1. Technical Field
The present disclosure relates to an antenna device.
2. Description of the Related Art
As a conventional antenna device, an antenna device for base station that includes a dielectric substrate and a parasitic element has been known. In the dielectric substrate, a grounding conductor plate provided with a slot is formed on one surface and a strip conductor is formed on the other surface. The parasitic element is provided so as to face the grounding conductor plate (see Japanese Unexamined Patent Application Publication No. 2002-359517, for instance).
In the antenna device for base station of Japanese Unexamined Patent Application Publication No. 2002-359517, an antenna has directivity in a direction of +Z axis of the parasitic element 400. In technology of Japanese Unexamined Patent Application Publication No. 2002-359517, it is difficult to maintain gain of the antenna of the antenna device for base station by tilting the directivity of the antenna to a desired direction (substrate horizontal direction, for instance).
One non-limiting and exemplary embodiment provides an antenna device in which directivity of an antenna can favorably be tilted so that gain of the antenna can be improved.
In one general aspect, the techniques disclosed here feature an antenna device including a dielectric substrate, a conductor plate that is placed on one surface of the dielectric substrate, that includes a first slot element, a second slot element, and one or more slits, and a ground conductor that is placed at a specified distance from the conductor plate in a first direction, a center of the first slot element is placed between a center of the second slot element and a center of each of slits, in a second direction.
According to the disclosure, the directivity of the antenna can favorably be tilted so that the gain of the antenna can be improved.
Additional benefits and advantages of the disclosed embodiments will become apparent from the specification and drawings. The benefits and/or advantages may be individually obtained by the various embodiments and features of the specification and drawings, which need not all be provided in order to obtain one or more of such benefits and/or advantages.
Hereinbelow, an embodiment of the disclosure will be described with reference to the drawings.
A use case illustrated in
For the embodiment below, the antenna device in which the directivity of an antenna can favorably be tilted so that the gain of the antenna can be improved will be described.
The antenna device of the embodiment is used for a radio communication circuit for high-frequency waves in millimeter band (60 GHz, for instance), for instance, and various electronic components (such as antenna and semiconductor chips) are mounted on the antenna device. The antenna device operates as a slot antenna with slits, for instance.
The antenna device 10 includes the first dielectric substrate 100, the second dielectric substrate 101, a third dielectric substrate 102, the ground conductor 103, the pattern 104, a radiating element 105, a reflector element 106, the feeder 107, and the slits 110. That is, the antenna device 10 includes the multilayer substrate. The pattern 104 has a substantially square shape in plan view, for instance, and is formed of metal conductor (such as copper foil).
The first dielectric substrate 100, the second dielectric substrate 101, and the third dielectric substrate 102 are substrates having a relative dielectric constant of Er (3.6, for instance). The first dielectric substrate 100, the second dielectric substrate 101, and the third dielectric substrate 102 are placed so as to be substantially parallel to one another.
In
In the embodiment, one surface side (+Z side) of the first dielectric substrate 100 is referred to as a first layer (L1 layer) and the one surface side (+Z side) of the second dielectric substrate 101 is referred to as a second layer (L2 layer). The one surface side (+Z side) of the third dielectric substrate 102 is referred to as a third layer (L3 layer) and the other surface side (−Z side) of the third dielectric substrate 102 is referred to as a fourth layer (L4 layer).
In
In the L1 layer, the pattern 104 that is formed of the copper foil pattern and that is substantially square, for instance, is placed on the one surface side (+Z side) of the first dielectric substrate 100. The radiating element 105 and the reflector element 106 that are formed by cutting of portions of the pattern 104 in shape of slots are provided on the pattern 104. The radiating element 105 is an example of the first slot element. The reflector element 106 is an example of the second slot element.
With respect to the X direction, the pattern 104 is placed on a side (−X side) opposite to a radiation direction from center of the first dielectric substrate 100, for instance. Radio waves radiated from the pattern 104 are guided into the first dielectric substrate 100 and are propagated through inside of the first dielectric substrate 100. The radiation direction (beam) of the radio waves is thereby inclined in the +X direction.
The radiating element 105 and the reflector element 106 are placed so as to be substantially parallel to each other in the L1 layer. The reflector element 106 is longer than the radiating element 105 in a longitudinal direction (Y direction in
The radiating element 105 operates as a radiator for radiating the radio waves. Therefore, a slot length (length in the longitudinal direction of the radiating element 105 in
The reflector element 106 operates as a reflector. Therefore, a distance d between the radiating element 105 and the reflector element 106 is set to be approximately ¼ λg. Setting of the distance d at approximately ¼ λg makes it possible to tilt the directivity of the antenna from a horizontal direction (XY direction) or a vertical direction (Z direction) for the substrate. A slot length (length in the longitudinal direction of the reflector element 106 in
Length from the radiating element 105 to an end side of the first dielectric substrate 100 that faces the reflector element 106 (on −X side) is dx1 (1.15 λg, for instance). Length from the radiating element 105 to an end side of the first dielectric substrate 100 that exists in the radiation direction (on +X side) is dx2 (2.89 λg, for instance).
The pattern 104 includes the slits 110 that are formed by cutting of portions of the pattern 104, in end parts (an example of the second end parts) of the pattern 104 with respect to the Y direction. The slits 110 are formed in either or both of the end parts of the pattern 104 with respect to the Y direction. Though the slits 110 that are formed at the same position with respect to the X direction in both of the end parts with respect to the Y direction so as to face each other are illustrated as the examples in
The slits 110 are formed between the radiating element 105 and a +X direction end part (an example of the first end part) of the pattern 104 with respect to the X direction. Providing that a distance (interval) between center of the radiating element 105 and center of the slits 110 in the X direction is designated by ds, setting of ds≧0λ is made. For instance, setting of 0λ≦ds≦0.08λ is made. That is, the distance ds designates the position (slit position) of the slits 110 relative to the radiating element 105 in the X direction. A −X direction end part of the pattern 104 is an example of a third end part.
The slits 110 are formed so as not to overlap with the radiating element 105 with respect to the Y direction. Providing that a length (slit length) of the slits 110 along the Y direction is designated by Ls, setting of 0.016λ≦Ls≦0.05, is made, for instance.
In the L2 layer, the feeder 107 is provided on the one surface side (+Z side) of the second dielectric substrate 101. The feeder 107 is placed in a position substantially orthogonal to the radiating element 105 in plan view of XY plane so as to be electromagnetically coupled to the radiating element 105.
The feeder 107 extends to the L4 layer via a through hole 108 formed from the L2 layer to the L3 layer and is connected to a feeder unit 109. The feeder unit 109 is provided on an external substrate (such as motherboard) not illustrated, for instance.
As described above, the radiating element 105 is a feed element and the reflector element 106 is a parasitic element. The feeder 107 does not have to supply electricity to a plurality of radiating elements and has only to have a length that enables supply of electricity to the radiating element 105. Therefore, length of the feeder 107 in the L2 layer can be shortened and thus signal loss caused by the feeder 107 can be reduced.
In the L3 layer, the ground conductor 103 is placed on the one surface side (+Z side) of the third dielectric substrate 102. The ground conductor 103 is placed so as to be substantially parallel to the pattern 104 placed on the first dielectric substrate 100.
In the L4 layer, electronic components may be mounted on the other surface side (−Z side) of the third dielectric substrate 102. On condition that electronic components (such as semiconductor chips) are mounted in the L4 layer, the ground conductor 103 is placed between the electronic components and the radiating element 105 or the reflector element 106 as the antenna. Thus electrical interference between the electronic component side and the antenna side can be prevented and reliability of the antenna device 10 is thereby improved.
The other surface side (−Z side) of the third dielectric substrate 102 is an example of the other surface of the second dielectric substrate 101 on which the electronic components are mounted.
Subsequently, gains of the antenna device that are obtained in presence or absence of the slits 110 will be described.
In
Subsequently, examples of analysis of antenna radiation patterns of the antenna device 10 will be described.
It is observed from the radiation patterns 204 and 205 in
It is observed from the radiation patterns 206 and 207 in
Subsequently, current distribution in the antenna device 10 will be described.
In
In the antenna device 10 of
In the antenna device 10 of
Subsequently, an example of change in antenna performance with change in the distance ds will be described.
With reference to
With reference to
Subsequently, an example of change in the antenna performance with change in the length L1 will be described.
With reference to
Accordingly, the tilt angle θ can be adjusted by adjustment in the length L1 of one side of the pattern 104. For instance, the desired tilt angle θ is set to be 50 to 60 degrees on assumption that the antenna device 10 is mounted on the portable terminal 501 illustrated in
Subsequently, an example of change in the antenna performance with change in the length dx2 of the antenna device 10 will be described.
With reference to
Thus the tilt angle θ can be adjusted by adjustment in the length dx2. For instance, the desired tilt angle θ is set to be 50 to 60 degrees on assumption that the antenna device 10 is mounted on the portable terminal 501 illustrated in
Subsequently, an example of change in the antenna performance with change in the length dx1 of the antenna device 10 will be described.
In
With reference to
Thus the side lobe level can be adjusted by adjustment in the length dx1.
In the antenna device 10, the pattern 104 is provided between the radiating element 105 and the +X direction end part with respect to the X direction of the pattern 104 and thus the currents can extensively be distributed along the radiation direction (on +X side) in the pattern 104. Thus the directivity of the antenna can favorably be tilted so that the gain of the antenna resulting from the tilt can be improved. Provision of the slits 110 enhances paths in the pattern 104 through which the currents flow and thereby enables wide-band characteristics.
In the antenna device 10, the provision of the slits 110 in the end parts of the pattern 104 with respect to the Y direction facilitates retention of high-frequency currents between the radiating element 105, the slits 110, and the +X direction end part (see the pattern region (3 in
With the slits 110 provided in both the end parts of the pattern 104 with respect to the Y direction so as to face each other, the antenna device 10 excels in symmetry in the Y direction and improves accuracy in radio wave radiation in the +X direction, for instance. In the antenna device 10, the two slits 110 focus the beam and the conical plane directivity and intensify the directivity of the antenna.
In the antenna device 10, the beam tilt (the tilt angle of 50 to 60 degrees, for instance) that is nearer to the substrate horizontal direction (XY direction) than to the substrate vertical direction (Z direction) can be attained, for instance.
The antenna device 10 supplies electricity by electromagnetic coupling to the radiating element 105, for instance, and thus allows the feeder 107 to be shortened. Accordingly, the antenna device 10 reduces transmission loss in the feeder 107 and thus improves the antenna performance. Furthermore, influence of length of conductor line is prone to be greater as communication is performed with higher frequency. Accordingly, high-frequency communication with little loss can be attained by application of the antenna device 10 to millimeter-wave communication.
In the antenna device 10, the ground conductor 103 that functions as a reflecting plate can be provided in the multilayer substrate in order to prevent radiation of radio waves in the −Z direction, for instance. Accordingly, there is no need to provide a reflecting plate as a separate member in addition to the dielectric substrates and thus the configuration of the antenna device 10 can be simplified.
In the antenna device 10, electronic components (such as chip components and/or integrated circuits (ICs)) are mounted in the L4 layer, for instance, so that the ground conductor 103 that functions as a ground is placed between the antenna and the electronic components. Thus the antenna device 10 is capable of reducing the electrical interference between the antenna and the electronic components. Therefore, the antenna device 10 can easily be modularized with maintenance of satisfactory electrical characteristics thereof.
The antenna device 10 may be mounted on a receiver side instead of a transmitter side.
The disclosure is not limited to the configuration of the embodiment and can be applied to any configuration as long as the configuration achieves functions disclosed in the claims or functions the configuration of the embodiment has.
Though the embodiment in which the radiating element 105 and the reflector element 106 are formed in the pattern 104 has been described, for instance, a director may further be formed therein. The director is an example of a third slot element.
Like the radiating element 105 and the reflector element 106, the director is formed by cutting of the pattern 104 into a slot shape. The director is placed substantially in parallel with the radiating element 105, on a side (+X side in
The directivity in the substrate horizontal direction (XY plane) can further be improved by provision of the director.
A first antenna device according to the disclosure includes a dielectric substrate, a conductor plate that is placed on one surface of the dielectric substrate, that includes a first slot element, a second slot element, and one or more slits, and a ground conductor that is placed at a specified distance from the conductor plate in a first direction. A center of the first slot element is placed between a center of the second slot element and a center of each of slits, in a second direction.
A second antenna device according to the disclosure is the first antenna device in which the first slot element is supplied with electricity from a feeder, and has an electrical length of an approximately half wavelength for a frequency that is used, the second slot element has an electrical length longer than the first slot element has, the center of the second slot is placed at a distance of an approximately quarter wavelength in electrical length from the center of the first slot element in the second direction, and a longitudinal direction of the first slot and a longitudinal direction of the second slot in a longitudinal direction are placed substantially in parallel in a third direction.
A third antenna device according to the disclosure is the first antenna device in which the one or more slits are placed on at least either of two end parts of the conductor plate, the two end parts are placed substantially in parallel in a third direction.
A fourth antenna device according to the disclosure is the first antenna device in which the slits are placed to face each other on both of the two end parts of the conductor plate, the two end parts are placed substantially in parallel in a third direction.
A fifth antenna device according to the disclosure is the first antenna device in which center of the each of slits is placed at a distance equal to or smaller than 0.08 wavelength in electrical length for the frequency that is used by the antenna device, from center of the first slot element in the second direction.
A sixth antenna device according to the disclosure is the first antenna device in which a length of the each of slits in the first direction along the first end part is equal to or longer than 0.016 wavelength and equal to or shorter than 0.05 wavelength in electrical length for the frequency that is used by the antenna device.
Though various embodiments have been described above with reference to the drawings, it is needless to say that the disclosure is not limited to such examples. It is apparent that those skilled in the art can conceive various alterations or modifications within the scope described in the claims and it is to be understood that such alterations and modifications shall fall under the technical scope of the disclosure as a matter of course. Components of the embodiments may arbitrarily be combined unless departing from the purport of the disclosure.
The disclosure is effective for antenna devices and the like in which directivity of an antenna can favorably be tilted so that gain of the antenna can be improved.
Number | Date | Country | Kind |
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2014-114915 | Jun 2014 | JP | national |