CN110418528B

CN110418528B - Electronic device and electronic device control method

Info

Publication number: CN110418528B
Application number: CN201910704733.6A
Authority: CN
Inventors: 周意保
Original assignee: Guangdong Oppo Mobile Telecommunications Corp Ltd
Current assignee: Guangdong Oppo Mobile Telecommunications Corp Ltd
Priority date: 2019-07-31
Filing date: 2019-07-31
Publication date: 2021-04-16
Anticipated expiration: 2039-07-31
Also published as: CN110418528A

Abstract

The embodiment of the application provides electronic equipment and an electronic equipment control method. Electronic equipment includes antenna module, metal casing, non-shielding medium, leaded light spare and light source, the metal casing has the antenna seam, the antenna seam is used for supplying antenna module receiving and dispatching radio frequency signal, non-shielding medium part at least is located in the antenna seam, non-shielding medium can be penetrated by light, leaded light spare is located one side of metal casing, leaded light spare part at least is just right non-shielding medium sets up, the light source is located one side of leaded light spare, the light that the light source sent via lead to the back orientation of leaded light spare non-shielding medium transmission. The embodiment of the application provides an electronic equipment can form light in the position of antenna seam, can make electronic equipment's outward appearance be convenient for adjust.

Description

Electronic device and electronic device control method

Technical Field

The present disclosure relates to the field of electronic technologies, and in particular, to an electronic device and a control method for the electronic device.

Background

With the development of science and technology, the functions of intelligent electronic devices are more and more abundant, and consumers not only pay attention to the application functions of the electronic devices, but also pay attention to the appearances of the electronic devices. In the correlation technique, the metal luster of the metal piece is adopted to decorate the appearance of the electronic equipment, and aiming at the specific electronic equipment, the decorating part is fixed and is single, and flexible adjustment cannot be carried out.

Disclosure of Invention

The embodiment of the application provides electronic equipment and a control method of the electronic equipment, which can form brightness on an antenna slot part of the electronic equipment, so that the adjustment of the appearance of the electronic equipment is more flexible.

An embodiment of the present application provides an electronic device, which includes:

an antenna module;

the antenna module comprises a metal shell, a metal cover and a metal cover, wherein the metal shell is provided with an antenna seam, and the antenna seam is used for the antenna module of the electronic equipment to receive and transmit radio frequency signals;

a non-shielding medium at least partially within the antenna seam, the non-shielding medium being penetrable by light and radio frequency signals;

the light guide piece is positioned on one side of the metal shell, and at least part of the light guide piece is arranged right opposite to the non-shielding medium; and

the light source is positioned on one side of the light guide piece, and light rays emitted by the light source are guided by the light guide piece and then transmitted towards the non-shielding medium.

The electronic equipment that this application embodiment provided, through set up the non-shielding medium in metal casing's antenna seam, and set up leaded light spare and light source in one side of non-shielding medium for the light that the light source sent can penetrate after the leaded light spare direction the transmission of non-shielding medium goes out, thereby forms brightly at the position of antenna seam, sends luminance and colour etc. of light through adjusting the light source, just can form different decorations to metal casing, makes the decoration to metal casing more nimble changeable, makes electronic equipment's outward appearance more diversified.

Embodiments of the present application also provide an electronic device comprising a metal housing, a non-shielding medium, an antenna module, a light guide, a light source, and a processor, the metal shell is provided with an antenna seam, the non-shielding medium is at least partially positioned in the antenna seam, the non-shielding medium is made of a light-transmitting material, and can be penetrated by radio frequency signals, the antenna module is electrically connected with the processor and receives and transmits the radio frequency signals through the antenna seam under the control of the processor, the light guide member is at least partially opposite to the non-shielding medium, the light guide member and the light source are positioned on the same side of the metal shell, the light emitted by the light source can be transmitted out of the non-shielding medium after being guided by the light guide part, the processor is used for adjusting the brightness of the light emitted by the light source according to the intensity of the radio-frequency signals transmitted and received by the antenna module.

The embodiment of the present application further provides an electronic device control method, where the electronic device includes a metal housing, a non-shielding medium, a light guide member, a light source, and an antenna module, the metal housing has an antenna seam, the non-shielding medium is located in the antenna seam, the light guide member is at least partially aligned to the non-shielding medium, the light source is located on one side of the light guide member, the antenna module transmits a radio frequency signal through the antenna seam, and light emitted by the light source is transmitted through the non-shielding medium after being guided by the light guide member, the electronic device control method includes:

acquiring the transmitting frequency of network equipment;

judging whether the transmitting frequency is matched with the current working frequency of the antenna module;

and under the condition that the transmitting frequency is matched with the current working frequency of the antenna module, controlling the light source to emit light.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

Fig. 1 is a schematic structural diagram of an electronic device according to an embodiment of the present application.

Fig. 2 is a schematic structural diagram of an I-I sectional view of the electronic device provided in fig. 1.

Fig. 3 is a schematic structural diagram of another I-I sectional view of the electronic device provided in fig. 1.

Fig. 4 is a schematic structural diagram of a cross-sectional view I-I of the electronic device provided in fig. 1.

Fig. 5 is a schematic structural diagram of a cross-sectional view I-I of the electronic device provided in fig. 1.

Fig. 6 is a schematic structural diagram of a cross-sectional view I-I of the electronic device provided in fig. 1.

Fig. 7 is a schematic structural diagram of a cross-sectional view I-I of the electronic device provided in fig. 1.

Fig. 8 is a schematic diagram of a partial structure of the electronic device provided in fig. 1.

Fig. 9 is a schematic structural diagram of a cross-sectional view I-I of the electronic device provided in fig. 1.

Fig. 10 is another partial structural schematic diagram of the electronic device provided in fig. 1.

Fig. 11 is a schematic view of another partial structure of the electronic device provided in fig. 1.

Fig. 12 is a schematic structural diagram of a cross-sectional view I-I of the electronic device provided in fig. 1.

Fig. 13 is a schematic structural diagram of a cross-sectional view I-I of the electronic device provided in fig. 1.

Fig. 14 is a schematic view of another partial structure of the electronic device provided in fig. 1.

Fig. 15 is a flowchart illustrating an electronic device control method according to an embodiment of the present application.

Fig. 16 is a schematic partial flowchart of an electronic device control method according to an embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments obtained by a person of ordinary skill in the art without any inventive effort based on the embodiments in the present application are within the scope of protection of the present application. It should be noted that the features in all the following examples can be combined with each other to constitute a new embodiment.

Referring to fig. 1 and fig. 2, an electronic device provided in an embodiment of the present application includes an antenna module 100, a metal housing 150, a non-shielding medium 200, a light guide 300 and a light source 400, where the metal housing 150 has an antenna seam 151, the antenna seam 151 is used for the antenna module 100 to receive and transmit radio frequency signals, the non-shielding medium 200 is at least partially located in the antenna seam 151, the non-shielding medium 200 can be penetrated by light and radio frequency signals, the light guide 300 is located on one side of the metal housing 150, the light guide 300 is at least partially disposed opposite to the non-shielding medium 200, the light source 400 is located on one side of the light guide 300, and light emitted by the light source 400 is guided by the light guide 300 and then transmitted toward the non-shielding medium 200.

The electronic device may be any device having a communication function. For example: the system comprises intelligent equipment with a communication function, such as a tablet Computer, a mobile phone, an electronic reader, a remote controller, a Personal Computer (PC), a notebook Computer, vehicle-mounted equipment, a network television, wearable equipment and the like.

The non-shielding medium 200 may be a semi-transparent material, that is, the non-shielding medium 200 may be penetrated by a part of light, the non-shielding medium 200 may partially shield the light, and the non-shielding medium 200 may be penetrated by a radio frequency signal. The non-shielding dielectric 200 may be plastic, and is filled in the antenna slot 151 of the metal housing 150 through an injection molding process. The radio frequency signal may be an electromagnetic wave signal or a non-electromagnetic wave signal. The light guide 300 is used for guiding light, so that the transmission of the light is uniform, and the light guide 300 can be a light guide film. The light source 400 may be an LED lamp, and the light source 400 may be one LED lamp, or may be a set formed by arranging a plurality of LED arrays. The radio frequency signal emitted by the antenna module 100 of the electronic device can penetrate through the non-shielding medium 200 in the antenna seam 151 and be transmitted, and the light emitted by the light source 400 can be transmitted through the non-shielding medium 200 after being guided by the light guide 300.

The metal shell 150 has an inner surface 150a, an outer surface 150b and a connecting surface 150c connected between the inner surface 150a and the outer surface 150b, the antenna slot 151 penetrates through the inner surface 150a, the outer surface 150b and the connecting surface 150c at the same time, and the penetrating direction of the antenna slot 151 refers to the direction in which the antenna slot 151 penetrates through the inner surface 150a and the outer surface 150b at the same time. The antenna slot 151 divides the metal case 150 into a first case 152 and a second case 153 which are disposed at an interval. The outer surface 150b forms at least a part of the outer surface of the metal housing 150, the light guide 300 and the light source 400 are located on the side of the inner surface 150a facing away from the outer surface 150b, the light guide 300 at least partially faces the non-shielding medium 200, and the light source 400 is located on the side of the light guide 300.

In an embodiment, the light source 400 is located on a side of the light guide 300 away from the non-shielding medium 200, at this time, the light source 400, the light guide 300 and the non-shielding medium 200 are stacked, and the light guide 300 can enable light emitted by the light source 400 to be transmitted to the non-shielding medium 200 more uniformly, so that light with uniform brightness is formed at the position of the antenna slot 151. And the arrangement does not occupy the length and width dimensions of the electronic device.

In another embodiment, the light source 400 is located on the periphery of the light guide 300, and the light source 400 is disposed adjacent to the non-shielding medium 200, at this time, the light source 400 and the light guide 300 are disposed side by side, and the light guide 300 can enable the light emitted by the light source 400 to be transmitted to the non-shielding medium 200 more uniformly, so as to form light with uniform brightness at the position of the antenna slot 151. And the arrangement mode does not occupy the thickness dimension of the electronic equipment, and the thickness of the electronic equipment can be reduced.

The electronic equipment that this application embodiment provided, through set up non-shielding medium 200 in the antenna seam 151 at metal casing 150, and set up leaded light 300 and light source 400 in one side of non-shielding medium 200, make the light that light source 400 sent can penetrate after the leaded light 300 leads non-shielding medium 200 transmits away, thereby form bright at the position of antenna seam 151, through luminance and the colour etc. of adjusting light source 400 and sending light, just can form different decorations to metal casing 150, make the decoration to metal casing 150 more nimble changeable, make electronic equipment's outward appearance more diversified.

With continued reference to fig. 3, the non-shielding medium 200 includes a first portion 210 and a second portion 220 connected to each other, the first portion 210 is located in the antenna seam 151, the second portion 220 is located between the light guide 300 and the metal housing 150, and the peripheral side dimension of the first portion 210 is smaller than the peripheral side dimension of the second portion 220.

Specifically, the cross section of the non-shielding dielectric 200 along the penetrating direction of the antenna seam 151 is in a shape of a Chinese character 'tu', the first portion 210 is filled in the antenna seam 151, and the first portion 210 is flush with the outer surface 150 b. The second portion 220 is attached to a portion of the inner surface 150a, and the second portion 220 is attached to the light guide 300. In one embodiment, the dimension of the peripheral side of the first portion 210 is a constant value, the dimension of the peripheral side of the second portion 220 is a constant value, the dimension of the peripheral side of the first portion 210 is smaller than the dimension of the peripheral side of the second portion 220, and the peripheral side of the second portion 220 protrudes from the peripheral side of the first portion 210, so that the light from the second portion 220 can be transmitted to the first portion 210 and further to the other side of the metal shell 150 more sufficiently.

With reference to fig. 4, in another embodiment, the circumferential dimension of the first portion 210 is a gradual value, the circumferential dimension of the second portion 220 is a gradual value, and the circumferential dimension of the first portion 210 is smaller than the circumferential dimension of the second portion 220. Specifically, the first portion 210 is cone-shaped, and the second portion 220 is cone-shaped, so that the non-shielding medium 200 can be conveniently formed by a dispensing process, and the filling of the non-shielding medium 200 in the antenna slot 151 can be more stable. In addition, after the light emitted from the light source 400 is guided by the light guide 300 and reflected by the inner wall of the antenna slot 151 formed by the metal shell 150, more light is transmitted through the antenna slot 151, and the utilization rate of the light source 400 is improved.

Referring to fig. 5, the electronic device further includes a first adhesive member 510, a groove a is defined between the metal shell 150, the second portion 220 and the light guide member 300, the first adhesive member 510 is located between the light guide member 300 and the metal shell 150, and at least a portion of the first adhesive member 510 is accommodated in the groove a to fixedly connect the light guide member 300, the metal shell 150 and the non-shielding medium 200.

Specifically, the first adhesive member 510 is located between the light guide 300 and the metal shell 150, and the first adhesive member 510 contacts the second portion 220 to fixedly connect the light guide 300, the metal shell 150 and the non-shielding medium 200, and the first adhesive member 510 is further used to fix the light source 400 to the metal shell 150.

The first adhesive 510 may be a transparent optical adhesive, the first adhesive 510 is connected between the metal shell 150 and the light guide 300, the first adhesive 510 at least partially surrounds the second portion 220, and the first adhesive 510 contacts the second portion 220 to position the second portion 220. The first adhesive member 510 is also used to fix the light source 400 to the inner surface 150a of the metal housing 150.

Referring to fig. 6, further, the electronic device further includes a carrier plate 520, the carrier plate 520 is used for carrying the light source 400 and the light guide 300, the carrier plate 520 includes a bottom plate 521 and a connecting plate 522 extending from one side of the bottom plate 521, the connecting plate 522 is connected to the metal housing 150, and the bottom plate 521 is used for supporting the light source 400 and the light guide 300. The supporting plate 520 is made of a non-light-transmitting material and has a light shielding effect, and the supporting plate 520 is used for shielding light emitted by the light source 400, so that more light emitted by the light source 400 is transmitted to the light guide 300, and the utilization rate of the light source 400 is improved. And the bottom plate 521 is disposed on the side of the light guide 300 away from the non-shielding medium 200, so as to shield the light source 400 on the side of the light guide 300, so that more light is transmitted to the non-shielding medium 200 and further transmitted out from the antenna slot 151, thereby forming light.

With reference to fig. 7, the electronic device further includes a second adhesive piece 530, the second adhesive piece 530 is located between the first portion 210 and the metal shell 150, the second adhesive piece 530 includes a plurality of first sub-adhesive pieces 531, and the plurality of first sub-adhesive pieces 531 are arranged at intervals in the penetrating direction of the antenna seam 151.

The second adhesive 530 may be an optical adhesive. The penetrating direction of the antenna seam 151 refers to a direction in which the antenna seam 151 penetrates both the inner surface 150a and the outer surface 150b of the metal case 150. The first sub-adhesives 531 are arranged at intervals in the thickness direction of the metal case 150 to connect the non-shielding medium 200 to the metal case 150. The first sub-adhesive pieces 531 are arranged in pairs at two sides of the non-shielding medium 200, that is, the first sub-adhesive piece 531 at one side of the non-shielding medium 200 has the first sub-adhesive piece 531 arranged opposite to the first sub-adhesive piece 531 and arranged at the other side of the non-shielding medium 200, and at least part of the first sub-adhesive pieces 531 arranged in pairs are arranged opposite to each other, so that the stress of the metal shell 150 can be balanced, and the non-shielding medium 200 can be firmly fixed to the metal shell 150.

With reference to fig. 8, the electronic device further includes a third adhesive member 540, the third adhesive member 540 is located between the first portion 210 and the metal shell 150, the third adhesive member 540 includes a plurality of second sub-adhesive members 541, an extending direction of the second sub-adhesive members 541 is consistent with a penetrating direction of the antenna seam 151, and the plurality of second sub-adhesive members 541 are arranged around the first portion 210 at intervals.

The third adhesive member 540 may be an optical adhesive. The penetrating direction of the antenna seam 151 refers to a direction in which the antenna seam 151 penetrates both the inner surface 150a and the outer surface 150b of the metal case 150. The second sub-bonding pieces 541 are connected between the first portion 210 and the metal shell 150, the second sub-bonding pieces 541 are arranged at two opposite sides of the first portion 210 at intervals, and the adjacent second sub-bonding pieces 541 are arranged at two sides of the first portion 210 in a staggered manner, so that on one hand, the stress of the metal shell 150 is relatively balanced, and on the other hand, the non-shielding medium 200 can be firmly fixed to the metal shell 150. Further, the second sub-adhesives 541 are all hidden inside the metal housing 150, so that the appearance of the metal housing 150 is not adversely affected.

Referring to fig. 9, the non-shielding medium 200 includes a transparent adhesive layer 550 and light-shielding particles 560 doped in the transparent adhesive layer 550, the transparent adhesive layer 550 is used for adhering the metal shell 150, and the light-shielding particles 560 are used for shielding a portion of light transmitted from the light guide 300.

The transparent adhesive layer 550 may be a transparent optical adhesive, and the transparent adhesive layer 550 may be adhered to the metal shell 150. The light-shielding particles 560 are used for shielding light, so that the non-shielding medium 200 can be penetrated by a part of light and can shield a part of light. The light-shielding particles 560 may be uniformly mixed in the transparent adhesive layer 550. The light-shielding particles 560 can shield the functional devices inside the electronic device, and when a user observes from the outside of the electronic device, the user cannot observe the functional devices inside the electronic device, which is beneficial to improving the appearance of the electronic device.

Further, the light-shielding particles 560 may be particles having a metallic luster, so that the non-shielding medium 200 presents a metallic luster similar to that of the metal shell 150, and the appearance of the metal shell 150 is consistent with that of the non-shielding medium 200, which is helpful for solving the problem of appearance consistency of the electronic device.

Referring to fig. 10, the electronic device further includes a camera 600 and a transparent decoration 610, the metal housing 150 has a mounting hole 150A, the camera 600 is located in the mounting hole 150A, the transparent decoration 610 at least partially surrounds the periphery of the camera 600, the transparent decoration 610 at least partially faces the light guide 300, and the light emitted from the light source 400 can be transmitted to the transparent decoration 610 through the light guide 300.

Specifically, the transparent decoration 610 is made of a light-transmitting material, at least a portion of the transparent decoration 610 faces the light guide 300, and when the light emitted from the light source 400 is guided by the light guide 300, the light can be transmitted toward the non-shielding medium 200, so that light is formed in the antenna seam 151. And in this process, the light among the light guide 300 has some to transmit to transparent decoration 610 in, because transparent decoration 610 at least partially encircles camera 600 to can form brightly in camera 600's week side, decorate camera 600 for adopting the metal decorative ring, this embodiment can make decorative effect to camera 600 more diversified through luminance and the colour of adjusting light etc. and is more nimble to camera 600's brightness.

With reference to fig. 11 and 12, the metal housing 150 further has a light hole 150B spaced apart from the mounting hole 150A, the light hole 150B is disposed adjacent to the antenna seam 151, the electronic device further includes a flash 650 and a rotating portion 660 carrying the flash 650, the rotating portion 660 is configured to drive the flash 650 to rotate, and when the rotating portion 660 rotates to enable the flash 650 to face the light hole 150B, the flash 650 is configured to fill in light for a target object photographed by the camera 600; when the rotating part 660 rotates to make the flash lamp 650 face the light guide 300, the light emitted from the flash lamp 650 is guided by the light guide 300 and transmitted toward the non-shielding medium 200, wherein the light source 400 includes at least the flash lamp 650.

Specifically, the metal shell 150 has a light hole 150B, the flash 650 is at least partially aligned to the light hole 150B, the flash 650 is installed in the rotating portion 660, the rotating portion 660 can adjust the light emitting direction of the flash 650 by adjusting the structure thereof, and when the rotating portion 660 rotates to enable the flash 650 to face the light hole 150B of the metal shell 150, the flash 650 is used for supplementing light to the target object shot by the camera 600. When the rotating part 660 rotates to make the flash lamp 650 face the light guide 300, the flash lamp 650 may form the light source 400 to provide light to the light guide 300, so that the light guided by the light guide 300 is transmitted toward the non-shielding medium 200 in the antenna seam 151, thereby forming light at the position of the antenna seam 151. Through multiplexing flash lamp 650, both can carry out the light filling to the target object that camera 600 shot, can act on light source 400 again and provide light for the position of antenna seam 151, reduced the complexity of controlling flash lamp 650.

Referring to fig. 1 and 13, an electronic device provided in an embodiment of the present application includes a metal housing 150, a non-shielding medium 200, an antenna module 100, a light guide 300, a light source 400, and a processor 700, where the metal housing 150 has an antenna seam 151, the non-shielding medium 200 is at least partially located in the antenna seam 151, the non-shielding medium 200 is made of a light-transmitting material and can be penetrated by a radio frequency signal, the antenna module 100 is electrically connected to the processor 700 and receives and transmits the radio frequency signal through the antenna seam 151 under the control of the processor 700, the light guide 300 at least partially faces the non-shielding medium 200, the light guide 300 and the light source 400 are located on the same side of the metal housing 150, light emitted from the light source 400 is guided by the light guide 300 and can be transmitted from the non-shielding medium 200, and the processor 700 is configured to perform brightness adjustment on the light emitted from the light source 400 according to intensity of the radio frequency signal received and transmitted by the antenna module 100 And (6) adjusting.

With respect to the electronic device, the metal housing 150, the non-shielding medium 200, the light guide 300, and the light source 400, reference is made to the foregoing description, and no further description is provided herein. The antenna module 100 is configured to receive and transmit radio frequency signals through the antenna seam 151, so as to implement a communication function of an electronic device. The processor 700 may be a microprocessor 700, and is configured to adjust the light emission and the light extinction of the light source 400, and adjust the light emission brightness of the light source 400 during light emission.

The non-shielding medium 200 is made of a light-transmitting material, when light is transmitted to the non-shielding medium 200, a part of the light can penetrate through the non-shielding medium 200 for transmission, the other part of the light can be shielded by the non-shielding medium 200, the non-shielding medium 200 is arranged in the antenna seam 151 and can shield the functional device inside the electronic device, and when a user observes from the outside of the electronic device, the user cannot observe the functional device inside the electronic device through the antenna seam 151. The non-shielding dielectric 200 may be penetrated by a radio frequency signal, and the non-shielding dielectric 200 may be made of a plastic material and formed by an injection molding process. In one embodiment, the non-shielding medium 200 is the same color as the metal housing 150, so that the problem of uniformity of appearance of the electronic device can be solved. In other embodiments, the non-shielding medium 200 may be patterned to form a decoration for the electronic device, such as the shape of the non-shielding medium 200 forming a logo of the electronic device.

In one embodiment, in a case that the intensity of the rf signal transmitted and received by the antenna module 100 is a first intensity, the processor 700 controls the light source 400 to emit a first light; when the intensity of the rf signal transmitted and received by the antenna module 100 is the second intensity, the processor 700 controls the light source 400 to emit the second light.

Specifically, the electronic device includes a signal sensor 750, where the signal sensor 750 is configured to detect an intensity of the rf signal transmitted and received by the antenna module 100, and when the signal sensor 750 detects that the intensity of the rf signal transmitted and received by the antenna module 100 is a first intensity, the signal sensor 750 sends a feedback signal to the processor 700, and when the processor 700 receives the feedback signal that the intensity of the rf signal transmitted and received by the antenna module 100 is the first intensity, the processor 700 controls the light source 400 to send out a first light. When the signal sensor 750 detects that the intensity of the rf signal transmitted and received by the antenna module 100 is the second intensity, the signal sensor 750 sends a feedback signal to the processor 700, and when the processor 700 receives the feedback signal that the intensity of the rf signal transmitted and received by the antenna module 100 is the second intensity, the processor 700 controls the light source 400 to send out the second light.

Further, when the first intensity is different from the second intensity, the first light is different from the second light, the first light includes at least one of the brightness, the color and the flashing frequency of the light, and the second light includes at least one of the brightness, the color and the flashing frequency of the light. The first light different from the second light includes at least one of a brightness, a color, and a flicker frequency of the first light different from the second light.

In one embodiment, when the signal sensor 750 detects that the intensity of the rf signal transmitted and received by the antenna module 100 is a first intensity, the processor 700 controls the light source 400 to emit light with a first brightness. When the signal sensor 750 detects that the intensity of the rf signal transmitted and received by the antenna module 100 is a second intensity, the processor 700 controls the light source 400 to emit light with a second brightness. When the first intensity is less than the second intensity, the first brightness is less than the second brightness.

In one embodiment, when the signal sensor 750 detects that the intensity of the rf signal transmitted and received by the antenna module 100 is a first intensity, the processor 700 controls the light source 400 to emit a first color light. When the signal sensor 750 detects that the intensity of the rf signal transmitted and received by the antenna module 100 is a second intensity, the processor 700 controls the light source 400 to emit a second color light. The first color is different from the second color when the first intensity is different from the second intensity.

In one embodiment, when the signal sensor 750 detects that the intensity of the rf signal transmitted and received by the antenna module 100 is a first intensity, the processor 700 controls the light source 400 to emit light of a first frequency. When the signal sensor 750 detects that the intensity of the rf signal transmitted and received by the antenna module 100 is a second intensity, the processor 700 controls the light source 400 to emit light of a second frequency. The first frequency is different from the second frequency when the first intensity is different from the second intensity.

In another embodiment, the processor 700 controls the light source 400 to emit light at a predetermined frequency when the intensity of the rf signal transmitted and received by the antenna module 100 is less than a predetermined threshold.

Specifically, when the signal sensor 750 detects that the intensity of the rf signal transmitted and received by the antenna module 100 is smaller than the preset threshold, it indicates that the radiation performance of the antenna module 100 is poor, at this time, the processor 700 controls the light source 400 to emit light at the preset frequency, that is, the processor 700 controls the light source 400 to emit light at the preset interval, so that the antenna seam 151 forms bright flashing at the preset frequency band to prompt that the radiation performance of the antenna module 100 is poor.

Referring to fig. 14, the light source 400 includes a plurality of sub light sources 410, the plurality of sub light sources 410 are arranged at intervals on one side of the light guide 300, and the processor 700 controls the plurality of sub light sources 410 to be sequentially lighted along a first direction D1 when the antenna module 100 operates in a first frequency band; under the condition that the antenna module 100 operates in the second frequency band, the processor 700 controls a plurality of the sub light sources 410 to be sequentially illuminated along the second direction D2.

Wherein, the sub-light sources 410 are illuminated to indicate that the sub-light sources 410 emit light at this time. The plurality of sub-light sources 410 are arranged at intervals along a first direction D1 or a second direction D2 on one side of the light guide 300, and the first direction D1 and the second direction D2 are extension directions of the antenna slots 151. When the antenna module 100 operates in the first frequency band, the processor 700 controls the plurality of sub-light sources 410 to be sequentially illuminated along the first direction D1, when the antenna module 100 operates in the second frequency band, the processor 700 controls the plurality of light sources 400 to be sequentially illuminated along the second direction D2, and when the first frequency band is different from the second frequency band, the first direction D1 is different from the second direction D2. Wherein the first direction D1 is opposite to the second direction D2. The first frequency band may be a high frequency, for example, the first frequency band may be a millimeter wave frequency band. The second frequency band may be a low frequency, e.g., sub6GHz band. The operating frequency band of the currently operating antenna module 100 can be determined according to the sequential direction in which the sub-light sources 410 are sequentially lighted.

Referring to fig. 1, fig. 2 and fig. 15, an embodiment of the present invention further provides a method for controlling an electronic device, where the electronic device includes a metal housing 150, a non-shielding medium 200, a light guide 300, a light source 400 and an antenna module 100, the metal housing 150 has an antenna seam 151, the non-shielding medium 200 is located in the antenna seam 151, at least a portion of the light guide 300 faces the non-shielding medium 200, the light source 400 is located on one side of the light guide 300, the antenna module 100 transmits and receives a radio frequency signal through the antenna seam 151, and light emitted by the light source 400 is guided by the light guide 300 and then can be transmitted through the non-shielding medium 200. With respect to the metal housing 150, the non-shielding medium 200, the light guide 300, the light source 400, and the antenna module 100, reference is made to the foregoing description, and no further description is given here. The electronic device control method includes, but is not limited to, S100, S200, and S300, which are described below with respect to S100, S200, and S300.

S100: the transmitting frequency of the network device is obtained.

The obtaining of the transmitting frequency of the network device may be by obtaining frequency information issued by an authority, or by accessing the internet to obtain frequency information related to a region.

S200: it is determined whether the transmission frequency matches the current operating frequency of the antenna module 100.

S300: and controlling the light source 400 to emit light when the emission frequency is matched with the current working frequency of the antenna module 100.

Specifically, the network device is taken as a base station for illustration, the transmitting frequency of the base station is obtained, the transmitting frequency is compared with the current working frequency of the antenna module 100, whether the transmitting frequency is matched with the current working frequency of the antenna module 100 is judged, and under the condition that the transmitting frequency is matched with the current working frequency of the antenna module 100, the light source 400 is controlled to emit light to prompt that the current working frequency of the antenna module 100 is matched with the transmitting frequency of the network device, and at this time, the electronic device is in a normal communication function.

Continuing to refer to fig. 16, in one embodiment, the "S300: controlling the light source 400 to emit light "includes, but is not limited to, S310 and S320 in case the emission frequency matches the current operating frequency of the antenna module 100, which is described below with respect to S310 and S320.

S310: and under the condition that the transmitting frequency band and the working frequency band of the antenna module 100 are both the first frequency band, controlling the light source 400 to emit light rays with a first rule.

S320: and under the condition that the transmitting frequency band and the working frequency band of the antenna module 100 are both the second frequency band, controlling the light source 400 to emit light rays with the second rule.

Specifically, when the first frequency band is different from the second frequency band, the light ray of the first law is different from the light ray of the second law. The light rays of the first law comprise at least one of the brightness, the color and the flicker frequency band of the light rays, and the light rays of the second law comprise at least one of the brightness, the color and the flicker frequency band of the light rays.

In one embodiment, when the frequency band of the antenna module 100 for receiving and transmitting the radio frequency signal is a first frequency band, the processor 700 controls the light source 400 to emit light with a first brightness. When the signal sensor 750 detects that the frequency band of the antenna module 100 for receiving and transmitting the rf signal is the second frequency band, the processor 700 controls the light source 400 to emit light with the second brightness. When the first frequency band is smaller than the second frequency band, the first brightness is smaller than the second brightness.

In one embodiment, when the frequency band of the antenna module 100 for receiving and transmitting the radio frequency signal is a first frequency band, the processor 700 controls the light source 400 to emit light of a first color. When the signal sensor 750 detects that the frequency band of the antenna module 100 for receiving and transmitting the rf signal is the second frequency band, the processor 700 controls the light source 400 to emit the light of the second color. The first color is different from the second color when the first frequency band is different from the second frequency band.

In one embodiment, when the frequency band of the antenna module 100 for receiving and transmitting the rf signal is a first frequency band, the processor 700 controls the light source 400 to emit light of a first frequency. When the signal sensor 750 detects that the frequency band of the antenna module 100 for receiving and transmitting the rf signal is the second frequency band, the processor 700 controls the light source 400 to emit light of the second frequency. The first frequency is different from the second frequency when the first frequency band is different from the second frequency band.

The foregoing detailed description of the embodiments of the present application has been presented to illustrate the principles and implementations of the present application, and the above description of the embodiments is only provided to help understand the method and the core concept of the present application; meanwhile, for a person skilled in the art, according to the idea of the present application, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present application.

Claims

1. An electronic device, characterized in that the electronic device comprises:

an antenna module;

the antenna module comprises a metal shell, a metal cover and a metal cover, wherein the metal shell is provided with an antenna seam, and the antenna seam is used for the antenna module to transmit and receive radio frequency signals;

the light source is positioned on one side of the light guide piece, which is far away from the metal shell, and light rays emitted by the light source are guided by the light guide piece and then transmitted towards the non-shielding medium;

wherein the non-shielding medium comprises a first portion and a second portion connected, wherein the first portion is located within the antenna seam and the second portion is located between the light guide and the metal housing;

wherein the antenna module is electrically connected with the processor and can transmit and receive radio frequency signals through the antenna seam under the control of the processor,

the processor can adjust the brightness of the light emitted by the light source according to the intensity of the radio-frequency signals transmitted and received by the antenna module.

2. The electronic device of claim 1, wherein a peripheral side dimension of the first portion is smaller than a peripheral side dimension of the second portion.

3. The electronic device of claim 2, further comprising a first adhesive member, wherein a groove is defined between the metal housing, the second portion and the light guide member, the first adhesive member is located between the light guide member and the metal housing, and the first adhesive member is at least partially received in the groove to fixedly connect the light guide member, the metal housing and the non-shielding medium.

4. The electronic device according to claim 2 or 3, wherein the electronic device further comprises a second adhesive member, the second adhesive member is located between the first portion and the metal shell, the second adhesive member comprises a plurality of first sub-adhesive members, and the plurality of first sub-adhesive members are arranged at intervals in a penetrating direction of the antenna seam.

5. The electronic device according to claim 2 or 3, further comprising a third adhesive member, the third adhesive member being located between the first portion and the metal case, wherein the third adhesive member includes a plurality of second sub-adhesive members, an extending direction of the second sub-adhesive members is consistent with a penetrating direction of the antenna seam, and the plurality of second sub-adhesive members are arranged on a peripheral side of the first portion at intervals.

6. The electronic device of claim 1, wherein the non-shielding medium comprises a transparent adhesive layer and light-shielding particles doped in the transparent adhesive layer, the transparent adhesive layer is used for adhering the metal shell, and the light-shielding particles are used for shielding part of light transmitted from the light guide member.

7. The electronic device according to any one of claims 1 to 6, further comprising a camera and a transparent decoration, wherein the metal housing has a mounting hole, the camera is located in the mounting hole, the transparent decoration at least partially surrounds the periphery of the camera, the transparent decoration at least partially faces the light guide, and the light emitted from the light source can be transmitted to the transparent decoration through the light guide.

8. The electronic device of claim 7, wherein the metal shell further has a light hole spaced apart from the mounting hole, and the light hole is disposed adjacent to the antenna seam, the electronic device further includes a flash lamp and a rotating portion for carrying the flash lamp, the rotating portion is configured to rotate the flash lamp, and when the rotating portion rotates to enable the flash lamp to face the light hole, the flash lamp is configured to supplement light to a target object photographed by the camera; when the rotating part rotates to enable the flash lamp to face the light guide piece, light emitted by the flash lamp is guided by the light guide piece and then transmitted towards the non-shielding medium, wherein the light source at least comprises the flash lamp.

9. An electronic device comprising a metal housing, a non-shielding medium, an antenna module, a light guide, a light source, and a processor, the metal shell is provided with an antenna seam, the non-shielding medium is at least partially positioned in the antenna seam, the non-shielding medium is made of a light-transmitting material, and can be penetrated by radio frequency signals, the antenna module is electrically connected with the processor and receives and transmits the radio frequency signals through the antenna seam under the control of the processor, the light guide member is at least partially opposite to the non-shielding medium, the light guide member and the light source are positioned on the same side of the metal shell, the light emitted by the light source can be transmitted out of the non-shielding medium after being guided by the light guide part, the processor is used for adjusting the brightness of the light emitted by the light source according to the intensity of the radio-frequency signals transmitted and received by the antenna module.

10. The electronic device of claim 9, wherein the processor controls the light source to emit a first light when the intensity of the rf signal transmitted and received by the antenna module is a first intensity; and under the condition that the intensity of the radio-frequency signals transmitted and received by the antenna module is a second intensity, the processor controls the light source to emit a second light ray.

11. The electronic device of claim 10, wherein the first light is different from the second light when the first intensity is different from the second intensity, wherein the first light being different from the second light comprises at least one of a brightness, a color, and a blinking frequency of the first light being different from the second light.

12. The electronic device of claim 9, wherein the processor controls the light source to emit light at a predetermined frequency when the intensity of the radio frequency signal transmitted and received by the antenna module is less than a predetermined threshold.

13. The electronic device of claim 9, wherein the light source comprises a plurality of sub-light sources, the plurality of sub-light sources are spaced apart on one side of the light guide, and the processor controls the plurality of sub-light sources to be sequentially illuminated along a first direction when the antenna module operates in a first frequency band; and under the condition that the antenna module works in a second frequency band, the processor controls the sub light sources to be sequentially lightened along a second direction.

14. An electronic device control method, wherein the electronic device includes a metal housing, a non-shielding medium, a light guide member, a light source, and an antenna module, the metal housing has an antenna seam, the non-shielding medium is located in the antenna seam, the light guide member at least partially faces the non-shielding medium, the light source is located on one side of the light guide member, the antenna module transmits and receives radio frequency signals through the antenna seam, and light emitted by the light source is guided by the light guide member and then transmitted through the non-shielding medium, the electronic device control method includes:

acquiring the transmitting frequency of network equipment;

15. The method for controlling electronic equipment according to claim 14, wherein the controlling the light source to emit light in the case that the transmission frequency matches the current operating frequency of the antenna module comprises:

under the condition that the transmitting frequency and the working frequency band of the antenna module are both first frequency bands, controlling the light source to emit light rays with a first rule;

and under the condition that the transmitting frequency and the working frequency band of the antenna module are both the second frequency band, controlling the light source to emit light rays with the second rule.

16. An electronic device, characterized in that the electronic device comprises:

an antenna module;

wherein the content of the first and second substances,

the electronic equipment further comprises a camera and a transparent decoration part, the metal shell is provided with a mounting hole, the camera is located in the mounting hole, the transparent decoration part at least partially surrounds the periphery of the camera, at least part of the transparent decoration part is opposite to the light guide part, and light rays emitted by the light source can be transmitted to the transparent decoration part through the light guide part;

the electronic equipment further comprises a flash lamp and a rotating part for bearing the flash lamp, the rotating part is used for driving the flash lamp to rotate, and when the rotating part rotates to enable the flash lamp to face the light transmitting hole, the flash lamp is used for supplementing light to a target object shot by the camera; when the rotating part rotates to enable the flash lamp to face the light guide piece, light emitted by the flash lamp is guided by the light guide piece and then transmitted towards the non-shielding medium, wherein the light source at least comprises the flash lamp.