KR100732914B1 - Structure of micro-strip patch antenna - Google Patents

Abstract

Disclosed is a structure of a microstrip patch antenna. The structure of the microstrip patch antenna according to the present invention includes a plurality of microstrip patch antennas each having a different frequency characteristic and arranged in layers, and a feeding pin through a plurality of microstrip patch antennas and receiving satellite signals. It is characterized by including. As a result, two or more different satellite signals may be received, and even when mounted on a vehicle, a characteristic change or two overlapping patch antennas may be fixed without being separated by vibration.

Microstrip Patch Antenna, Conductive Material, Feeding Pin, GPS, DMB, DAB

Description

Structure of micro-strip patch antenna

1 is a view showing a microstrip patch antenna according to the prior art,

2 is a view showing an embodiment of a microstrip patch antenna structure according to the present invention,

3 is a view showing another embodiment of a microstrip patch antenna structure according to the present invention;

4 is a view showing another embodiment of a microstrip patch antenna structure according to the present invention;

5 is a view showing another embodiment of a microstrip patch antenna structure according to the present invention;

6 is a view showing another embodiment of a microstrip patch antenna structure according to the present invention, and

7 is a view showing another embodiment of a microstrip patch antenna structure according to the present invention.

Explanation of symbols on the main parts of the drawings

11, 21, 31, 41, 51, 61: dielectric

13, 23, 33, 43, 53, 63: conductive material

15, 25, 35, 45, 55, 65: feeding pin

27, 37, 47, 57, 67: solder (adhesive)

69: conductive surface for adhesion

The present invention relates to a microstrip patch antenna structure, and more particularly, to two or more satellite signals different from each other such as a GPS (Global Positing System) and a Digital Multimedia Broadcasting (DMB) or a GPS and a Digital Audio Broadcasting (DAB) signal. The present invention relates to a microstrip patch antenna structure capable of receiving and fixing a characteristic change or two overlapping patch antennas without separation by vibrating the vehicle.

In general, a microstrip patch antenna is a type of antenna that has a light weight, space-saving planar structure and can have the greatest gain and directivity in a given space. In addition to being used as an integrated communication relay antenna, its application range is wide.

Microstrip patch antenna is one of the planar antennas. One of the conductor plates bonded to both sides of the insulator is made of strip (thin steel plate), and it is called microstrip line. It is named micro because it can be structured. Here, the strip and the conductor plate become two feed lines. It is the microstrip antenna that cuts the strip line from the end to half-wavelength position and feeds the coaxial line on the underside of the fingerboard with a cross point in the center of the strip instead of the transmission line. The wider the strip of the microstrip patch antenna, the wider the frequency bandwidth and the easier it is to radiate radio waves. A microstrip antenna in the forward direction is called a square patch antenna and a circular patch antenna is used. Since the microstrip antenna is made of printed board, it is suitable for mass production, and has various advantages such as low height and flatness. Microstrip antennas, on the other hand, are generally characterized by their small frequency and low efficiency, but have been recently researched and developed because of their advantages.

FIG. 1 is a view showing a structure of a typical patch antenna having a circular polarization characteristic in which an electric field is rotated along an advancing axis with respect to a single specific frequency by using a coupling between an antenna in a direction and a direction in a direction. . Referring to the drawings, the conductive material 13 is applied to both sides of the dielectric 11, the feeding pin 15 is provided near the center of the dielectric (11). As shown in Fig. 3, when the C-picking of the conductive material 13, the circular polarization direction is determined by the direction of the C-picking, and when the C-picking is performed on the ① antenna, the RHCP (Right Hand Circular Polarization) is realized. Done.

However, the conventional method as shown in FIG. 1 is a method of implementing only a single frequency antenna among GPS, DAB, and DMB using a single patch antenna, and in case of implementing GPS, DAB, and DMB antennas in a set, for each frequency. Each antenna is required, and in this case, there is a possibility that antenna characteristics are degraded because frequency interference and matching between the patch antennas are difficult to match.

In addition, when the GPS, DAB, and DMB antennas are respectively implemented in the set, the size of the set is not only increased, but when such an antenna is mounted in a vehicle, each frequency characteristic is separated by vibration to change characteristics. There is a problem that occurs.

The present invention was devised to solve the above problems, and can receive two or more different satellite signals, such as GPS and DMB, or GPS and DAB signals, and changes characteristics due to vibration even when mounted on a vehicle. It is another object of the present invention to provide a microstrip patch antenna structure in which two overlapping patch antennas can be fixed without being separated.

Microstrip patch antenna structure according to the present invention for achieving the above object, each having a different frequency characteristics, a plurality of microstrip patch antennas arranged in layers; And one feeding pin penetrating the plurality of microstrip patch antennas and receiving satellite signals.

Preferably, the plurality of microstrip patch antennas are adhered to each other by solder of tin or lead.

Alternatively, the plurality of microstrip patch antennas may be adhered to each other by an adhesive material.

Preferably, the feeding pin is short with the conductive surface located on the top of the upper microstrip patch antenna among the plurality of microstrip patch antennas, and the conductive surface and the lower microstrip on the lower side of the upper layer for impedance matching. It is open with the conducting surface located at the top and bottom of the patch antenna.

Here, in the microstrip patch antenna structure according to the present invention, the conductive surface located at the bottom of the microstrip patch antenna of the upper layer of the plurality of microstrip patch antennas may be removed to reduce manufacturing costs.

In addition, in the microstrip patch antenna structure according to the present invention, the conductive surface located at the bottom of the microstrip patch antenna of the lower layer of the plurality of microstrip patch antennas may be removed to reduce manufacturing costs.

As a result, the microstrip patch antenna can receive two or more different satellite signals, such as GPS and DMB or GPS and DAB signals. It can be fixed without being separated.

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

2 is a view schematically showing the structure of a microstrip patch antenna according to the present invention. Referring to the drawings, the structure of the microstrip patch antenna according to the present invention has a different frequency characteristic, each of which has a plurality of microstrip patch antennas arranged in layers and through a plurality of microstrip patch antennas to receive satellite signals One feeding pin 25 is included. Although a plurality of microstrip patch antennas are illustrated as being implemented with a GPS antenna and a DMB antenna in the drawings, the present invention is not limited thereto and may be modified in various forms such as a GPS antenna and a DAB antenna.

Here, the dielectric material 21 of each microstrip patch antenna is coated with a conductive material 23 having a rectangular shape on the front and rear surfaces thereof. In this case, the dielectric constant or thickness of each microstrip patch antenna does not need to be the same as each other due to the characteristics of the antenna, and may be implemented differently as necessary. In addition, as illustrated, the conductive surface formed on each of the plurality of microstrip patch antennas has a larger pattern area of the conductive surface formed on the lower microstrip patch antenna than the pattern area of the conductive surface formed on the upper microstrip patch antenna. It is preferably formed. The same applies to other embodiments of the microstrip patch antenna structure according to the present invention.

Feeding pins 25 penetrating the upper microstrip patch antenna (DMB antenna) and the lower microstrip patch antenna (GPS antenna) are positioned at the top of the upper microstrip patch antenna (DMB antenna) for impedance matching. Short with the drawing, it is preferable to penetrate so as to be open with a conductive surface located at the bottom of the upper layer and a conductive surface located at the top and bottom of the microstrip patch antenna (GPS antenna) of the lower layer.

In addition, the upper microstrip patch antenna (DMB antenna) and the lower microstrip patch antenna (GPS antenna) are mutually bonded by solder (Sn) or lead (Pb) component or adhesive material 27. It is preferred to be fixed without separation.

Thus, it is possible to receive two or more desired satellite signals of different frequencies with one feeding pin, and even when the vehicle is vibrated, two overlapping patch antennas can be firmly fixed without being separated from each other. In addition, since two signals are received by one feeding pin, the volume of the patch antenna can be reduced, and in the case of implementing a low noise amplifier (LNA) stage for amplifying a signal later, two primary LNA stages are used. It is possible to amplify the branch signals at the same time, thereby reducing the cost and miniaturization of the product.

3 is a view showing another embodiment of a microstrip patch antenna structure according to the present invention. Referring to the drawings, the structure of the microstrip patch antenna is a microstrip patch antenna (DMB antenna) of the upper layer from which the conductive surface at the bottom is removed, and a microstrip patch antenna of the lower layer coated with the conductive material 33 on the upper and lower ends thereof. GPS antenna), and one feeding pin 35 penetrating the upper microstrip patch antenna (DMB antenna) and the lower microstrip patch antenna (GPS antenna). In this case, the upper microstrip patch antenna (DMB antenna) and the lower microstrip patch antenna (GPS antenna) are preferably bonded by solder or adhesive material 37 as in the embodiment of FIG. 2. The same applies to other embodiments of the microstrip patch antenna structure according to the present invention.

In addition, the feeding pin 35 is shorted with a conductive surface located at the top of the upper microstrip patch antenna (DMB antenna) for impedance matching, and a conductive surface located at the bottom of the upper layer and the microstrip patch antenna of the lower layer ( It is preferable to penetrate so as to be open with the conductive surfaces located at the top and bottom of the GPS antenna.

4 is a view showing another embodiment of a microstrip patch antenna structure according to the present invention. Referring to the drawings, the structure of the microstrip patch antenna is an upper layer of the microstrip patch antenna (DMB antenna) from which the conductive surface at the bottom is removed, and the conductive layer 43 is coated on the upper layer and the lower layer is removed. A microstrip patch antenna (GPS antenna), and one feeding pin 45 penetrating the upper microstrip patch antenna (DMB antenna) and the lower microstrip patch antenna (GPS antenna).

Here, the feeding pin 45 is short with the conductive surface located at the top of the upper microstrip patch antenna (DMB antenna) for impedance matching, and the conductive surface and the microstrip patch antennas at the bottom of the upper layer ( It is preferable to penetrate so as to be open with the conductive surface located at the top of the GPS antenna).

5 is a view showing another embodiment of a microstrip patch antenna structure according to the present invention. Referring to the drawings, the structure of the microstrip patch antenna, the upper and lower microstrip patch antenna (DMB antenna) is coated with a conductive material 53, the conductive material 53 is applied to the top and the conductive material at the bottom The removed microstrip patch antenna (GPS antenna), and one feeding pin 55 penetrating the upper microstrip patch antenna (DMB antenna) and the lower microstrip patch antenna (GPS antenna).

Here, the feeding pin 55 is short with the conductive surface located on the top of the upper microstrip patch antenna (DMB antenna) for impedance matching, and the conductive surface located on the bottom of the upper layer and the microstrip patch antenna of the lower layer ( It is preferable to penetrate so as to be open with the conductive surface located at the top of the GPS antenna).

6 is a view showing another embodiment of a microstrip patch antenna structure according to the present invention. Referring to the drawings, the structure of the microstrip patch antenna is a top layer microstrip patch antenna (DMB) having at least one conductive surface 69 of a predetermined area where a conductive material 63 is coated on the top and soldered on the bottom. Antenna), a lower layer microstrip patch antenna (GPS antenna) coated with a conductive material 63 on the top and bottom, and an upper layer microstrip patch antenna (DMB antenna) and a lower layer microstrip patch antenna (GPS antenna). It includes a feeding pin (65).

Here, the feeding pin 65 is short with the conductive surface located on the top of the upper microstrip patch antenna (DMB antenna) for impedance matching, and the conductive surface and the microstrip patch antennas under the upper layer ( It is preferable to penetrate so as to be open with the conductive surfaces located at the top and bottom of the GPS antenna.

7 is a view showing another embodiment of a microstrip patch antenna structure according to the present invention. As shown, the top surface of the microstrip patch antenna can be implemented in various shapes, regardless of the pattern of the top surface of the microstrip patch antenna, a plurality of patch antennas are overlapped and a satellite signal is received using one feeding pin. It may be implemented to.

The structure of the microstrip patch antenna according to the present invention is capable of receiving satellite signals of two or more different frequencies with a single feeding pin that passes through the plurality of microstrip patch antennas, even when the vehicle vibrates. Overlapping patch antennas can be securely fixed without being separated from each other.

In addition, since two or more signals are received by one feeding pin, the volume of the patch antenna can be reduced, and when the LNA stage for signal amplification is implemented later, the two signals can be amplified simultaneously with the primary LNA stage. Therefore, cost reduction and product miniaturization are possible.

Although the preferred embodiments of the present invention have been illustrated and described above, the present invention is not limited to the specific embodiments described above, and the present invention is not limited to the specific embodiments of the present invention without departing from the spirit of the present invention as claimed in the claims. Anyone skilled in the art can make various modifications, as well as such modifications are within the scope of the claims.

Claims (6)

A plurality of microstrip patch antennas each having a different frequency characteristic and arranged in layers; And It penetrates through the plurality of microstrip patch antenna, and includes a feeding pin for receiving a satellite signal, The pattern area of the conductive surface formed on the lower microstrip patch antenna of the plurality of microstrip patch antennas is wider than the pattern area of the conductive surface of the upper microstrip patch antenna. The method of claim 1, The plurality of microstrip patch antenna structure is characterized in that the microstrip patch antenna is bonded to each other by a solder (solder) of the tin or lead. delete The method of claim 2, The feeding pin is shorted with a conductive surface located at an upper end of the upper microstrip patch antenna among the plurality of microstrip patch antennas for impedance matching, and has a conductive surface located at the lower end of the upper layer and the microstrip patch antennas at the lower layer. Microstrip patch antenna structure, characterized in that the top and bottom conduction surface is opened (open). The method of claim 4, wherein Microstrip patch antenna structure, characterized in that the conductive surface located at the bottom of the microstrip patch antenna of the plurality of microstrip patch antenna is removed. The method of claim 4, wherein Microconducting patch antenna structure, characterized in that the conductive surface located at the bottom of the microstrip patch antenna of the plurality of microstrip patch antenna is removed.

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