CN105932417A - Terminal - Google Patents

Abstract

The invention relates to a terminal, belonging to the technical field of wireless communication. The terminal comprises a front shell and a rear shell; furthermore, the front shell and the rear shell form a cavity; a mainboard and an antenna bracket parallel to the mainboard are arranged in the cavity; and an array antenna is arranged between the surface opposite to the mainboard in the antenna bracket and the rear shell. According to the terminal disclosed by the invention, the mainboard and the antenna bracket parallel to the mainboard are arranged in the cavity formed by the front shell and the rear shell of the terminal; the array antenna is arranged between the surface opposite to the mainboard in the antenna bracket and the rear shell; at this time, the array antenna is positioned between the antenna bracket and the rear shell; a clearance area between the antenna bracket and the rear shell in the height direction is utilized; the problem that the array antenna does not have the clearance area due to the fact that the array antenna is positioned in the mainboard or positioned between the mainboard and the antenna bracket is solved; and thus, the implementation effect of the array antenna is improved.

Description

Terminal device

Technical Field

The present disclosure relates to the field of wireless communication technologies, and in particular, to a terminal.

Background

The 802.11ad standard is mainly used for realizing transmission of wireless high-definition audio and video signals in a home, and abandons crowded 2.4GHz and 5GHz frequency bands, and uses a 60GHz frequency spectrum of a high-frequency carrier. Due to the high frequency spectrum, an antenna based on the 802.11ad standard needs to have beam forming capability, and is usually implemented by using an array antenna technology.

Disclosure of Invention

To solve the problems in the related art, the present disclosure provides a terminal.

According to a first aspect of the embodiments of the present disclosure, there is provided a terminal, including: a front shell and a rear shell, and the front shell and the rear shell form a cavity,

a main board and an antenna bracket parallel to the main board are arranged in the cavity;

an array antenna is arranged between the surface of the antenna support, back to the main board, and the rear shell.

Optionally, the terminal has a metal frame, and the array antenna and the metal frame are located on different planes.

Optionally, the terminal further includes a signal source and a feed network, a feed port of the feed network is connected to a signal output port in the signal source, a ground port of the feed network is connected to a ground port in the signal source, a feed point of each antenna in the array antenna is connected to the feed port, and a ground point of each antenna in the array antenna is connected to the ground port of the feed network.

Optionally, the signal source and the feed network are both located between the surface of the antenna bracket opposite to the main board and the rear housing.

Optionally, the signal source is located in the motherboard, the feed network is located between the surface of the antenna support opposite to the motherboard and the rear shell, a feed port of the feed network passes through the antenna support and is connected to a signal output port of the signal source, and a ground port of the feed network passes through the antenna support and is connected to a ground port of the signal source.

Optionally, a conductive area is disposed in a surface of the antenna bracket opposite to the motherboard, a feeding point and two grounding points are disposed in the conductive area, a distance between each grounding point and the feeding point is different, the feeding point is connected to a signal output port in a signal source, and the two grounding points are respectively connected to a grounding port in the signal source to form an antenna assembly.

Optionally, the feeding point and the grounding point farthest from the feeding point are portions of a first antenna in the antenna assembly, and a distance between the feeding point and the grounding point farthest from the feeding point is in a negative correlation with a resonant frequency of the first antenna.

Optionally, the feeding point and the grounding point closest to the feeding point are part of a second antenna in the antenna assembly, and a distance between the grounding point closest to the feeding point and the end for radiation in the conductive region is in a negative correlation with a resonant frequency of the second antenna.

Optionally, the resonant frequency of the antenna assembly is a preset frequency,

the resonant frequency of the first antenna is smaller than the preset frequency, and the resonant frequency of the second antenna is larger than the preset frequency; or,

the resonant frequency of the first antenna is greater than the preset frequency, and the resonant frequency of the second antenna is less than the preset frequency.

Optionally, the first antenna is a Loop (Loop) antenna; the second Antenna is a PIFA (planar inverted F Antenna).

The technical scheme provided by the embodiment of the disclosure can have the following beneficial effects:

a main board and an antenna bracket parallel to the main board are arranged in a cavity formed by a front shell and a rear shell of the terminal; the array antenna is arranged between the surface, back to back, of the main board in the antenna support and the rear shell, and at the moment, the array antenna is located between the antenna support and the rear shell, a clearance area in the height direction between the antenna support and the rear shell is utilized, the problem that the array antenna is located in the main board or located between the main board and the antenna support and accordingly does not have the clearance area is solved, and the implementation effect of the array antenna is improved.

By placing the array antenna and the metal frame in the terminal on different planes, signals transmitted by the array antenna located in the main board or located between the main board and the antenna support cannot be shielded by the metal frame.

The resonant frequency of the antenna assembly is a preset frequency, the resonant frequency of the first antenna is smaller than the preset frequency, and the resonant frequency of the second antenna is larger than the preset frequency; or the resonant frequency of the first antenna is greater than the preset frequency, and the resonant frequency of the second antenna is less than the preset frequency, so that the resonant frequency of one antenna is slightly less than the preset frequency, the resonant frequency of the other antenna is slightly greater than the preset frequency, and the bandwidth of the antenna assembly obtained by combining the two antennas is wider.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the disclosure.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the disclosure and together with the description, serve to explain the principles of the disclosure.

Fig. 1 is a schematic diagram illustrating a terminal structure according to an exemplary embodiment.

Fig. 2 is a schematic diagram of a terminal structure according to another exemplary embodiment.

Fig. 3 is a schematic diagram of another terminal structure shown according to the terminal.

Fig. 4 is a schematic diagram illustrating a relationship between an antenna mount and a metal bezel according to the terminal.

Fig. 5 is a schematic diagram of an antenna assembly shown in accordance with the terminal.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The implementations described in the exemplary embodiments below are not intended to represent all implementations consistent with the present disclosure. Rather, they are merely examples of apparatus and methods consistent with certain aspects of the present disclosure, as detailed in the appended claims.

Fig. 1 is a schematic diagram illustrating a terminal structure according to an exemplary embodiment, as shown in fig. 1, the terminal includes a front case 110 and a rear case 120, the front case 110 and the rear case 110 form a cavity,

the cavity is internally provided with a main board 130 and an antenna bracket 140 parallel to the main board 130;

an array antenna 150 is disposed between the surface of the antenna support 140 opposite to the main board 130 and the rear case 120.

In summary, in the terminal provided by the present disclosure, the main board and the antenna bracket parallel to the main board are disposed in the cavity formed by the front shell and the rear shell of the terminal; the array antenna is arranged between the surface, back to back, of the main board in the antenna support and the rear shell, and at the moment, the array antenna is located between the antenna support and the rear shell, a clearance area in the height direction between the antenna support and the rear shell is utilized, the problem that the array antenna is located in the main board or located between the main board and the antenna support and accordingly does not have the clearance area is solved, and the implementation effect of the array antenna is improved.

Fig. 2 is a schematic diagram illustrating a structure of a terminal according to another exemplary embodiment, as shown in fig. 2, the terminal includes: the front case 210 and the rear case 220, the front case 210 and the rear case 210 form a cavity, and a main board 230 and an antenna support 240 parallel to the main board 230 are disposed in the cavity.

The cavity formed by the front shell 210 and the rear shell 220 may be closed or not, and this embodiment is not limited.

The main board 230 is generally a circuit board in the terminal, and a plurality of devices are disposed in the circuit board. For example, a CPU (Central Processing Unit), a memory, a power amplifier, and the like are disposed in the circuit board, and the present embodiment does not limit the devices in the main board 230.

The antenna holder 240 is a holder for placing an antenna. The antenna bracket 240 is parallel to the main board 230, and the antenna bracket 240 is opposite to the main board 230.

An array antenna 250 is disposed between the surface of the antenna support 240 opposite to the main board 230 and the rear case 220.

The array antenna 250 includes a plurality of antenna units, which may be the same or different, and the embodiment is not limited thereto. It should be noted that the array antenna 250 in this embodiment may be an array antenna implemented in the related art, and this embodiment is not limited.

When the antenna holder 240 is positioned on the upper side of the main board 230, the surface opposite to the main board 230 is the upper surface of the antenna holder 240; when the antenna holder 240 is located at the lower side of the main board 230, the surface opposite to the main board 230 is the lower surface of the antenna holder 240; when the antenna holder 240 is located on the left side of the main board 230, the surface opposite to the main board 230 is the left surface of the antenna holder 240; when the antenna holder 240 is located on the right side of the main board 230, the surface opposite to the main board 230 is the right surface of the antenna holder 240. Fig. 2 illustrates the antenna holder 240 positioned on the upper side of the main board 230.

In this embodiment, the terminal further includes a signal source 260 and a feeding network 270, a feeding port 271 of the feeding network 270 is connected to a signal output port 261 in the signal source 260, a ground port 272 of the feeding network 270 is connected to a ground port 262 in the signal source 260, a feeding point 251 of each antenna element in the array antenna 250 is connected to the feeding port 271, and a grounding point 252 of each antenna element in the array antenna 250 is connected to the ground port 272 of the feeding network 270.

The signal source 260 is configured to provide signals and a ground point for the array antenna 250, and the signal source 260 includes a signal output port 261 and a ground port 262, where the signal output port 261 is connected to a feed port 271 of the feed network 270 to provide signals for the feed port 271, and the feed port 271 provides signals to the feed point 251 of each antenna unit in the array antenna 250; the ground port 262 of the signal source 260 is connected to the ground port 272 of the feed network 270 to provide a location for the ground port 272, which in turn provides a location for the ground point 252 of each antenna element in the array antenna 250. Referring to fig. 2, a right side view of fig. 2 shows a connection diagram of the feeding point 251 and the feeding port 271 of one antenna unit in the array antenna, and a connection diagram of the grounding point 252 and the grounding port 272.

In this embodiment, the signal source 260 and the feed network 270 are both located between the surface of the antenna support 240 opposite to the main board 230 and the rear case 220; alternatively, the signal source 260 is located in the main board 230, the feeding network 270 is located between the surface of the antenna support 240 opposite to the main board 230 and the rear case 220, the feeding port 271 of the feeding network 270 passes through the antenna support 240 and is connected to the signal output port 261 of the signal source 260, and the ground port 270 of the feeding network 270 passes through the antenna support 240 and is connected to the ground port 262 of the signal source 260.

When the signal source 260 and the feeding network 270 are both located between the surface of the antenna support 240 opposite to the main board 230 and the rear case 220, the signal source 260 and the feeding network 270 are located in the same space, which is convenient for wiring, please refer to fig. 3. When the feeding network 270 is located between the surface of the antenna support 240 opposite to the main board 230 and the rear housing 220, and the signal source 260 is located in the main board 230, the feeding network 270 and the signal source 260 need to pass through the antenna support 240 to be connected, please refer to fig. 2. That is, the feed port 271 of the feed network 270 is connected to the signal output port 261 of the signal source 260 through the antenna stand 240, and the ground port 270 of the feed network 270 is connected to the ground port 262 of the signal source 260 through the antenna stand 240. At this time, a hole may be formed in the antenna holder 240, and the feed port 271 of the feed network 270 and the signal output port 261 of the signal source 260 are connected through the thimble; and connects the ground port 270 of the feed network 270 and the ground port 262 of the signal source 260 through the thimble.

The array antenna is located in a terminal having a metal bezel 280, and the array antenna 250 is located in a different plane from the metal bezel 280.

Generally, the metal frame 280 surrounds the main board 230 and is located on the same plane as the main board 230, and since the antenna support 240 is parallel to the main board 230 and the antenna support 240 and the metal frame 280 are located on different planes, the array antenna 250 and the metal frame 280 are located on different planes, please refer to fig. 4.

Because the antenna assembly radiates signals to the periphery, when the array antenna 250 is located in the main board 230, the signals radiated by the array antenna 250 are shielded by the metal frame 280; in the embodiment, since the array antenna 250 and the metal frame 280 are located on different planes, the signals transmitted by the array antenna 250 are not shielded by the metal frame 280.

In this embodiment, the antenna disposed in the antenna support 240 may be an antenna in the related art, or alternatively, an antenna assembly may be disposed in the antenna support 240, which is described below.

A conductive area 290 is arranged in the surface of the antenna bracket 240 opposite to the main board 230, a feeding point 291 and two grounding points 292 are arranged in the conductive area 290, and the distance between each grounding point 292 and the feeding point 291 is different; the feeding point 291 is connected to the signal output port 301 of the signal source 300, and the two grounding points 292 are respectively connected to the grounding ports 302 of the signal source 300 to form an antenna assembly, please refer to fig. 5.

If the requirement of the current input from the feeding point 291 of the antenna assembly is consistent with the requirement of the current input from the feeding point 251 of each antenna unit in the array antenna, the antenna assembly and the array antenna share one signal source, i.e. the signal source 300 and the signal source 260 are one signal source; if the requirement of the current input from the feeding point 291 of the antenna component is not consistent with the requirement of the current input from the feeding point 251 of each antenna element in the array antenna, the antenna component corresponds to different signal sources with respect to the array antenna.

The conductive region 290 may be a region of a metal sheet disposed within the surface, or a region of a metal coating sprayed within the surface, and the embodiment is not limited thereto.

In this embodiment, a signal source 300 is the same as the signal source 260, and the signal source 260 is used to provide a signal and a location for an antenna assembly, and a signal output port 261 in the signal source 260 is connected to the feeding point 291 to provide a signal for the feeding point 291; the ground port 262 is connected to a ground point 292 to provide a location for the ground point 292. One of the ground ports 262 may be used, and in this case, two ground points 292 are connected to the ground port 262; alternatively, there may be two ground ports 262, and each ground point 292 is connected to one ground port 262.

In fig. 5, the right side view is a plan view of the antenna holder 240 viewed from the surface opposite to the main board 230. In fig. 5, the feeding point 291 is located above the two grounding points 292, and in practical implementation, the feeding point 291 may be located below the two grounding points 292, between the two grounding points 292, or at another position, which is not limited in this embodiment. The positions of the feeding point 291 and the grounding point 292 may be determined by the position of the signal source 260. For example, in order to reduce the length of the connection line between the feeding point 291 and the signal output port 261, the position of the feeding point 291 may be set at the relative position of the signal output port 261; alternatively, in order to reduce the length of the connection line between the ground point 292 and the ground port 262, the position of the ground point 292 may be set at a relative position to the ground port 262.

In this embodiment, each ground point 292 is at an unequal distance from the feed point 291. This is because the feeding point 291 needs to form a closed loop antenna with one of the ground points 292, and the feeding point 291 forms a closed loop with the ground point 292 only when the feeding point 291 is distant from the ground point 292, so that the distance between the ground point 292 and the feeding point 291 is distant. The feeding point 291 needs to form an open loop antenna with another grounding point 292, and the feeding point 291 forms an open loop with the grounding point 292 when the feeding point 291 is closer to the grounding point 292, so that the grounding point 292 is closer to the feeding point 291.

In this embodiment, the feeding point 291 and the grounding point 292 farthest from the feeding point 291 are portions of a first antenna, and the feeding point 291 and the grounding point 292 closest to the feeding point 291 are portions of a second antenna. In one possible implementation, the first antenna is a Loop antenna, and the second antenna is a PIFA.

It should be noted that the first antenna may not only have the characteristics of a Loop antenna, but also have the characteristics of a PIFA antenna; the second antenna may have not only the characteristics of a PIFA antenna but also the characteristics of a Loop antenna.

When the first antenna is a Loop antenna, current flows into the first antenna through the feeding point 291 and then flows out from the ground point 292 to form a Loop. At this time, the distance between the feeding point 291 and the grounding point 292 farthest from the feeding point is in a negative correlation with the resonant frequency of the first antenna. Wherein the distance between the feeding point 291 and the grounding point 292, which is the farthest from the feeding point, is denoted by d1 in fig. 5.

The lowermost end of the conductive region 290 is the end 293 for radiation.

When the second antenna is a PIFA antenna, current flows in through the feed point 291 and radiates out from the end 293 of the conductive region 290. At this time, the distance between the grounding point 292 closest to the feeding point 291 and the end 293 for radiation in the conductive region 290 is in a negative correlation with the resonant frequency of the second antenna. In fig. 5, the distance between the grounding point 292 closest to the feeding point 291 and the end 293 is denoted by d 2.

In this embodiment, the resonant frequency of the antenna assembly is a preset frequency, the resonant frequency of the first antenna is smaller than the preset frequency, and the resonant frequency of the second antenna is larger than the preset frequency; or the resonant frequency of the first antenna is greater than the preset frequency, and the resonant frequency of the second antenna is less than the preset frequency.

The absolute value of the difference value between the resonant frequency of the first antenna and the preset frequency and the absolute value of the difference value between the resonant frequency of the second antenna and the preset frequency are both smaller than a preset threshold value, so that the resonant frequency of one antenna is set to be slightly smaller than the preset frequency, the resonant frequency of the other antenna is set to be slightly larger than the preset frequency, and the bandwidth of an antenna assembly obtained by combining the two antennas is wide.

For example, when the preset frequency is 2.4GHz, the bandwidths of the first antenna and the second antenna are both 80MHz, and when the resonant frequencies of the first antenna and the second antenna are both 2.4GHz, the bandwidth of the antenna assembly is still 80 MHz; when the resonant frequency of the first antenna is slightly less than 2.4GHz and the resonant frequency of the second antenna is slightly more than 2.4GHz, the bandwidth of the antenna assembly is more than 80 MHz.

In summary, in the terminal provided by the present disclosure, the main board and the antenna bracket parallel to the main board are disposed in the cavity formed by the front shell and the rear shell of the terminal; the array antenna is arranged between the surface, back to back, of the main board in the antenna support and the rear shell, and at the moment, the array antenna is located between the antenna support and the rear shell, a clearance area in the height direction between the antenna support and the rear shell is utilized, the problem that the array antenna is located in the main board or located between the main board and the antenna support and accordingly does not have the clearance area is solved, and the implementation effect of the array antenna is improved.

By placing the array antenna and the metal frame in the terminal on different planes, signals transmitted by the array antenna located in the main board or located between the main board and the antenna support cannot be shielded by the metal frame. .

The resonant frequency of the antenna assembly is a preset frequency, the resonant frequency of the first antenna is smaller than the preset frequency, and the resonant frequency of the second antenna is larger than the preset frequency; or the resonant frequency of the first antenna is greater than the preset frequency, and the resonant frequency of the second antenna is less than the preset frequency, so that the resonant frequency of one antenna is slightly less than the preset frequency, the resonant frequency of the other antenna is slightly greater than the preset frequency, and the bandwidth of the antenna assembly obtained by combining the two antennas is wider.

Other embodiments of the disclosure will be apparent to those skilled in the art from consideration of the specification and practice of the disclosure herein. This application is intended to cover any variations, uses, or adaptations of the disclosure following, in general, the principles of the disclosure and including such departures from the present disclosure as come within known or customary practice within the art to which the disclosure pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the disclosure being indicated by the following claims.

It will be understood that the present disclosure is not limited to the precise arrangements described above and shown in the drawings and that various modifications and changes may be made without departing from the scope thereof. The scope of the present disclosure is limited only by the appended claims.

Claims (10)

1. A terminal, characterized in that the terminal comprises: a front shell and a rear shell, and the front shell and the rear shell form a cavity,

a main board and an antenna bracket parallel to the main board are arranged in the cavity;

an array antenna is arranged between the surface of the antenna support, back to the main board, and the rear shell.

2. The terminal of claim 1, wherein the terminal has a metal bezel, and wherein the array antenna is located in a different plane than the metal bezel.

3. The terminal according to claim 1, further comprising a signal source and a feeding network, wherein a feeding port of the feeding network is connected to a signal output port of the signal source, a ground port of the feeding network is connected to a ground port of the signal source, a feeding point of each antenna of the array antenna is connected to the feeding port, and a ground point of each antenna of the array antenna is connected to a ground port of the feeding network.

4. A terminal according to claim 3, characterized in that the signal source and the feed network are both located between the rear housing and a surface of the antenna support opposite the main board.

5. A terminal according to claim 3, wherein the signal source is located in the main board, the feed network is located between a surface of the antenna bracket opposite to the main board and the rear housing, a feed port of the feed network passes through the antenna bracket and is connected to a signal output port of the signal source, and a ground port of the feed network passes through the antenna bracket and is connected to a ground port of the signal source.

6. A terminal as claimed in any one of claims 1 to 5, characterised in that a conductive region is provided in the face of the antenna support opposite the main board, in that a feed point is provided in the conductive region, each ground point being spaced from the feed point by a different distance, the feed point being connected to a signal output port in a signal source, and two ground points being connected to respective ground ports in the signal source to form an antenna assembly.

7. A terminal as claimed in claim 6, characterised in that the feed point and the ground point furthest from the feed point are part of a first antenna in the antenna assembly and in that the distance between the feed point and the ground point furthest from the feed point is inversely related to the resonant frequency of the first antenna.

8. A terminal as claimed in claim 7, characterised in that the feed point and the closest ground point to the feed point are part of a second antenna in the antenna assembly and in that the distance between the closest ground point to the feed point and the end of the conductive region for radiation is inversely related to the resonant frequency of the second antenna.

9. A terminal according to claim 8, characterised in that the resonant frequency of the antenna component is a predetermined frequency,

the resonant frequency of the first antenna is smaller than the preset frequency, and the resonant frequency of the second antenna is larger than the preset frequency; or,

the resonant frequency of the first antenna is greater than the preset frequency, and the resonant frequency of the second antenna is less than the preset frequency.

10. The terminal of claim 8, the first antenna being a Loop antenna and the second antenna being a planar inverted-F antenna (PIFA).