Patent Grant
11316255
This application is a national stage of International Application No. PCT/CN2017/078623, filed on Mar. 29, 2017, which is hereby incorporated by reference in its entirety.
This application relates to communications technologies, and in particular, to an antenna and a terminal device.
With development of communications technologies, a terminal device such as a mobile phone or a tablet computer usually has wireless communication functions such as cellular communication, Wireless Fidelity (Wireless Fidelity, Wi-Fi), and Bluetooth (Bluetooth).
To meet a requirement for a light and thin terminal device, an antenna is usually built in the device. In terms of housing materials, there may be a plastic housing, a metal housing, and the like. Due to an aesthetical requirement for appearance, a terminal device with a metal housing becomes increasingly popular because the metal housing has advantages in terms of, for example, texture, durability, and service life. However, because the metal housing shields an electromagnetic wave, a built-in antenna of the terminal device cannot receive/send a signal. To ensure normal communication of the terminal device, currently, a slot or groove may be provided on up and down edge components of the metal housing to form a slot antenna.
However, because an end of the slot antenna is usually bent to a longer side of the metal housing, when the terminal device is held in hand, antenna performance is likely to attenuate, and consequently communication performance deteriorates.
Embodiments of this application provide an antenna and a terminal device, so as to reduce antenna performance attenuation caused by holding the terminal device in hand, and improve communication performance.
According to a first aspect, an embodiment of this application provides an antenna, including a metal frame and at least one resonating structure, where the metal frame is provided with a slot to form a first radiating element and a second radiating element on the metal frame;
the first radiating element includes at least one radiation arm, and each radiation arm is connected to a feedpoint of a terminal device on which the antenna is located; and
the second radiating element includes at least one suspended radiation arm, each resonating structure includes one suspended radiation arm and a resonating component, the suspended radiation arm is connected to the resonating component, and the resonating component is further connected to a ground point of the terminal device.
The antenna provided in this embodiment of this application may enable one low-frequency bandwidth radiator to work even if another low-frequency bandwidth radiator is held in hand, thereby effectively improving antenna efficiency in a low-frequency operating band when the terminal device is held in hand, reducing antenna performance attenuation, and improving communication performance.
Optionally, the resonating component includes an inductance component, the suspended radiation arm is connected to the inductance component, and the inductance component is further connected to the ground point.
Optionally, the resonating component includes a capacitance component, the suspended radiation arm is connected to the capacitance component, and the capacitance component is further connected to the ground point.
Optionally, the resonating component includes an inductance component and a capacitance component, the inductance component is connected to the capacitance component, the inductance component is further connected to the suspended radiation arm, and the capacitance component is further connected to the ground point.
Optionally, the inductance component is an adjustable inductance component, and/or the capacitance component is an adjustable capacitance component.
In this embodiment of this application, antennas of different structures are provided when a plurality of different resonating structures are included, and an inductance component and/or a capacitance component of a resonating component may be configured as a component having a variable parameter value, so as to implement resonating structure switching between different resonance frequencies, thereby improving antenna radiation efficiency on each resonance frequency.
Optionally, the resonating component includes a first inductance component, a second inductance component, a first switch, and a second switch, the first inductance component is connected to the first switch, the second inductance component is connected to the second switch, the first inductance component and the second inductance component are further connected to the suspended radiation arm, and the first switch and the second switch are further connected to the ground point.
The antenna provided in this embodiment of this application can make an adjustment between different switch states, so as to implement resonating structure switching between different resonance frequencies, thereby improving antenna radiation efficiency on each resonance frequency.
Optionally, a shortest radiation arm in the first radiating element is further connected to a third inductance component and a fourth inductance component that are connected in parallel, the third inductance component is further connected to the ground point of the terminal device by using a third switch component, and the fourth inductance component is further connected to the ground point of the terminal device by using a fourth switch component.
In the antenna provided in this embodiment, antenna efficiency reduction caused when the antenna switches between different frequency bands in a low-frequency operating band can be effectively lessened.
Optionally, the third inductance component is further connected to a first capacitance component in parallel, and the fourth inductance component is further connected to the second capacitance component in parallel.
Optionally, a difference between a capacitance of the first capacitance component and an equivalent capacitance generated when the third switch is in a disconnected state is less than or equal to a preset value; and
a difference between a capacitance of the second capacitance component and an equivalent capacitance generated when the fourth switch is in a disconnected state is less than or equal to a preset value.
The antenna in this embodiment of this application can further filter out a spurious wave.
Optionally, the slot is a PI-shaped slot or a U-shaped slot.
According to a second aspect, an embodiment of this application further provides a terminal device, including a printed circuit board PCB and an antenna, where the PCB includes a radio frequency processing unit and a baseband processing unit, the antenna is any one of the foregoing antennas, each radiation arm in the first radiating element in the antenna is connected to a feedpoint on the radio frequency processing unit, and the radio frequency processing unit is connected to the baseband processing unit;
the antenna is configured to transmit a received radio signal to the radio frequency processing unit, or send a transmit signal of the radio frequency processing unit;
the radio frequency processing unit is configured to: after processing the radio signal received by the antenna, send the radio signal to the baseband processing unit; or after processing a signal sent by the baseband processing unit, send the signal by using the antenna; and
the baseband processing unit is configured to process the signal sent by the radio frequency processing unit.
According to the antenna and the terminal device provided in the embodiments of this application, the antenna may include the metal frame and the at least one resonating structure. The metal frame is provided with the slot to form the first radiating element and the second radiating element on the metal frame. The first radiating element includes the at least one radiation arm, and each radiation arm is connected to the feedpoint of the terminal device on which the antenna is located. The second radiating element includes the at least one suspended radiation arm. Each resonating structure includes the suspended radiation arm and the resonating component, and the suspended radiation arm is connected to the ground point of the terminal device by using the resonating component. The resonating structure is disposed in the antenna, so that in addition to a low-frequency bandwidth radiator included in the at least one radiation arm, the antenna may further include a low-frequency bandwidth radiator formed by the resonating structure. Therefore, even if one low-frequency bandwidth radiator is held in hand, another low-frequency bandwidth radiator may work, thereby effectively improving antenna efficiency in low-frequency bandwidth when the terminal device is held in hand, reducing antenna performance attenuation, and improving communication performance.
An antenna provided in the following embodiments of this application is applicable to a terminal device provided with a metal frame. A rear cover in the terminal device provided with the metal frame may be a non-metal rear cover, or may be a metal rear cover. For a terminal device having a non-metal rear cover, an inner surface of the non-metal rear cover of the terminal device may be covered by a metal layer, so as to provide a slot to form a radiation arm of an antenna and the like. The terminal device may be an electronic device having a wireless communication function, such as a mobile phone or a tablet computer. With reference to a plurality of instances, the following describes the antenna provided in the embodiments of this application.
The first radiating element includes at least one radiation arm 103, and each radiation arm 103 is connected to a feedpoint 104 of a terminal device on which the antenna is located.
The second radiating element includes at least one suspended radiation arm 105. Each resonating structure 102 includes one of the at least one suspended radiation arm 105 and a resonating component 106. The suspended radiation arm 105 is connected to the resonating component 106, and the resonating component 106 is further connected to a ground point of the terminal device.
Specifically, in the antenna shown in
If there are a plurality of slots on the metal frame 101, at least one of the plurality of slots may be connected outside the terminal device. In this case, the plurality of slots are still presented on an appearance surface. Optionally, if there are a plurality of slots on the metal frame 101, at least one of the plurality of slots may be connected inside the terminal device. In this case, there are the plurality of slots on an appearance surface, but an actual quantity of antenna slots is less than the plurality of slots.
The at least one of the plurality of slots on the metal frame 101 is connected, thereby improving low-frequency bandwidth antenna efficiency by using the resonating structure 102 while improving an appearance of the terminal device.
Optionally, in any one of the foregoing antennas, the slot may be a PI-shaped slot or a U-shaped slot.
For example,
Referring to
In the at least one radiation arm 103 shown above, a longer radiation arm indicates a smaller radiation frequency corresponding to the radiation arm. On the contrary, a shorter radiation arm indicates a larger radiation frequency corresponding to the radiation arm.
An example in which the first radiating element includes two radiation arms 103 is used in
By using a lumped device with a preset resistance, each radiation arm 103 may be connected to the feedpoint 104 of the terminal device on which the antenna is located, so that a signal that is output by the feedpoint 104 is transmitted to each radiation arm 103, and radiates by using the radiation arm 103, so as to implement radio signal sending. In addition, a signal received by each radiation arm 103 may be transmitted to the feedpoint 104, so as to implement radio signal receiving.
The feedpoint 104 may be located on a radio frequency processing unit of the terminal device.
Each resonating structure 102 may also be referred to as a resonating element (resonating element). Each resonating structure 102 may be corresponding to one fixed frequency in a preset frequency band, or may be corresponding to at least one variable frequency in the preset frequency band. A specific resonance frequency corresponding to each resonating structure 102 may be determined based on a length of the suspended radiation arm 105 in the resonating structure 102, a resonant parameter of the resonating component 106, and the like.
A preset frequency band corresponding to each resonating structure 102 may have low-frequency bandwidth. Therefore, each resonating structure 102 may be referred to as a low-frequency resonating structure. The ground point of the terminal device may be any ground point in any unit structure such as the radio frequency processing unit or a baseband processing unit in the terminal device.
In the antenna shown in
In the at least one resonating structure 102, a resonating structure 102 close to the feedpoint 104 may be electrically connected to the feedpoint 104 through magnetic field coupling. In the at least one resonating structure 102, a resonating structure 102 far away from the feedpoint 104 may be electrically connected to the feedpoint 104 through electric field coupling. An example in which the antenna in
If there is one resonating structure 102, the resonating structure 102 may include any one of the at least one suspended radiation arm 105. If there are a plurality of resonating structures 102, a quantity of resonating structures 102 may be less than or equal to a quantity of at least one suspended radiation arm 105.
Referring to
In addition to a low-frequency bandwidth radiator included in the at least one radiation arm 104, the antenna in this embodiment of this application further includes a low-frequency bandwidth radiator formed by the resonating structure 103. Therefore, even if one low-frequency bandwidth radiator is held in hand, another low-frequency bandwidth radiator may work, thereby ensuring antenna efficiency in low-frequency bandwidth.
Referring to
The antenna provided in this embodiment of this application may include a metal frame and at least one resonating structure. The metal frame is provided with a slot to form a first radiating element and a second radiating element on the metal frame. The first radiating element includes at least one radiation arm, and each radiation arm is connected to a feedpoint of a terminal device on which the antenna is located. The second radiating element includes at least one suspended radiation arm. Each resonating structure includes one suspended radiation arm and a resonating component, and the suspended radiation arm is connected to the ground point of the terminal device by using the resonating component. The resonating structure is disposed in the antenna, so that in addition to a low-frequency bandwidth radiator included in the at least one radiation arm, the antenna may further include a low-frequency bandwidth radiator formed by the resonating structure. Therefore, even if one low-frequency bandwidth radiator is held in hand, another low-frequency bandwidth radiator may work, thereby effectively improving antenna efficiency in low-frequency bandwidth when the terminal device is held in hand, reducing antenna performance attenuation, and improving communication performance.
Optionally, based on the antenna shown in
Optionally, based on the antenna shown in
Optionally, based on the antenna shown in
This embodiment of this application provides locations of a plurality of different resonating structures, and provides antennas of a plurality of different structures.
Optionally, an embodiment of this application further provides an antenna.
The inductance component 1061 may be an inductance component having a preset fixed inductance, or may be an adjustable inductance component having a preset inductance range.
The capacitance component 1062 may be a capacitance component having a preset fixed capacitance, or may be a variable capacitance component having a preset capacitance range.
Optionally, the inductance component 1061 shown in
In this embodiment of this application, antennas of different structures are provided when a plurality of different resonating structures are included, and an inductance component and/or a capacitance component of a resonating component may be configured as a component having a variable parameter value, so as to implement resonating structure switching between different resonance frequencies, thereby ensuring antenna radiation efficiency on each resonance frequency.
Optionally, an embodiment of this application further provides an antenna.
It should be noted that alternatively the first inductance component 1063 and the second inductance component 1064 may be connected to the ground point, and the first switch 1065 and the second switch 1066 are connected to the suspended radiation arm 105.
The first switch 1065 and the second switch 1066 each may be a radio frequency switch (Radio Frequency Switch).
The antenna provided in this embodiment of this application can make an adjustment between different switch states, so as to implement resonating structure switching between different resonance frequencies, thereby ensuring antenna radiation efficiency on each resonance frequency.
If the antenna shown in
When a finger of a user is in contact with an antenna slot during use of a mobile phone, the first switch 1065 and/or the second switch 1066 may be adjusted in status, so that an inductance of the inductance component connected to the suspended radiation arm 105 is less than a preset inductance. In this case, the inductance component connected to the suspended radiation arm 105 may be referred to as a small inductor L1, and the inductance of the small inductor may be, for example, 6.8 nH. In this case, from the antenna feedpoint to a relatively short radiation arm in the first radiating element, to the finger, to the suspended radiation arm 105, and through the small inductor, to the ground, a new resonance frequency of a ¾ wavelength is formed. The new resonance frequency may be tuned by using the grounded small inductor L0, and the new resonance frequency may be, for example, near an intermediate frequency 1710 MHz. Therefore, the antenna provided in this embodiment of this application can further effectively avoid antenna efficiency attenuation caused when a finger is in contact with an antenna slot in intermediate frequency bandwidth and high frequency bandwidth. Compared with a conventional antenna, the antenna can have an increase of at least 7.5 dB in antenna efficiency, thereby effectively ensuring communication quality of the user.
For example,
A curve 1 in
A curve 1 in
Referring to
Optionally, an embodiment of this application further provides an antenna.
The transfer switch 107 includes a third inductance component 1071 and a fourth inductance component 1072 that are connected in parallel. The third inductance component 1071 is further connected to the ground point of the terminal device by using a third switch component 1073, and the fourth inductance component 1072 is further connected to the ground point of the terminal device by using a fourth switch component 1074.
In the antenna provided in this embodiment, the transfer switch 107 is disposed on a side of the shortest radiation arm, thereby effectively lessening antenna efficiency reduction caused by a frequency increase in low-frequency bandwidth. The third switch component 1073 and the fourth switch component 1074 included in the transfer switch 107 are two single-pole single-throw switches. Therefore, the switches in the transfer switch 107 may be referred to as a double-pole double-throw switch. Switching is performed between three switch states of the third switch component 1073 and the fourth switch component 1074, so that a radiation frequency of the shortest radiation arm in the antenna may separately cover different ranges within the low-frequency bandwidth (698 MHz to 960 MHz), for example, a first frequency band (698 MHz to 787 MHz) including 700 MHz, a second frequency band (814 MHz to 894 MHz) including 800 MHz, and a third frequency band (880 MHz to 960 MHz) including 900 MHz. A first switch state in the three switch states is both the third switch component 1073 and the fourth switch component 1074 are disconnected; a second switch state in the three switch states is either the third switch component 1073 or the fourth switch component 1074 is disconnected; and a third switch state in the three switch states is both the third switch component 1073 and the fourth switch component 1074 are closed.
In the first switch state, the radiation frequency of the shortest radiation arm in the antenna may cover the first frequency band (698 MHz to 787 MHz) including 700 MHz in the low-frequency bandwidth (698 MHz to 960 MHz). In the second switch state, the radiation frequency of the shortest radiation arm in the antenna may cover the second frequency band (814 MHz to 894 MHz) including 800 MHz in the low-frequency bandwidth (698 MHz to 960 MHz). In the third switch state, the radiation frequency of the shortest radiation arm in the antenna may cover the third frequency band (880 MHz to 960 MHz) including 900 MHz in the low-frequency bandwidth (698 MHz to 960 MHz).
For example,
A curve 1 in
Referring to
Optionally, an embodiment of this application further provides an antenna.
A parasitic capacitor is disposed inside each of the third switch component 1073 and the fourth switch component 1074. During disconnection, the parasitic capacitor may be equivalent to one small capacitor COff, and a capacitance of the small capacitor may be, for example, 0.3 pF.
If the first switch component 1073 and/or the second switch component 1074 are/is disconnected, the parasitic capacitor in each switch component 1073 and an inductance component connected to the switch component can form a resonance circuit. When an inductance of the inductance component falls within a preset range, a resonance frequency of the resonance circuit covers a corresponding frequency band in the low-frequency bandwidth.
Optionally, a difference between a capacitance of the first capacitance component 1075 and an equivalent capacitance generated when the third switch component 1073 is in a disconnected state is less than or equal to a preset value.
A difference between a capacitance of the second capacitance component 1076 and an equivalent capacitance generated when the fourth switch component is in a disconnected state is less than or equal to a preset value.
The equivalent capacitance generated when the third switch component 1073 is in a disconnected state may be a capacitance of the parasitic capacitor in the third switch component 1073. The equivalent capacitance generated when the fourth switch component 1074 is in a disconnected state may be a capacitance of the parasitic capacitor in the fourth switch component 1074.
In an instance, the capacitance of the first capacitance component 1075 may be equal to or approximate to the capacitance, for example, 0.3 pF, of the parasitic capacitor in the third switch component 1073. The capacitance of the second capacitance component 1076 may be equal to or approximate to the capacitance, for example, 0.3 pF, of the parasitic capacitor in the fourth switch component 1074.
In
When a switch is disconnected, resonant impedance is formed on the third inductance component 1071 and the first capacitance component 1075 or the fourth inductance component 1072 and the second capacitance component on an original spurious-wave frequency band, and a small capacitance in low-frequency bandwidth and a large inductance in intermediate frequency bandwidth and high frequency bandwidth are presented, so that the frequency band is not affected. Therefore, frequency bands B4 in Long Term Evolution (Long Term Evolution, LTE) in a carrier aggregation (Carrier Aggregation, CA) state and a non-CA state have same performance. A capacitance presented in a low frequency in a switch disconnected state is less than a capacitance in a conventional filtering method, so that low-frequency bandwidth is correspondingly relatively narrow, thereby facilitating frequency tuning in a low-frequency bandwidth. The frequency bands B4 include a transmit frequency band from 1710 MHz to 1755 MHz and a receive frequency band from 2110 MHz to 2155 MHz.
In addition, referring to
An embodiment of this application further provides a terminal device.
The antenna 2002 is configured to transmit a received radio signal to the radio frequency processing unit 1803, or send a transmit signal of the radio frequency processing unit 1803.
The radio frequency processing unit 2003 is configured to: after processing the radio signal received by the antenna 2002, send the radio signal to the baseband processing unit 2004; or after processing a signal sent by the baseband processing unit 2004, send the signal by using the antenna 2002.
The baseband processing unit 2004 is configured to process the signal sent by the radio frequency processing unit 2003.
The resonating structure is disposed in the antenna included in the terminal device provided in this embodiment of this application, so that in addition to a low-frequency bandwidth radiator included in the at least one radiation arm, the antenna may further include a low-frequency bandwidth radiator formed by the resonating structure. Therefore, even if one low-frequency bandwidth radiator is held in hand, another low-frequency bandwidth radiator may work, thereby effectively improving antenna efficiency in low-frequency bandwidth when the terminal device is held in hand, reducing antenna performance attenuation, and improving communication performance of the terminal device.
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| WO2018/176279 | 10/4/2018 | WO | A |
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