CN114827350A

CN114827350A - Smart watch and communication method of smart watch

Info

Publication number: CN114827350A
Application number: CN202210306633.XA
Authority: CN
Inventors: 何岸; 刘荣; 陈超
Original assignee: DO Technology Co ltd
Current assignee: DO Technology Co ltd
Priority date: 2020-12-21
Filing date: 2020-12-21
Publication date: 2022-07-29
Also published as: CN112468644A; CN114866642A; CN112468644B

Abstract

The embodiment of the application provides an intelligent watch and a communication method of the intelligent watch, and relates to the field of wearable equipment. The intelligent watch comprises a watch body and an earphone, wherein the watch body is detachably connected with the earphone, the earphone is in communication connection with the watch body when being in a pulled-out state, when the watch body receives incoming call information, whether the incoming call is connected or not is determined according to acquired earphone operation information, and when the incoming call is determined to be connected, received audio data are sent to the earphone; the earphone plays audio according to the audio data and sends the voice information input by the user to the watch body. So, when the incoming telegram information was received to the intelligence wrist-watch, the user can converse through the earphone in this intelligence wrist-watch, has promoted the operation convenience, has avoided adopting the inconvenient and not enough problem of privacy nature of intelligence wrist-watch conversation to be favorable to user privacy protection.

Description

Smart watch and communication method of smart watch

The invention relates to a smart watch and a communication method of the smart watch, and the application is filed on a divisional application with the patent application number of 2020115218480 and the application date of 2020, 12 and 21.

Technical Field

The application relates to the field of wearable equipment, in particular to an intelligent watch and a communication method of the intelligent watch.

Background

At present, the intelligent wrist-watch that possesses conversation function all sets up speaker and microphone on the wrist-watch body basically, and the user is when using intelligent wrist-watch and another user's conversation, and user's speech content is gathered to the microphone, and another user's speech content is broadcast to the speaker, and this kind of conversation mode does not have any privacy, is unfavorable for user privacy protection.

Disclosure of Invention

Therefore, in order to solve the technical problems, it is necessary to provide a smart watch and a communication method of the smart watch, so as to solve the problem that privacy is not sufficient when the smart watch is used for communication in the prior art.

The embodiment of the application can be realized as follows:

in a first aspect, an embodiment of the present application provides an intelligent watch, including a watch body and an earphone, where the watch body includes a first control chip, the watch body is detachably connected to the earphone, and the earphone is in communication connection with the watch body when in a pull-out state;

the watch body is used for determining whether to put through an incoming call according to the acquired earphone operation information when receiving the incoming call information; when the incoming call is determined to be connected, sending the received audio data to the earphone; the earphone operation information comprises the generation times and/or duration of wearing detection information and touch information;

the earphone is used for playing audio according to the audio data and sending voice information input by a user to the watch body;

the first control chip is used for determining to put through an incoming call under the condition that the earphone is judged to be in a wearing state according to the wearing detection information and the generation times and/or duration of the touch information meet a first preset condition; and determining to reject the incoming call or hang up the call under the condition that the earphone is judged to be in the wearing state according to the wearing detection information and the generation times and/or the duration of the touch information accord with a second preset condition.

In an optional embodiment, the watch body includes a containing hole, an earphone detection module and a first bluetooth module, and the earphone detection module and the first bluetooth module are both electrically connected to the first control chip; the earphone comprises a second control chip, a second Bluetooth module, a wearing detection sensor and a touch detection sensor, wherein the second Bluetooth module and the wearing detection sensor are both electrically connected with the second control chip;

the accommodating hole is used for accommodating the earphone, and the earphone detection module is arranged in the accommodating hole;

the earphone detection module is used for detecting plugging information of the earphone and outputting the plugging information to the first control chip; the first control chip is used for controlling the first Bluetooth module to establish communication connection with the second Bluetooth module when the plugging information represents that the earphone is in a plugging state; when the plugging information represents that the earphone is in the plugging state, controlling the first Bluetooth module to be disconnected from the second Bluetooth module in communication;

the wearing detection sensor is used for detecting whether the earphone is in a wearing state or not, obtaining wearing detection information and outputting the wearing detection information to the second control chip; the second control chip is used for sending the wearing detection information to the first Bluetooth module through the second Bluetooth module under the condition that the first Bluetooth module is in communication connection with the second Bluetooth module, so that the first control chip can acquire the wearing detection information through the first Bluetooth module;

the touch detection sensor is used for generating touch information according to touch operation of a user and outputting the touch information to the second control chip;

the second control chip is used for recording the generation times and/or the duration of the touch information, and sending the generation times and/or the duration of the touch information to the first Bluetooth module through the second Bluetooth module under the condition that the first Bluetooth module is in communication connection with the second Bluetooth module, so that the first control chip can acquire the generation times and/or the duration of the touch information through the first Bluetooth module.

In an alternative embodiment, the touch detection sensor includes a vibration sensor and/or a touch sensor, and the touch information includes a vibration signal generated by the vibration sensor according to a click operation of a user and/or a touch signal generated by the touch sensor according to a touch operation of the user.

In an alternative embodiment, the first preset condition is that the generation number of the vibration signal is one; the second preset condition is that the generation times of the vibration signal are two times.

In an optional embodiment, the first preset reduction is that the generation times of the touch signal are one time, and the duration is lower than a preset first duration; the second preset condition is that the generation frequency of the touch signal is one time, and the duration time exceeds a preset second duration time.

In an optional embodiment, the first preset condition is that the generation frequency of the touch signal is one time, and the duration is lower than a preset first duration; the second preset condition is that the generation frequency of the vibration signal is two times.

In an optional embodiment, the watch body further comprises a touch display, and the touch display is electrically connected with the first control chip;

the first control chip is also used for controlling the touch display to display an answering button and a hang-up button for a user to operate when receiving incoming call information; if first operation information sent by the touch display is received, determining to connect the incoming call, and if second operation information sent by the touch display is received, determining to reject the incoming call or hang up the call; the first operation information is generated by the touch display in response to the operation of the user on the answer button, and the second operation information is generated by the touch display in response to the operation of the user on the hang-up button.

In an optional embodiment, the watch body further includes a first battery, a first charging control module and a first charging interface, and the first battery, the first charging interface and the first control chip are all electrically connected to the first charging control module; the earphone further comprises a second battery, a second charging control module and a second charging interface, wherein the second battery, the second charging interface and the second control chip are all electrically connected with the second charging control module, and the second charging interface is electrically connected with the first charging interface when the earphone is in an inserted state;

the first charging control module is used for controlling an external power supply to charge the first battery and outputting the electric energy of the first battery to the second charging interface through the first charging interface when the earphone is in the inserted state;

the second charging control module is used for charging the second battery according to the electric energy received by the second charging interface;

the second charging control module is further used for monitoring the residual electric quantity information of the second battery in real time, when the earphone is in a plug-in state, the residual electric quantity information is transmitted to the first control chip through the second charging interface, the first charging interface and the first charging control module in sequence, and when the earphone is in a pull-out state, the residual electric quantity information is transmitted to the first control chip through the second control chip, the second Bluetooth module and the first Bluetooth module in sequence, so that the first control chip controls the touch display to display the residual electric quantity information.

In an optional implementation manner, the watch body is provided with a containing hole, the containing hole is used for containing the earphone, and the earphone detection module is arranged in the containing hole.

In a second aspect, an embodiment of the present application provides a method for calling a smart watch, which is applied to a smart watch, where the smart watch includes a watch body and an earphone, the watch body includes a first control chip, the watch body is detachably connected to the earphone, and the earphone is in communication connection with the watch body when the earphone is in a pull-out state; the method comprises the following steps:

when the watch body receives the incoming call information, whether the incoming call is connected or not is determined according to the acquired earphone operation information; when the incoming call is determined to be connected, sending the received audio data to the earphone; the earphone operation information comprises the generation times and/or duration of wearing detection information and touch information;

the earphone plays audio according to the audio data and sends voice information input by a user to the watch body;

the first control chip determines to put through an incoming call under the condition that the earphone is judged to be in a wearing state according to the wearing detection information and the generation times and/or duration of the touch information meet a first preset condition; and determining to reject the incoming call or hang up the call under the condition that the earphone is judged to be in the wearing state according to the wearing detection information and the generation times and/or the duration of the touch information accord with a second preset condition.

In a third aspect, an embodiment of the present application provides a method for calling an intelligent watch, which is applied to an intelligent watch, where the intelligent watch includes a watch body, the watch body includes a first control chip, the watch body is detachably connected to an earphone, and the earphone is in communication connection with the watch body when the earphone is in a pulled-out state; the communication method comprises the following steps:

when the watch body receives the incoming call information, whether the incoming call is connected or not is determined according to the acquired earphone operation information; the earphone operation information comprises the generation times and/or duration of wearing detection information and touch information;

when the watch body determines to put through an incoming call, the watch body sends the received audio data to the earphone; receiving voice information input through the earphone;

In a fourth aspect, an embodiment of the present application provides a communication method for an intelligent watch, which is applied to an earphone, the earphone is detachably connected to a watch body, the watch body includes a first control chip, and the earphone is in communication connection with the watch body when being in a pull-out state; the communication method comprises the following steps:

when the earphone receives the incoming call information, the earphone sends earphone operation information to the watch body so that the watch body can determine whether to put through the incoming call; determining to put through an incoming call under the condition that the earphone is judged to be in a wearing state according to the wearing detection information and the generation times and/or duration of touch information meet a first preset condition through the first control chip; determining to reject the incoming call or hang up the call under the condition that the earphone is judged to be in a wearing state according to the wearing detection information and the generation times and/or duration of the touch information meet a second preset condition; the earphone operation information comprises the generation times and/or duration of wearing detection information and touch information;

and when the watch body determines to put through the incoming call, the earphone receives audio data sent by the watch body to play audio, and sends voice information input by a user to the watch body.

The intelligent watch comprises a watch body and an earphone, wherein the watch body is detachably connected with the earphone, the earphone is in communication connection with the watch body when being in a pulled-out state, the watch body determines whether to call up according to acquired earphone operation information when receiving call information, and sends received audio data to the earphone when determining to call up; the earphone plays audio according to the audio data and sends the voice information input by the user to the watch body. So, when the incoming telegram information was received to the intelligence wrist-watch, the user can converse through the earphone in this intelligence wrist-watch, has promoted the operation convenience, has avoided adopting the inconvenient and not enough problem of privacy nature of intelligence wrist-watch conversation to be favorable to user privacy protection.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained from the drawings without inventive effort.

Fig. 1 is a schematic structural diagram of a smart watch in which an earphone is in an inserted state according to an embodiment of the present application;

fig. 2 is a schematic structural diagram of a smart watch in which an earphone is in an unplugged state according to an embodiment of the present application;

fig. 3 is a schematic diagram of a functional module of a smart watch according to an embodiment of the present application;

fig. 4 is a schematic diagram of another functional module of the smart watch according to the embodiment of the present application;

fig. 5 is a schematic diagram of another functional module of a smart watch provided in an embodiment of the present application;

fig. 6 is a schematic diagram of another functional module of a smart watch provided in an embodiment of the present application;

fig. 7 is a schematic flowchart of a call method of a smart watch according to an embodiment of the present application.

An icon: 10-a smart watch; 100-a watch body; 200-a headset; 101-a containment hole; 110-a first control chip; 120-a headphone detection module; 130-a first bluetooth module; 140-touch display; 150-a first battery; 160-a first charging control module; 170-a first charging interface; 102-an I/O subsystem; 103-an optical sensor; 104-a first memory; 105-a radio frequency communication module; 106-other I/O devices; 111-a first processor; 112-a first storage controller; 113-a first peripheral interface; 1021-a display controller; 1022-an optical sensor controller; 1023-other I/O controllers; 210-a second control chip; 220-a second bluetooth module; 230-wear detection sensor; 240-touch detection sensor; 250-a second battery; 260-a second charging control module; 270-a second charging interface; 280-a loudspeaker; 290-a microphone; 201-an audio processing module; 202-second memory.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, 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 some embodiments of the present application, but not all embodiments. The components of the embodiments of the present application, generally described and illustrated in the figures herein, can be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present application, as presented in the figures, is not intended to limit the scope of the claimed application, but is merely representative of selected embodiments of the application. 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 application. It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

In the description of the present application, if the terms "upper", "lower", "inner", "outer", etc. indicate an orientation or positional relationship based on that shown in the drawings, or that the product of the invention is used as it is, it is only for convenience of description and simplicity of description, and it is not intended to indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, is not to be considered as limiting the present application. Furthermore, the appearances of the terms "first," "second," and the like, if any, are used solely to distinguish one from another and are not to be construed as indicating or implying relative importance. It should be noted that the features of the embodiments of the present application may be combined with each other without conflict.

Please refer to fig. 1 and fig. 2, which are schematic structural diagrams of a smart watch 10 according to an embodiment of the present application. This intelligent wrist-watch 10 includes wrist-watch body 100 and earphone 200, and wrist-watch body 100 is connected with earphone 200 detachably, and earphone 200 is in communication connection with wrist-watch body 100 when pulling out the state. Fig. 1 is a schematic structural diagram of the smart watch 10 when the earphone 200 is in the plugged-in state, and fig. 2 is a schematic structural diagram of the smart watch 10 when the earphone 200 is in the unplugged state.

In the present embodiment, the watch body 100 is provided with a receiving hole 101, and the receiving hole 101 is used for receiving the earphone 200, so that the earphone 200 can be inserted into the watch body 100 or pulled out from the watch body 100.

In this embodiment, the watch body 100 is configured to determine whether to answer an incoming call according to the acquired earphone operation information when receiving the incoming call information; when it is determined that the incoming call is connected, transmitting the received audio data to the headset 200; the earphone 200 is used for playing audio according to the audio data and sending the voice information input by the user to the watch body 100.

The earphone operation information may include information related to the earphone 200 detected by the watch body 100, and may also include information related to the earphone 200 detected by the earphone 200 itself, and these information may be generated according to the operation of the user on the earphone 200.

For example, when the watch body 100 receives incoming call information, the user pulls out the earphone 200 in the inserted state to realize the communication connection between the earphone 200 and the watch body 100, the user places the earphone 200 at the ear for answering the incoming call, the earphone 200 processes and plays the audio data transmitted from the watch body 100, and simultaneously collects the voice information input by the user and sends the voice information to the watch body 100, so that the functions of audio playing, voice input, incoming call answering and the like are realized.

It can be seen that the smart watch 10 provided in the embodiment of the present application includes a watch body 100 and an earphone 200, where the watch body 100 is detachably connected to the earphone 200, and the earphone 200 is in a pull-out state and is in communication connection with the watch body 100, when receiving incoming call information, the watch body 100 determines whether to connect an incoming call according to acquired earphone operation information, and when determining to connect the incoming call, sends received audio data to the earphone 200; the earphone 200 plays audio according to the audio data, and transmits the voice information input by the user to the watch body 100. So, when the intelligent watch 10 receives incoming call information, the user can talk through the earphone 200 in the intelligent watch 10, operation convenience is improved, the problem that the intelligent watch 10 is inconvenient to talk and privacy is not enough is avoided, and privacy protection of the user is facilitated.

Optionally, please refer to fig. 3, which is a schematic diagram of a functional module of the smart watch 10 according to an embodiment of the present application. The watch body 100 comprises a first control chip 110, an earphone detection module 120 and a first Bluetooth module 130, wherein the earphone detection module 120 and the first Bluetooth module 130 are electrically connected with the first control chip 110; the headset 200 includes a second control chip 210, a second bluetooth module 220, and a wearing detection sensor 230, and both the second bluetooth module 220 and the wearing detection sensor 230 are electrically connected to the second control chip 210.

The wearing detection sensor 230 may be an optical sensor (e.g., an infrared sensor, a PPG sensor), an ultrasonic sensor, a capacitance sensor, or the like.

The earphone detection module 120 is configured to detect plugging information of the earphone 200 and output the plugging information to the first control chip 110; the first control chip 110 is configured to control the first bluetooth module 130 to establish a communication connection with the second bluetooth module 220 when the plugging information indicates that the earphone 200 is in a unplugged state; and when the plugging information indicates that the headset 200 is in the plugging state, controlling the first bluetooth module 130 to be disconnected from the second bluetooth module 220. The wearing detection sensor 230 is configured to detect whether the earphone 200 is in a wearing state, obtain wearing detection information, and output the wearing detection information to the second control chip 210; the second control chip 210 is configured to send the wearing detection information to the first bluetooth module 130 through the second bluetooth module 220 under the condition that the first bluetooth module 130 establishes a communication connection with the second bluetooth module 220, so that the first control chip 110 obtains the wearing detection information through the first bluetooth module 130.

The earphone detection module 120 can be disposed in the receiving hole 101 for detecting whether the earphone 200 is in a plug-in state or a plug-out state (i.e. plug-in and plug-out information). The headphone detection module 120 may employ an optical sensor, such as an infrared sensor.

In one embodiment, the headset operation information may include the plugging information and the wearing detection information described above. The first control chip 110 is used for determining to switch on the incoming call under the condition that the earphone 200 is judged to be changed from the plug-in state to the plug-out state according to the plug-in and plug-out information and the earphone 200 is judged to be in the wearing state according to the wearing detection information; when it is determined that the earphone 200 is changed from the unplugged state to the plugged-in state based on the plugging information, it is determined that the incoming call is rejected or the call is hung up.

For example, when the watch body 100 receives incoming call information, the earphone detection module 120 detects that the earphone 200 is initially in the insertion state, then the insertion state is changed to the extraction state, and wearing detection information representing that the earphone 200 is in the wearing state is received, in this case, it indicates that the user performs an action of extracting the earphone 200 and completing wearing of the earphone 200 with respect to the incoming call information, so that the earphone 200 establishes a bluetooth communication connection with the watch body 100, and therefore it is determined that the incoming call is connected, so that the user can communicate through the earphone 200. Similarly, the watch body 100 detects that the earphone 200 is initially in the unplugged state through the earphone detection module 120, and then the unplugged state is changed into the plugged state, which indicates that the user performs the action of plugging the earphone 200 into the watch body 100 according to the incoming call information or the current call event, so that the earphone 200 is disconnected from the watch body 100 in the bluetooth communication connection, and therefore the incoming call is rejected or the call is hung up.

It should be noted that, in practical applications, in order to avoid the problem of increased energy consumption caused by repeatedly plugging and unplugging the headset 200 by a user, a time threshold may be set, and after the headset 200 is plugged out of the watch body 100, the user does not plug in the headset 200 within a predefined time threshold, a bluetooth communication connection with the headset 200 is established; when the earphone 200 is inserted into the watch body 100, the earphone 200 is not detected to be pulled out within a predefined time threshold, and then the Bluetooth communication connection with the earphone 200 is disconnected. The predefined time threshold may be set to 0.5s to 1 s.

Optionally, please refer to fig. 4, which is a schematic diagram of another functional module of the smart watch 10 according to the embodiment of the present application. The headset 200 further includes a touch detection sensor 240, and the touch detection sensor 240 is electrically connected to the second control chip 210.

The touch detection sensor 240 is configured to generate touch information according to a touch operation of a user, and output the touch information to the second control chip 210; the second control chip 210 is configured to record the generation times and/or the duration of the touch information, and send the generation times and/or the duration of the touch information to the first bluetooth module 130 through the second bluetooth module 220 under the condition that the first bluetooth module 130 establishes a communication connection with the second bluetooth module 220, so that the first control chip 110 obtains the generation times and/or the duration of the touch information through the first bluetooth module 130.

In an embodiment, the headset operating information may include the generation times and/or the duration of the wearing detection information and the touch information, and the first control chip 110 is configured to determine that the incoming call is connected when the headset 200 is determined to be in the wearing state according to the wearing detection information and the generation times and/or the duration of the touch information meet a first preset condition; and under the condition that the earphone 200 is in the wearing state and the generation times and/or the duration of the touch information meet/meet the second preset condition according to the wearing detection information, determining to reject the incoming call or hang up the call.

The touch detection sensor 240 may include a vibration sensor and/or a touch sensor, and the touch information includes a vibration signal generated by the vibration sensor according to a click operation of a user and/or a touch signal generated by the touch sensor according to a touch operation of the user.

For example, in a first case, the touch detection sensor 240 includes a vibration sensor, and the touch information includes a vibration signal generated by the vibration sensor according to the user clicking (or tapping) the earphone 200, the first preset condition may be that the generation number of the vibration signal is one, and the second preset condition may be that the generation number of the vibration signal is two; when the first control chip 110 determines that the headset 200 is in a wearing state and the number of times of generation of the acquired vibration signal is one (that is, the vibration sensor detects that the vibration signal generated when the user clicks the headset 200 once), it is determined that the incoming call is connected, so that the user can make a call through the headset 200; when the first control chip 110 determines that the headset 200 is in a wearing state and the number of times of generation of the acquired vibration signal is two (i.e. the vibration sensor detects the vibration signal generated by the user clicking the headset 200 twice), it is determined to reject the incoming call or hang up the call. Of course, in practical applications, the setting of the first preset condition and the second preset condition is not limited thereto.

In the second case, the touch detection sensor 240 includes a touch sensor, the touch information includes a touch signal generated by the touch sensor according to the touch of the user on the earphone 200, the first preset condition may be that the number of times of generation of the touch signal is one, and the duration is less than a first duration (short time, e.g., 2s), and the second preset condition may be that the number of times of generation of the touch signal is one, and the duration is more than a second duration (long time, e.g., 3 s); when the first control chip 110 determines that the headset 200 is in a wearing state and the acquired touch signal is a touch signal generated by a user touching the headset 200 for a single short time, it is determined that the incoming call is connected, so that the user can make a call through the headset 200; when the first control chip 110 determines that the headset 200 is in a wearing state and the acquired touch signal is a touch signal generated by a user touching the headset 200 for a single long time, it is determined that the incoming call is rejected or the call is hung up. Of course, in practical applications, the first preset condition may also be that the number of times of generating the touch signal is two, and the duration is lower than the first duration (short time, for example, 2s), and the second preset condition may be that the number of times of generating the touch signal is one, and the duration exceeds the second duration (long time, for example, 3s), which is not limited in this embodiment of the application.

In a third case, the touch detection sensor 240 includes a vibration sensor and a touch sensor, and the touch information may include a vibration signal generated when the vibration sensor clicks the earphone 200 by a user and a touch signal generated when the touch sensor touches the earphone 200 by the user, and thus the vibration signal generated by the vibration sensor and the touch signal generated by the touch sensor may be simultaneously combined to set the first preset condition and the second preset condition. For example, the first preset condition may be that the generation frequency of the touch signal is one, the duration is lower than the first duration (short time, for example, 2s), and the second preset condition may be that the generation frequency of the vibration signal is two, when the first control chip 110 determines that the headset 200 is in the wearing state and the acquired touch signal is a touch signal generated by a user touching the headset 200 for a single short time, it is determined that an incoming call is connected, so that the user can talk through the headset 200; when the first control chip 110 determines that the earphone 200 is in the wearing state and the number of times of generation of the acquired vibration signal is two, it is determined that the incoming call is rejected or the call is hung up.

Optionally, please refer to fig. 5, which is a schematic diagram of another functional module of the smart watch 10 according to the embodiment of the present application. The watch body 100 may further include a touch display 140, and the touch display 140 is electrically connected to the first control chip 110.

The first control chip 110 is further configured to control the touch display 140 to display an answer button and a hang-up button for a user to operate when receiving the incoming call information; if first operation information sent by the touch display 140 is received, the incoming call is determined to be connected, and if second operation information sent by the touch display 140 is received, the incoming call is determined to be refused or the call is hung up; the first operation information is generated by the touch display 140 in response to the operation of the user on the listen button, and the second operation information is generated by the touch display 140 in response to the operation of the user on the hang-up button.

That is, after the user pulls out the earphone 200 and finishes wearing, the user can directly operate the answer button or hang-up button displayed on the gui of the touch display 140 to answer or hang-up the phone call.

In this embodiment, the first control chip 110 is further configured to control the touch display 140 to display a recommended application program when the headset 200 is determined to be in the unplugged state according to the plugging information and when the headset 200 is determined to be in the worn state according to the wearing detection information; and opens the corresponding application program when receiving the application selection information transmitted by the touch display 140 according to the selection operation of the user.

That is, when determining that the headset 200 is unplugged and worn, the first control chip 110 may control the touch display 140 to display a recommended application program on the graphical user interface, for example, display a menu page including a telephone call, music, and a voice assistant application on the graphical user interface, where the menu page may be displayed on the entire touch display 140 or displayed in a pop-up window (i.e., occupying only a portion of the screen area) on the touch display 140. When the user selects a target application on the menu page, the touch display 140 sends corresponding application selection information to the first control chip 110 according to the selection operation of the user, and the first control chip 110 controls to open the corresponding target application.

Optionally, the watch body 100 may further include a first battery 150, a first charging control module 160, and a first charging interface 170, and the first battery 150, the first charging interface 170, and the first control chip 110 are all electrically connected to the first charging control module 160; the headset 200 may further include a second battery 250, a second charging control module 260, and a second charging interface 270, wherein the second battery 250, the second charging interface 270, and the second control chip 210 are electrically connected to the second charging control module 260, and the second charging interface 270 is electrically connected to the first charging interface 170 when the headset 200 is in the inserted state.

The first charging interface 170 may be a charging pin or a micro usb or other interface capable of realizing a charging function.

The first charging control module 160 is used for controlling an external power supply to charge the first battery 150, and outputting the electric energy of the first battery 150 to the second charging interface 270 through the first charging interface 170 when the earphone 200 is in the inserted state; the second charging control module 260 is configured to charge the second battery 250 according to the electric energy received by the second charging interface 270.

The second charging control module 260 is further configured to monitor remaining power information of the second battery 250 in real time, transmit the remaining power information to the first control chip 110 through the second charging interface 270, the first charging interface 170, and the first charging control module 160 in sequence when the earphone 200 is in the plugged state, and transmit the remaining power information to the first control chip 110 through the second control chip 210, the second bluetooth module 220, and the first bluetooth module 130 in sequence when the earphone 200 is in the unplugged state, so that the first control chip 110 controls the touch display 140 to display the remaining power information. Therefore, the user can timely acquire the residual electric quantity information of the earphone 200 in the using process, and the phenomenon that the earphone 200 cannot be used suddenly due to electric quantity exhaustion is avoided, so that the user experience can be effectively improved.

Optionally, please refer to fig. 6, which is a schematic diagram of another functional module of the smart watch 10 according to the embodiment of the present application. The earphone 200 may further include a speaker 280, a microphone 290 and an audio processing module 201, wherein the speaker 280 and the microphone 290 are electrically connected to the audio processing module 201, and the audio processing module 201 is electrically connected to the second control chip 210.

The first control chip 110 is further configured to send the received audio data to the second bluetooth module 220 through the first bluetooth module 130, the second control chip 210 is further configured to receive the audio data through the second bluetooth module 220 and output the audio data to the audio processing module 201 for processing, and the audio processing module 201 is configured to output the processed audio data to the speaker 280 for playing.

The microphone 290 is used for collecting voice information input by a user and outputting the voice information to the audio processing module 201 for processing, the audio processing module 201 is used for outputting the processed voice information to the second control chip 210, and the second control chip 210 is used for sending the processed voice information to the first bluetooth module 130 through the second bluetooth module 220.

In this embodiment, the second control chip 210 may receive bluetooth data (e.g., audio data, control instructions, etc.) transmitted by the watch body 100 through the second bluetooth module 220, forward the audio data to the audio processing module 201 for reading, decoding, digital-to-analog conversion, amplification, etc., and finally transmit the audio data to the speaker 280 for playing; the microphone 290 is configured to receive an external audio signal (e.g., voice information input by a user), transmit the voice information input by the user to the audio processing module 201, perform filtering, analog-to-digital conversion, encoding and the like by the audio processing module 201, and then transmit the voice information to the watch body 100 through the second control chip 210 and the second bluetooth module 220. In this manner, the audio playing and voice input functions of the headset 200 can be achieved.

In this embodiment, the watch body 100 may further include a first processor 111, a first storage controller 112, a first peripheral interface 113, an I/O subsystem 102, an optical sensor 103, a first storage 104, a radio frequency communication module 105, and other I/O devices 106; the first processor 111, the first memory controller 112, and the first peripheral interface 113 may be integrated onto the first controller chip 110. The various elements or modules in the watch body 100 are electrically connected to each other, directly or indirectly, to enable data transmission or interaction. For example, the components or modules may be electrically connected to each other via one or more communication buses or signal lines.

Wherein the first memory 104 is for storing a software program and/or a set of instructions; the first memory controller 112 is used for controlling other modules in the watch body 100 to access the first memory 104 so as to realize corresponding functions; the first processor 111 may perform data processing and call software programs and/or instruction sets from the first memory 104 to implement various functions of the watch body 100; the first peripheral interface 113 is used to connect various input and output peripherals in the watch body 100 to the first processor 111 and the first memory controller 112; the radio frequency communication module 105 is used for receiving and sending electromagnetic wave signals so as to facilitate the watch body 100 to carry out mobile communication; peripheral devices such as touch display 140, optical sensor 103, other I/O devices 106, etc. may be connected to first peripheral interface 113 through I/O subsystem 102, I/O subsystem 102 may include display controller 1021, optical sensor controller 1022, and other I/O controllers 1023, display controller 1021 being electrically connected to touch display 140, optical sensor controller 1022 being electrically connected to optical sensor 103, other I/O devices 106 being electrically connected to other I/O controllers 1023, other I/O devices 106 may include a rotatable crown, switches, etc. Of course, the watch body 100 may further include an accelerometer, a gyroscope, a magnetometer, and the like, for acquiring data such as the posture and the inertia of the watch body 100.

In this embodiment, the headset 200 may further include a second memory 202, the second control chip 210 further includes a second processor, a second memory controller and a second peripheral interface (not shown), which implement similar functions to the first control chip 110, and the various elements or modules in the headset 200 are electrically connected to each other directly or indirectly to implement data transmission or interaction. For example, the components or modules may be electrically connected to each other via one or more communication buses or signal lines.

The second memory 202 is used for storing software programs and/or instruction sets, and the second control chip 210 is connected to the input/output peripherals of the headset 200, implements control of the input/output peripherals, and calls the software programs and/or instruction sets from the second memory 202 to implement various functions of the headset 200.

Optionally, please refer to fig. 7, which is a flowchart illustrating a call method of a smart watch according to an embodiment of the present application. It should be noted that, the basic principle and the generated technical effects of the conversation method of the smart watch provided in the embodiment are the same as those of the embodiment described above, and for the sake of brief description, no part of the present embodiment is mentioned, and reference may be made to corresponding contents in the embodiment described above. The communication method of the smart watch can be applied to the smart watch 10, and comprises the following steps:

step S701, when the watch body receives the incoming call information, whether the incoming call is connected or not is determined according to the acquired earphone operation information; and when the incoming call is determined to be connected, sending the received audio data to the earphone.

Step S702, the earphone plays audio according to the audio data and sends the voice information input by the user to the watch body.

Optionally, the headset operating information includes plug information and wearing detection information, and the first control chip 110 determines to switch on the incoming call when determining that the headset 200 is changed from the plugged-in state to the unplugged state according to the plug information and determining that the headset 200 is in the wearing state according to the wearing detection information; and determining to reject the incoming call or hang up the call when the earphone 200 is determined to be changed from the unplugged state to the plugged-in state according to the plugging information.

Optionally, the headset operation information includes wearing detection information and generation times and/or duration of touch information, and the first control chip 110 determines to connect the incoming call when it is determined that the headset 200 is in a wearing state according to the wearing detection information and the generation times and/or duration of the touch information meet a first preset condition; and determining to reject the incoming call or hang up the call under the condition that the earphone 200 is in the wearing state and the generation times and/or the duration of the touch information meet/meet the second preset condition according to the wearing detection information.

Optionally, when receiving the incoming call information, the first control chip 110 controls the touch display 140 to display an answer button and a hang-up button for the user to operate; if first operation information sent by the touch display 140 is received, the incoming call is determined to be connected, and if second operation information sent by the touch display 140 is received, the incoming call is determined to be refused or the call is hung up; the first operation information is generated by the touch display 140 in response to the operation of the user on the listen button, and the second operation information is generated by the touch display 140 in response to the operation of the user on the hang-up button.

It can be seen that in the method for calling of the smart watch provided in the embodiment of the present application, the smart watch 10 includes the watch body 100 and the earphone 200, the watch body 100 is detachably connected to the earphone 200, and the earphone 200 is in a pull-out state and is in communication connection with the watch body 100, when receiving call information, the watch body 100 determines whether to call according to the acquired earphone operation information, and when determining to call, sends the received audio data to the earphone 200; the earphone 200 plays audio according to the audio data, and transmits the voice information input by the user to the watch body 100. So, when intelligent wrist-watch 10 received the incoming telegram information, the user can converse through earphone 200 among this intelligent wrist-watch 10, has promoted the operation convenience, has avoided adopting intelligent wrist-watch 10 to converse inconvenient and the not enough problem of privacy nature to be favorable to user privacy protection.

The above description is only for the specific embodiments of the present application, but the scope of the present application is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present application should be covered within the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims

1. An intelligent watch is characterized by comprising a watch body and an earphone, wherein the watch body comprises a first control chip, the watch body is detachably connected with the earphone, and the earphone is in communication connection with the watch body when being in a pull-out state;

2. The smart watch of claim 1, wherein the watch body comprises a containing hole, an earphone detection module and a first bluetooth module, and the earphone detection module and the first bluetooth module are electrically connected with the first control chip; the earphone comprises a second control chip, a second Bluetooth module, a wearing detection sensor and a touch detection sensor, wherein the second Bluetooth module and the wearing detection sensor are both electrically connected with the second control chip;

the earphone detection module is used for detecting plugging and unplugging information of the earphone and outputting the plugging and unplugging information to the first control chip; the first control chip is used for controlling the first Bluetooth module to establish communication connection with the second Bluetooth module when the plugging information represents that the earphone is in a plugging state; when the plugging information represents that the earphone is in the plugging state, controlling the first Bluetooth module to be disconnected from the second Bluetooth module in communication;

3. The smartwatch of claim 2, wherein the touch detection sensor comprises a vibration sensor and/or a touch sensor, and wherein the touch information comprises a vibration signal generated by the vibration sensor according to a click operation of a user and/or a touch signal generated by the touch sensor according to a touch operation of the user.

4. The smartwatch according to claim 3, wherein the touch detection sensor includes a vibration sensor, and the first preset condition is that the number of times of generation of the vibration signal is one; the second preset condition is that the generation frequency of the vibration signal is two times.

5. The smartwatch according to claim 3, wherein the touch detection sensor includes a touch sensor, and the first preset condition is that the touch signal is generated once for a duration shorter than a preset first duration; the second preset condition is that the generation frequency of the touch signal is one time, and the duration time exceeds a preset second duration time.

6. The smart watch according to claim 3, wherein the touch detection sensor includes a vibration sensor and a touch sensor, and the first preset condition is that the touch signal is generated once for a duration shorter than a preset first duration; the second preset condition is that the generation frequency of the vibration signal is two times.

7. The smart watch of claim 2, wherein the watch body further comprises a touch display, the touch display being electrically connected to the first control chip;

8. The smart watch of claim 7, wherein the watch body further comprises a first battery, a first charging control module and a first charging interface, the first battery, the first charging interface and the first control chip all being electrically connected to the first charging control module; the earphone further comprises a second battery, a second charging control module and a second charging interface, wherein the second battery, the second charging interface and the second control chip are all electrically connected with the second charging control module, and the second charging interface is electrically connected with the first charging interface when the earphone is in an inserted state;

9. The intelligent watch communication method is applied to an intelligent watch, the intelligent watch comprises a watch body and an earphone, the watch body comprises a first control chip, the watch body is detachably connected with the earphone, and the earphone is in communication connection with the watch body when being in a pull-out state; the method comprises the following steps:

10. The intelligent watch communication method is applied to an intelligent watch, the intelligent watch comprises a watch body, the watch body comprises a first control chip, the watch body is detachably connected with an earphone, and the earphone is in communication connection with the watch body when being in a pull-out state; the communication method comprises the following steps:

11. The communication method of the intelligent watch is characterized by being applied to an earphone, wherein the earphone is detachably connected with a watch body, the watch body comprises a first control chip, and the earphone is in communication connection with the watch body when being pulled out; the communication method comprises the following steps:

and when the earphone determines to put through the incoming call, the watch body receives the audio data sent by the watch body to play audio, and sends the voice information input by the user to the watch body.