The present invention contains subject matter related to Japanese Patent Application JP 2008-5516 filed in the Japanese Patent Office on Jan. 15, 2008, the entire contents of which being incorporated herein by reference.
1. Field of the Invention
The present invention relates to a surface mount antenna and an antenna module used for a radio communication device such as mobile phone.
2. Background Art
As shown in
Japanese Unexamined Patent Publication No. 2003-08326 discloses a surface mount antenna in a configuration where a feed radiation conductor and a parasitic radiation conductor are formed in a ring shape respectively in the same plane. Japanese Unexamined Patent Publication No. 2003-51705 discloses a surface mount antenna in a configuration where a feed radiation conductor and a parasitic radiation conductor are patterned such that respective open ends of the conductors are not adjacently disposed, but disposed away from each other.
To achieve broadband, for example, as shown in
In the structure described in Japanese Unexamined Patent Publication No. 2003-08326, the radiation conductors configuring the feed element and parasitic element are formed into a ring shape respectively, which reduces the number of points at which a physical distance between the feed element and the parasitic element is decreased, therefore the resonance frequency f1 can be made close to the resonance frequency f2. However, the radiation conductors are formed into a ring shape respectively in the same plane, which prevents reduction in size of an antenna as a whole.
In the structure described in Japanese Unexamined Patent Publication No. 2003-51705, the open ends of the respective elements are disposed at positions away from each other to decrease the amount of electromagnetic coupling between the feed element and the parasitic element, therefore the radiation conductors are significantly different in electric length from each other, and the two resonance frequency f1 and f2 are considerably separated from each other, and consequently the structure is not suitable to meet the issue that the two resonance frequencies f1 and f2 are made close to each other to achieve broadband as shown in
In view of forgoing, it is desirable to provide a surface mount antenna and an antenna module, in which both of small size and broadband can be achieved.
A surface mount antenna according to an embodiment of the invention includes a substrate including a dielectric material or a magnetic material as a main material; a feed radiation conductor formed on a surface of the substrate, one end of the feed radiation conductor being formed as a first feed end to be supplied with power, and the other end thereof being formed as a first open end; and a parasitic radiation conductor formed on the surface of the substrate at a distance from the feed radiation conductor, one end of the parasitic radiation conductor being formed as a second feed end to be supplied with power from the feed radiation conductor through an action of electromagnetic coupling, and the other end thereof being formed as a second open end; wherein a region having a dielectric constant lower than that of the main material of the substrate or having a magnetic permeability lower than that of the main material of the substrate is provided between the feed radiation conductor and the parasitic radiation conductor.
An antenna module according to an embodiment of the invention is configured by mounting the surface mount antenna according to an embodiment of the invention on a circuit board.
In the surface mount antenna or the antenna module according to an embodiment of the invention, the region having a lower dielectric constant than a dielectric constant of the substrate (or the region having a lower magnetic permeability than a magnetic permeability of the substrate) is provided between the feed radiation conductor and the parasitic radiation conductor, so that the amount of electromagnetic coupling between the radiation conductors can be decreased. The amount of electromagnetic coupling between the radiation conductors is decreased, thereby resonance frequencies of the radiation conductors can be made close to each other within a range where double resonance may be established, so that broadband can be achieved. In the past, a physical distance between the radiation conductors has been necessary to be increased in order to decrease the amount of electromagnetic coupling, and therefore small size has been hardly achieved. However, in an embodiment of the invention, the region having a low dielectric constant (or the region having a low magnetic permeability) is provided, thereby a small broadband antenna using double resonance can be achieved without increasing the physical distance.
In the surface mount antenna according to an embodiment of the invention, the region having a low dielectric constant (or the region having a low magnetic permeability) can be achieved by forming one or more grooves on the substrate in at least a part of a region between the feed radiation conductor and the parasitic radiation conductor. Inside spaces of the grooves function as the region having a low dielectric constant or a low magnetic permeability.
In this case, the grooves are formed as an air layer, so that the grooves are reduced in dielectric constant (or magnetic permeability) compared with the substrate.
In the surface mount antenna according to an embodiment of the invention, the substrate may have a rectangular solid shape with a first surface, a second surface perpendicular to the first surface and a third surface opposed to the first surface, and the feed radiation conductor and the parasitic radiation conductor may be formed in parallel with each other to extend around the substrate along the first, the second and the third surfaces.
In the surface mount antenna according to an embodiment of the invention, the first feed end of the feed radiation conductor and the second feed end of the parasitic radiation conductor may be located on the first surface of the substrate. A width, at least at the first feed end, of the feed radiation conductor on the first surface may be larger than a width of the feed radiation conductor on the other surfaces, and a width, at least at the second feed end, of the parasitic radiation conductor on the first surface may be larger than a width of the parasitic radiation conductor on the other surfaces.
In the case of such a configuration, a conductor at a feed side, through which much current flows, is formed larger in width, so that a resistance value is decreased in such a portion, leading to ease in current flow. This improves radiation efficiency.
Furthermore, in this case, the first open end of the feed radiation conductor and the second open end of the parasitic radiation conductor may be located on the third surface of the substrate. In addition, grooves may be formed on at least the first surface and the third surface of the substrate in a region between the feed radiation conductor and the parasitic radiation conductor, and a groove formed in the third surface may be larger than that formed in the first surface.
In a case of such a configuration, conductor width at a feed side is made larger, thereby even if the amount of electromagnetic coupling increases at the feed side, the amount of electromagnetic coupling can be decreased at the open end side by the groove formed in the third surface.
Alternatively, in the surface mount antenna according to an embodiment of the invention, the first open end of the feed radiation conductor and the second open end of the parasitic radiation conductor may be located on the third surface of the substrate. A width, at least at the first open end, of the feed radiation conductor on the third surface may be larger than a width of the feed radiation conductor on the other surfaces, and a width, at least at the second open end, of the parasitic radiation conductor on the third surface may be larger than a width of the parasitic radiation conductor on the other surfaces.
In the case of such a configuration, width of a conductor at an open end side is formed larger, so that resonance frequency can be reduced, leading to ease in size reduction.
Furthermore, in this case, the first feed end of the feed radiation conductor and the second feed end of the parasitic radiation conductor may be located on the first surface of the substrate. In addition, grooves may be formed on at least the first surface and the third surface of the substrate in a region between the feed radiation conductor and the parasitic radiation conductor, and a groove formed in the first surface may be larger than that formed in the third surface.
In a case of such a configuration, conductor width at an open end side is made larger, thereby even if the amount of electromagnetic coupling increases at the open end side, the amount of electromagnetic coupling can be decreased at the feed side by the groove formed in the first surface.
In the surface mount antenna according to an embodiment of the invention, a conductor portion in a neighborhood of the first open end in the feed radiation conductor and a conductor portion in a neighborhood of the second open end in the parasitic radiation conductor may be configured to extend onto different surfaces which are perpendicular to the first to third surfaces.
In this case, since each conductor is configured to extend onto different surfaces, conductor length is increased, and thereby resonance frequency can be reduced, leading to ease in size reduction.
The surface mount antenna according to an embodiment of the invention further includes a circuit element for adjusting a frequency characteristic. The circuit element may be connected, via a capacitor, to the first open end of the feed radiation conductor, or to the second open end of the parasitic radiation conductor, or to both of them.
In this case, for example, an inductance element or a capacitance element is provided as the circuit element for adjusting a frequency characteristic via capacitance, which enables adjustment of the amount of electromagnetic coupling occurring via a ground electrode on the circuit board. Thus, an interval and central frequency of double resonance may be adjusted. Therefore, even if frequency is shifted due to other components disposed near an antenna, the frequency can be readjusted to a desired frequency, consequently various devices may be managed by a single antenna, the devices being disposed near the antenna, and having different components. Moreover, a frequency characteristic is adjusted at a circuit element side, thereby an antenna can be formed into an approximately symmetric configuration, leading to reduction in dependence on a feed direction.
In the antenna module according to an embodiment of the invention, the surface mount antenna is preferably mounted such that the first open end of the feed radiation conductor and the second open end of the parasitic radiation conductor is situated to point inward on the circuit board.
Thus, radiation efficiency is improved compared with a case where the antenna is mounted such that the open end is situated at an outer side on the circuit board.
According to the surface mount antenna or the antenna module of an embodiment of the invention, a region having a lower dielectric constant than a dielectric constant of a substrate (or a region having a lower magnetic permeability than a magnetic permeability of the substrate) is provided between a feed radiation conductor and a parasitic radiation conductor. Therefore, the amount of electromagnetic coupling between the radiation conductors can be decreased without increasing a physical distance between the radiation conductors. In addition, resonance frequencies of the radiation conductors can be made close to each other, so that broadband can be achieved without increasing a physical distance between the radiation conductors. Thus, both of small size and broadband can be achieved.
Other and further objects, features and advantages of the invention will appear more fully from the following description.
Hereinafter, embodiments of the invention will be described in detail with reference to drawings.
The antenna module has a plate-like circuit board 2, and the surface mount antenna 1 mounted on a top of the circuit board 2. On the top of the circuit board 2, a ground electrode layer 24 is formed in regions other than a region where the surface mount antenna 1 is mounted. Moreover, on the top of the circuit board 2, a feed section 23 to be connected to an external signal source 25 (
The surface mount antenna 1 has a dielectric substrate 10 configured of a dielectric block having an approximately rectangular shape including a dielectric material as a main material. On a surface of the dielectric substrate 10, a feed radiation conductor 11 as a main radiation element (feed element), and a parasitic radiation conductor 12 as a parasitic element are formed by a line pattern of a conductor (strip line).
The feed radiation conductor 11 has one end 11A as a first feed end being connected to the signal source 25 via the source connection electrode 21 and the feed section 23 formed on the circuit board 2 so that power is supplied from a side of the one end 11A, and has the other end 11B formed to be a first open end (signal radiation side). The one end 11A of the feed radiation conductor 11 is formed such that it slightly comes into a bottom of the dielectric substrate 10 as shown in
The parasitic radiation conductor 12 has one end 12A as a second feed end being connected to the ground electrode layer 24 via the ground connection terminal electrode 22 formed on the circuit board 2 and thus shorted. The parasitic radiation conductor 12 is supplied with power on a side of the one end 12A via the feed radiation conductor 11 by electromagnetic coupling. The one end 12A of the parasitic radiation conductor 12 is formed such that it slightly comes into a bottom of the dielectric substrate 10 as shown in
The feed radiation conductor 11 and the parasitic radiation conductor 12 are formed in a parallel manner with a certain interval such that each conductor goes around a first surface of the dielectric substrate 10 (one side face shown in
The surface mount antenna 1 has a region having a lower dielectric constant than that of the dielectric substrate 10 between the feed radiation conductor 11 and the parasitic radiation conductor 12. More specifically, portions (a substrate top portion 41A and substrate side portions 41B and 41C) corresponding to a region of the dielectric substrate 10 between the feed radiation conductor 11 and the parasitic radiation conductor 12 are formed into a groove shape, and each portion formed into the groove shape is formed as an air layer, thereby the periphery of a substrate center portion 40 is made as a region having a low dielectric constant except a bottom of the portion 40. The substrate top portion 41A and the substrate side portions 41B and 41C are made to be approximately the same in groove width and in groove depth.
In the surface mount antenna 1, as shown in
The circuit connection electrodes 31 and 32 are connected with adjustment circuit elements 53 and 54 for adjusting a frequency characteristic as shown in the equivalent circuit of
The adjustment circuit elements 53 and 54 may be provided at the open end of only one of the feed radiation conductor 11 and the parasitic radiation conductor 12.
The surface mount antenna 1 of the embodiment can be manufactured, for example, according to the following process.
(1) First, dielectric granules are molded into a block body having a rectangular shape by die molding, and then the block body is baked and thus a dielectric sintered body is obtained. In such molding, when a die is used, the die being beforehand shaped to have a configuration corresponding to the groove of the dielectric substrate 10, grooving is not necessary after baking. When the groove configuration is not formed by die molding, the block body having the rectangular shape is subjected to grooving by using a processing machine such as an outer slicer.
(2) The sintered body is used as the dielectric substrate 10, and silver paste (Au, Cu or Al paste may be used instead) to be a radiation conductor and the like is printed thereon, and then baked in air atmosphere by a tunnel baking furnace or the like. The conductor is printed after forming the groove, thereby waste of silver paste can be prevented.
Next, operation of the antenna module according to the embodiment is described together with an advantage.
In the antenna module, power is supplied from the external signal source 25 to the one end 11A of the feed radiation conductor 11 via the feed connection electrode 21 and the feed section 23 formed on the circuit board 2, and power is supplied to the parasitic radiation conductor 12 via the feed radiation conductor 11 by electromagnetic coupling. This induces double resonance of the feed radiation conductor 11 and the parasitic radiation conductor 12, consequently antenna operation is performed at a desired frequency band.
In the antenna module, the region having a lower dielectric constant than that of the dielectric substrate 10 is provided between the feed radiation conductor 11 and the parasitic radiation conductor 12 of the surface mount antenna 1, thereby the amount of electromagnetic coupling between the radiation conductors can be decreased. The amount of electromagnetic coupling between the radiation conductors is decreased, thereby resonance frequencies of the radiation conductors can be made close to each other within a range where double resonance is established, leading to achievement of broadband. In the past, a physical distance between the radiation conductors has been necessary to be increased to decrease the amount of electromagnetic coupling, and therefore size reduction has been difficult. However, in the surface mount antenna 1, since the region having a low dielectric constant is provided, a small broadband antenna using double resonance can be achieved without increasing a physical distance.
In the antenna module, the adjustment circuit elements 53 and 54 for adjusting a frequency characteristic are connected to the open ends of the feed radiation conductor 11 and the parasitic radiation conductor 12 of the surface mount antenna 1 via capacitance 51C and 52C (gap portions 51 and 52) respectively, therefore the amount of electromagnetic coupling occurring via the ground electrode layer 24 on the circuit board 2 can be adjusted. Thus, an interval and central frequency of double resonance can be adjusted. Therefore, even if frequency is shifted due to other components disposed near the surface mount antenna 1, frequency can be readjusted to a desired frequency, consequently various devices may be managed by a single antenna, the devices being disposed near the antenna, and having different components. Moreover, since a frequency characteristic is adjusted at a circuit element side, an antenna can be formed into an approximately symmetric configuration, leading to reduction in dependence on a feed direction.
Here, a preferable mounting position of the surface mount antenna 1 with respect to the circuit board 2 is described with reference to
As described hereinbefore, according to an embodiment of the invention, since the region having a lower dielectric constant than that of the dielectric substrate 10 is provided between the feed radiation conductor 11 and the parasitic radiation conductor 12, the amount of electromagnetic coupling between the radiation conductors can be decreased without increasing a physical distance between the radiation conductors, and consequently resonance frequencies of the respective radiation conductors can be made close to each other, leading to achievement of broadband. Thus, both small size and broadband can be achieved.
Next, a second embodiment of the invention is described. Substantially the same components as in the antenna module according to the first embodiment are marked with the same symbols, and description of them is appropriately omitted.
The surface mount antenna 1 according to the first embodiment is configured such that each of the feed radiation conductor 11 and the parasitic radiation conductor 12 has approximately the same conductor width on the first to third surfaces respectively. However, the embodiment is configured such that each conductor is partially varied in configuration and size. In addition, the surface mount antenna 1 according to the first embodiment is configured such that the groove is approximately the same in width and depth in the substrate top portion 41A and the substrate side portions 41B and 41C respectively. However, the embodiment is configured such that a groove is partially varied in configuration and size.
Specifically, each of the feed radiation conductor 11 and the parasitic radiation conductor 12 at the feed side formed on the first surface (one side face) is configured such that its conductor width is large compared with conductor portions formed on other surfaces. More specifically, each of conductors 11 and 12 is configured to have such a tapered shape that the conductor becomes wider with approaching an end at a feed side (one end 11A or 12A) (refer to
Moreover, each of grooves formed in the second surface (substrate top portion 41A) and the third surface (substrate side portion 41C) of the dielectric substrate 10 is configured to be larger than a groove formed in the first surface (substrate side portion 41B) thereof. Thus, even if the amount of electromagnetic coupling increases at the feed side due to the increased conductor width at the feed side, since grooves are formed larger in other surfaces, the amount of electromagnetic coupling can be decreased particularly at an open end side.
Next, a third embodiment of the invention is described. Substantially the same components as in the antenna module according to each of the above embodiments are marked with the same symbols, and description of them is appropriately omitted.
As in the surface mount antenna 1A according to the second embodiment, the surface mount antenna 1B according to the embodiment is configured such that each of the feed radiation conductor 11 and the parasitic radiation conductor 12 is partially varied in conductor configuration and size. In addition, the embodiment is configured such that grooves of the dielectric substrate 10 are partially different in configuration and size from one another.
Specifically, each of the feed radiation conductor 11 and the parasitic radiation conductor 12 at the feed side formed on the first surface (one side face) is configured such that its conductor width is large compared with conductor portions formed on other surfaces. More specifically, each of conductors 11 and 12 is configured to be generally wider on the first surface (refer to
Moreover, each of grooves formed in the second surface (substrate top portion 41A) and the third surface (substrate side portion 41C) of the dielectric substrate 10 is configured to be larger than a groove formed in the first surface (substrate side portion 41B) thereof. Thus, even if the amount of electromagnetic coupling increases at the feed side due to the increased conductor width at the feed side, since grooves on other surfaces are formed larger, the amount of electromagnetic coupling can be decreased particularly at the open end side.
Next, a fourth embodiment of the invention is described. Substantially the same components as in the antenna module according to each of the above embodiments are marked with the same symbols, and description of them is appropriately omitted.
As in the surface mount antenna 1A according to the second embodiment, the surface mount antenna 1C according to the embodiment is configured such that each of the feed radiation conductor 11 and the parasitic radiation conductor 12 is partially varied in conductor configuration and size. In addition, the embodiment is configured such that grooves of the dielectric substrate 10 are partially different in configuration and size from one another. However, while the second embodiment is configured such that conductor width is larger at the feed side, the surface mount antenna 1C according to the embodiment is configured such that conductor width is larger at the open end side.
Specifically, each of the feed radiation conductor 11 and the parasitic radiation conductor 12 at the open end side formed on the third surface (the other side face) is configured such that its conductor width is large compared with conductor portions formed on other surfaces. More specifically, each of conductors 11 and 12 is configured to be generally wider on the third surface (refer to
Moreover, each of grooves formed in the second surface (substrate top portion 41A) and the first surface (substrate side portion 41B) of the dielectric substrate 10 is configured to be larger than a groove formed in the third surface (substrate side portion 41C) thereof. Thus, even if the amount of electromagnetic coupling increases at the open end side due to the increased conductor width at the open end side, since grooves on other surfaces are formed larger, the amount of electromagnetic coupling can be decreased particularly at the feed side.
Next, a fifth embodiment of the invention is described. Substantially the same components as in the antenna module according to each of the above embodiments are marked with the same symbols, and description of them is appropriately omitted.
As in the surface mount antenna 1C according to the fourth embodiment, the surface mount antenna 1D according to the embodiment is configured such that each of the feed radiation conductor 11 and the parasitic radiation conductor 12 is partially varied in conductor configuration and size. In addition, the embodiment is configured such that grooves of the dielectric substrate 10 are partially different in configuration and size from one another.
Specifically, each of the feed radiation conductor 11 and the parasitic radiation conductor 12 at the open end side formed on the third surface (the other side face) is configured such that its conductor width is large compared with conductor portions formed on other surfaces. More specifically, each of conductors 11 and 12 is configured to have such a tapered shape that the conductor becomes wider with approaching an end at the open end side (the other end 11B or 12B) (refer to
Moreover, each of grooves formed in the second surface (substrate top portion 41A) and the first surface (substrate side portion 41B) of the dielectric substrate 10 is configured to be larger than a groove formed in the third surface (substrate side portion 41C) thereof. Thus, even if the amount of electromagnetic coupling increases at the open end side due to the increased conductor width at the open end side, since grooves on other surfaces are formed larger, the amount of electromagnetic coupling can be decreased particularly at the feed side.
Next, a sixth embodiment of the invention is described. Substantially the same components as in the antenna module according to each of the above embodiments are marked with the same symbols, and description of them is appropriately omitted.
The surface mount antenna 1E according to the embodiment is configured such that a conductor at an open end side of each of the feed radiation conductor 11 and the parasitic radiation conductor 12 is extended compared with the surface mount antenna 1 according to the first embodiment. Specifically, the other end 11B of the feed radiation conductor 11 is extensionally formed such that it comes from the third surface into a different surface perpendicular to the first to third surfaces (refer to a conductor portion 11C shown in
According to the surface mount antenna 1E according to the embodiment, since each conductor is formed such that it comes into the different surface, conductor length is increased, and thereby resonance frequency can be reduced, leading to ease in size reduction.
Next, a seventh embodiment of the invention is described. Substantially the same components as in the antenna module according to each of the above embodiments are marked with the same symbols, and description of them is appropriately omitted.
In the surface mount antenna 1 according to the first embodiment, the groove is formed in each of the substrate top portion 41A and the substrate side portions 41B and 41C of the dielectric substrate 10. However, in the embodiment, a groove is not formed in the substrate top portion 41A, and formed only in the substrate side portions 41B and 41C. Even if a groove is provided only partially in this way, small size and broadband can be achieved compared with a previous structure.
Next, an eighth embodiment of the invention is described. Substantially the same components as in the antenna module according to each of the above embodiments are marked with the same symbols, and description of them is appropriately omitted.
In the surface mount antenna 1 according to the first embodiment, the groove is formed in each of the substrate top portion 41A and the substrate side portions 41B and 41C of the dielectric substrate 10. However, in the embodiment, a groove is not formed in the substrate top portion 41A and in one substrate side portion 41B, and formed only in the other substrate side portion 41C. Even if a groove is provided only in the other substrate side portion 41C in this way, small size and broadband can be achieved compared with a previous structure.
While not shown, the groove may be provided only in one substrate side portion 41B.
Next, a ninth embodiment of the invention is described. Substantially the same components as in the antenna module according to each of the above embodiments are marked with the same symbols, and description of them is appropriately omitted.
The invention is not limited to the above embodiments, and may be carried out in variously modified modes. For example, in each of the above embodiments, grooves are provided in the dielectric substrate 10 to be formed as the air layer, thereby a region having a low dielectric constant is provided. However, the region may be formed using a different dielectric layer instead of the air layer. For example, an embodiment of the invention may be configured such that each groove portion of the dielectric substrate 10 in each of the above embodiments is filled with a dielectric having a low dielectric constant compared with the dielectric substrate 10.
Moreover, for example, the first embodiment was described on a case that the feed radiation conductor 11 and the parasitic radiation conductor 12 were formed such that each conductor went around the first surface (one side face), the second surface (top), and the third surface (the other side face) of the dielectric substrate 10. However, formation positions of the feed radiation conductor 11 and the parasitic radiation conductor 12 are not limited to those in such a configuration. For example, an embodiment of the invention may be configured such that each radiation conductor is formed only on the first and second surfaces.
Moreover, each of the above embodiments was described assuming that a substrate included the dielectric substrate 10 including a dielectric material as a main material. However, a magnetic substrate including a magnetic material as a main material may be used as the substrate. In this case, a “region having a low magnetic permeability” can be provided instead of the “region having a low dielectric constant” in each of the above embodiments. The “region having a low magnetic permeability” may be an air layer given by forming a groove, or may be a different magnetic layer configured of a magnetic material with a lower magnetic permeability, which fills the groove.
It should be understood by those skilled in the art that various modifications, combinations, sub-combinations and alterations may occur depending on design requirements and other factors insofar as they are within the scope of the appended claims or the equivalent thereof.
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2008-005516 | Jan 2008 | JP | national |
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Number | Date | Country | |
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20090179815 A1 | Jul 2009 | US |