transmission in the tunnel.

1 is a microstrip patch array antenna for KU (X) -BAND according to the present invention.

2 is a microstrip coupling circuit coupling the patch element arrangement of FIG.

3 is a micro strip patch array antenna for KU-BAND showing another embodiment of FIG.

4 is a microstrip coupling circuit combining the patch element arrangement of FIG.

Fig. 5 is a side view of the antenna according to Figs. 1 and 2 or according to Figs. 3 and 4. * Description of the symbols for the main parts of the drawings * 10 Printed dielectric substrate 11 Patch element 12 Strip line 20 Strip line Arranged dielectric printed circuit board 21 Strip line 30 Cable

Hereinafter, a high frequency microstrip patch array antenna according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a microstrip patch array antenna for KU (X) -BAND according to the present invention, FIG. 2 is a microstrip coupling circuit for coupling the patch element arrangement of FIG. 1, and FIG. 3 shows another embodiment of FIG. Micro strip patch array antenna for KU-BAND, FIG. 4 is a micro strip coupling circuit diagram combining the patch element arrangement of FIG. 3, and FIG. 5 is a side view of the antenna according to FIGS. 1 and 2 or 3 and 4. .

As shown in FIG. 1 or 2, the present invention includes a frit dielectric substrate 10 formed in a quadrangular shape, and includes a frit dielectric substrate 10 formed at a predetermined interval on an upper portion of the printed dielectric substrate 10 and belonging to a centimeter wave KU-BAND. The patch element 11 is formed of the same material so as to receive a frequency signal in the 12 GHz band, and the beam width of the radio wave is reduced so as to be advantageous for long distance communication using microwave waves.

As shown in FIG. 1, the patch element 11 connects the strip line 12 such that four patch elements 11 are in a set.

In addition, the stripline 21 is arranged on the printed dielectric substrate 20 in which a separate stripline is arranged to collect frequencies of the 10 GHz to 12 GHz band received through the patch element 11, as illustrated in FIG. 2 or 4. In addition, as illustrated in FIG. 5, the frit dielectric substrate 910 in a state where the printed dielectric substrate 10 and the printed dielectric substrate 20 on which the strip lines are arranged are spaced apart from each other at a predetermined interval. The strip line 21 of the printed dielectric substrate 20 having the strip line arranged thereon is connected through the cable 30 so as to transmit and receive the radio wave transmitted and received through the patch element 11. Transmission and reception of radio waves by connecting the radio waves transmitted and received through the patch element 11 of the printed dielectric substrate 10 with the strip lines 21 of the printed dielectric substrate 20 having the strip lines arranged thereon. The operation effect of the high frequency transmission and reception microstrip patch array antenna according to the present invention configured as described above is as follows. The present invention provides a dielectric printed circuit board 10 having a dielectric constant E of 3 or less. The circuit is constructed using a thin film printed dielectric substrate 10 having a dielectric constant so that the patch elements 11 are connected to the distribution circuit using the strip line 12 to reduce the loss and to collect radio waves in one place to increase the reception sensitivity. The patch elements 11 are arranged as shown in FIG. 1 or 3, and the strip lines 12 are connected to connect them to each other to couple the signals. Here, the size of the patch elements 11 is related to the frequency and the strip lines ( The length and thickness of 12 are determined by the permittivity of the printed dielectric substrate 10, and the strip line 12 and the printed dielectric substrate 10 is typically determined using a formula for determining the size of the patch element 11. Then, on the copper foil printed dielectric substrate 10 having the dielectric constant, the strip line 12 as shown in FIG. 1 and 3 to combine the signals received through the patch element 11 of Fig. 1 or 3 or to overlap the 3 and 4 overlapping up and down to assemble a planar antenna as shown in FIG. In addition, since the beam width of the antenna configured as described above is small, the antenna has a feature that it can be used as a sensor for an electromagnetic fence as well as communication between long distance base stations or a radio wave transmission in a tunnel. Designed for 10 GHz to 12 GHz), it has a voltage standing wave ratio (VSWR) of 1.5 or less, gain (GAIN) of 30 db or more, beam width of 5 degrees or less, and radio wave reception as well as transmission. The KU-BAND communication antenna can be manufactured in a flat surface using a printed board, which is easy to manufacture, low in weight and small in size, and greatly reduces the manufacturing cost and installation cost of the antenna, and enables an antenna having high gain. As described above, the planar microstrip patch array antenna of the present invention can easily adjust the transmission / reception width (beam width) of the radio wave in the present invention. Instead, the antenna is designed to increase the transmission / reception gain of the radio wave to be advantageous for the long-distance communication using the microwave. Furthermore, since the frequency of the radio wave is high, the linearity (LOS, LINE-OF-SIGHT) is large, which is why the antenna of the present invention is used. Can be used for electromagnetic fences with a small beam width As an antenna, it is within the scope of the present invention to distribute small patch elements in an array using a printed substrate having a low dielectric constant (E) so that each patch receives a signal and merges them using a stripline to increase reception gain. can do.

Looking at the effect of the high-frequency transmission and reception microstrip patch array antenna according to the present invention, by manufacturing the KU-BAND communication antenna in a flat surface using a printed board, easy to manufacture, low weight, miniaturization and breakthrough manufacturing cost and installation cost of the antenna In addition, the antenna with high gain is possible, so that it can be installed not only outdoors but also indoors.In addition, the beam width of the antenna is small, and the electromagnetic field fence ( It can be used as a sensor for magnetic fence.

Claims (4)

In the antenna which can transmit and receive an electric wave in the frequency band of 10GHz-12GHz belonging to KU-BAND, A frit dielectric substrate is formed in a rectangular shape, and is formed of the same material so as to receive frequency signals in the 10 GHz to 12 GHz band belonging to the centimeter wave KU-BAND at predetermined intervals on the printed dielectric substrate, and the beam width of the radio wave. The patch element to form a patch element for the long-distance communication by using a microwave wave, and the strip line is arranged on a printed dielectric substrate in which a separate strip line is arranged to collect frequencies of the 10 GHz to 12 GHz band received through the patch element. Strip lines are arranged to transmit and receive radio waves transmitted and received through a patch element of the frit dielectric substrate in a state where the printed dielectric substrate and the printed dielectric substrate on which the strip lines are arranged are spaced apart at a predetermined interval. Stripline 21 of Printed Dielectric Substrate Microstrip for high-frequency transmission and reception, characterized in that the cable 30 is installed, the patch array antenna. The method of claim 1, The patch element is a high-frequency transmission and reception microstrip patch array antenna, characterized in that for connecting the strip line (12) to a set of four. The method of claim 1, A microstrip patch array antenna for high frequency transmission and reception, characterized in that the reception angle (beam width) of radio waves is 5 degrees or less. The method of claim 1, A microstrip patch array antenna for high frequency transmission and reception, characterized by a small beam width, which is a sensor for an electromagnetic fence as well as communication between long distance base stations and radio waves in a tunnel.