CN111683358A

CN111683358A - Control method, control device, mobile terminal, storage medium and wireless headset

Info

Publication number: CN111683358A
Application number: CN202010639194.5A
Authority: CN
Inventors: 张秀生
Original assignee: Oppo Chongqing Intelligent Technology Co Ltd
Current assignee: Oppo Chongqing Intelligent Technology Co Ltd
Priority date: 2020-07-06
Filing date: 2020-07-06
Publication date: 2020-09-18

Abstract

The application discloses a control method, a control device, a mobile terminal, a storage medium and a wireless headset. The control method is used for controlling the wireless earphone to communicate with the wearable device through the mobile terminal, the wireless earphone comprises a first LoRa module, the wearable device comprises a second LoRa module, the first LoRa module is communicated with the second LoRa module, and the control method comprises the following steps: send control signal to wireless earphone in order to control first loRa module and receive the first pair signal of second loRa module, according to first pair signal control first loRa module and the second loRa module that corresponds pair, control first loRa module and send data to second loRa module. In the control method, the mobile terminal is paired with the second loRa module of the wearable device by controlling the first loRa module of the wireless headset, so that communication with the wearable device is realized. Therefore, the mobile terminal can be ensured to be communicated with the wearable device under the condition that the network communication signals are not good, and the user experience is enhanced.

Description

Control method, control device, mobile terminal, storage medium and wireless headset

Technical Field

The present application relates to the field of communications, and in particular, to a control method and apparatus, a mobile terminal, a storage medium, and a wireless headset for use in the field of communications.

Background

At present, communication of communication equipment is mostly limited by the strength of mobile communication signals at the current position, and if the mobile communication network at the position where the communication equipment is located is not good, effective communication cannot be performed, for example, in some parking lots or scenic spots, the situation that the network communication signals are not good is often encountered, and thus the communication equipment cannot perform effective communication.

Disclosure of Invention

The application provides a control method, the mobile terminal communicates with a wearable device through controlling the wireless earphone, the wireless earphone comprises a first LoRa module, the wearable device comprises a second LoRa module, the first LoRa module communicates with the second LoRa module, and the control method comprises the following steps:

sending a control signal to the wireless headset to control the first LoRa module to receive a first pairing signal of the second LoRa module;

controlling the first LoRa module to be paired with the corresponding second LoRa module according to the first pairing signal; and

and controlling the first LoRa module to send data to the second LoRa module.

The application also provides a control device for mobile terminal control wireless headset, mobile terminal passes through control wireless headset and wearable equipment communication, wireless headset includes first loRa module, wearable equipment includes second loRa module, wireless headset passes through first loRa module and second loRa module communication, control device includes:

the sending module is used for sending a control signal to the wireless earphone so as to control the first LoRa module to receive a first pairing signal of the second LoRa module;

the pairing module is used for controlling the first LoRa module to be paired with the corresponding second LoRa module according to the first pairing signal; and

and the control module is used for controlling the first LoRa module to send data to the second LoRa module.

The application provides a mobile terminal, mobile terminal passes through wireless earphone and wearable device communication, wireless earphone includes first loRa module, wearable device includes second loRa module, first loRa module with second loRa module communication, mobile terminal includes the treater, the treater is used for:

and controlling the first LoRa module to send data to the second LoRa module.

The application provides a mobile terminal, which comprises one or more processors and a memory; and

one or more programs, wherein the one or more programs are stored in the memory and executed by the one or more processors, the programs comprising instructions for performing the control method.

One or more non-transitory computer-readable storage media containing computer-executable instructions that, when executed by one or more processors, cause the processors to perform the control methods are provided.

The application also provides a wireless earphone which is respectively communicated with the mobile terminal and the wearable device in the control method.

In the control method, the control device, the mobile terminal, the computer-readable storage medium and the wireless headset, the mobile terminal is paired with the wearable device by controlling the first LoRa module of the wireless headset to be paired with the second LoRa module of the wearable device. Therefore, the mobile terminal can be ensured to be communicated with the wearable device under the condition that the network communication signal is not good, and the user experience is enhanced.

Drawings

The foregoing and/or additional aspects and advantages of the present application will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

fig. 1 is a schematic diagram of an implementation process of a control method according to some embodiments of the present application.

FIG. 2 is a schematic flow chart of a control method according to some embodiments of the present application.

FIG. 3 is a block schematic diagram of a control device according to certain embodiments of the present application.

Fig. 4 is a block diagram of a mobile terminal according to some embodiments of the present application.

FIG. 5 is a schematic diagram of a connection between a processor and a computer-readable storage medium according to some embodiments of the present application.

Fig. 6 is a schematic diagram of another implementation of the control method according to some embodiments of the present application.

Fig. 7 is a schematic diagram of another implementation of the control method according to some embodiments of the present application.

FIG. 8 is a schematic flow chart of a control method according to some embodiments of the present application.

FIG. 9 is a flow chart illustrating a control method according to some embodiments of the present application.

FIG. 10 is yet another flow chart illustrating a control method according to some embodiments of the present application.

FIG. 11 is a further schematic flow chart of a control method according to certain embodiments of the present application.

Detailed Description

Reference will now be made in detail to embodiments of the present application, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative and are only for the purpose of explaining the present application and are not to be construed as limiting the present application.

In the description of the present application, it is to be understood that the terms "first", "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implying any number of technical features indicated. Thus, features defined as "first", "second", may explicitly or implicitly include one or more of the described features. In the description of the present application, "a plurality" means two or more unless specifically defined otherwise.

In the description of the present application, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; may be mechanically connected, may be electrically connected or may be in communication with each other; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate.

The following disclosure provides many different embodiments or examples for implementing different features of the application. In order to simplify the disclosure of the present application, specific example components and arrangements are described below. Of course, they are merely examples and are not intended to limit the present application. Moreover, the present application may repeat reference numerals and/or letters in the various examples, such repetition is for the purpose of simplicity and clarity and does not in itself dictate a relationship between the various embodiments and/or configurations discussed.

Referring to fig. 1 and fig. 2, the present application provides a control method for a mobile terminal 100 to control a wireless headset 200, the mobile terminal 100 communicates with a wearable device 300 by controlling the wireless headset 200, the wireless headset 200 includes a first LoRa module 210, the wearable device 300 includes a second LoRa module 310, the first LoRa module 210 communicates with the second LoRa module 310, and the control method includes the steps of:

s12, sending a control signal to the wireless headset to control the first LoRa module to receive the first pairing signal of the second LoRa module;

s14, controlling the first LoRa module to be paired with the corresponding second LoRa module according to the first pairing signal; and

and S16, controlling the first LoRa module to send data to the second LoRa module.

Referring further to fig. 3, the present embodiment provides a control device 10. The control device 10 includes a sending module 12, a pairing module 14, and a control module 16.

The step S12 may be implemented by the sending module 12, the step S14 may be implemented by the pairing module 14, and the step S16 may be implemented by the control module 16.

Alternatively, the sending module 12 may be configured to send a control signal to the wireless headset 200 to control the first LoRa module 210 to receive the first pairing signal of the second LoRa module 310.

The pairing module 14 may be configured to control the first LoRa module 210 to be paired with the corresponding second LoRa module 310 according to the first pairing signal.

The control module 16 may be configured to control the first LoRa module 210 to send data to the second LoRa module 310.

Referring to fig. 1, the present application provides a mobile terminal 100, and the control method of the present application can be completed by the mobile terminal 100. The mobile terminal 100 includes a processor 30.

The processor 30 may be configured to send a control signal to the wireless headset 200 to control the first LoRa module 210 to receive the first pairing signal of the second LoRa module 310. The processor 30 may further be configured to control the first LoRa module 210 to pair with the corresponding second LoRa module 310 according to the first pairing signal and control the first LoRa module 210 to send data to the second LoRa module 310.

Referring to fig. 4, the present application provides a mobile terminal 100 comprising one or more processors 30, a memory 40; and one or more programs 42, wherein the one or more programs 42 are stored in the memory 40 and executed by the one or more processors 30, the programs 42 being executed by the processors 30 to perform the instructions of the control method.

Referring to fig. 5, the present application provides one or more non-transitory computer-readable storage media 50 containing computer-executable instructions that, when executed by one or more processors 30, cause the processors 30 to perform a control method.

In the control method, the control apparatus 10, the mobile terminal 100, and the computer-readable storage medium 50 of these embodiments, the mobile terminal 100 enables communication with the wearable device 300 by controlling the first LoRa module 210 of the wireless headset 200 to be paired with the second LoRa module 310 of the wearable device 300. Thus, the mobile terminal 100 is guaranteed to communicate with the wearable device 300 under the condition that the network communication signal is not good, and user experience is enhanced.

In some embodiments, the mobile terminal 100 may be a mobile phone, a tablet computer, a smart wearable device (smart watch, smart bracelet, smart helmet, smart glasses, etc.), a virtual reality device, or a head-up display device.

In the present embodiment, the mobile terminal 100 is a mobile phone, that is, the control method and the control device 10 are applied to, but not limited to, a mobile phone. The control device 10 may be hardware or software preinstalled in the handset and may perform the control method when the operation is started on the handset. For example, the control device 10 may be an underlying software code segment of a mobile phone or a part of an operating system. As such, when the cell phone is in communication with the wireless headset 200, the cell phone may be enabled to communicate with the wearable device 300.

In some embodiments, the control device 10 may be part of the mobile terminal 100. In other words, the mobile terminal 100 includes the control device 10.

In some embodiments, the control device 10 may be a discrete component assembled in such a way as to have the aforementioned functions, or a chip having the aforementioned functions in the form of an integrated circuit, or a piece of computer software code that causes a computer to have the aforementioned functions when run on the computer.

In some embodiments, the control device 10 may be a stand-alone or add-on peripheral component to a computer or computer system as hardware. The control device 10 may also be integrated into a computer or computer system, for example, where the control device 10 is part of a mobile terminal 100, the control device 10 may be integrated into the processor 30.

In some embodiments where the control apparatus 10 is part of the mobile terminal 100, as software, code segments corresponding to the control apparatus 10 may be stored on the memory 40 and executed on the processor 30 to implement the aforementioned functions. Or the control device 10, includes one or more of the programs 42 described above, or one or more of the programs 42 described above includes the control device 10.

In some embodiments, the computer-readable storage medium 50 may be a storage medium built in the mobile terminal 100, such as the memory 40, or a storage medium that can be plugged into the mobile terminal 100 in a pluggable manner, such as an SD card.

Those skilled in the art can understand that the LoRa technology is a long-distance wireless transmission technology based on a spread spectrum technology, and belongs to one of Low-power wide-area network technologies (LPWAN). The low-power-consumption wide area network technology is a wireless communication technology for the communication requirements of long distance and low power consumption in the Internet of things, and has the characteristics of low cost, low power consumption, wide coverage and large connection.

The control signal refers to a control command for controlling the wireless headset 200 by the mobile terminal 100, and the wireless headset 200 can perform corresponding operations according to the control signal after receiving the control signal, and the control signal may include multiple types, for example, a power switch, a volume adjustment, a play start/stop function, or a switch of the first LoRa module 210 of the wireless headset 200.

The mobile terminal 100 includes a first communication module 20, and the first communication module 20 can receive and play or display data such as video, audio, or text transmitted from the wireless headset 200, and can also transmit data such as video, audio, or text to the wireless headset 200.

The mobile terminal 100 can be wirelessly connected with the wireless headset 200 through the first communication module 20 to realize communication with the wireless headset 200, the connection mode includes but is not limited to bluetooth connection, Wi-Fi connection, LoRa connection, etc., for example, the first communication module 20 and the wireless headset 200 of the mobile terminal 100 both include bluetooth modules, and the mobile terminal 100 is wirelessly connected with the wireless headset 200 through the bluetooth modules. For another example, the first communication module 20 of the mobile terminal 100 is provided with an LoRa module, and the mobile terminal 100 is wirelessly connected to the wireless headset 200 through the LoRa module, so that communication power consumption of the mobile terminal 100 and the wireless headset 200 can be reduced. It should be noted that, in the present application, the distance between the mobile terminal 100 and the wireless headset 200 should be within the wireless communication range. For example, the mobile terminal 100 and the wireless headset 200 are both held by the same user, wherein the wireless headset 200 is worn on the user's head and the mobile terminal 100 is held by the user's hand.

The wireless headset 200 further includes a Micro Control Unit (MCU) and a second communication module 220. The micro control unit is connected to the first LoRa module 210 and the second communication module 220, respectively. Wherein the second communication module 220 wirelessly communicates with the first communication module 20 of the mobile terminal 100. The micro control unit can control the first LoRa module 210 and the second communication module 220, for example, the micro control unit can control the first LoRa module 210 and the second communication module 220 to initialize, configure communication parameters, switch operation modes, receive and transmit data, and the like.

The first LoRa module 210 includes a sleep mode, a standby mode, an Rx mode, a Tx mode, and other operation modes, wherein the first LoRa module 210 is in an on state in the Rx mode and the Tx mode. In the sleep mode, the first LoRa module 210 does not perform data transceiving, does not perform data processing, and only performs mode switching. In the standby mode, data transmission and reception are not performed, but data processing is possible. In the RX mode, data transmitted by other LoRa modules may be received. The first LoRa module 210 may continuously scan the channel (for example, the first LoRa module 210 may continuously scan a communication channel that the wireless headset 200 has agreed with the wearable control device) to search for data sent by other LoRa modules. If no data is received for a period of time in RX mode, the standby mode is automatically entered. In the standby mode, the micro control unit may control the first LoRa module 210 to enter the RX mode. For example, when the wireless headset 200 is worn, the first LoRa module 210 may automatically enter the RX mode. Alternatively, when the wireless headset 200 is communicatively connected to the mobile terminal 100, the mobile terminal 100 sends a control signal to the wireless headset 200 to control the micro control unit to control the first LoRa module 210 to enter the RX mode. In Tx mode, the first LoRa module 210 can transmit data to other LoRa modules paired therewith.

Wearable device 300 may include wireless headset 200, smart watch, smart bracelet, smart helmet, smart glasses, virtual reality device or head display device, etc., and specifically do not set up the limitation. In addition, the wearable device 300 also communicates with other electronic devices, such as a cell phone or tablet, thereby enabling the mobile terminal 100 to communicate with the electronic devices. In this way, the mobile terminal 100 can transmit data to the wearable device 300 through the wireless headset 200, and the wearable device 300 transmits the data to the electronic device, and meanwhile, the electronic device can also transmit data to the wireless headset 200 through the wearable device 300, and then the data is transmitted to the mobile terminal 100 through the wireless headset 200. For example, in some examples, the smart terminal is a mobile phone, the wearable device 300 is a wireless headset 200, and the electronic device is also a mobile phone, that is, communication between the mobile phone and the mobile phone is realized through two wireless headsets.

Specifically, the processor 30 may generate a control signal for switching the operation mode of the first LoRa module 210 and control the first communication module 20 to transmit the control signal to the second communication module 220, and after the second communication module 220 receives the control signal, the micro control unit controls the first LoRa module 210 to switch the operation mode to the Rx mode according to the control signal. So that the first LoRa module 210 can receive the first pairing signal sent by the second LoRa module 310 of the wearable device 300 within the communication range. It is understood that if the first LoRa module 210 receives a plurality of first pairing signals, a plurality of wearable devices 300 are included in the communication range of the first LoRa module 210, and each first pairing signal corresponds to one wearable device 300.

Further, after the first LoRa module 210 receives the first pairing signal, the micro control unit controls the second communication module 220 to send the first pairing signal to the first communication module 20. After the first communication module 20 receives the first pairing signal, the processor 30 processes the first pairing signal to enable the mobile terminal 100 to display the first pairing signal, which is not limited, for example, in a list form. The user can operate the mobile terminal 100, select the first pairing signal to be paired, after the user selects, the processor 30 controls the first communication module 20 to send a control signal to the wireless headset 200 to control the micro control unit to control the first LoRa module 210 to pair with the second LoRa module 310 corresponding to the selected first pairing signal, and after the pairing is successful, the wireless headset 200 communicates with the wearable device 300, so that the mobile terminal 100 communicates with the wearable device 300 through the wireless headset 200.

Further, the processor 30 controls the first communication module 20 to send a control signal to the wireless headset 200 again to control the micro control unit to switch the operation mode of the first LoRa module 210 to the Tx mode, so that after the mobile terminal 100 sends data to the wireless headset 200, the first LoRa module 210 can directly send the data to the wearable device 300.

In addition, if the mobile terminal 100 is to receive data transmitted from the wearable device 300, the processor 30 controls the first communication module 20 to transmit a control signal to the wireless headset 200 to control the micro control unit to switch the operation mode of the first LoRa module 210 to the Rx mode. In this way, the wireless headset 200 may receive the data sent by the second LoRa module 310 through the first LoRa module 210. The second communication module 220 transmits the data to the mobile terminal 100, and the mobile terminal 100 may directly display or play the data, or transmit the data to the wireless headset 200 for playing by the wireless headset 200. In this way, it is achieved that the mobile terminal 100 receives data transmitted from the wearable device 300.

It should be noted that, after the first LoRa module 210 receives the data sent by the second LoRa module 310, the micro control unit directly controls the second communication module 220 to send the data to the first communication module 20, and the processor 30 of the mobile terminal 100 processes the data. Thus, the wireless headset 200 does not need to process data, and the hardware cost, the volume and the power consumption of the wireless headset 200 are reduced.

Referring to fig. 6, additionally, in some examples, the wearable device 300 further includes a third communication module 320. The wearable device 300 may also communicate with other electronic devices 400, such as a cell phone or a tablet, through the third communication module 320, thereby enabling the mobile terminal 100 to communicate with the electronic devices 400. The connection manner of the wearable device 300 and the electronic device 400 for wireless communication is not limited, and for example, the connection manner may be a bluetooth connection, a Wi-Fi connection, or the like. In this way, the mobile terminal 100 can transmit data to the wearable device 300 through the wireless headset 200, and the wearable device 300 transmits the data to the electronic device 400, and meanwhile, the electronic device 400 can also transmit data to the wireless headset 200 through the wearable device 300, and then the wireless headset 200 transmits the data to the mobile terminal 100. For example, in some examples, the mobile terminal 100 is a mobile phone, the wearable device 300 is a wireless headset 200, and the electronic device 400 is also a mobile phone, that is, communication between the mobile phone and the mobile phone is achieved through two wireless headsets.

Referring to fig. 7 and 8, in some embodiments, the wireless headset 200 includes a first wireless headset 230 and a second wireless headset 240, the first LoRa module 210 includes a first LoRa sub-module 211 and a second LoRa sub-module 212, the first LoRa sub-module 211 is disposed on the first wireless headset 230, the second LoRa sub-module 212 is disposed on the second wireless headset 240, and step S16 includes the steps of:

s161, detecting the communication signal intensity of the communication between the first LoRa module and the second LoRa module;

s162, judging the intensity of the communication signal and the preset value;

and S163, when the intensity of the communication signal is greater than the preset value, starting the first LoRa submodule or the second LoRa submodule to send data to the second LoRa submodule.

And S164, when the intensity of the communication signal is smaller than or equal to the preset value, the first LoRa submodule and the second LoRa submodule are started to send data to the second LoRa submodule.

Referring further to fig. 3, in some embodiments, the control module 16 includes a detection unit 161, a determination unit 162, and a first control unit 163 and a second control unit 164. Wherein step S161 may be implemented by the detection unit 161. Step S162 may be implemented by the determination unit 162, and step S163 may be implemented by the first control unit 163. Step S164 may be implemented by the second control unit 164.

Alternatively, the detecting unit 161 may be configured to detect the communication signal strength of the communication between the first LoRa module 210 and the second LoRa module 310.

The determining unit 162 may be configured to determine the communication signal strength and the predetermined value.

The first control unit 163 may be configured to activate the first LoRa sub-module 211 or the second LoRa sub-module 212 to send data to the second LoRa module 310 when the intensity of the communication signal is greater than the preset value.

The second control unit 164 may be configured to activate the first LoRa sub-module 211 and the second LoRa sub-module 212 to send data to the second LoRa module 310 when the communication signal strength is less than or equal to the preset value.

In some embodiments, the processor 30 is configured to detect a communication signal strength of the first LoRa module 210 in communication with the wearable device 300. The processor 30 is configured to determine the communication signal strength and the predetermined value. The processor 30 may be further configured to activate the first LoRa sub-module 211 or the second LoRa sub-module 212 to send data to the second LoRa module 310 when the communication signal strength is greater than the preset value, and activate the first LoRa sub-module 211 and the second LoRa sub-module 212 to send data to the second LoRa module 310 when the communication signal strength is less than or equal to the preset value.

The preset value is a predefined value, and the preset value may be set by a manufacturer when the mobile terminal 100 leaves a factory, or may be set by a user. The preset value may be stored in the computer-readable storage medium 50, and called by the processor 30 or the control device 10.

It should be noted that the effective communication distances of the first LoRa sub-module 211 and the second LoRa sub-module 212 are different, for example, the effective communication distance of the first LoRa sub-module 211 is 8000 m, and the effective communication distance of the second LoRa sub-module 212 is 12000 m. In some examples, the first LoRa sub-module 211 and the second LoRa sub-module 212 employ different operating frequency chips such that the effective communication distances of the first LoRa sub-module 211 and the second LoRa sub-module 212 are different, e.g., the first LoRa sub-module 211 may employ a 868 mhz chip, the second LoRa sub-module 212 may employ a 433 mhz chip, etc. In addition, the second LoRa module 310 also includes a third LoRa submodule 311 paired with the first LoRa submodule 211 and a fourth LoRa submodule 312 paired with the second LoRa submodule 212. It should be further noted that, turning on the first LoRa sub-module 211 and/or the second LoRa sub-module 212 means switching the operation mode of the first LoRa sub-module 211 and/or the second LoRa sub-module 212 to the Tx mode or the Rx mode. In addition, even if the first LoRa sub-module 211 and the second LoRa sub-module 212 are simultaneously turned on, only one LoRa sub-module can transmit data at the same time.

It is understood that the distance between the wireless headset 200 and the wearable device 300 affects the communication signal strength of the communication between the wireless headset 200 and the wearable device 300, and the longer the distance between the wireless headset 200 and the wearable device 300 is, the greater the effect on the communication signal strength is. In addition, obstacles between the wireless headset 200 and the wearable device 300 may also affect the strength of the communication signal of the wireless headset 200 and the wearable device 300. Thus, when the wireless headset 200 is in communication with the wearable device 300, the processor 30 may detect the communication signal strength of the wireless headset 200 in communication with the wearable device 300 to determine whether communication between the wireless headset 200 and the wearable device 300 is normal.

Specifically, the processor 30 controls the micro control unit to obtain the communication signal strength of the communication between the first LoRa module 210 and the second LoRa module 310, and compare the communication signal strength with a preset value, so as to determine whether the communication signal strength is greater than the preset value. When the intensity of the communication signal is greater than the preset value, it is determined that the communication signal of the wireless headset 200 communicating with the wearable device 300 is stronger, the processor 30 may control the micro control unit to control the working modes of the first LoRa sub-module 211 and the second LoRa sub-module 212, such that one of the first LoRa sub-module and the second LoRa sub-module is in the Tx mode to transmit data to the wearable device 300, and the other one of the first LoRa sub-module and the second LoRa sub-module is in the sleep mode or the standby mode. When the communication signal strength is less than or equal to the preset value, it can be determined that the communication signal of the wireless headset 200 communicating with the wearable device 300 is weak, and the processor 30 can control the micro control unit to further control the working modes of the first LoRa sub-module 211 and the second LoRa sub-module 212, so that the first LoRa sub-module 211 and the second LoRa sub-module 212 are both in the Tx mode, and thus it is ensured that data can be normally transmitted when the communication signal strength of the first LoRa module 210 communicating with the second LoRa module 310 is weak.

In addition, in some examples, the wireless headset 200 is further provided with a rescue mode, and the mobile terminal 100 can control the wireless headset 200 to turn on the rescue mode, thereby controlling the operation modes of the first LoRa sub-module 211 and the second LoRa sub-module 212, wherein one is in the Tx mode and the other is in the sleep mode or the standby mode. As such, the first wireless headset 230 and the second wireless headset 240 can improve endurance.

Referring to fig. 9, in some embodiments, step S163 includes the steps of:

s1631, comparing the electric quantity of the first wireless earphone with the electric quantity of the second wireless earphone;

s1632, when the electric quantity of the first wireless earphone is less than or equal to the electric quantity of the second wireless earphone, starting the second LoRa sub-module to send data to the second LoRa module;

s1633, when the power of the first wireless headset is greater than the power of the second wireless headset, the first LoRa sub-module is turned on to send data to the second LoRa module.

Referring further to fig. 3, in some embodiments, the control module 16 further includes a comparing unit 165, and step S1631 can be implemented by the comparing unit 165. Steps S1632 and S1633 may be implemented by the first control unit 163.

Alternatively, the comparing unit 165 may be configured to compare the power of the first wireless headset 230 with the power of the second wireless headset 240.

The first control unit 163 may be configured to turn on the second LoRa sub-module 212 to send data to the second LoRa module 310 when the power of the first wireless headset 230 is less than or equal to the power of the second wireless headset 240. The first control unit 163 may be further configured to turn on the first LoRa sub-module 211 to transmit data to the second LoRa module 310 when the power of the first wireless headset 230 is greater than the power of the second wireless headset 240.

In some embodiments, the processor 30 may be configured to compare the power of the first wireless headset 230 to the power of the second wireless headset 240. The processor 30 may be configured to turn on the second LoRa sub-module 212 to send data to the second LoRa module 310 when the power of the first wireless headset 230 is less than or equal to the power of the second wireless headset 240. The processor 30 may also be configured to turn on the first LoRa sub-module 211 to send data to the second LoRa module 310 when the power of the first wireless headset 230 is greater than the power of the second wireless headset 240.

It can be understood that the communication signal when the wireless headset communicates with the wearable device 300 is strong, and communication with the second LoRa module 310 can be realized only by opening one LoRa sub-module. However, if one LoRa sub-module is selected for communication with the second LoRa module 310 for a long time, the duration of the first wireless headset 230 and the second wireless headset 240 may not be balanced. Therefore, when the communication signal when the wireless headset 200 communicates with the wearable device 300 is strong, the processor 30 further detects the power of the first wireless headset 230 and the second wireless headset 240, respectively, so as to select the wireless headset with high power to communicate with the wearable device 300. In this way, the endurance of the first wireless headset 230 and the second wireless headset 240 can be made more uniform.

Referring to fig. 10, in some embodiments, step S16 further includes the steps of:

s165, judging the type of data, wherein the type of the data comprises real-time communication data;

and S166, starting the first LoRa submodule and the second LoRa submodule to send data to the second LoRa submodule when the intensity of the communication signal is smaller than or equal to the preset value and the data is real-time communication data.

In some embodiments, step S165 may be implemented by the determination unit 162, and step S166 may be implemented by the first control unit 163.

Or, the determining unit 162 is further configured to determine the type of data, where the type of data includes real-time communication data and instant communication data.

The first control unit 163 is further configured to start the first LoRa sub-module 211 and the second LoRa sub-module 212 to send data to the second LoRa module 310 when the communication signal strength is less than or equal to the preset value and the data is real-time communication data.

In some embodiments, processor 30 is configured to determine a type of data, which includes real-time communication data and instant communication data. The processor 30 is further configured to start the first LoRa sub-module 211 and the second LoRa sub-module 212 to send data to the second LoRa module 310 when the communication signal strength is less than or equal to the preset value and the data is real-time communication data.

It should be noted that the data category includes instant communication data and real-time communication data. The real-time communication data may include real-time voice data, real-time video data, and the like. The instant communication data may include instant video data, instant voice data, and text data.

It is understood that the communication rate of the wireless headset 200 and the wearable device 300 is required to be high when the mobile terminal 100 communicates with the wearable device 300 through the wireless headset 200 in real time, for example, the minimum communication rate required when the mobile terminal 100 communicates with the wearable device 300 through the wireless headset 200 in real time is 30 kb/s. The communication signal strength of the communication between the wireless headset 200 and the wearable device 300 is positively correlated with the communication rate, and the weaker the communication signal strength is, the smaller the corresponding communication rate is. Therefore, when the communication signal intensity is less than or equal to the preset value and the data type is real-time communication data, the micro control unit can be controlled to open the first LoRa submodule 211 and the second LoRa submodule 212, so that the wireless headset 200 and the wearable device 300 can communicate normally.

In addition, in some examples, when the communication signal intensity is less than or equal to the preset value and the data is instant communication data, the processor 30 may further determine the instant communication data, and if the instant communication data is instant video data, control the micro control unit to start the first LoRa sub-module 211 and the second LoRa sub-module 212, thereby ensuring that the wireless headset 200 and the wearable device 300 can communicate normally. If the instant messaging data is instant voice data or text data, the micro control unit is controlled to only start the first LoRa submodule 211 or only start the second LoRa submodule 212.

Referring to fig. 11, in some embodiments, before step S12, the method further includes the steps of:

s11, sending a second pairing signal to the wireless headset to pair with the wireless headset.

In some embodiments, step S11 may be implemented by the sending module 12, or the sending module 12 may be further configured to send a second pairing signal to the wireless headset to pair with the wireless headset.

In some embodiments, the processor 30 may be configured to send a second pairing signal to the wireless headset 200 to pair with the wireless headset 200.

Specifically, in the process that the mobile terminal 100 controls the wireless headset 200, the processor 30 first controls the first communication module 20 to send the second pairing signal to the second communication module 220, pairs with the first communication module 20 after the second communication module 220 receives the second pairing signal, and after the pairing is successful, the mobile terminal 100 establishes communication with the wireless headset 200, so that the mobile terminal 100 can send the control signal to control the wireless headset 200, and the mobile terminal 100, the wireless headset 200, and the second communication module 220 can transmit data to each other.

The above examples only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present application. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. A control method is used for a mobile terminal to control a wireless earphone, the mobile terminal is communicated with a wearable device by controlling the wireless earphone, the wireless earphone comprises a first LoRa module, the wearable device comprises a second LoRa module, the first LoRa module is communicated with the second LoRa module, and the control method comprises the following steps:

and controlling the first LoRa module to send data to the second LoRa module.

2. The control method of claim 1, wherein the wireless headset comprises a first wireless headset and a second wireless headset, the first LoRa module comprises a first LoRa sub-module and a second LoRa sub-module, the first LoRa sub-module is disposed on the first wireless headset, the second LoRa sub-module is disposed on the second wireless headset, and the controlling the first LoRa module to send data to the second LoRa module comprises:

detecting the communication signal strength of the communication between the first LoRa module and the second LoRa module;

judging the intensity of the communication signal and the preset value;

when the communication signal intensity is larger than the preset value, starting the first LoRa submodule or the second LoRa submodule to send data to the second LoRa submodule;

and when the communication signal intensity is smaller than or equal to the preset value, starting the first LoRa submodule and the second LoRa submodule to send data to the second LoRa submodule.

3. The control method according to claim 2, wherein the step of controlling the first or second LoRa sub-module to send data to the second LoRa module when the communication signal strength is greater than a preset value comprises:

comparing the power of the first wireless headset with the power of the second wireless headset;

when the electric quantity of the first wireless earphone is less than or equal to the electric quantity of the second wireless earphone, starting the second LoRa sub-module to send data to the second LoRa module;

and when the electric quantity of the first wireless earphone is larger than that of the second wireless earphone, the first LoRa submodule is started to send data to the second LoRa module.

4. The control method according to claim 2, wherein the controlling the first LoRa module to send data to the second LoRa module further comprises:

judging the type of the data, wherein the type of the data comprises real-time communication data;

and when the communication signal intensity is smaller than or equal to the preset value and the data is real-time communication data, starting the first LoRa submodule and the second LoRa submodule to send the data to the second LoRa submodule.

5. The control method according to claim 1, further comprising, before the detecting the communication signal strength of the communication between the first LoRa module and the second LoRa module:

sending a second pairing signal to the wireless headset to pair with the wireless headset.

6. The utility model provides a controlling means for mobile terminal control wireless earphone, its characterized in that, mobile terminal is through control wireless earphone communicates with wearable equipment, wireless earphone includes first loRa module, wearable equipment includes second loRa module, first loRa module with second loRa module communication, controlling means includes:

7. A mobile terminal, characterized in that mobile terminal communicates with wearable device through wireless earphone, wireless earphone includes first loRa module, wearable device includes second loRa module, first loRa module with second loRa module communication, mobile terminal includes the treater, the treater is used for:

and controlling the first LoRa module to send data to the second LoRa module.

8. A mobile terminal comprising one or more processors, memory; and

one or more programs, wherein the one or more programs are stored in the memory and executed by the one or more processors, the programs comprising instructions for performing the control method of any of claims 1-5.

9. One or more non-transitory computer-readable storage media containing computer-executable instructions that, when executed by one or more processors, cause the processors to perform the control method of any of claims 1-5.

10. A wireless headset characterized in that it communicates with a mobile terminal and a wearable device according to any of claims 1-5, respectively.