KR101308344B1 - Antenna module - Google Patents

Abstract

The antenna module may include a substrate unit and an antenna unit. The substrate unit comprises at least one carrier substrate having a dielectric constant substantially between 7 and 13. The carrier substrate comprises a dielectric and a plurality of nanoscale microparticulate structures dispersed within the dielectric, each nanoscale microparticulate structure completely enclosing at least one nanoscale carbon particle and at least one nanoscale carbon particle. And nanoscale insulating encapsulation layers for encapsulation. The antenna unit includes at least one antenna track disposed on the carrier substrate. The antenna track has an antenna usage volume that is adjustable within a predetermined volume range according to the VSWR value maintained within the first and second predetermined ranges and the antenna efficiency, wherein the antenna track has at least one supply and at least one ground.

Description

Antenna module {ANTENNA MODULE}

The present invention relates to an antenna module, and more particularly, to an antenna module capable of maintaining the VSWR value and the antenna efficiency in the first and second predetermined ranges, respectively, when the antenna use volume is reduced within a predetermined reduction range.

With the development of wireless communication technology, wireless transmission technology is widely used in mobile information carriers or personal data management tools. For example, electronic products such as notebook computers generally need to transmit / receive data with other data devices. Based on the wireless transmission technology, many structures can be simplified and many connections can be avoided. In order to achieve the above wireless transmission, conventional electronic products must have an antenna, and most electronic products have an antenna device for wireless communication.

It is an object of the present invention to provide an antenna module capable of maintaining the VSWR value and the antenna efficiency in the first and second predetermined ranges, respectively, when the antenna usage volume is reduced within the predetermined reduction range.

One aspect of the present invention relates to an antenna module capable of maintaining the VSWR value and the antenna efficiency in the first and second predetermined ranges, respectively, when the antenna usage volume is reduced within the predetermined reduction range.

One embodiment of the present invention provides an antenna module that may include a substrate unit and an antenna unit. The substrate unit comprises at least one carrier substrate, the at least one carrier substrate having a dielectric constant substantially between 7 and 13 depending on the VSWR value and antenna efficiency within the first and second predetermined ranges, The at least one carrier substrate comprises a dielectric body and a plurality of nanoscale microparticle structures dispersed within the dielectric, each nanoscale microparticle structure comprising at least one nanoscale structure. And nanoscale encapsulation layers for completely encapsulating the carbon particles and the at least one nanoscale carbon particles. The antenna unit includes at least one antenna track disposed on the at least one carrier substrate, wherein the at least one antenna track is dependent on the VSWR value and the antenna efficiency maintained within the first and second predetermined ranges. The antenna usage volume is adjustable within a predetermined volume range, and the antenna track has at least one feeding portion and at least one grounding portion.

Yet another embodiment of the present invention provides an antenna module that may include a substrate unit and an antenna unit. The substrate unit includes at least one carrier substrate, wherein the at least one carrier substrate has a dielectric constant between 7 and 13, depending on the VSWR value and antenna efficiency within the first and second predetermined ranges, The carrier substrate includes a dielectric, a plurality of first nanoscale microparticulate structures dispersed within the dielectric, and a plurality of second nanoscale microparticulate structures dispersed within the dielectric, each of the first nanoscale The microparticulate structure comprises at least one first nanoscale carbon particle and a first nanoscale insulating encapsulation layer for completely encapsulating the at least one first nanoscale carbon particle, each second nanoscale The ultrafine structure completely encapsulates at least one second nanoscale carbon particle and the at least one second nanoscale carbon particle. And a second nano-scale of the insulating layer for sealing group. The antenna unit includes at least one antenna track disposed on the at least one carrier substrate, wherein the at least one antenna track is in a predetermined volume range according to the VSWR value and the antenna efficiency maintained within the first and second predetermined ranges. With an adjustable antenna usage volume into the antenna track, the antenna track has at least one supply and at least one ground.

Thus, when the nanoscale microparticle structures are dispersed within the dielectric or the first and second nanoscale microparticle structures are dispersed within the dielectric, the antenna usage volume of the present invention is reduced to within a predetermined reduction range. The antenna module may be used to maintain the VSWR value and the antenna efficiency in the first and second predetermined ranges, respectively.

In order to further understand the techniques, means and effects of the present invention applied to achieve the above objects, reference is made to the following detailed description and the accompanying drawings, through which the objects, features and aspects of the present invention are fully and It can be specifically understood. However, the accompanying drawings are provided for reference and explanation only without intending to limit the invention.

1A shows a top schematic view of an original antenna module according to the first embodiment of the present invention;
1B shows a partial cross-sectional schematic diagram of an antenna module according to a first embodiment of the present invention;
1C shows a top schematic view of a reduced antenna module according to the first embodiment of the present invention;
1D shows a graph comparing the VSWR value of the original antenna module according to the first embodiment of the present invention with the VSWR value of the reduced antenna module;
1E shows a graph comparing the antenna efficiency of the original antenna module according to the first embodiment of the present invention with the antenna efficiency of the reduced antenna module;
2 shows a partial cross-sectional schematic diagram of an antenna module according to a second embodiment of the present invention;
3 shows a partial cross-sectional schematic diagram of an antenna module according to a third embodiment of the present invention; And
4 shows a partial cross-sectional schematic diagram of an antenna module according to a fourth embodiment of the invention.

[First Embodiment]

1A to 1E, a first embodiment of the present invention provides an antenna module M including a substrate unit 1 and an antenna unit 2. When the volume of use of the antenna is reduced within the predetermined reduction range, the antenna module M may maintain the VSWR value and the antenna efficiency in the first predetermined range and the second predetermined range, respectively. Antenna module (M).

1A and 1B, the substrate unit 1 includes at least one carrier substrate 10. The carrier substrate 10 has a dielectric constant substantially between 7 and 13 depending on the VSWR value and antenna efficiency within the first and second predetermined ranges, and a better dielectric constant is close to ten. In addition, the carrier substrate 10 includes a dielectric material 100 and a plurality of nanoscale microparticle structures 101 dispersed in the dielectric material 100, and each nanoscale microparticle structure 101 includes At least one nanoscale carbon particle 1010 and a nanoscale insulating encapsulation layer 1011 for completely encapsulating the nanoscale carbon particle 1010. For example, the carrier substrate 10 may be a microwave substrate. The nano-scale microparticle structure 101 may be separated from each other inside the dielectric 100 and distributed on average. Most nanoscale microparticle structures 101 may be completely contained within the dielectric 100, and a portion of each of the other nanoscale microparticle structures 101 may be exposed from the dielectric 100. Of course, the nanoscale microparticle structures 101 may also be dispersed within the dielectric 100 unaveragely or unequally. However, the nano-scale microparticle structure 101 used in the first embodiment is merely an example and does not limit the present invention.

1A and 1B, the antenna unit 2 includes at least one antenna track 20 disposed on a carrier substrate 10, the antenna track 20 having a first and second predetermined range. The antenna track 20 has at least one supply portion 200 and at least one ground portion 201, which has an antenna usage volume that is adjustable within a predetermined volume range according to the VSWR value and antenna efficiency maintained therein. In addition, the antenna track 20 has an antenna length L that can be adjusted or adjusted within a predetermined length range according to the VSWR value maintained within the first and second predetermined ranges and the antenna efficiency, and the first and second predetermined ranges. It has an antenna height (H) that can be adjusted or adjusted within a predetermined height range depending on the VSWR value held within and the antenna efficiency, and a substantially uniform antenna thickness (D). The antenna length L may extend from the leftmost side of the antenna track 20 to the rightmost side of the antenna track 20 and the antenna height H may be from the top side of the antenna track 20 of the antenna track 20. It can extend to the lowest side and the antenna length L multiplied by the antenna height H and the antenna thickness D is equal to the antenna usage volume of the antenna track 20.

For example, before the antenna usage volume of the antenna track 20 is reduced (as shown in FIG. 1A), the antenna length L is 70 mm, the antenna height H is 10 mm, and the antenna thickness D is Is 3 mm, the original antenna usage volume of the antenna track 20 can be represented as 70 mm x 10 mm x 3 mm = 2,100 mm ³ , and the antenna track 20 is perfect with a perfect VSWR value (shown in solid lines in FIG. 1D). Antenna efficiency (shown in solid lines in FIG. 1E) can be obtained. After the antenna usage volume of the antenna track 20 is reduced (as shown in FIG. 1C), the antenna length L is reduced to 65 mm, the antenna height H is reduced to 8 mm, and the antenna thickness D is Since is maintained at 3mm, the reduced antenna use volume of the antenna track 20 can be represented as 65mm × 8mm × 3mm = 1,560mm ³ . Although the original antenna usage volume of the antenna track 20 has been reduced by 25%, the VSWR value (shown by the broken line in FIG. 1D) and antenna efficiency (shown by the broken line in FIG. 1E) can also be maintained within a good range. .

For this reason, even if the original antenna use volume of the antenna track 20 has been reduced to a predetermined reduction rate (such as 1% to 25%), the antenna module M is substantially a carrier substrate having a dielectric constant between 7 and 13. The design of (10) allows the VSWR value and the antenna efficiency to be maintained in the good first predetermined range and the good second predetermined range, respectively.

[Second Embodiment]

Referring to FIG. 2, the second embodiment of the present invention can maintain the VSWR value and the antenna efficiency in the first predetermined range and the second predetermined range, respectively, when the antenna use volume is reduced within the predetermined reduction range. An antenna module (M) comprising a unit (1) and an antenna unit (2) is provided. Comparing FIG. 2 with FIG. 1B, the differences between the second embodiment and the first embodiment are as follows: In the second embodiment, the nano-scale microparticle structures 101 may be adjacent to each other inside the dielectric 100. Can be distributed on average. Of course, the nano-scale microparticle structures 101 may also be distributed non-averagely or non-uniformly within the dielectric 100.

However, the nano-scale microparticle structure 101 used in the second embodiment is merely an example and does not limit the present invention. For example, with respect to the arrangement of nanoscale microparticle structures 101, some of the nanoscale microparticle structures 101 may be separated from one another and distributed on average within the dielectric 100. The outer nanoscale microparticle structures 101 may be adjacent to each other and distributed on average within the dielectric 100.

[Third embodiment]

Referring to FIG. 3, the third embodiment of the present invention can maintain the VSWR value and the antenna efficiency in the first predetermined range and the second predetermined range, respectively, when the antenna use volume is reduced within the predetermined reduction range. An antenna module (M) comprising a unit (1) and an antenna unit (2) is provided. Comparing FIG. 3 with FIG. 1B, the differences between the third embodiment and the first embodiment are as follows: In the third embodiment, the carrier substrate 10 is dispersed in the dielectric 100, inside the dielectric 100. A plurality of first nanoscale microparticle structures 101A, and a plurality of second nanoscale microparticle structures 101B dispersed within the dielectric 100. Each first nanoscale microparticle structure 101A has a first nanoscale insulation for completely encapsulating at least one first nanoscale carbon particle 1010A and the first nanoscale carbon particle 1010A. An encapsulation layer 1011A, wherein each second nanoscale microparticle structure 101B is comprised of at least one second nanoscale carbon particle 1010B and the second nanoscale carbon particle 1010B. And a second nanoscale insulating encapsulation layer 1011B for encapsulation. For this reason, the carrier substrate 10 having a dielectric constant substantially between 7 and 13 can be manufactured using at least two types of nanoscale microparticle structures.

For example, the first nanoscale microparticle structure 101A can be separated from each other and distributed on an average within the dielectric 100, and the second nanoscale microparticle structure 101B can be a dielectric material 100. Internally they can be separated from each other and distributed on average. Of course, the first nanoscale microparticulate structures 101A and the second nanoscale microparticulate structures 101B may also be non-averaged or nonuniformly dispersed within the dielectric 100. However, the first nanoscale microparticle structure 101A or the second nanoscale microparticle structure 101B used in the third embodiment is merely an example and does not limit the present invention.

[Fourth Embodiment]

Referring to FIG. 4, the fourth embodiment of the present invention can maintain the VSWR value and the antenna efficiency in the first predetermined range and the second predetermined range, respectively, when the antenna use volume is reduced within the predetermined reduction range. An antenna module (M) comprising a unit (1) and an antenna unit (2) is provided. Comparing FIG. 4 with FIG. 3, the differences between the fourth embodiment and the third embodiment are as follows: In the fourth embodiment, the first nanoscale microparticle structures 101A are interconnected inside the dielectric 100. Adjacent and averagely dispersed, the second nanoscale microparticle structures 101B are adjacent to each other and averagely dispersed within the dielectric 100. Of course, the first nanoscale microparticulate structures 101A and the second nanoscale microparticulate structures 101B may also be non-averagely or nonuniformly dispersed in the dielectric 100.

However, the first nanoscale microparticle structure 101A or the second nanoscale microparticle structure 101B used in the fourth embodiment is just one example and does not limit the present invention. For example, with respect to the arrangement of the first nanoscale microparticulate structures 101A, portions of the first nanoscale microparticulate structures 101A are separated from each other and averagely dispersed within the dielectric 100, and The outer first nanoscale microparticle structures 101A are adjacent to each other and averagely dispersed within the dielectric 100. With respect to the arrangement of the second nanoscale microparticle structures 101B, some of the second nanoscale microparticle structures 101B are separated from each other and averagely dispersed within the dielectric 100, and the other second nanoscales. The microparticle structures 101B of scale are adjacent to each other and are distributed on average within the dielectric 100.

Finally, if the nanoscale microparticulate structures are dispersed within the dielectric or the first and second nanoscale microparticulate structures are dispersed within the dielectric, the antenna usage volume of the present invention is reduced within a predetermined reduction range, The antenna module may be used to maintain the VSWR value and the antenna efficiency in the first and second predetermined ranges, respectively.

The foregoing description merely shows preferred embodiments of the invention, without any intention or ability to limit the scope of the invention as fully set forth in the claims below. Based on the claims of the present invention, various corresponding alterations, modifications or modifications are therefore all considered to be within the scope of the present invention.

1: substrate unit
2: antenna unit
M: antenna unit
10: carrier substrate
20: antenna track
100: dielectric
101, 101A, 101B: microparticle structure
1010, 1010A, 1010B: Carbon Particles
1011, 1011A, 1011B: insulation encapsulation layer
200: supply unit
201: grounding part

Claims (10)

An antenna module capable of maintaining a VSWR value and an antenna efficiency in a first and a second predetermined range, respectively, when an antenna use volume is reduced within a predetermined reduction range,
A substrate unit comprising at least one carrier substrate, said at least one carrier substrate having a dielectric constant substantially between 7 and 13 depending on the VSWR value and antenna efficiency within the first and second predetermined ranges; The at least one carrier substrate comprises a dielectric body and a plurality of nanoscale microparticle structures dispersed within the dielectric, each nanoscale microparticle structure comprising at least one nanoscale A nanoscale encapsulation layer for completely encapsulating the at least one nanoscale carbon particle and the carbon particles of;
An antenna unit including at least one antenna track disposed on the at least one carrier substrate, wherein the at least one antenna track is maintained within a first and second predetermined range and antenna efficiency And an antenna usage volume adjustable within a predetermined volume range, wherein the antenna track has at least one feeding portion and at least one grounding portion. The method of claim 1,
And said nanoscale microparticulate structures are separated from each other and averagely dispersed within said dielectric. The method of claim 1,
And said nanoscale microparticle structures are adjacent to each other and averagely dispersed within said dielectric. The method of claim 1,
And wherein some of the nanoscale microparticulate structures are separated from each other and averagely dispersed within the dielectric, and other nanoscale microparticulate structures are adjacent to each other and averagely distributed within the dielectric. The method of claim 1,
The at least one antenna track is an antenna length adjustable within a predetermined length range according to a VSWR value maintained within the first and second predetermined ranges and an antenna efficiency, a VSWR value maintained within the first and second predetermined ranges and an antenna Antenna height adjustable within a predetermined height range according to efficiency, and uniform antenna thickness,
The antenna length extends from the leftmost side of the at least one antenna track to the rightmost side of the at least one antenna track, and the antenna height extends from the uppermost side of the at least one antenna track to the lowermost side of the at least one antenna track. And an antenna length multiplied by an antenna height and an antenna thickness is equal to an antenna usage volume of said at least one antenna track. An antenna module capable of maintaining a VSWR value and an antenna efficiency in a first and a second predetermined range, respectively, when an antenna use volume is reduced within a predetermined reduction range,
A substrate unit comprising at least one carrier substrate, said at least one carrier substrate having a dielectric constant substantially between 7 and 13, depending on the VSWR value and antenna efficiency within the first and second predetermined ranges; A carrier substrate comprises a dielectric, a plurality of first nanoscale microparticulate structures dispersed within the dielectric, and a plurality of second nanoscale microparticulate structures dispersed within the dielectric, each first nanoscale The microparticulate structure of includes at least one first nanoscale carbon particle and a first nanoscale insulating encapsulation layer for completely encapsulating the at least one first nanoscale carbon particle, each second nanoscale The ultrafine structure of the at least one second nanoscale carbon particles and the at least one second nanoscale carbon particles completely A second nano-scale of the insulating encapsulation layer to the support;
An antenna unit including at least one antenna track disposed on the at least one carrier substrate, wherein the at least one antenna track is predetermined according to a VSWR value and antenna efficiency maintained within the first and second predetermined ranges; And an antenna usage volume that is adjustable within the volume range of the antenna track, wherein the antenna track has at least one supply and at least one ground. The method according to claim 6,
And wherein the first nanoscale microparticulate structures are separated from each other and averagely dispersed within the dielectric, and the second nanoscale microparticulate structures are separated from each other and averagely distributed within the dielectric. The method according to claim 6,
And wherein the first nanoscale microparticle structures are adjacent to each other and averagely dispersed within the dielectric, and the second nanoscale microparticle structures are adjacent to each other and averagely dispersed within the dielectric. The method according to claim 6,
Some of the first nanoscale microparticulate structures are separated from each other and averagely dispersed within the dielectric, and other first nanoscale microparticulate structures are adjacent to each other and averagely dispersed within the dielectric, and the second And wherein some of the nanoscale microparticulate structures are separated from each other and averagely dispersed within the dielectric, and the other second nanoscale microparticulate structures are adjacent to each other and averagely distributed within the dielectric. The method according to claim 6,
The at least one antenna track has a VSWR value maintained within a first and second predetermined range and an antenna length adjustable within a predetermined length range according to the antenna efficiency, a VSWR value maintained within the first and second predetermined range and an antenna efficiency. According to the antenna height adjustable within a predetermined height range, and has a uniform antenna thickness,
The antenna length extends from the leftmost side of the at least one antenna track to the rightmost side of the at least one antenna track, and the antenna height extends from the uppermost side of the at least one antenna track to the lowermost side of the at least one antenna track. And an antenna length multiplied by an antenna height and an antenna thickness is equal to an antenna usage volume of said at least one antenna track.

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