CN110138401B

CN110138401B - Double-screen wearable device based on coaxial turnover

Info

Publication number: CN110138401B
Application number: CN201811152731.2A
Authority: CN
Inventors: 胥干; 齐磊; 金祖涛
Original assignee: Guangdong Genius Technology Co Ltd
Current assignee: Guangdong Genius Technology Co Ltd
Priority date: 2018-09-29
Filing date: 2018-09-29
Publication date: 2021-06-01
Anticipated expiration: 2038-09-29
Also published as: CN110138401A

Abstract

A dual-screen wearable device based on coaxial flipping, comprising: the watch comprises a host, a bracket, a host rotating shaft and a watchband; the watchband comprises a first watchband and a second watchband, one end of the first watchband is connected with one side of the support, and one end of the second watchband is connected with the other side of the support; the one end of host computer is passed through the host computer pivot rotate connect in the support, the host computer is including the host computer front and the host computer back of relative setting, the host computer rotate to laminate in during the support the host computer back of the body laminate in the support, the host computer openly is equipped with first screen, the host computer back is equipped with the second screen. By implementing the embodiment of the invention, the probability of occurrence of the situation that the arms of a wearer are in a twisting state for a long time in use can be reduced, and the heat dissipation performance is good.

Description

Double-screen wearable device based on coaxial turnover

Technical Field

The invention relates to the technical field of wearable equipment, in particular to double-screen wearable equipment based on coaxial turnover.

Background

At present, a conventional wearable device (such as a telephone watch) has only one screen, and when the wearable device is used, a wearer of the wearable device is often required to twist an arm to orient the screen of the wearable device to himself, so as to obtain content information included in the screen of the wearable device or perform corresponding operations by using virtual function keys on the screen of the wearable device. In practice, it is found that the arm of the wearer of the wearable device is in a twisting state for a long time in the process of using the wearable device, and the user experience is poor.

Meanwhile, the wearable device generates a large amount of heat when performing a video call, but a wearer of the wearable device concentrates the heat generated by the wearable device on the plastic bottom case of the wearable device when wearing the wearable device, and the plastic bottom case of the wearable device directly contacts with the skin of the wearer of the wearable device, thereby resulting in poor heat dissipation performance.

In summary, it is an urgent need to solve the above-mentioned problems to develop a wearable device with good heat dissipation and reduced arm twisting during use.

Disclosure of Invention

The embodiment of the invention discloses a double-screen wearable device based on coaxial turnover, which can reduce the probability of the occurrence of the situation that the arms of a wearer are in a twisting state for a long time in use and has good heat dissipation performance.

The embodiment of the invention discloses a double-screen wearable device based on coaxial turnover, which comprises a host, a support, a host rotating shaft and watchbands, wherein one end of a first watchband is connected with one side of the support, and one end of a second watchband is connected with the other side of the support; the one end of host computer is passed through the host computer pivot rotate connect in the support, the host computer is including the host computer front and the host computer back of relative setting, the host computer rotate to laminate in during the support the host computer back of the body laminate in the support, the host computer openly is equipped with first screen, the host computer back is equipped with the second screen.

As an alternative embodiment, the host can be turned around the host rotation shaft so that the first screen or the second screen faces the face of the user.

As an optional implementation manner, a first limiting block and a second limiting block are respectively arranged at two ends of the host rotating shaft, the wearable device further comprises a damping elastic sheet, the damping elastic sheet is arranged on the host rotating shaft and located between the first limiting block and the second limiting block, and the damping elastic sheet is used for increasing friction force between the host rotating shaft and the support, so that the host rotating shaft drives the host to be fixed on the support.

As an alternative embodiment, the support is a hollow structure.

As an optional embodiment, the host is configured to flip around the host rotation axis to face the first screen to the face of the user when detecting a first use instruction triggered by the user to use the first screen; when a second use instruction triggered by the user and used for using the second screen is detected, the second screen is turned to face, facing the user, of the second screen around the rotating shaft of the host.

As an optional implementation manner, a first camera is disposed on the first screen, and a second camera is disposed on the second screen, wherein:

the host is used for detecting a first operation instruction which is triggered by a user on the first screen and used for indicating video call, displaying a first video call interface according to the first operation instruction, setting a picture captured by the first camera as a first display interface, and displaying the first display interface on the first video call interface; when a user sends a switching instruction for switching the first display interface on the first video call interface, switching the first display interface according to a switching mode corresponding to the switching instruction, wherein the switching mode corresponding to the switching instruction at least comprises switching to a picture captured by the second camera or switching to a combined picture containing the picture captured by the first camera and the picture captured by the second camera;

as an optional implementation manner, the host is further configured to detect a second operation instruction, triggered by the user on the second screen, for indicating a video call, display a second video call interface according to the second operation instruction, set a picture captured by the second camera as a second display interface, and display the second display interface on the second video call interface; when a user sends a switching instruction for switching the second display interface on the second video call interface, switching the second display interface according to a switching mode corresponding to the switching instruction, wherein the switching mode corresponding to the switching instruction at least comprises switching to a picture captured by the first camera or switching to a combined picture containing the picture captured by the first camera and the picture captured by the second camera.

As an optional implementation manner, the host is further configured to detect a setting instruction triggered by a user, and set a combination manner of the master screen and the slave screen according to a setting manner corresponding to the setting instruction; wherein the combination of the master screen and the slave screen comprises that the master screen is the first screen and the slave screen is the second screen, or that the master screen is the second screen and the slave screen is the first screen;

the host is further used for controlling the slave screen to enter a black screen mode and the master screen to enter a standby display mode when the wearable device is in the standby mode, wherein the standby display mode is a display mode for displaying key information on the master screen.

As an optional implementation manner, the host is further configured to turn around the host rotation shaft to a plurality of positions when receiving a wake-up instruction for instructing to wake up the wearable device, and determine, at each of the positions, whether a gesture image of a user exists by using the first camera and the second camera; when the gesture image of the user is judged to exist at a certain position, the gesture image of the user is obtained, and a use instruction corresponding to the gesture image is determined, wherein the use instruction is the first use instruction or the second use instruction.

As an optional implementation manner, the host is further configured to turn over to a preset heat dissipation position around the host rotating shaft and control the heat dissipation hole of the wearable device to adjust to an opening area matched with the heat of the host when the heat of the host reaches a preset heat.

Compared with the prior art, the embodiment of the invention has the following beneficial effects:

in the embodiment of the invention, the user can turn over the host machine of the double-screen wearable device based on coaxial turning, so that the probability of the situation that the arm of the user is in a twisting state for a long time in use is reduced, and the user experience is improved. Furthermore, designs utilizing coaxial flipping may better dissipate heat generated by the wearable device by flipping the body of the wearable device. In addition, the double-screen display can bear more content information and is more suitable for users to use.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, 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 only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a dual-screen wearable device based on coaxial flipping according to an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of another wearable device with two screens based on coaxial flipping according to the embodiment of the present invention;

fig. 3 is a schematic structural diagram of a main machine rotating shaft of a dual-screen wearable device based on coaxial flipping according to an embodiment of the present invention;

FIG. 4 is a schematic flow chart of a method for using a dual-screen wearable device based on coaxial flipping according to an embodiment of the present disclosure;

fig. 5 is a schematic flowchart of a video call using a dual-screen wearable device based on coaxial flipping according to an embodiment of the present disclosure;

fig. 6 is a flowchart illustrating a method for using a master screen and a slave screen of a dual-screen wearable device based on coaxial flipping according to an embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It is to be noted that the terms "comprises" and "comprising" and any variations thereof in the embodiments and drawings of the present invention are intended to cover non-exclusive inclusions. For example, a process, method, system, article, or apparatus that comprises a list of steps or elements is not limited to only those steps or elements listed, but may alternatively include other steps or elements not listed, or inherent to such process, method, article, or apparatus.

The embodiment of the invention discloses a double-screen wearable device based on coaxial turnover, which can reduce the probability of the occurrence of the situation that the arms of a wearer are in a twisting state for a long time in use and has good heat dissipation performance. The following are detailed below.

Example one

Referring to fig. 1 to 3 together, an embodiment of the invention provides a wearable device with dual screens based on coaxial flipping, the wearable device includes a host 11, a bracket 12, a host rotation shaft 13, and a watchband 14; the watch band 14 comprises a first watch band 141 and a second watch band 142, one end of the first watch band 141 is connected with one side of the bracket 12, and one end of the second watch band 142 is connected with the other side of the bracket 12; the one end of host computer 11 is passed through host computer pivot 13 and is rotated and connect in support 12, and host computer 11 is including the host computer front and the host computer back that set up relatively, and the host computer back is laminated in support 12 when host computer 11 rotates to laminating in support 12, and the host computer front is equipped with first screen 15, and the host computer 11 back is equipped with second screen 16.

In the embodiment of the present invention, the band 14 includes a first band 141 and a second band 142, and in fig. 1 and fig. 2, the first band 141 and the second band 142 are two separate bands, but in practical applications, the first band 141 and the second band 142 may also be a complete band, that is, a connected band clasp is used instead of a separate band clasp, or a derivative product of an elastic band and an elastic band is used as a band without using a band clasp, and the specific form of the band 14 is not limited in the embodiment of the present invention. In addition, the setting directions of the main unit rotation shaft 13 in fig. 1 to fig. 3 are all directions perpendicular to the watch band, but in practical applications, the main unit rotation shaft 13 may also be set to a direction parallel to the watch band, and the specific setting orientation of the main unit rotation shaft 13 is not limited in the embodiment of the present invention. The bottom side of the main unit 11 in contact with the skin is the side in direct contact with the support 12 in the use state of fig. 1, and is provided with a second screen 16, and the top side of the main unit 11 is the side where the first screen 15 is located in the use state of fig. 1.

By adopting the structure, the user can turn the host machine of the double-screen wearable device based on coaxial turning, so that the probability of the situation that the arm of the user is in a twisting state for a long time during use is reduced, and the user experience is improved. Furthermore, designs utilizing coaxial flipping may better dissipate heat generated by the wearable device by flipping the body of the wearable device. In addition, the double-screen display can bear more content information and is more suitable for users to use.

Further, the host 11 can be turned around the host hinge 13 so that the first screen 15 or the second screen 16 faces the face of the user.

Specifically, the user may manually turn the host 11 around the host rotation shaft 13, or may trigger a preset instruction to automatically turn the host 11 around the host rotation shaft 13, which is not limited in the embodiment of the present invention.

Further, the two ends of the host rotating shaft 13 are respectively provided with a first limiting block 131 and a second limiting block 132, the wearable device further comprises a damping elastic sheet 133, the damping elastic sheet 133 is arranged on the host rotating shaft 13 and located between the first limiting block 131 and the second limiting block 132, and the damping elastic sheet 133 is used for increasing the friction force between the host rotating shaft 13 and the support 12, so that the host rotating shaft 13 drives the host 11 to be fixed on the support 12.

Further, the holder 12 has a hollow structure.

In the embodiment of the present invention, the holder 12 may also be a solid structure, but considering that the solid structure has poor heat dissipation performance when the wearable device is in the use state shown in fig. 1, the holder 12 with the hollow structure is preferably used in the embodiment of the present invention, and at this time, since a certain gap is formed between the band 14, the holder 12 and the arm of the user when the user wears the wearable device, the body 11 can dissipate heat by using the holder 12 with the hollow structure and the gap, thereby improving the heat dissipation performance of the wearable device. And, compare solid construction's support, hollow structure's support 12 can also alleviate wearable equipment's total weight to a certain extent to bring better wearing experience for the user.

Example two

In the embodiment of the present invention, a first camera is disposed on the first screen, a second camera is disposed on the second screen, and the first camera and the second camera may be located on the same side or different sides, and the specific arrangement position of the first camera and the second camera is not limited in the embodiment of the present invention. As shown in fig. 4, a method of using a dual screen wearable device based on coaxial flipping may include the steps of:

401. when a wake-up command for instructing to wake up the wearable device is received, the host is turned to a plurality of positions around the host rotating shaft.

In an embodiment of the present invention, the wake-up instruction may be an instruction input by a user through voice for waking up the wearable device, for example, the wake-up instruction may be a voice message including "turn on", "start up", or "power on". Or, the wake-up instruction may also be voice information input by the user through voice for starting a certain operation of the wearable device, such as voice information including "several points are reached", "make a call", or "send a short message", and the like. The plurality of positions can be multiple positions that have set up in advance, for example, a plurality of positions can include that the contained angle between host computer and the horizontal plane is 5 degrees positions, the contained angle between host computer and the horizontal plane is 10 degrees positions and the contained angle between host computer and the horizontal plane is 15 degrees positions etc. to this realizes the all-round search to current wearable equipment place space through host computer around host computer pivot upset to a plurality of position, compares single camera and carries out fixed angle's search, and intelligent degree is higher.

402. The host judges whether a gesture image of the user exists at each position by using the first camera and the second camera, if so, step 403 is executed, and if not, the process is ended.

In the embodiment of the invention, the host judges whether the gesture image of the user exists or not by utilizing the first camera and the second camera at each position, and compared with the judgment method of using a single camera, the judgment method is more comprehensive and specific. Moreover, the gesture image of the user may be a static gesture image or a dynamic gesture image, which is not limited in the embodiment of the present invention.

As an optional implementation manner, when the gesture image of the user is a static gesture image, the determining, by the host at each location, whether the gesture image of the user exists by using the first camera and the second camera may include:

the host judges whether to capture the image of the hand of the user or not at each position by using the first camera and the second camera;

when the image of the hand of the user is captured, the host stops overturning around the rotating shaft of the host, and whether the posture information of the hand included in the image of the hand of the user is matched with the posture information of the preset gesture image is judged;

when the gesture information of the hand of the user is judged to be matched with the gesture information of the preset gesture image, determining that the gesture image of the user exists;

and when the gesture information of the hand of the user is judged not to be matched with the gesture information of the preset gesture image, determining that the gesture image of the user does not exist.

By implementing such an alternative embodiment, when the gesture image of the user is a static gesture image, it may be determined that the gesture image of the user exists when the gesture information included in the image of the hand of the user matches the gesture information of the preset gesture image, for example, the user may determine to start the first screen by using a gesture with a dash number "1", and may also determine to start the second screen by using a gesture with a dash number "2".

As another optional implementation manner, when the gesture image of the user is a dynamic gesture image, the determining, by the host at each position, whether the gesture image of the user exists by using the first camera and the second camera may include:

when the image of the hand of the user is captured, the host stops overturning around the rotating shaft of the host, and whether the motion track of the hand of the user is matched with the motion track of the preset gesture image is judged;

when the motion track of the hand of the user is judged to be matched with the motion track of the preset gesture image, the host machine determines that the gesture image of the user exists;

and when the motion trail of the hand of the user is judged not to be matched with the motion trail of the preset gesture image, the host machine determines that the gesture image of the user does not exist.

By implementing the optional implementation manner, when the gesture image of the user is a dynamic gesture image, it may be determined whether the motion trajectory of the hand of the user matches a motion trajectory of a preset gesture image of the user, for example, the dynamic gesture image may be a motion trajectory of a dash number "1" or a motion trajectory of a dash number "2". The process may determine the gesture image of the user in the process of the user stroke, and with the above optional embodiments, the gesture image of the user may also be determined after the user stroke is completed, so that the determination of the gesture image is more accurate.

403. The host computer obtains a gesture image of a user and determines a use instruction corresponding to the gesture image, wherein the use instruction is a first use instruction or a second use instruction.

In the embodiment of the present invention, the first use instruction is a use instruction for using the first screen, and the second use instruction is a use instruction for using the second screen.

404. When a first use instruction triggered by a user and used for using the first screen is detected, the host computer is turned to the face, facing the user, of the first screen around the rotating shaft of the host computer.

As an alternative embodiment, the turning of the host around the host rotation axis to the first screen facing the face of the user may include:

the host turns around a host rotating shaft according to the position corresponding to the host when the gesture image of the user is acquired, and a first camera of a first screen is started to judge whether the face image of the user is captured or not;

when the face image of the user is captured, the host machine adjusts the orientation of the host machine according to the eye fixation point of the user in the face image, so that the first screen faces the face of the user and faces the eye fixation point of the user.

By implementing the optional implementation mode, the first camera can be used for face recognition, the eye fixation point of the user can be further determined when the face of the user is recognized, and the direction of the host can be further adjusted according to the eye fixation point of the user, so that the position of the host after being turned over is more in line with the use requirement of the user, and the user experience is improved.

405. When a second use instruction triggered by the user and used for using the second screen is detected, the host computer is turned to the face, facing the user, of the second screen around the rotating shaft of the host computer.

As an alternative embodiment, the turning of the host around the host rotation axis to the second screen facing the face of the user may include:

the host turns around a rotating shaft of the host according to the position corresponding to the host when the gesture image of the user is acquired, and a second camera of a second screen is started to judge whether the face image of the user is captured or not;

when the face image of the user is captured, the host machine adjusts the orientation of the host machine according to the eye fixation point of the user in the face image, so that the second screen faces the face of the user and faces the eye fixation point of the user.

By implementing the optional implementation mode, the second camera can be used for face recognition, the eye fixation point of the user can be further determined when the face of the user is recognized, and the direction of the host can be further adjusted according to the eye fixation point of the user, so that the position of the host after being turned over is more in line with the use requirement of the user, and the user experience is improved.

Optionally, as shown in fig. 5, the video call using the dual-screen wearable device based on coaxial flipping may include the following steps:

501. the host detects a first operation instruction which is triggered by a user on a first screen and used for indicating video call, displays a first video call interface according to the first operation instruction, and sets a picture captured by a first camera as a first display interface.

In the embodiment of the invention, when a user triggers a first operation instruction on a first screen, a picture captured by a first camera is used as a first display interface by default.

502. The host displays the first display interface on the first video call interface.

503. When a user sends a switching instruction for switching a first display interface on the first video call interface, the first display interface is switched according to a switching mode corresponding to the switching instruction.

In the embodiment of the present invention, the switching manner corresponding to the switching instruction at least includes switching to a picture captured by the second camera, or switching to a combined picture including the picture captured by the first camera and the picture captured by the second camera.

504. And the host detects a second operation instruction which is triggered by the user on the second screen and used for indicating the video call, displays a second video call interface according to the second operation instruction, and sets a picture captured by the second camera as a second display interface.

505. And the host displays a second display interface on the second video call interface.

506. And when the user sends a switching instruction for switching the second display interface on the second video call interface, the host switches the second display interface according to a switching mode corresponding to the switching instruction.

In the embodiment of the present invention, the switching manner corresponding to the switching instruction at least includes switching to a picture captured by the first camera, or switching to a combined picture including the picture captured by the first camera and the picture captured by the second camera.

It should be noted that, step 504 to step 506 may also occur before step 501 to step 503, or step 504 to step 506 may also occur simultaneously with step 501 to step 503, which is not limited in the embodiment of the present invention.

Further optionally, as shown in fig. 6, the method of using a master screen and a slave screen of a dual-screen wearable device based on coaxial flipping may comprise the steps of:

601. the host computer detects a setting instruction triggered by a user and sets a combination mode of a main screen and a slave screen according to a setting mode corresponding to the setting instruction.

In the embodiment of the present invention, the combination manner of the master screen and the slave screen includes that the master screen is the first screen and the slave screen is the second screen, or the master screen is the second screen and the slave screen is the first screen. The setting instruction can be an instruction in a voice form, or a setting instruction corresponding to a certain key triggered by a user is received on a setting interface displayed on a screen.

Optionally, after the step 601 is executed, the following steps may also be executed:

602. when the wearable device is in the standby mode, the host computer controls the screen to enter a black screen mode and controls the main screen to enter a standby display mode, wherein the standby display mode is a display mode for displaying key information on the main screen.

In this embodiment of the present invention, the key information may include any one or several items of time, weather, or information notification, and may also include other information, and a specific category of the key information is not limited in this embodiment of the present invention.

Optionally, after step 602 is executed, the following steps may also be executed:

603. when the heat of the host reaches the preset heat, the host overturns to the preset heat dissipation position around the host rotating shaft and controls the heat dissipation hole of the wearable device to adjust the opening area matched with the heat of the host.

In the embodiment of the invention, the preset heat is the heat which needs to be radiated by the wearable device, and the setting can be changed by a user. The preset heat dissipation position may be a position at a certain angle between the preset host and the horizontal plane, or a position determined according to the current environment, which is not limited in the embodiment of the present invention.

As an optional implementation manner, when the preset heat dissipation position is a position determined according to the current environment, the host may turn over to the preset heat dissipation position around the host rotation shaft and control the heat dissipation hole of the wearable device to adjust to the opening area matched with the heat of the host, where the opening area may include:

the host machine is turned to a plurality of preset positions around a host machine rotating shaft, and wind direction information and wind intensity information of each preset position are detected;

the host selects a position with downwind direction information and maximum wind strength indicated by the wind strength information as a preset heat dissipation position according to the wind direction information and the wind strength information of each preset position;

the host computer is around host computer pivot upset to predetermineeing the heat dissipation position to the louvre of control wearable equipment is adjusted to the trompil area with the heat assorted of host computer, and wherein, the heat of host computer is higher, and the trompil area is big more.

Through implementing this kind of optional implementation, when the heat of host computer reached preset heat, the host computer can overturn to the preset heat dissipation position of following the wind and wind intensity is the biggest around the host computer pivot to the louvre of control wearable equipment is adjusted to the trompil area with the heat assorted of host computer, thereby realizes better radiating effect.

In various embodiments of the present invention, it should be understood that the sequence numbers of the above-mentioned processes do not imply an inevitable order of execution, and the execution order of the processes should be determined by their functions and inherent logic, and should not constitute any limitation on the implementation process of the embodiments of the present invention.

In the embodiments provided herein, it should be understood that "B corresponding to A" means that B is associated with A from which B can be determined. It should also be understood, however, that determining B from a does not mean determining B from a alone, but may also be determined from a and/or other information.

In summary, the wearable device with the double screens based on coaxial overturn can reduce the probability of occurrence of the situation that the arms of a wearer are in a twisting state for a long time in use, and is good in heat dissipation performance.

The above detailed description is made on a dual-screen wearable device based on coaxial flipping disclosed by the embodiment of the present invention, and a specific example is applied in the detailed description to explain the principle and the implementation of the present invention, and the description of the above embodiment is only used to help understanding the method and the core idea of the present invention; meanwhile, for a person skilled in the art, according to the idea of the present invention, 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 invention.

Claims

1. A double-screen wearable device based on coaxial turnover is characterized by comprising a host, a support, a host rotating shaft and a watchband;

the watchband comprises a first watchband and a second watchband, one end of the first watchband is connected with one side of the support, and one end of the second watchband is connected with the other side of the support;

one end of the host is rotatably connected to the support through the host rotating shaft, the host comprises a host front side and a host back side which are arranged oppositely, the host back side is attached to the support when the host rotates to be attached to the support, the host front side is provided with a first screen, and the host back side is provided with a second screen;

the wearable device further comprises a damping elastic sheet, the damping elastic sheet is arranged on the host rotating shaft and is positioned between the first limiting block and the second limiting block, and the damping elastic sheet is used for increasing the friction force between the host rotating shaft and the support so as to enable the host rotating shaft to drive the host to be fixed on the support; the support is of a hollow structure.

2. The dual-screen wearable device based on coaxial flipping of claim 1, wherein the host can flip around the host hinge to face the first screen or the second screen to a user's face.

3. The dual-screen wearable device based on coaxial flipping of claim 2, wherein:

the host is used for turning over the host rotating shaft to the face, facing the user, of the first screen when a first using instruction, triggered by the user, for using the first screen is detected; when a second use instruction triggered by the user and used for using the second screen is detected, the second screen is turned to face, facing the user, of the second screen around the rotating shaft of the host.

4. The dual-screen wearable device based on coaxial flipping of claim 3, wherein a first camera is disposed on the first screen and a second camera is disposed on the second screen, wherein:

the host is used for detecting a first operation instruction which is triggered by a user on the first screen and used for indicating video call, displaying a first video call interface according to the first operation instruction, setting a picture captured by the first camera as a first display interface, and displaying the first display interface on the first video call interface; when a user sends a switching instruction for switching the first display interface on the first video call interface, switching the first display interface according to a switching mode corresponding to the switching instruction, wherein the switching mode corresponding to the switching instruction at least comprises switching to a picture captured by the second camera or switching to a combined picture containing the picture captured by the first camera and the picture captured by the second camera.

5. The dual-screen wearable device based on coaxial flipping of claim 4, wherein:

the host is further used for detecting a second operation instruction which is triggered by the user on the second screen and used for indicating video call, displaying a second video call interface according to the second operation instruction, setting a picture captured by the second camera as a second display interface, and displaying the second display interface on the second video call interface; when a user sends a switching instruction for switching the second display interface on the second video call interface, switching the second display interface according to a switching mode corresponding to the switching instruction, wherein the switching mode corresponding to the switching instruction at least comprises switching to a picture captured by the first camera or switching to a combined picture containing the picture captured by the first camera and the picture captured by the second camera.

6. The dual-screen wearable device based on coaxial flipping of claim 5, wherein:

the host is also used for detecting a setting instruction triggered by a user and setting a combination mode of a main screen and a slave screen according to a setting mode corresponding to the setting instruction; wherein the combination of the master screen and the slave screen comprises that the master screen is the first screen and the slave screen is the second screen, or that the master screen is the second screen and the slave screen is the first screen;

7. The dual-screen wearable device based on coaxial flipping of any of claims 4 to 6, wherein:

the host is further used for turning over to a plurality of positions around the host rotating shaft when a wake-up instruction for instructing to wake up the wearable device is received, and judging whether a gesture image of a user exists or not at each position by using the first camera and the second camera; when the gesture image of the user is judged to exist at a certain position, the gesture image of the user is obtained, and a use instruction corresponding to the gesture image is determined, wherein the use instruction is the first use instruction or the second use instruction.

8. The dual-screen wearable device based on coaxial flipping of claim 7, wherein:

the host is further used for overturning to a preset heat dissipation position around the host rotating shaft and controlling the heat dissipation hole of the wearable device to adjust to the opening area matched with the heat of the host when the heat of the host reaches the preset heat.