The present disclosure relates to the field of communications technologies, and in particular, to an antenna structure and a terminal.
The antenna in package (AiP) technology is mostly used for millimeter-wave antennas. In this technology, a millimeter-wave array antenna, a radio frequency integrated circuit (RFIC), and a power management integrated circuit (PMIC) are integrated into one module. Antenna elements that constitute a millimeter-wave array are mainly patch antennas, Yagi-Uda antennas, or dipole antennas. These antenna elements are relatively narrow-band antennas. For example, the relative bandwidth percentage of conventional patch antennas is generally not greater than 8%, while the millimeter-wave frequency band usually requires dual-frequency band or multi-frequency band and large bandwidth, which poses a great challenge to the antenna design.
According to a first aspect, an embodiment of the present disclosure provides an antenna structure, including:
a metal plate, where the metal plate is provided with a first surface and a second surface that are disposed oppositely, and an accommodating groove is formed in the metal plate and adjacent to the first surface; and
a spiral radiator, where the spiral radiator is mounted in the accommodating groove and insulated from the metal plate, and the spiral radiator is provided with a feed end used to be connected to a feed source.
According to a second aspect, an embodiment of the present disclosure provides a terminal, including:
an antenna structure, where the antenna structure is the antenna structure provided in the foregoing embodiment, and the metal plate is grounded; and
a radio frequency module, where the radio frequency module is located on the second surface of the metal plate, and the radio frequency module is electrically connected to or coupled with the feed end of the spiral radiator.
The following clearly describes the technical solutions in the embodiments of this disclosure with reference to the accompanying drawings in the embodiments of this disclosure. Apparently, the described embodiments are some rather than all of the embodiments of this disclosure. All other embodiments obtained by a person of ordinary skill in the art based on the embodiments of the present disclosure shall fall within the protection scope of the present disclosure.
In order to meet the requirements for dual-frequency band, multi-frequency band, and multi-broadband, it is often necessary to form slots in radiation fins of patch antennas or adopt a laminated structure. However, in most cases, either dual-polarization of similar performance is difficult to achieve or the thickness of the millimeter-wave array antenna is increased by this method. As a result, more layout space on a mobile phone is occupied, which goes against the miniaturization or thinning of the mobile phones and overall design and integration of the mobile phones.
In addition, the space loss in the millimeter-wave band is high. Therefore, array antennas need to be adopted in the design of antennas in the millimeter-wave band to increase the antenna gain, compensate for high path loss, and expand the wireless coverage. Therefore, a high gain is also one of the important performance indexes for a millimeter-wave antenna array. However, a high-grain array requires not only increasing of antenna elements, but also design of high-gain antenna elements in the array.
An embodiment of the present disclosure provides an antenna structure, shown in
a metal plate 1, where the metal plate 1 is provided with a first surface and a second surface that are disposed oppositely, and an accommodating groove 3 is formed in the metal plate 1 and adjacent to the first surface; and
a spiral radiator 2, where the spiral radiator 2 is mounted in the accommodating groove 3 and insulated from the metal plate 1, and the spiral radiator 2 is provided with a feed end used to be connected to a feed source.
According to the antenna structure in this embodiment of the present disclosure, the accommodating groove 3 is formed in the metal plate 1, and the spiral radiator 2 is mounted in the accommodating groove 3, so that the characteristic that electricity properties of the spiral radiator 2 such as the pattern, antenna gain, and input impedance have little change within a relatively wide frequency range is utilized. Therefore, circular polarization is realized and any polarized incoming waves could be received to reduce the disconnection probability of wireless communication. In addition, to some extent, design problems such as multi-frequency band, large bandwidth, and high gain are resolved, the stability of wireless communication is improved, and the space occupied by the antenna structure is reduced. This facilitates miniaturization and overall integration.
Optionally, the spiral radiator 2 is a planar spiral radiator, that is, any structure constituting the spiral radiator 2 is in the same plane. For example, the spiral radiator 2 may be an Archimedean spiral radiator. Because the planar spiral radiator 2 has a symmetrical gradient structure, and electricity properties of the spiral radiator 2 such as the pattern, antenna gain, and input impedance have little change within a relatively wide frequency range, broadband coverage can be easily realized.
Optionally, the orthographic projection image of the spiral radiator 2 on the metal plate 1 is approximately round or square, and the accommodating groove 3 fits the spiral radiator 2. Therefore, the spiral radiator 2 can be processed and manufactured conveniently, and the spiral radiator 2 can be easily mounted in the accommodating groove 3.
When the spiral radiator 2 is a planar spiral radiator, and the orthographic projection image thereof on the metal plate 1 is approximately circular, the structure of the spiral radiator 2 is shown in
It can be understood that, as shown in
In addition, the spiral radiator 2 is integrated on the metal plate 1, which reduces the space of the terminal occupied by the antenna structure. According to the embodiments of the present disclosure, the following problem in the related art is resolved: In order to realize multi-frequency band, large bandwidth, and high gain, millimeter-wave antennas are disposed in a terminal, which goes against the miniaturization and overall integration design because they occupy too much space.
Optionally, the planar spiral radiator 2 may be a part of the metal plate 1, that is, a part of the metal plate 1 is processed into a planar spiral structure, which constitutes the radiator. When a part of the metal plate 1 is used as the spiral radiator 2, the antenna bandwidth can be increased, and multi-frequency band coverage is realized. Furthermore, when the metal plate 1 is used as a part of a metal shell of a mobile terminal, a part of the metal shell is used as the spiral radiator 2. In this way, the space occupied by the antenna is reduced without affecting the metal texture of the terminal.
In some embodiments, an insulating medium piece is disposed between the spiral radiator 2 and the metal plate 1. That is, the accommodating groove 3 is filled with the insulating medium piece, and the spiral radiator 2 is fixed on the insulating medium piece. Furthermore, the spiral radiator 2 is fixed in the insulating medium piece or on the surface thereof. The insulating medium piece may be made of the low-dielectric-constant and low-loss dielectric material.
As shown in
Optionally, the depth of the accommodating grooves 3 is less than or equal to the thickness of the metal plate 1. That is, the accommodating grooves 3 may penetrate or not penetrate the metal plate 1. When the depth of the accommodating grooves 3 is less than the thickness of the metal plate 1, that is, when the accommodating grooves 3 are formed in the metal plate 1 but do not penetrate the metal plate 1, the accommodating grooves 3 can be used as reflectors 11 of the spiral radiators 2 when being grounded (that is, the metal plate 1 is grounded), as shown in
It should be noted that when a part of the metal plate 1 is used as the reflectors 11 of the spiral radiators 2, if the antenna structure in this embodiment of the present disclosure is mounted on the terminal, the spiral radiators 2 may be less sensitive to the environment inside the system behind the metal plate 1. Therefore, more components can be integrated and more functions can be realized, thereby improving the competitiveness of the terminal.
An embodiment of the present disclosure further provides a terminal, where the terminal includes:
an antenna structure, where the antenna structure is the antenna structure provided in the foregoing embodiment; and a
radio frequency module, where the radio frequency module is located on the second surface of the metal plate 1, and the radio frequency module is electrically connected to or coupled with the feed ends of the spiral radiators 2. The radio frequency module is used to provide radio frequency signals, and when the radio frequency module is electrically connected to or coupled with the feed ends of the spiral radiators 2, the radio frequency module can transmit output radio frequency signals to the spiral radiators 2. It can be understood that the radio frequency module may alternatively be disposed in the system of the terminal.
The depth of the accommodating grooves 3 formed in the metal plate 1 is less than or equal to the thickness of the metal plate 1. That is, the accommodating grooves 3 may or may not penetrate the metal plate 1. When the depth of the accommodating grooves 3 is less than the thickness of the metal plate 1, that is, when the accommodating grooves 3 are formed in the metal plate 1 but do not penetrate the metal plate 1, the accommodating grooves 3 can be used as the reflectors 11 of the spiral radiators 2, as shown in
It can be seen that when the metal plate 1 is grounded, the accommodating grooves 3 can be used as the reflectors 11 of the spiral radiators 2. In this way, the spiral radiators 2 may be less sensitive to the environment inside the system behind the metal plate 1. Therefore, more components can be integrated and more functions can be realized, thereby improving the competitiveness of the terminal.
Optionally, as shown in
Optionally, when the depth of the accommodating grooves 3 is equal to the thickness of the metal plate 1 (that is, the accommodating grooves 3 are formed in the metal plate 1 and penetrate the metal plate 1), and an insulating medium piece is disposed between the spiral radiator 2 and the metal plate 1, each of the feed holes is formed in the insulating medium piece in the corresponding accommodating groove 3. When the depth of the accommodating grooves 3 is less than the thickness of the metal plate 1 (that is, the accommodating grooves 3 are formed in the metal plate 1 but do not penetrate the metal plate 1), and an insulating medium piece is disposed between the spiral radiator 2 and the metal plate 1, each of the feed holes includes a first feed hole in the bottom of the corresponding accommodating groove 3 and a second feed hole in the corresponding insulating medium piece, and each of the feed pins 6 passes through the corresponding first feed hole and the corresponding second feed hole in sequence to be electrically connected to the corresponding spiral radiator 2.
If the insulating medium pieces are formed in the accommodating grooves 3 via injection molding of the insulating material, each feed hole is formed in the corresponding insulating medium piece because the feed pins are in the accommodating grooves 3 during injection molding.
Optionally, the accommodating grooves 3 are spaced apart from each other, the spiral radiators 2 are mounted in the accommodating grooves 3 in a one-to-one correspondence manner, and the distance between every two adjacent spiral radiators 2 is equal to half of the wavelength of the operating frequency of the antenna structure.
The spiral radiators 2 form an array antenna, which can lead to multi-frequency band coverage. In addition, during the beam scanning, performance of the array antenna formed by the spiral radiators 2 may be the same or similar in a spatial symmetrical or mapping direction. In addition, the distance between every two adjacent spiral radiators 2 is equal to half of the wavelength of the operating frequency of the antenna structure. Optionally, when the spiral radiators 2 are disposed at intervals on the metal plate 1 in the length direction thereof, the interval is the distance between every two adjacent spiral radiators 2 in the length direction of the metal plate 1. When the spiral radiators 2 are disposed at an interval on the metal plate 1 in the width direction thereof, the interval is the distance between every two adjacent spiral radiators 2 in the width direction of the metal plate 1.
Optionally, the radio frequency module includes a radio frequency integrated circuit 504 and a power management integrated circuit 505, and the radio frequency integrated circuit 504 is electrically connected to the feed ends and the power management integrated circuit 505. The radio frequency module may also be provided with a BTB connector 506 used for intermediate-frequency signal connection between the radio frequency module and the main board of the terminal.
Furthermore, as shown in
It should be noted that when the radio frequency module is disposed on the side, facing the inner part of the terminal, of the metal plate 1, the first ground layer 501 of the radio frequency module can be used as the reflectors of the spiral radiators 2.
In addition, as shown in
It can be learned from the above that, the radio frequency module shown in
Alternatively, the spiral radiators 2 may be disposed on the radio frequency module, as shown in
Optionally, when the orthographic projection images of the spiral radiators 2 on the metal plate 1 are approximately circular, the accommodating grooves 3 are circular, and the insulating components 8 on the first ground layer 501 of the radio frequency module are circular, as shown in
Optionally, the terminal is provided with a shell, at least a part of the shell is a metal shell, and the metal plate 1 is the first part of the metal shell. For example, as shown in
That is, the spiral radiators 2 are integrated on the metal shell of the terminal, which reduces the space of the terminal occupied by the spiral radiators 2.
It can be understood that the metal plate 1 is not limited to a part of the metal shell. Alternatively, the metal plate 1 may be a part of a target antenna radiator on the terminal, and the operating frequency band of the target antenna radiator is different from that of the spiral radiators 2. That is, the spiral radiators 2 may be integrated on the other antenna radiators on the terminal.
Optionally, the first part is the side part and/or the back part of the metal shell. When the first part is the side part of the metal shell, it can be avoided that the back part of the terminal is shielded by a metal table when the terminal is placed (with the screen facing upwards) on a metal table, and it can also be avoided that the antenna performance of the spiral radiators 2 is greatly reduced when the terminal is hold in hand.
Optionally, the radio frequency module is a millimeter-wave radio frequency module.
In view of the above, in the embodiments of the present disclosure, millimeter-wave antennas are integrated into the metal frame, a part of the metal frame is used as radiation fins of the millimeter-wave antennas, which can increase the bandwidth of the millimeter-wave antennas to cover multiple 5G millimeter-wave frequency bands without affecting the metal texture of the mobile terminal, thereby enhancing the broadband wireless experience of users in multiple millimeter-wave frequency bands when roaming across countries or even globally.
In addition, the quantities, location, shapes, dimensions, angles, distances, arrangement modes, communication frequency bands, implementations, and the like are not limited to those described in the embodiments. All other applications and designs made based on the thinking and spirit of the present disclosure shall fall within the protection scope of the present disclosure.
The foregoing descriptions are merely the optional implementations of the present disclosure. It should be noted that those of ordinary skill in the art may further make several improvements and refinements without departing from the principles described in the present disclosure, and these improvements and refinements also fall within the protection scope of the present disclosure.
Number | Date | Country | Kind |
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201811616012.1 | Dec 2018 | CN | national |
This application is a Bypass Continuation Application of PCT/CN2019/126190 filed on Dec. 18, 2019, which claims priority to Chinese Patent Application No. 201811616012.1 filed on Dec. 27, 2018, which are incorporated herein by reference in their entirety.
Number | Date | Country | |
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Parent | PCT/CN2019/126190 | Dec 2019 | US |
Child | 17358297 | US |