TWI566471B - Wideband antenna structure - Google Patents

Description

Broadband antenna structure

The present invention relates to an antenna structure, and more particularly to a wideband antenna structure.

In recent years, the rapid development of wireless communication technology, Long Term Evolution (LTE) mobile communication technology came into being; because the LTE LTE700/2300/2500 frequency band covers 704~960MHz and 1710~2690MHz, covering The wireless wide area network (Wireless Wide Area Network, usually referred to as WWAN) has five-frequency operation. Compared with the traditional wireless local area network (Wireless Local Area Network, usually referred to as WLAN) 2.4G, 5G antenna, LTE antenna covers lower. Frequency and larger bandwidth; therefore, how to balance the antenna multi-frequency operation and receiving quality for antenna design needs to pay attention to.

However, various types of antenna devices of the prior art only have the functions of transmitting or receiving electromagnetic wave signals by dual-frequency transmission or transmission, and cannot meet the communication frequency band of the current 4G communication field, and are still limited in use.

For example, Taiwan Patent No. I257740 discloses a dual-band internal antenna for a dual-band communication device, which discloses an inverted-F antenna design suitable for dual-band, but the antenna has only a single feed, which is generally used in practical applications. It must be connected to a diplexer to separate two different feed signals (such as GSM and DCS) and then connected to the back-end module; the switch circuit will occupy part of the space of the mobile circuit module. Part of the power is also consumed, resulting in reduced overall antenna efficiency and increased matching complexity.

In order to improve the above disadvantages of the prior art, it is an object of the present invention to provide a wideband antenna structure.

To achieve the above object of the present invention, the broadband antenna structure of the present invention comprises: an antenna radiator having a point at both ends and extending in a horizontal direction; a grounding metal comprising a radio frequency grounding point and an antenna a grounding point, the RF grounding point is disposed relative to the antenna grounding point; a grounded radiating metal, the grounding metal has two ends located between the antenna radiator and the grounding metal, and an end thereof is electrically connected to the antenna radiator Connected, the other end is electrically connected to the antenna grounding point of the grounding metal; a first antenna feeding portion radiating portion, the first antenna feeding portion radiating portion has two end points and is located at the antenna radiator and the antenna Between the grounding metal and the antenna radiator; a first antenna feeding portion connecting portion, the first antenna feeding portion connecting portion having two ends and located at the first antenna feeding portion radiating portion and the grounding metal An end point is electrically connected to the first antenna feeding portion radiating portion and includes a radio frequency feeding point; a second antenna feeding portion radiating portion, and the second antenna feeding portion radiating portion has The end point is located between the antenna radiator and the grounding metal, parallel to the antenna radiator; a second antenna feeding portion connecting portion, the second antenna feeding portion connecting portion has two ends and is located at the second Between the antenna feeding portion radiating portion and the grounding metal, an end point is electrically connected to the second antenna feeding portion radiating portion; and an impedance converting transmission line, the two ends of the impedance converting transmission line and the first antenna feeding portion respectively The connecting portion and the second antenna feeding portion connecting portion are in contact with each other and are parallel to the grounding metal for impedance conversion.

10‧‧‧Broadband antenna structure

20‧‧‧High frequency transmission line

102‧‧‧Grounded metal

110‧‧‧RF feed point

111‧‧‧RF grounding point

112‧‧‧ impedance conversion transmission line

1022‧‧‧Antenna grounding point

1042‧‧‧Antenna radiator

1044‧‧‧Grounding radiation metal

1062‧‧‧First Antenna Feeder Radiation Department

1064‧‧‧First antenna feed connection

1082‧‧‧Second antenna feed-in radiation

1084‧‧‧Second antenna feed connection

The first figure is a schematic diagram of a first embodiment of a broadband antenna structure of the present invention.

The second figure is a schematic diagram of the return loss of the antenna radiator and the first antenna feeding portion radiating portion (solid line) and the antenna radiator and the second antenna body receiving portion radiating portion (dashed line).

The third figure is a schematic diagram of the return loss of the broadband antenna structure of the present invention.

The fourth figure is a schematic diagram of a second embodiment of the broadband antenna structure of the present invention.

The fifth figure is a schematic view of a third embodiment of the wideband antenna structure of the present invention.

Figure 6 is a schematic view showing a fourth embodiment of the wideband antenna structure of the present invention.

Please refer to the first figure, which is a schematic diagram of a first embodiment of the broadband antenna structure of the present invention. A broadband antenna structure 10 includes an antenna radiator 1042, a grounding metal 102, a grounded radiating metal 1044, a first antenna feeding portion radiating portion 1062, a first antenna feeding portion connecting portion 1064, and a second antenna. The feeding portion radiating portion 1082, a second antenna feeding portion connecting portion 1084, and an impedance conversion transmission line 112.

The antenna radiator 1042 has two ends and extends in a horizontal direction; the grounding metal 102 includes an RF grounding point 111 and an antenna grounding point 1022, and the RF grounding point 111 is disposed relative to the antenna grounding point 1022; the grounding radiation The metal 1044 has two ends between the antenna radiator 1042 and the grounding metal 102, one end of which is electrically connected to the antenna radiator 1042, and the other end is electrically connected to the antenna grounding point 1022 of the grounding metal 102. .

The first antenna feeding portion radiating portion 1062 has two end points and is located between the antenna radiator 1042 and the grounding metal 102, parallel or nearly parallel to the antenna radiator 1042; the first antenna feeding portion connecting portion 1064 An end point is located between the first antenna feeding portion radiating portion 1062 and the grounding metal 102, and an end point is electrically connected to the first antenna feeding portion radiating portion 1062 and includes a radio frequency feeding point 110.

The second antenna feeding portion radiating portion 1082 has two end points and is located between the antenna radiator 1042 and the grounding metal 102, parallel or nearly parallel to the antenna radiator 1042; the second antenna feeding portion connecting portion 1084 There is a terminal point between the second antenna feeding portion radiating portion 1082 and the grounding metal 102, and an end point is electrically connected to the second antenna feeding portion radiating portion 1082; the two ends of the impedance converting transmission line 112 are respectively The first antenna feeding portion connecting portion 1064 and the second antenna feeding portion connecting portion 1084 are in contact with each other and are parallel or nearly parallel to the grounding metal 102 for impedance conversion (described later in detail).

The RF feed point 110 and the RF ground point 111 are connected to a high frequency transmission line 20; the first antenna feed portion radiating portion 1062 and the antenna radiator 1042 The distance between the second antenna feed portion radiating portion 1082 and the antenna radiator 1042 is less than 2 mm; one end of the impedance conversion transmission line 112 is connected to the RF feed point 110; the impedance conversion transmission line The distance between 112 and the grounded metal 102 is less than 2 mm.

The impedance value of the first antenna feeding portion radiating portion 1062 plus the impedance value of the first antenna feeding portion connecting portion 1064 is approximately one hundred ohms; the impedance value of the impedance converting transmission line 112 is between fifty and one hundred ohms. The impedance value of the second antenna feeding portion radiating portion 1082 plus the impedance value of the second antenna feeding portion connecting portion 1084 is approximately forty to fifty ohms, which together with the impedance converting transmission line 112 constitutes an impedance substantially One hundred ohms; therefore, the first antenna feeding portion radiating portion 1062, the first antenna feeding portion connecting portion 1064, the second antenna feeding portion radiating portion 1082, the second antenna feeding portion connecting portion 1084, and The impedance of the impedance conversion transmission line 112 to the RF feed point 110 is 50 ohms required.

The first antenna feeding portion radiating portion 1062 is a high frequency radiator in addition to the coupling energy to the antenna radiator 1042 to generate a low frequency. The first antenna feeding portion radiating portion 1062 is also a high frequency radiator. The second antenna feeding portion radiating portion 1082 is a high frequency radiator in addition to coupling energy to the antenna radiator 1042 to generate a low frequency. The second antenna feeding portion radiating portion 1082 is also a high frequency radiator.

Please refer to the second figure, which is a schematic diagram of the return loss of the antenna radiator and the first antenna feeding portion radiating portion (solid line) and the antenna radiator and the second antenna feeding portion radiating portion (dashed line); Please refer to the third figure, which is a schematic diagram of the return loss of the broadband antenna structure of the present invention. That is, in combination with the solid line and the broken line of the second figure, a third picture can be formed (using, for example, an overlap theorem). The low frequency and high frequency range of the present invention are 704 to 960 MHz and 1710 to 2700 MHz. The antenna radiator 1042 and the first antenna feeding portion radiating portion 1062 (solid line) have low frequency and high frequency of 704 MHz and 1710 MHz; the antenna radiator 1042 and the second antenna feeding portion radiating portion 1082 (dashed line) have low frequency and The high frequency is 960MHz and 2700MHz.

Please refer to the fourth figure, which is a schematic diagram of a second embodiment of the broadband antenna structure of the present invention; please refer to the fifth figure, which is a schematic diagram of a third embodiment of the broadband antenna structure of the present invention; It is the broadband antenna structure of the present invention. A schematic view of the fourth embodiment. The fourth, fifth, and sixth figures are the same as those in the above first figure, and the difference is that the antenna radiator 1042 extends to form a T-shape with the grounded radiation metal 1044, or the first antenna feeding portion. The radiating portion 1062 extends to form a T-shape with the first antenna feeding portion connecting portion 1064, or the second antenna feeding portion radiating portion 1082 extends to form a T-shape with the second antenna feeding portion connecting portion 1084. It can even be used in combination with any of the above conditions to improve antenna efficiency.

Furthermore, in a specific embodiment (unless limited by the invention), the antenna radiator 1042, the grounding radiation metal 1044, the first antenna feeding portion radiating portion 1062, and the first antenna feeding portion connecting portion 1064 The second antenna feeding portion radiating portion 1082, the second antenna feeding portion connecting portion 1084, and the impedance conversion transmission line 112 are linear.

The two ends of the grounded radiating metal 1044 are perpendicular to the antenna radiating body 1042 and the grounding metal 102. That is, after the grounding radiating metal 1044 and the antenna radiating body 1042 are L-shaped, the grounding radiating metal 1044 is connected to the grounding metal. 102, wherein the antenna radiator 1042 is an L-shaped long side, and the grounded radiation metal 1044 is an L-shaped short side.

Both ends of the first antenna feeding portion connecting portion 1064 are perpendicular to the first antenna feeding portion radiating portion 1062 and the impedance conversion transmission line 112, that is, the first antenna feeding portion connecting portion 1064 and the first day After the line feeding portion radiating portion 1062 assumes an L shape, the first antenna feeding portion connecting portion 1064 is further connected to the impedance conversion transmission line 112, wherein the first antenna feeding portion radiating portion 1062 is an L-shaped long side, the first The antenna feed portion connecting portion 1064 is an L-shaped short side.

The two ends of the second antenna feeding portion connecting portion 1084 are perpendicular to the second antenna feeding portion radiating portion 1082 and the impedance conversion transmission line 112, that is, the second antenna feeding portion connecting portion 1084 and the second day. After the line feeding portion radiating portion 1082 assumes an L shape, the second antenna feeding portion connecting portion 1084 is further connected to the impedance conversion transmission line 112, wherein the second antenna feeding portion connecting portion 1084 is an L-shaped long side, and the second The antenna feeding portion radiating portion 1082 is an L-shaped short side.

In other words, the first antenna feeding portion radiating portion 1062 and the first antenna feeding portion The connecting portion 1064, the second antenna feeding portion radiating portion 1082, the second antenna feeding portion connecting portion 1084, and the impedance conversion transmission line 112 form a 杓 type. The second antenna feeding portion connecting portion 1084 is located between the grounding radiation metal 1044 and the first antenna feeding portion connecting portion 1064.

The object of the present invention is to provide an innovative design of a multi-frequency antenna with dual feed, using an antenna double feed design, and adding an antenna circuit of the impedance conversion transmission line between the two antennas, and adjusting the antenna bandwidth by the length of the impedance conversion transmission line. The multi-mode is excited to increase the flexibility of the use bandwidth and antenna adaptation and improve the overall antenna efficiency. The invention has the characteristics of high isolation between the double feeds, and it is not necessary to add a switching circuit of the switching frequency band at the antenna feeding end as before, and the feeding end can be directly connected to the back end circuit, thereby not only reducing the passive components. The resulting power consumption can simplify the complexity of the matching and improve the overall antenna efficiency.

The advantages of the wideband antenna structure of the present invention are as follows:

1. The antenna covers a wider bandwidth.

2. Reduced design cost: no need to use a duplexer for band switching.

3. Reduce system power consumption: Do not use any electronic components for antenna design, reducing system power consumption.

However, the above is only a preferred embodiment of the present invention, and the scope of the present invention is not limited thereto, that is, the equivalent changes and modifications made by the scope of the present invention should still be covered by the patent of the present invention. The scope of the scope is intended to protect. In summary, it is known that the present invention has industrial applicability, novelty and advancement, and the structure of the present invention has not been seen in similar products and public use, and fully complies with the requirements of the invention patent application, and is filed according to the patent law.

10‧‧‧Broadband antenna structure

20‧‧‧High frequency transmission line

102‧‧‧Grounded metal

110‧‧‧RF feed point

111‧‧‧RF grounding point

112‧‧‧ impedance conversion transmission line

1022‧‧‧Antenna grounding point

1042‧‧‧Antenna radiator

1044‧‧‧Grounding radiation metal

1062‧‧‧First Antenna Feeder Radiation Department

1064‧‧‧First antenna feed connection

1082‧‧‧Second antenna feed-in radiation

1084‧‧‧Second antenna feed connection

Claims (7)

A broadband antenna structure comprising: an antenna radiator having a point at both ends and extending in a horizontal direction; a grounding metal, the grounding metal comprising an RF grounding point and an antenna grounding point, the RF grounding point being relatively Provided at the antenna grounding point; a grounded radiating metal having two ends between the antenna radiating body and the grounding metal, one end of which is electrically connected to the antenna radiating body, and the other end is connected to the grounding The antenna grounding point of the metal is electrically connected; a first antenna feeding portion radiating portion, the first antenna feeding portion radiating portion has two end points and is located between the antenna radiator and the grounding metal, and radiates with the antenna The body is parallel; a first antenna feeding portion connecting portion, the first antenna feeding portion connecting portion has two end points and is located between the first antenna feeding portion radiating portion and the grounding metal, and an end point and the first end The antenna feeding portion radiating portion is electrically connected, and includes a radio frequency feeding point; a second antenna feeding portion radiating portion, the second antenna feeding portion radiating portion has two end points and is located at the antenna radiator and Between the grounding metal and the antenna radiator; a second antenna feeding portion connecting portion, the second antenna feeding portion connecting portion having two ends and located at the second antenna feeding portion radiating portion and the grounding metal An end point is electrically connected to the radiation portion of the second antenna feeding portion; and an impedance conversion transmission line, the two ends of the impedance conversion transmission line are respectively connected to the first antenna feeding portion and the second antenna feeding portion The connecting portion is connected and parallel to the grounding metal for impedance conversion, wherein a distance between the second antenna feeding portion radiating portion and the antenna radiator is less than 2 mm. The broadband antenna structure of claim 1, wherein the RF feed point and the RF ground point are connected to a high frequency transmission line. The wideband antenna structure of claim 1, wherein the first antenna feed portion radiating portion is a high frequency radiator. The wideband antenna structure of claim 1, wherein a distance between the first antenna feed portion radiating portion and the antenna radiator is less than 2 mm. The wideband antenna structure of claim 1, wherein the second antenna feed portion radiating portion is a high frequency radiator. The broadband antenna structure of claim 1, wherein one end of the impedance conversion transmission line is connected to the RF feed point. The wideband antenna structure of claim 1, wherein the distance between the impedance conversion transmission line and the grounded metal is less than 2 mm.