KR101321195B1 - Multi-band antenna structure - Google Patents

Abstract

The present invention relates to a multi-band antenna structure for receiving a supply signal. The antenna structure includes a ground portion, a radiating portion and a tuning portion. The radiating section is spaced apart from the ground section and is arranged on one side of the ground section. The spinneret has a first spinneret segment and a second spinneret segment connected perpendicularly to each other. The tuning portion is connected between the first radiation segment and the ground portion. The tuning portion has a hairpin segment and a ground segment. The hairpin segment is almost U shaped and has one end connected to one end of the first radiation segment close to the ground portion. Opposite ends of the ground segment are connected to the other end of the hairpin segment and to the ground. The connection point of the first radiation segment and the hairpin segment is used to receive the supply signal. Higher efficiency can be obtained using such a multi-band antenna structure.

Description

Multi-Band Antenna Structures {MULTI-BAND ANTENNA STRUCTURE}

The present invention relates to an antenna structure; More specifically, it relates to a multi-band antenna structure having a hairpin tuning portion to improve antenna efficiency.

Most wireless communication devices such as mobile phones, laptops and tablet computers found on the market today are equipped with antenna structures. Such an antenna structure serves to transmit and receive electromagnetic signals. Antennas are usually built-in components and are located within the limited space inside the radio.

A conventional antenna structure is shown in FIG. Structurally, this antenna structure comprises a grounding portion 1a, a linear radiating portion 2a, and a connecting portion 3a perpendicularly connected to the grounding portion 1a and the radiating portion 2a at opposite ends. . The radiating portion 2a consists of a high frequency segment 21a and a low frequency segment 22a. The connecting portion 3a is connected between the high frequency segment 21a and the low frequency segment 22a. The point at which the connecting portion 3a and the radiating portion 2a are connected to each other is defined as a feed point O for the supply signal.

Moreover, the connection part 3a is provided with the supply segment 31a, the connection segment 32a, and the ground segment 33a which are connected in order. One end of the supply segment 31a is vertically connected between the high frequency segment 21a and the low frequency segment 22a. Opposite ends of the connecting segment 32a are connected perpendicularly to the other end of the supply segment 31a and to one end of the ground segment 33a. On the other hand, the other end of the ground segment 33a is vertically connected to the ground portion 1a. By using a structure in which several segments of the ground portion 3a are arranged vertically, antenna efficiency is adjusted.

The test result of the high frequency efficiency with respect to the conventional antenna structure is shown by the broken line A in FIG. The low frequency efficiency is indicated by broken line A 'in FIG. Since the efficiency value is an important parameter in designing the antenna structure, the measurement data shows that the conventional antenna still has room for improvement.

In order to solve the above problems, the inventor has made an effort to provide the present invention that can effectively improve the above-mentioned limitations through field experience and academic research.

The present invention provides a multi-band antenna structure that uses tuning to improve antenna efficiency in both high and low frequency operation.

Embodiment of the present invention and the ground; A radiating part spaced apart from the ground part and arranged on one side of the ground part; A multi-band antenna structure is provided which is arranged between the ground portion and the radiating portion and comprises a tuning portion connecting the ground portion and the radiating portion. The radiating part comprises a first radiating segment and a second radiating segment. One portion of the first radiation segment is arranged facing towards the ground. The second spinning segment extends perpendicularly from the first spinning segment as the structurally extending portion of the first spinning segment. The tuning portion connects the ground portion with the first radiation segment of the radiation portion. The tuning portion has a hairpin segment and a ground segment. The hairpin segment is almost U-shaped. One end of the hairpin segment is connected to a portion of the first radiating segment facing towards the ground and the other end of the hairpin segment extends to form a ground segment, thus connecting to the ground. The portion where the first spinning segment and the hairpin segment are connected to each other forms a feed point.

Preferably, the hairpin segment has a first arm connected in sequence, a connecting arm and a second arm. The first arm is connected to one end of the first radiation segment close to the ground portion. The second arm is disposed between the first arm and the ground portion and is connected to the ground portion.

Preferably, the first radiating segment and the first arm cooperate to form a substantially U-shaped structure. The second radiation segment is connected to one end of the first radiation segment close to the ground portion. The second radiating segment and the first arm are connected to the same point in the first radiating segment but are facing in opposite directions.

Preferably, the first radiating segment and the first arm cooperate to form a substantially U-shaped structure. At a position remote from the ground portion, the second radiation segment is connected to one end of the first radiation segment, and the second radiation segment is disposed between the first radiation segment and the first arm.

Preferably, the first radiating segment and the second radiating segment cooperate to form an L-shaped structure. The second radiating segment extends from the first radiating segment toward the first arm and is bent to extend parallel to the first arm.

Advantageously, the multi-band antenna structure further comprises a coupling portion extending from said ground portion towards said first radiation segment to couple to said radiation portion.

According to the above description, the multi-band antenna structure utilizes the relative positional relationship between the signal feed point, the hairpin segment of the tuning section, and the first and second radiating segments to improve antenna efficiency for high frequency operation and low frequency operation. It is improving.

In order to further understand the features and technical details of the present invention, reference is made to the following description and attached drawings in connection with the present invention.

However, the accompanying drawings are only shown by way of example and do not limit the scope of the invention.

1 is a schematic diagram of a multi-band antenna structure of a first embodiment of the present invention.
2 is a schematic diagram of a multi-band antenna structure of a second embodiment of the present invention.
3 is a schematic diagram of an embodiment of a modified multi-band antenna structure of a second embodiment of the present invention.
4 is a diagram comparing the efficiency of a multi-band antenna structure of the present invention and a conventional antenna structure for high frequency operation.
5 is a chart comparing the efficiency of a multi-band antenna structure of the present invention and a conventional antenna structure for low frequency operation.
6 is a schematic diagram of a conventional antenna structure.

For example, with reference to the first embodiment disclosed, reference is made to FIG. 1 along with FIGS. 4 and 5. 1 is a schematic representation of one embodiment, and FIGS. 4 and 5 show measurement data for this embodiment.

As can be seen in Figure 1, a multi-band antenna structure is formed in the substrate 5 to obtain a supply signal. The antenna structure has a ground part 1, a radiating part 2 disposed on one side of the ground part while being spaced from the ground part 1, and a ground part and a radiating part connected between the ground part and the radiating part. The tuning part 3 is provided.

The substrate 5 is composed of a first substrate 51 and a second substrate 52. The first substrate 51 and the second substrate 52 are surfaces of the substrate 5 that face each other. In one embodiment, the antenna structure is formed on the first substrate 51 of the substrate 5. Meanwhile, the antenna structure may be formed on the second substrate 52. In one embodiment, the substrate 5 has a plate shape. However, in practice, the shape of the substrate 5 is not limited. For example, the substrate 5 may be formed in the shape of an arc.

Indeed, multi-band antenna structures may be used in tablet computers, laptops, cell phones or other various wireless communications devices. Furthermore, in the case of one embodiment, the structural features of the antenna structure are shown in the drawings. However, according to the requirements of the user, the structural configuration can be adjusted to meet the demand. For example, the segment of the antenna structure may be widened or implemented in a wave-like shape.

The radiation section 2 is connected to the ground section 1 by the tuning section 3. The spinning part 2 has a first spinning segment 21 and a second spinning segment 22. The first radiation segment 21 has a portion (eg, segment 211) arranged to bend towards the grounding portion 1. The second radiation segment 22 extends from the first radiation segment 21. As a structure, it extends perpendicularly from the first radiation segment 21.

The tuning part 3 is arranged between the first radiating segment 21 of the radiating part 2 and the ground part 1. The tuning section 3 has a hairpin segment 31 and a ground segment 32. The hairpin segment 31 has a substantially U shape. One end of the hairpin segment 31 is connected to one end of the first radiation segment 21 near the ground 1. The opposite ends of the ground segment 32 are connected to the other end of the hairpin segment 31 and to the ground 1.

More specifically, the hairpin segment 31 includes a first arm 311, a connecting arm 312, and a second arm 313, which are sequentially formed. One end of the first arm 311 is connected to one end of the first radiation segment 21 near the ground 1. Opposite ends of the connecting arm 312 are connected to the other end of the first arm 311 and one end of the second arm 313. The second arm 313 is disposed between the first arm 311 and the ground portion 1, and the other end of the second arm 313 is connected to the ground segment 32.

In one embodiment, the first arm 311 and the second arm 313 are substantially parallel to each other. The connecting arm 312 is shorter than the first arm 311. However, in practice, there is no restriction on the structure constituting the tuning section 3.

By adjusting the dimensions of the first arm 311 and the second arm 313 of the hairpin segment 31, the multi-band antenna structure can increase the frequency bandwidth, which in turn can improve the efficiency of the antenna.

The radiation unit 2 which operates in cooperation with the tuning unit 3 will now be described in more detail. The first spinning segment 21 is almost L-shaped. That is, the first radiation segment 21 has a short arm 211 and a long arm 212 connected perpendicular to each other. The first radiation segment 21 and the first arm 311 form a substantially U-shaped structure. The short arm 211 of the first radiation segment 21 is connected perpendicular to the first arm 311. The long arm 212 of the first radiation segment 21 is parallel to the first arm 311.

Specifically, the connection point of the first radiation segment 21 and the hairpin segment 31 is defined as a feed point P for receiving a supply signal. More specifically, the position of the feed point P is formed in the short arm 211 of the first spinning segment 21 close to the hairpin segment 31.

On the other hand, the relative position and dimensions of the short arm 211 and the long arm 212 of the first radiation segment 21 can be adjusted according to the user's request, and is not limited by the contents shown in FIG.

The second radiation segment 22 is connected to one end of the first radiation segment 21 near the ground 1. That is, the second radiation segment 22 and the hairpin segment 31 are directed in opposite directions while sharing the same connection point on the short arm 211 of the first radiation segment 21. In other words, the second radiation segment 22 and the first arm 311 diverge from the first radiation segment 21 in the opposite direction.

In practice, the first radiation segment 21 can be used for low frequency operation and the second radiation segment 22 can be used for high frequency operation. The structure of the multi-band antenna structure, for example the feed point P, the adjustment of the length of the hairpin segment 31 for the tuning part 3, the first radiating segment 21 and the first part of the radiating part 2. Through the relative position of the two radiating segments 22, the antenna structure can perform higher efficiency for high frequency operation and low frequency operation.

For high frequency operation, the results of testing the antenna structure disclosed in the present invention are indicated by the broken line B in FIG. Measurement data for a conventional general antenna structure (shown in FIG. 6) is indicated by broken line A. FIG. The comparison result shows that the efficiency of the antenna structure disclosed in the present invention is greatly improved.

Similarly, in the case of low frequency operation, the result of testing the antenna structure of the present invention is indicated by broken line B 'in FIG. Measurement data for a conventional antenna structure (shown in FIG. 6) is indicated by broken line A '. The comparison result shows that the efficiency of the antenna structure of the present invention is greatly improved.

4 and 5, it can be seen that the multi-band antenna structure of the present invention has improved efficiency for high frequency operation as well as low frequency operation as compared to the conventional antenna.

[Second Embodiment]

For a second embodiment of the present invention, reference may be made to FIGS. 2 to 5. 2 and 3 are schematic diagrams of embodiments of the present invention, and FIGS. 4 and 5 show actual test results for the present invention.

This embodiment is similar to the embodiment described above. Therefore, the same configuration is not repeated. Only the differences are discussed below.

As shown in FIG. 2, both the first spinning segment 21 and the second spinning segment 22 are L-shaped. That is, the second radiation segment 22 also has a short arm 221 and a long arm 222 connected perpendicular to each other.

The second radiation segment 22 is connected to one end of the first radiation segment 21 far from the ground portion 1, and the second radiation segment 22 is connected to the first radiation segment 21 and the first arm. 311).

More specifically, the second radiation segment 22 extends from one end of the long arm 212 of the first radiation segment 21 towards the first arm 311. The second radiation segment 22 is then bent and continues toward the first radiation segment 21 in parallel with the first arm 311. That is, the short arm 221 of the second radiating segment 22 extends toward the first arm 311 perpendicularly from the end of the long arm 212 of the first radiating segment 21 away from the short arm 211. Comes out. Then, the short arm 221 of the second radiation segment 22 is bent and extends toward the short arm 211 of the first radiation segment 21 in parallel with the first arm 311 so that the second radiation segment 22 Long arms 222 are formed.

On the other hand, the distance between the long arm 222 of the second radiation segment 22 and the long arm 212 of the first radiation segment 21 is the long arm 222 and the hairpin segment 31 of the second radiation segment 22. Is shorter than the distance between the first arms 311. However, in practice, the structure of the radiating section 2 is not limited to the contents shown in FIG. For example, the relative position and length of each of the short arms 211 and the long arms 212 of the first radiation segment 21 can be adjusted according to the requirements of the user, and likewise the second radiation segment 22 The same can be adjusted for).

In practice, the first radiation segment 21 is used for high frequency operation, and the first radiation segment 21 and the second radiation segment 22 operate in cooperating relationship with each other to perform low frequency operation. Based on the structure of the multi-band antenna structure of the invention, for example, the feed point P and the dimensional adjustment of the hairpin segment 31 of the tuning part 3, and the first radiating segment of the radiating part 2 ( Based on the relative position between 21 and the second radiation segment 22, it is possible to improve antenna efficiency for high frequency operation and low frequency operation. Furthermore, the relative position between the second radiation segment 22 and the hairpin segment 31 of the present invention is preferred when it is capable of generating a resonance frequency of 5 GHz. In addition, through the structural characteristics of the embodiment of the present invention, the antenna can take up less space.

The antenna structure of this embodiment further comprises a coupling part 4 to be coupled to the high frequency segment (ie the first radiation segment 21). The purpose is to improve efficiency for high frequency operation. The coupling part 4 extends from the ground part 1 towards the first radiation segment 21. More specifically, the connection part 4 extends from the grounding part 1 opposite the short arm 211 of the first radiation segment 21 toward the short arm 211 of the first radiation segment 21. The extended length of the connection part 4 is shorter than or equal to the distance between the first radiating segment 21 and the ground part 1, but is not limited thereto.

However, the coupling part 4 may be omitted in constructing the antenna structure as shown in FIG. 3.

The actual test results for the antenna structure of this embodiment operating at high frequencies are indicated by dashed lines C in FIG. 4. Measurement data of the conventional antenna structure (shown in FIG. 6) is indicated by broken line A. FIG. The comparison result shows that the efficiency of the antenna structure of the present invention is greatly improved.

Similarly, in the case of low frequency operation, the result of testing the antenna structure of the present invention is indicated by broken line C 'in FIG. Measurement data for a conventional antenna structure (shown in FIG. 6) is indicated by broken line A '. The comparison result shows that the efficiency of the antenna structure of the present invention is greatly improved.

4 and 5, it can be seen that the multi-band antenna structure of the present invention has improved efficiency for high frequency operation as well as low frequency operation as compared to the conventional antenna.

[Performance of Examples]

According to the above embodiment, the multi-band antenna structure of the present invention can greatly improve the efficiency for the high frequency operation and the low frequency operation through the following matters: positioning of the feed point P; Adjusting the length of the hairpin segment 31 of the tuning section 3; Adjustment of the relative position between the first radiation segment 21 and the second radiation segment 22 of the radiation section 2. In addition, antenna efficiency can be improved by including a coupling portion 4 for coupling with the high frequency segment.

Furthermore, the fact that the efficiency is improved is proved by the test result obtained by comparing with the conventional antenna, and this improvement in efficiency is made by the present invention.

The foregoing merely describes a preferred embodiment of the present invention; However, the nature of the present invention is by no means limited to this. As those skilled in the art can easily consider, changes, modifications, or modifications to the present invention can be understood as belonging to the scope of the present invention indicated by the following claims.

Claims (6)

As a multi-band antenna structure
Including a grounding part, a radiating part and a tuning part,
The radiation portion is spaced from the ground portion and arranged on one side of the ground portion, the radiation portion includes a first radiation segment and a second radiation segment extending vertically from the first radiation segment, wherein a portion of the first radiation segment is Facing towards the ground;
The tuning section is arranged between the ground section and the radiating section and connects the ground section and the radiating section, and includes a substantially U-shaped hairpin segment and a ground segment, wherein one end of the hairpin segment faces toward the ground section. Connected to a portion of a first radiation segment and the other end of the hairpin segment extends to form a ground segment, the ground segment connected to the ground portion;
The hairpin segment has a first arm connected in turn, a connecting arm and a second arm, the first arm being connected to an end of the first radiation segment close to the ground portion, End portions opposite to each other are connected to the first arm and the second arm, the second arm is disposed between the first arm and the ground portion and is connected to the ground portion,
And the portion of the first radiating segment and the hairpin segment connected to each other is defined as a feed point.
delete The method of claim 1,
The first radiation segment and the first arm form a substantially U-shaped structure, the second radiation segment is connected to an end of the first radiation segment close to the ground portion, the second radiation segment and the And the first arm extends in opposite directions from the same connection area in the first radiating segment.
The method of claim 1,
The first radiation segment and the first arm form a substantially U-shaped structure, the second radiation segment is connected to one end of the first radiation segment distant from the ground portion, and the second radiation segment is And between the first radiation segment and the first arm.
5. The method of claim 4,
The first radiation segment and the second radiation segment are each substantially L-shaped, and the second radiation segment extends from the end of the first radiation segment away from the ground portion to the first arm and is curved Extending toward the first radiation segment parallel to the first arm.
The method of claim 5,
And a coupling portion coupling to the radiating portion, wherein the coupling portion extends from the ground portion toward the first radiating segment.

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