CN101740866A

CN101740866A - Multi-frequency antenna for wireless communication device

Info

Publication number: CN101740866A
Application number: CN200810181191A
Authority: CN
Inventors: 张政伟; 洪志良; 张惟善
Original assignee: Wistron Neweb Corp
Current assignee: Wistron Neweb Corp
Priority date: 2008-11-27
Filing date: 2008-11-27
Publication date: 2010-06-16
Anticipated expiration: 2028-11-27
Also published as: CN101740866B

Abstract

The invention relates to a multi-frequency antenna for a wireless communication device, which comprises a grounding assembly, a first radiation assembly, a connecting assembly, a feed-in assembly, a short-circuit assembly and a second radiation assembly. The grounding assembly is grounded; the connecting assembly comprises a first end and a second end, wherein the first end is coupled with the first radiation assembly; the feed-in assembly is coupled between the second end of the connecting assembly and the grounding assembly and is used for receiving a feed-in signal; the short-circuit assembly is coupled between the second end of the connecting assembly and the grounding assembly; and the second radiation assembly is coupled with the short-circuit assembly. A single antenna of the invention covers different frequency bands required by different wireless communication devices so as to fit the trend of the reduction of the volume of portable wireless communicators.

Description

The multifrequency antenna that is used for a radio communication device

Technical field

The present invention relates to a kind of multifrequency antenna that is used for a radio communication device, relate in particular to a kind of extra radiation assembly that on short-circuit component, increases, so that the multifrequency antenna in extra path to be provided.

Background technology

Antenna is used for launching or the reception radio wave, to transmit or the exchange radio signal.The electronic product that generally has radio communication function as notebook computer, personal digital assistant (Personal Digital Assistant) etc., visits wireless network by built-in antenna usually.Therefore, in order to allow the user can visit cordless communication network more easily, the frequency range of ideal antenna should increase in tolerance band as much as possible, and size then should reduce as far as possible, to cooperate the trend of portable wireless communication equipment volume-diminished, aerial integration is gone in the notebook computer.In addition, along with the evolution of wireless communication technology, the frequency of operation of different wireless communication system may be different.Therefore, desirable antenna should be able to be contained the required frequency band of different wireless communication network with single antenna.

Summary of the invention

Therefore, the invention provides a kind of multifrequency antenna that is used for a radio communication device.

The present invention discloses a kind of multifrequency antenna that is used for a radio communication device, includes a grounding assembly, is coupled to a ground end; One first radiation assembly; One coupling assembling includes one first end and is coupled to this first radiation assembly, and one second end; One feed-in assembly is coupled between this second end and this grounding assembly of this coupling assembling, is used for receiving FD feed; One short-circuit component is coupled between this second end and this grounding assembly of this coupling assembling; And one second radiation assembly, be coupled to this short-circuit component.

The present invention can be contained the required frequency band in different wireless communication networking with single antenna, to cooperate the trend of portable wireless communication equipment volume-diminished.

Description of drawings

Figure 1A is the schematic diagram of the multifrequency antenna of the embodiment of the invention.

Figure 1B is the signal path schematic diagram of the multifrequency antenna of Figure 1A.

Fig. 1 C is the voltage standing wave ratio schematic diagram of Figure 1A.

Fig. 2 A is the schematic diagram of the multifrequency antenna of the embodiment of the invention.

Fig. 2 B is the voltage standing wave ratio schematic diagram of Fig. 2 A.

Fig. 3 A is the schematic diagram of the multifrequency antenna of the embodiment of the invention.

Fig. 3 B is the voltage standing wave ratio schematic diagram of Fig. 3 A.

Fig. 4 A is the schematic diagram of the multifrequency antenna of the embodiment of the invention.

Fig. 4 B is the voltage standing wave ratio schematic diagram of Fig. 4 A.

Fig. 5 A is the schematic diagram of the multifrequency antenna of the embodiment of the invention.

Fig. 5 B is the voltage standing wave ratio schematic diagram of Fig. 5 A.

Fig. 6 A is the schematic diagram of the multifrequency antenna of the embodiment of the invention.

Fig. 6 B is the voltage standing wave ratio schematic diagram of Fig. 6 A.

Fig. 7 A and Fig. 7 B are the schematic diagram of the multifrequency antenna of the embodiment of the invention.

Fig. 8 A is the schematic diagram of the multifrequency antenna of the embodiment of the invention.

Fig. 8 B is the voltage standing wave ratio schematic diagram of Fig. 8 A.

Fig. 9 A is the schematic diagram of the multifrequency antenna of the embodiment of the invention.

Fig. 9 B is the voltage standing wave ratio schematic diagram of Fig. 9 A.

Figure 10 A to Figure 10 D is the schematic diagram of the multifrequency antenna of the embodiment of the invention.

Figure 11 A is the schematic diagram of the multifrequency antenna of the embodiment of the invention.

Figure 11 B is the voltage standing wave ratio schematic diagram of Figure 11 A.

The primary clustering symbol description:

1,2,3,4,5,6,71,200 first short circuit portions

72,8,9,101,102,202 second short circuit portions

103,104,11 multifrequency antenna θ, Ф angle

12 grounding assembly R1, R2, R3 signal path

14,14A first radiation assembly 50 substrates

The perforation of 16 coupling assemblings, 52 circuit boards

18 feed-in assembly 52A coupling units

20,20A, 20B short-circuit component 24 the 3rd radiation assembly

22,22A, 22B, 22C second radiation assembly 224,144,146,148 the 3rd Departments of Radiation

140,220,140A first Department of Radiation 150 the 4th Department of Radiation

142,222,142A second Department of Radiation

Embodiment

Please refer to Figure 1A, Figure 1A is the schematic diagram of a multifrequency antenna 1 of the embodiment of the invention.Multifrequency antenna 1 is used for a radio communication device (as notebook computer), and it includes a grounding assembly 12, one first radiation assembly 14, a coupling assembling 16, a feed-in assembly 18, a short-circuit component 20 and one second radiation assembly 22.Grounding assembly 12 is held with being coupled to, is used to provide ground connection.First radiation assembly 14 includes one first Department of Radiation 140 and one second Department of Radiation 142, is used for emitting radio wave.Feed-in assembly 18 is coupled between coupling assembling 16 and the grounding assembly 12, is used for receiving FD feed, with by coupling assembling 16, is sent to first radiation assembly 14.Short-circuit component 20 is coupled between coupling assembling 16 and the grounding assembly 12, and it includes one first short circuit portion 200 and one second short circuit portion 202, and both angle Ф preferably are 90 °.In addition, second radiation assembly 22 couples short-circuit component 20, is used to provide extra signal path, and to reach the purpose of multifrequency, it includes one first Department of Radiation 220 and one second Department of Radiation 222, and both angle theta preferably are 90 °.

Please continue with reference to Figure 1B, Figure 1B is the signal path schematic diagram of multifrequency antenna 1.By Figure 1B as can be known, multifrequency antenna 1 can produce three signal paths, is respectively R1, R2, R3.Wherein, signal path R1, R2 are produced through coupling assembling 16, first Department of Radiation 140 and second Department of Radiation 142 by 18 beginnings of feed-in assembly, and this kind producing method is well known to those of ordinary skill in the art; Signal path R3 then is by 18 beginnings of feed-in assembly, through partial short circuit assembly 20, produces by second radiation assembly 22 at last.In other words, except signal path R1, R2, the present invention also provides extra signal path R3, to reach the purpose of three frequencies.

Therefore, by second radiation assembly 22, multifrequency antenna 1 can provide extra signal path R3, and then produces three transmission bands.In the case, as long as the length and width size of suitable adjustment first radiation assembly 14 and second radiation assembly 22 or material etc. promptly can produce the voltage standing wave ratio schematic diagram shown in Fig. 1 C.

The present invention is extra increase by second radiation assembly 22 on short-circuit component 20, and then signal path R3 is provided.The characteristic such as shape, material that it should be noted that second radiation assembly 22 is not limited to specified conditions, as long as can reach the required frequency range of designer.Certainly, can also on short-circuit component 20, increase other radiation assemblies, or go out extra Department of Radiation, so that more multiband to be provided in second radiation assembly, 22 top sets.Same, other assemblies beyond second radiation assembly 22 can also have similar variation, are not limited thereto.Below will be in regular turn explain at the variation of second radiation assembly 22, short-circuit component 20, first radiation assembly 14 etc., be variation of the present invention be not limited only to following for example.

In Figure 1A, second radiation assembly 22 is made up of the first vertical each other Department of Radiation 220 and second Department of Radiation 222.In fact, the angle theta of first Department of Radiation 220 and second Department of Radiation 222 is not limited to 90 °, can also be greater than or less than 90 °, and it is required to look the designer.In addition, the shape of second radiation assembly 22 also is not limited to first Department of Radiation 220 and second Department of Radiation 222 formed " L " shape, and it can also be arc or the formed inclined-plane of single metal arm.

For example, please refer to Fig. 2 A, Fig. 2 A is the schematic diagram of a multifrequency antenna 2 of the embodiment of the invention.The framework of multifrequency antenna 2 is similar to multifrequency antenna 1, and difference is that multifrequency antenna 2 is second radiation assemblies 22 that replace multifrequency antenna 1 with the second radiation assembly 22A of a cambered surface.In this case, the voltage standing wave ratio of multifrequency antenna 2 promptly shown in Fig. 2 B, can produce three frequency ranges equally.

In like manner, please refer to Fig. 3 A, Fig. 3 A is the schematic diagram of a multifrequency antenna 3 of the embodiment of the invention.The framework of multifrequency antenna 3 is similar to multifrequency antenna 1, and difference is that multifrequency antenna 3 is second radiation assemblies 22 that replace multifrequency antenna 1 with the second radiation assembly 22B on an inclined-plane.In this case, the voltage standing wave ratio of multifrequency antenna 3 promptly shown in Fig. 3 B, can produce three frequency ranges equally.

Except the shape that changes second radiation assembly 22, can also change the position that second radiation assembly 22 links to each other with short-circuit component 20.

For example, please refer to Fig. 4 A, Fig. 4 A is the schematic diagram of a multifrequency antenna 4 of the embodiment of the invention.The framework of multifrequency antenna 4 is similar to multifrequency antenna 1, and difference is that multifrequency antenna 4 is second radiation assemblies 22 that replace multifrequency antenna 1 with the second radiation assembly 22C that three Departments of Radiation are formed; Simultaneously, the second radiation assembly 22C is coupled to the second short circuit portion 202 of short-circuit component 20.In this case, the voltage standing wave ratio of multifrequency antenna 4 promptly shown in Fig. 4 B, can produce three frequency ranges equally.

In addition, when realizing multifrequency antenna of the present invention, except realizing, can also realize with multilayer circuit board according to different demands in sheet metal (iron plate) mode.For example, please refer to Fig. 5 A, Fig. 5 A is the schematic diagram of a multifrequency antenna 5 of the embodiment of the invention.The framework of multifrequency antenna 5 is similar to multifrequency antenna 1, difference is that multifrequency antenna 5 is to be formed on the substrate 50, and grounding assembly 12, first radiation assembly 14, coupling assembling 16, feed-in assembly 18 and short-circuit component 20 are formed at the front of substrate 50, and second radiation assembly 22 is formed at the back side of substrate 50.In addition, 20 of second radiation assembly 22 and short-circuit component are passed through circuit board perforation (via) 52 bindings.In this case, the voltage standing wave ratio of multifrequency antenna 5 promptly shown in Fig. 5 B, can produce three frequency ranges equally.

Except by circuit board perforation 52, can also pass through other linkage units, link second radiation assembly 22 and short-circuit component 20.For example, please refer to Fig. 6 A, Fig. 6 A is the schematic diagram of a multifrequency antenna 6 of the embodiment of the invention.The framework of multifrequency antenna 6 is similar to multifrequency antenna 5, and difference is that in multifrequency antenna 6 20 of second radiation assembly 22 and short-circuit component are to link by a coupling unit 52A.In this case, the voltage standing wave ratio of multifrequency antenna 6 promptly shown in Fig. 6 B, can produce three frequency ranges equally.

By Fig. 2 A, Fig. 2 B to Fig. 6 A, Fig. 6 B as can be known, the shape of second radiation assembly 22, position, mode of connection etc. all can have different designs according to different situations, and not as limit.In addition, the present invention can also be increasing other radiation assemblies on the short-circuit component 20 or increase other Departments of Radiation on second radiation assembly 22, to reach the purpose of multifrequency.For example, please refer to Fig. 7 A and Fig. 7 B, Fig. 7 A and Fig. 7 B are the schematic diagram of embodiment of the invention multifrequency antenna 71,72.The framework of

multifrequency antenna

71,72 is similar to multifrequency antenna 1, and difference is extra increase by one the 3rd radiation assembly 24 on the short-circuit component 20 of multifrequency antenna 71, and extra one the 3rd Department of Radiation 224 that increases on second radiation assembly 22 of multifrequency antenna 72.It should be noted that Fig. 7 A and Fig. 7 B only in order to variation of the present invention to be described, those of ordinary skills should adjust the radiation assembly quantity on the short-circuit component 20 according to required, or the Department of Radiation quantity that comprised of second radiation assembly 22.

Next the variation of short-circuit component 20 is described.Please refer to Fig. 8 A, Fig. 8 A is the schematic diagram of a multifrequency antenna 8 of the embodiment of the invention.The framework of multifrequency antenna 8 is similar to multifrequency antenna 1, and difference is that multifrequency antenna 8 is the short-circuit component 20 that replace multifrequency antenna 1 with the short-circuit component 20A of a cambered surface.In this case, the voltage standing wave ratio of multifrequency antenna 8 promptly shown in Fig. 8 B, can produce three frequency ranges equally.

In like manner, please refer to Fig. 9 A, Fig. 9 A is the schematic diagram of the embodiment of the invention one multifrequency antenna 9.The framework of multifrequency antenna 9 is similar to multifrequency antenna 1, and difference is that multifrequency antenna 9 is the short-circuit component 20 that replace multifrequency antenna 1 with the short-circuit component 20B on an inclined-plane.In this case, the voltage standing wave ratio of multifrequency antenna 9 promptly shown in 9B figure, can produce three frequency ranges equally.

The variation of first radiation assembly 14 is described at last.Please refer to Figure 10 A to Figure 10 D, Figure 10 A figure to Figure 10 D is the schematic diagram of embodiment of the invention multifrequency antenna 101,102,103 and 104.Multifrequency antenna 101,102,103 and 104 framework are similar to multifrequency antenna 1, difference is all to have increased extra Department of Radiation in multifrequency antenna 101,102,103 and 104 on first radiation assembly 14: in multifrequency antenna 101, increase by one the 3rd Department of Radiation 144 on first Department of Radiation 140 of first radiation assembly 14; In multifrequency antenna 102, first Department of Radiation 140 of first radiation assembly 14 and the intersection of second Department of Radiation 142 increase by one the 3rd Department of Radiation 146; In multifrequency antenna 103, increase by one the 3rd Department of Radiation 148 on second Department of Radiation 142 of first radiation assembly 14; In multifrequency antenna 104, except the 3rd Department of Radiation 148, also the intersection at first Department of Radiation 140 and second Department of Radiation 142 increases by one the 4th Department of Radiation 150.It should be noted that Figure 10 A to Figure 10 D only in order to variation of the present invention to be described, those of ordinary skills should adjust the Department of Radiation quantity that first radiation assembly 14 is comprised, and be not limited thereto according to required.

In addition, the shape of first radiation assembly 14 also is not limited to particular types.For example, please refer to Figure 11 A, Figure 11 A is the schematic diagram of the embodiment of the invention one multifrequency antenna 11.The framework of multifrequency antenna 11 is similar to multifrequency antenna 1, and difference is that multifrequency antenna 11 replaces first radiation assembly 14 of multifrequency antenna 1 with one first radiation assembly 14A; Wherein, the one first Department of Radiation 140A of the first radiation assembly 14A and one second Department of Radiation 142A all include bending structure.In this case, the voltage standing wave ratio of multifrequency antenna 11 promptly shown in Figure 11 B, can produce three frequency ranges equally.

It should be noted that above various embodiment is in order to spirit of the present invention to be described, those of ordinary skills should do suitable variation and modification, and be not limited thereto according to required.Simultaneously, the non-individualism of various embodiment can also be used with mutually, decides on the designer is required.

In sum, multifrequency antenna of the present invention is to increase extra radiation assembly on short-circuit component, so that extra signal path to be provided, thereby reaches the purpose of multifrequency.Therefore, as long as characteristics such as the size of suitable each assembly of adjustment, materials, the present invention promptly can be contained the required frequency band in different wireless communication networking with single antenna, to cooperate the trend of portable wireless communication equipment volume-diminished.

The above only is preferred embodiment of the present invention, and every claims scope is done according to the present invention equivalent variations and modification all should belong to covering scope of the present invention.

Claims

1. multifrequency antenna that is used for a radio communication device comprises:

One grounding assembly is coupled to a ground end;

One first radiation assembly;

One coupling assembling comprises that one first end is coupled to described first radiation assembly, and one second end;

One feed-in assembly is coupled between described second end and described grounding assembly of described coupling assembling, is used for receiving FD feed;

One short-circuit component is coupled between described second end and described grounding assembly of described coupling assembling; And

One second radiation assembly is coupled to described short-circuit component.

2. multifrequency antenna as claimed in claim 1, wherein said first radiation assembly comprises:

One first Department of Radiation is coupled to described first end of described coupling assembling, and extends along a first direction; And

One second Department of Radiation is coupled to described first end of described first Department of Radiation and described coupling assembling, and extends along the rightabout of described first direction.

3. multifrequency antenna as claimed in claim 2, wherein said first Department of Radiation comprises at least one bending.

4. multifrequency antenna as claimed in claim 2, wherein said second Department of Radiation comprises at least one bending.

5. multifrequency antenna as claimed in claim 1, wherein said short-circuit component comprises:

One first short circuit portion is coupled to described second end of described coupling assembling; And

One second short circuit portion is coupled between described first short circuit portion and the described grounding assembly.

6. multifrequency antenna as claimed in claim 5, the angle of wherein said first short circuit portion and the described second short circuit portion is 90 °.

7. multifrequency antenna as claimed in claim 5, wherein said second radiation assembly are coupled to the described first short circuit portion.

8. multifrequency antenna as claimed in claim 5, wherein said second radiation assembly are coupled to the described second short circuit portion.

9. multifrequency antenna as claimed in claim 1, wherein said short-circuit component are one circular-arc.

10. multifrequency antenna as claimed in claim 1, wherein said short-circuit component are a metal arm.

11. multifrequency antenna as claimed in claim 1, wherein said second radiation assembly comprises:

One first Department of Radiation is coupled to described short-circuit component; And

One second Department of Radiation is coupled to described first Department of Radiation.

12. multifrequency antenna as claimed in claim 11, the angle of wherein said first Department of Radiation and second Department of Radiation are 90 degree.

13. multifrequency antenna as claimed in claim 11, wherein said second radiation element also comprises one the 3rd Department of Radiation, is coupled to described second Department of Radiation.

14. multifrequency antenna as claimed in claim 1, it also comprises one the 3rd radiation assembly, is coupled to described short-circuit component.

15. multifrequency antenna as claimed in claim 1, wherein said second radiation assembly are one circular-arc.

16. multifrequency antenna as claimed in claim 1, wherein said second radiation assembly is a metal arm.

17. multifrequency antenna as claimed in claim 1, it also comprises a substrate, described substrate comprises one first and one second, described grounding assembly, described first radiation assembly, described feed-in assembly, described coupling assembling and described short-circuit component are formed at described first, and described second radiation assembly is formed at described second.

18. multifrequency antenna as claimed in claim 17, it also comprises circuit board perforation, is coupled between described second radiation assembly and the described short-circuit component.

19. multifrequency antenna as claimed in claim 17, it also comprises a coupling unit, is coupled between described second radiation assembly and the described short-circuit component.

20. multifrequency antenna as claimed in claim 1, wherein said radio communication device are a notebook computer.