CN114615729A - Data interaction method, earphone device and computer readable storage medium - Google Patents

Abstract

The application provides a data interaction method, earphone equipment and a computer readable storage medium, and relates to the technical field of Bluetooth earphones. The method comprises the following steps: the first earphone and the second earphone set a target timer through a first communication mode; at the appointed moment triggered by the target timer, the first earphone and the second earphone awaken a second communication mode in a low power consumption mode so as to transmit the data packet through the second communication mode; when the first earphone and the second earphone communicate in the second communication mode, the next communication time at the current time is the interaction time, and the appointed time is between the current time and the interaction time. According to the method and the device, after the earphone enters the low power consumption mode, the earphone can communicate between the two earphones through other communication modes when an event occurs, so that the earphone is awakened in advance at an appointed moment before an interaction moment, the earphone can timely respond to the interaction requirement of a user, and the response efficiency and the real-time performance of the earphone are improved while the power consumption is saved.

Description

Data interaction method, earphone device and computer readable storage medium

Technical Field

The present application relates to the field of bluetooth headset technology, and in particular, to a data interaction method, a headset device, and a computer-readable storage medium.

Background

More and more bluetooth headsets are available, and currently used bluetooth technologies, such as classic bluetooth, generally maintain a connection between the main and auxiliary ears for synchronously responding to a user's request. Such as the touch, button, ear, etc. of the user to the earphone, and the terminal connected to the earphone generally makes some additional UI control interfaces based on the above functions, such as adjusting the volume, playing a prompt tone synchronously, etc.

Because the connection between the main and auxiliary ears of the bluetooth headset needs less data to be transmitted at ordinary times and has less transmission times, in order to save power consumption, the prior art adopts a low power consumption mode that the bluetooth headset enters sniff (breathing), and the purpose of saving power consumption is achieved by reducing the number of time slots for transmitting data by the main device and correspondingly reducing the number of time slots for monitoring by the slave device. In order to further save power consumption, the sleep period of the low power consumption mode of the bluetooth headset is currently set to a longer period, such as 500ms, or longer 1s, etc. However, a long sleep cycle may cause that the bluetooth headset cannot synchronize data to the two headsets in real time when an event occurs, which may cause that the efficiency and real-time performance of the existing bluetooth headset for responding to a user are low, and the user experience is poor.

Disclosure of Invention

In view of the above, embodiments of the present invention provide a data interaction method, a headset device and a computer readable storage medium, so as to solve the problem in the prior art that the efficiency and the real-time performance of the bluetooth headset response are poor.

In order to solve the above problem, in a first aspect, the present application provides a data interaction method, where the method is applied to a headset device, where the headset device includes a first headset and a second headset, and the method includes:

the first earphone and the second earphone set a target timer through a first communication mode;

at the appointed moment triggered by the target timer, the first earphone and the second earphone awaken a second communication mode in a low power consumption mode so as to transmit a data packet through the second communication mode;

when the first earphone and the second earphone communicate in the second communication mode, the next communication time at the current time is an interaction time, and the appointed time is between the current time and the interaction time.

In the implementation process, when the second communication mode of the earphone device enters the sleep low-power-consumption mode, the interaction between the main earphone and the auxiliary earphone in the earphone device can be realized through the other first communication mode which is different from the second communication mode, has higher reliability and real-time performance and can transmit small data volume. After can be in the low-power consumption mode when sleeping at earphone equipment, when the incident takes place, can use first communication mode to inform each other between first earphone and the second earphone, in order to set for the target timer, the earphone is awaken in advance to carry out data interaction and transmission at the appointed moment before the original interaction moment in the sleep cycle of low-power consumption mode, still can respond to user's interactive demand in time when can making earphone equipment be in longer sleep cycle, when saving earphone equipment electric energy, still improved the response efficiency and the real-time of earphone effectively, use when promoting user's use earphone equipment is experienced.

Optionally, before the first headset and the second headset set the target timer through the first communication mode, the method further includes:

the first earphone acquires preset interaction duration of the second communication mode;

the first earphone determines a first duration between the interaction time and the current time;

when the interaction duration is longer than the first duration, the first earphone wakes up the second communication mode at the interaction moment so as to send the data packet to the second earphone through the second communication mode;

and the second earphone wakes up the second communication mode at the interaction moment so as to receive the data packet through the second communication mode.

In the implementation process, before the target timer is set, the first earphone can also determine an interaction time length required when the first earphone and the second earphone communicate in the second communication mode, compare a first time length between a current time and an interaction time when the second earphone communicates next in a sleep cycle of the second communication mode with the interaction time length, and judge whether the first earphone and the second earphone have enough time to interact before the interaction time length, so as to judge whether the target timer is set. When the interaction duration is longer than the first duration, the current time is closer to the interaction time, and the interaction of data transmission cannot be completed between the first earphone and the second earphone in the second communication mode before the interaction time, so that the target timer at the appointed time is not set to be awakened in advance in this case, but the second communication modes of the two earphones are directly awakened to perform data interaction and transmission when the interaction time is waited. And selecting proper time to wake up the second communication mode according to the time relationship between different current time and interaction time.

Optionally, the target timer comprises a first timer and a second timer; the first headset and the second headset set a target timer through a first communication mode, comprising:

when the interaction duration is shorter than the first duration, the first earphone determines the appointed time between the current time and the interaction time according to the current time and the interaction duration;

the first earphone sends a notification signal notifying the appointed moment to the second earphone through the first communication mode;

after the second earphone receives the notification signal through the first communication mode, the second earphone sets the first timer based on the appointed time determined by the notification signal;

the second earphone sends feedback information of successfully receiving the notification signal to the first earphone through the first communication mode;

after the first earphone receives the feedback information through the first communication mode, the first earphone sets the second timer based on the appointed time.

In the implementation process, when the interaction duration is less than the first duration, it means that there is enough time before the interaction time to enable the first headset and the second headset to interact in the second communication mode. Through the current time and the interaction duration, the appointed time after the current time and before the interaction time can be determined, so that the first earphone and the second earphone can inform and feed back the appointed time in the first communication mode. And corresponding first timers and second timers are set according to the receiving condition and the feedback condition of the respective notification signals, so that the second communication modes of the first earphone and the second earphone can be awakened at appointed time respectively according to the first timers and the second timers, the earphone is awakened in advance for interaction before the next interaction time when the sleep cycle of the low power consumption mode is long, the response speed and the real-time performance of the earphone equipment to user interaction and emergency are improved, and the use experience of a user is improved.

Optionally, the waking up, by the first headset and the second headset, a second communication mode in a low power consumption mode to transmit a data packet through the second communication mode includes:

the first earphone determines the data packet corresponding to the triggered event instruction;

the first earphone wakes up the second communication mode in a low power consumption mode at the appointed moment according to the triggered second timer;

and the first earphone sends the data packet to the second earphone through the awakened second communication mode.

In the implementation process, the first earphone is an earphone for triggering an event, a corresponding data packet is obtained according to a triggered event instruction, and the first earphone is triggered at an appointed moment according to the second timer so as to wake up the second communication mode in the low power consumption mode in the first earphone to send the data packet. The method and the device can wake up and send data on time according to the second timer before the interaction time, and efficiency and timeliness of the wake-up and data sending are improved.

Optionally, the waking up, by the first headset and the second headset, a second communication mode in a low power consumption mode to transmit a data packet through the second communication mode, further includes:

the second earphone wakes up the second communication mode in a low power consumption mode at the appointed moment according to the triggered first timer;

and the second earphone receives the data packet sent by the first earphone through the awakened second communication mode.

In the implementation process, the second earphone is the earphone which is notified of the trigger event, and the second earphone is triggered at the appointed moment according to the first timer so as to wake up a second communication mode in the second earphone, wherein the second communication mode is in a low power consumption mode, and the data packet is received. The method and the device can wake up and receive data on time according to the first timer before the interaction time, and efficiency and timeliness of waking up and receiving data are improved.

Optionally, the method further comprises:

after the second earphone receives the data packet, the second earphone sends success information of successfully receiving the data packet to the first earphone through the second communication mode;

and after the first earphone receives the success information through the second communication mode, the first earphone and the second earphone process the communication parameters when the second communication mode is in the low power consumption mode according to the data volume information during transmission.

In the implementation process, when the first earphone and the second earphone successfully transmit the data packet, the second earphone sends a success message to the first earphone according to the second communication mode after successfully receiving the data packet, so as to inform the first earphone of successful reception. And after the first earphone successfully receives the success information, the data packet is successfully transmitted. Due to the difference of the data volume during transmission, in order to improve the efficiency of data transmission, the two earphones can correspondingly process the communication parameters of the second communication mode in the low power consumption mode according to the data volume information so as to keep the original communication parameters or update the original communication parameters, and the earphone is suitable for transmission of various different data.

Optionally, the method further comprises:

when the first earphone does not receive the success information, the first earphone determines a second time length between the interaction time and the current transmission failure time;

and when the interaction duration is less than the second duration, the first earphone and the second earphone retransmit the data packet in the current transmission failure moment through the awakened second communication mode.

In the above implementation process, if the first earphone does not receive the success information, the data packet transmission may fail. In order to improve the success rate of data packet transmission, the data packet may be retransmitted, and when the second duration between the current transmission failure time and the interaction time is longer than the interaction duration, the time before the interaction time enables the first earphone, the second earphone and the second communication mode to interact again, so that the first earphone and the second earphone can directly retransmit the data packet through the woken-up second communication mode. After the transmission fails, the data can still be retransmitted at the interaction moment, so that the success rate of data transmission and the response speed and real-time performance of the earphone under various conditions are further improved.

Optionally, the method further comprises:

and when the interaction duration is longer than the second duration, the first earphone and the second earphone retransmit the data packet through the awakened second communication mode at the interaction moment.

In the implementation process, when the interaction duration is longer than the second duration, there is not enough time before the interaction time to enable the first earphone and the second earphone to perform data transmission again in the second communication mode. If the first earphone does not receive the success information, the data packet interaction may fail, and the communication parameters in the two earphones are not synchronized. In order to enable the two earphones to interact synchronously, the data is retransmitted through the awakened second communication mode at the original interaction time in the sleep cycle directly according to the original communication parameters of the second communication mode, so that the two earphones can still interact synchronously according to the original interaction time under the condition that the data packet interaction fails, and the reliability of data transmission is improved.

In a second aspect, the present application also provides an earphone device, including: a first earphone and a second earphone;

the first earphone is used for setting a target timer with the second earphone through a first communication mode;

the second earphone is used for setting the target timer with the first earphone through a first communication mode;

at the appointed moment triggered by the target timer, the first earphone is also used for waking up a second communication mode in a low power consumption mode so as to transmit a data packet with the second earphone through the second communication mode;

at the appointed moment triggered by the target timer, the second headset is further configured to wake up the second communication mode in a low power consumption mode, so as to transmit the data packet with the first headset through the second communication mode;

when the first earphone and the second earphone communicate in the second communication mode, the next communication time at the current time is an interaction time, and the appointed time is between the current time and the interaction time.

In a third aspect, the present application further provides a computer-readable storage medium, where computer program instructions are stored, and when the computer program instructions are read and executed by a processor, the steps in any implementation manner of the data interaction method are executed.

To sum up, the application provides a data interaction method, an earphone device and a computer readable storage medium, which can communicate between two earphones through other communication modes when an event occurs after the earphones enter a low power consumption mode, so as to wake up the earphones in advance at an appointed time before an interaction time and adopt the original communication mode for interaction, so that the earphone device can still timely respond to the interaction requirements of a user when in a longer sleep cycle, the electric energy of the earphone device is saved, meanwhile, the response efficiency and the real-time performance of the earphones are effectively improved, and the use experience of the user when using the earphone device is improved.

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 of the present application 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 that those skilled in the art can also obtain other related drawings based on the drawings without inventive efforts.

Fig. 1 is a schematic flowchart of a first data interaction method according to an embodiment of the present application;

fig. 2 is a schematic flowchart of a second data interaction method according to an embodiment of the present application;

fig. 3 is a detailed flowchart of a step S200 according to an embodiment of the present disclosure;

fig. 4 is a detailed flowchart of a step S300 according to an embodiment of the present disclosure;

fig. 5 is a detailed flowchart of another step S300 provided in the embodiment of the present application;

fig. 6 is a schematic flowchart of a third data interaction method according to an embodiment of the present application;

fig. 7 is a schematic structural diagram of an earphone device according to an embodiment of the present application.

Icon: 510-a first earpiece; 520-second earpiece.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application. It is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of them. All other embodiments obtained by persons of ordinary skill in the art based on the embodiments of the present application without creative efforts shall fall within the protection scope of the embodiments of the present application.

Currently, in various bluetooth headsets, such as TWS (True Wireless Stereo) bluetooth headsets, in order to save power consumption when the bluetooth headset is used, a mode of making the bluetooth headset enter a low power consumption mode is generally adopted. Since bluetooth is a TDMA (Time Division Multiple Access) system, it is possible to divide Time into periodic frames (frames), each of which is subdivided into several Time slots for transmitting signals to another earphone in the opposite ear. Thus, under the condition of satisfying timing and synchronization, two earphones in the ears can be respectively used as a master and a slave to carry out the consensus division of the future time slots. In the low power consumption mode, the purpose of saving electric energy is achieved by reducing the number of time slots for transmitting data by the master device and correspondingly reducing the number of time slots for monitoring by the slave device.

In order to further reduce the power consumption of the bluetooth headset, in the prior art, a mode of extending a sleep cycle in a low power consumption mode is adopted, and the sleep cycle is set to be longer, for example, 500ms, 1s, and the like. However, in a sleep cycle, a user may have some requirements for real-time synchronization to the ears, such as switching on and off a noise reduction function, adjusting a volume, pausing/continuing playing, and the like, and in a longer sleep cycle, the bluetooth headset may not wake up the low power consumption mode for data interaction until a predetermined interval (timeslot) is reached, for example, when the sleep cycle is 500ms, and when the sleep cycle is 100ms after the last interaction is completed, if the user has an interaction requirement, data that needs to be interacted is generated, and a timeslot for the next interaction of 400ms is needed for interaction, the real-time performance of the bluetooth headset is reduced, and data cannot be synchronized to two headsets in real time. Therefore, the efficiency and the real-time performance of the existing Bluetooth headset for responding to the user are low, the functions of energy conservation and response speed cannot be taken into consideration, and the user experience is poor.

In order to solve the above problem, an embodiment of the present application provides a data interaction method, which is applied to a headset device, where the headset device may be various types of bluetooth headsets, such as a TWS bluetooth headset. The earphone device may be connected to various types of terminal devices, such as a server, a Personal Computer (PC), a tablet Computer, a smart phone, a Personal Digital Assistant (PDA), and other terminal devices having a logic calculation function, so as to obtain interaction requirements and related data generated by a user in the terminal device.

Referring to fig. 1, fig. 1 is a schematic flowchart illustrating a first data interaction method according to an embodiment of the present disclosure, where the method includes the following steps S200 to S300.

Step S200, the first earphone and the second earphone set a target timer through a first communication mode.

The earphone device comprises a first earphone and a second earphone which are respectively used as a main earphone and an auxiliary earphone in the earphone device. The first earphone and the second earphone transmit and interact data through a second communication mode, the second communication mode is a plurality of communication modes in a low power consumption mode, for example, a communication mode in a breathing mode or a sleep mode in a Bluetooth system, for example, a low power consumption mode of classic Bluetooth, BLE (Bluetooth low energy) and the like, a fixed time slot can be set for data interaction based on a TDMA system of the Bluetooth, the two earphones are kept in a sleep state in a non-interactive time slot, the low power consumption mode exits in the interactive time slot, and the data interaction is performed in the second communication mode, so that the energy-saving effect of low power consumption is realized. In the embodiment of the application, another first communication mode different from the second communication mode is adopted to set the target timer so as to appoint and divide the time when the first earphone and the second earphone wake up the second communication mode in advance. The first communication mode may be an out-of-band link outside the second communication mode, such as multiple low-frequency phy forwarding modes, or multiple private links, such as a listening link, or multiple communication modes with high reliability and real-time performance, where the amount of data transmitted may be small, such as wifi.

It should be noted that, the two headsets have target timers set on the basis of the communication in the first communication mode, when the first headset and the second headset communicate in the second communication mode, the next communication time of the current time is an interaction time, the interaction times of the two headsets belong to the same bluetooth clock domain, and the interaction timings of the two headsets are synchronous, and the interaction periods and the like are also the same, for example, the same time is set in a periodic timing with an interval of 500ms for interaction. The current time is a time when time is generated, for example, after a first earphone in the earphone device triggers an event, the first earphone is immediately waken up to perform corresponding processing, and in order to synchronize the triggered event to a second earphone, for example, operations such as synchronously playing a prompt tone and the like, an appointed time can be set between the current time and an interaction time, so that the time of early wakening up is appointed on the basis of a target timer.

Step S300, at the appointed time triggered by the target timer, the first earphone and the second earphone wake up a second communication mode in a low power consumption mode, so as to transmit a data packet through the second communication mode.

And awakening the second communication mode in the low power consumption mode in advance to transmit the data packet at the appointed time triggered by the target timer. Because the second communication mode of the earphone device in the low power consumption mode can be awakened in advance, a longer interactive time slot can be set in the low power consumption mode of the second communication mode, and the response efficiency and the real-time performance of the earphone are improved while the electric energy of the earphone device is saved.

Optionally, the data packet may be corresponding data generated according to a time of the earphone interaction trigger, for example, a plurality of different types of data such as instructions and alert tones generated according to operations of a user touching, pressing a button, entering an ear, adjusting volume, pausing/turning on, and the like, of the earphone.

For example, since the current earphones are generally used in pairs, when the master earphone or the slave earphone has a time to notify the other earphone, and when the two earphones communicate in the second communication mode, the other earphone can be notified in real time by using a low-frequency communication method, but a large amount of data cannot be transmitted. Therefore, depending on the content of the transmission, when a large amount of data is transmitted, BT (BitTorrent, bit stream, a content distribution protocol) link or the like can be adopted as the second communication mode of the low power consumption mode of low power consumption.

In the embodiment shown in fig. 1, the energy-saving effect, the response efficiency and the real-time performance of the headset device are effectively improved, and the use experience of a user when using the headset device is improved.

Optionally, referring to fig. 2, fig. 2 is a flowchart illustrating a second data interaction method according to an embodiment of the present application, and before step S200, the method may further include steps S110 to S140.

Step S110, the first headset obtains a preset interaction duration of the second communication mode.

When the first earphone and the second earphone interact in the second communication mode, due to the failure condition during the interaction, in order to improve the success rate during the interaction, a margin (time difference) from the beginning of the interaction to the end of the interaction can be preset in the two earphones when data transmission is performed in the second communication mode, and the margin is used as the interaction duration required during the data transmission in the second communication mode, so that the first earphone and the second earphone can perform multiple interactions within the interaction duration. The interaction duration may include a time for the two headsets to perform data transmission for multiple times, for example, when the second communication mode is a bluetooth link, the interaction duration may be a time for performing 3 times of data packet transmission in the bluetooth link, and the like. When an interaction event occurs, the first earphone can acquire the preset interaction duration so as to judge whether to wake up the second communication mode of the earphone in advance.

Optionally, the interaction duration may also be determined by various factors such as the communication type of the second communication mode, the distance between the two headsets, and the like.

Step S120, the first earphone determines a first duration between the interaction time and the current time.

The first earphone can acquire the next interaction time for data interaction in the second communication mode of the earphone device, and determines the time difference between the current time and the interaction time as a first time length, wherein the first time length is the interaction time-the current time.

Step S130, when the interaction duration is longer than the first duration, the first headset wakes up the second communication mode at the interaction time, so as to send the data packet to the second headset through the second communication mode.

Step S140, the second headset wakes up the second communication mode at the interaction time to receive the data packet through the second communication mode.

Before the target timer is set, the first earphone compares the first time length with the interaction time length, and judges whether the first earphone and the second earphone can finish the interaction of data transmission in the second communication mode before the interaction time so as to judge whether the target timer is set. When the interaction duration is longer than the first duration, it indicates that the current time is closer to the interaction time, and there is not enough time before the interaction time to enable the first earphone and the second earphone to complete the interaction of data transmission in the second communication mode. When the first earphone and the second earphone are interacted in a short time, the success rate of data transmission can be adversely affected, in order to improve the success rate of the two earphones for data transmission in the second communication mode, when the interaction duration is longer than the first duration, a target timer is not set to wake up the second communication mode in the low power consumption mode in advance, the original low power consumption mode of the second communication mode is directly used, the first earphone and the second earphone are awakened again at the interaction time, the two earphones exit from the low power consumption mode at the interaction time, and data interaction and transmission are directly carried out in the second communication mode.

It is worth mentioning that when the duration before the interaction time cannot enable the first earphone and the second earphone to complete the interaction of data transmission in the second communication mode, the earphone device may interact at the interaction time in the original sleep cycle in the second communication mode, and because the original sleep cycle is preset in the second communication mode of the earphone device, a timer is not needed to wake up the first earphone or the second earphone, at the interaction time, the two earphones can synchronously and automatically exit from the low power consumption mode for interaction, and the steps Sc and Sd can be synchronously implemented.

In the embodiment shown in fig. 2, an appropriate time can be selected to wake up the second communication mode according to the time relationship between different current times and interaction times.

Optionally, referring to fig. 3, fig. 3 is a detailed flowchart of step S200 according to an embodiment of the present application, and step S200 may further include steps S210 to S250.

Step S210, when the interaction duration is less than the first duration, the first earphone determines the appointed time between the current time and the interaction time according to the current time and the interaction duration.

When the first earphone detects that the interaction duration is shorter than the first duration, it indicates that there is enough time before the interaction time to enable the first earphone and the second earphone to complete the interaction of data transmission in the second communication mode, so that a target timer can be set to enable the first earphone and the second earphone to wake up the second communication mode in the low power consumption mode in advance to perform data interaction and transmission. The first earphone determines a corresponding appointed time according to the current time and the interaction duration, and the appointed time is the current time plus the interaction duration, so that the two earphones can transmit data in enough time.

Step S220, the first earphone sends a notification signal notifying the appointed time to the second earphone through the first communication mode.

The first earphone generates a notification signal for notification according to the determined appointed time, and sends the notification signal to the second earphone in a first communication mode so as to synchronize the divided time slots to the second earphone, so that the two earphones can be synchronized in time.

Optionally, the notification signal can be transmitted in the form of a small amount of data, for example, 1 bit of data, so as to reduce the data transmission amount in the first communication mode, and improve the interaction efficiency and the success rate in the first communication mode.

Step S230, after the second headset receives the notification signal in the first communication mode, the second headset sets the first timer based on the appointed time determined by the notification signal.

The second earphone can directly determine the appointed time synchronized with the first earphone on the basis of successfully receiving the notification signal so as to set the corresponding first timer according to the appointed time to wake up in advance.

Alternatively, the rule of time slot division may be the wake-up time required for the two headsets to complete the notification in the first communication mode, including the time required for the second headset to wake up. Since the first communication mode has high real-time performance and reliability, the wake-up time is short, for example, 10ms, and the second headset can use the time 10ms after the current successful receiving time as the appointed time when the second headset successfully receives the notification signal. The rules for dividing the time slots in different first communication modes are different, and can be selected and adjusted accordingly according to the communication mode and the actual situation.

Step S240, the second headset sends feedback information of successfully receiving the notification signal to the first headset through the first communication mode.

After the second earphone successfully receives the notification signal, the second earphone can also send feedback information of successfully receiving the appointed time to the first earphone through the first communication mode, so that the first earphone is notified of the content of data interaction performed at the synchronous appointed time of the second earphone.

Step S250, after the first earphone receives the feedback information through the first communication mode, the first earphone sets the second timer based on the appointed time.

After the first earphone successfully receives the feedback information, the corresponding second timer can be set according to the appointed time, the time of the appointed time is successfully synchronized with the second earphone, and the corresponding timers are respectively set for awakening.

Optionally, since there is a case of interaction failure when the first headset and the second headset communicate in the first communication mode, for example, the first headset does not receive feedback information in the second headset through the first communication mode, the first headset may continuously retransmit the notification signal to the second headset through the first communication mode when the interaction fails, and continuously update the time of the appointed time according to the time when the notification signal is retransmitted. And a target time can be set, the target time is set between the interaction time and the current time, and the time length between the target time and the interaction time is the interaction time length.

If the first earphone receives the feedback information of the second earphone according to the retransmission action of the notification signal before the target time or the target time, the first earphone and the second earphone can complete the interaction of data transmission before the interaction time, so that the first earphone and the second earphone can determine the current updated appointed time according to the retransmission time corresponding to the feedback information, and set the second timer and the first timer respectively, thereby waking up the second communication mode in advance at the current updated appointed time.

If the first earphone still does not receive the feedback information of the second earphone after the target time, the first earphone and the second earphone may not complete the interaction of data transmission in the second communication mode before the interaction time, and the first earphone and the second earphone may directly wake up the second communication mode for data transmission at the interaction time.

In the embodiment shown in fig. 3, the two earphones can set the corresponding first timer and second timer according to the respective receiving condition and feedback condition, so that the second communication mode of the first earphone and the second earphone is awakened at the appointed time, the earphone is awakened in advance for interaction before the next interaction time when the sleep cycle of the low power consumption mode is long, the response speed and the real-time performance of the earphone device to user interaction and emergency are improved, the earphone can quickly respond to the use requirement of the user, and the use experience of the user is improved.

Optionally, referring to fig. 4, fig. 4 is a detailed flowchart of step S300 provided in the embodiment of the present application, and step S300 may further include steps S310 to S330.

Step S310, the first headset determines the data packet corresponding to the triggered event instruction.

The first earphone may be a primary earphone or a secondary earphone triggered by a user to generate an event in the earphone device, the triggered event instruction may include an instruction generated by operations of touching, pressing a key, entering an ear, adjusting volume, pausing/starting and the like of the earphone device by the user, and the data packet is data of a plurality of different types corresponding to the event instruction.

Step S320, the first headset wakes up the second communication mode in the low power consumption mode at the appointed time according to the triggered second timer.

Step S330, the first earphone sends the data packet to the second earphone through the awakened second communication mode.

And triggering a second timer arranged in the first earphone at an appointed moment to wake up a second communication mode in the low power consumption mode in the first earphone, so that the first earphone exits the low power consumption mode, and sending the determined data packet to the second earphone in the second communication mode.

In the embodiment shown in fig. 4, the wakeup and the data transmission can be performed on time according to the second timer before the interaction time, so that the efficiency and the timeliness of the wakeup and the data transmission are improved.

Optionally, referring to fig. 5, fig. 5 is a detailed flowchart of another step S300 according to an embodiment of the present application, and the step S300 may further include steps S340 to S350.

Step S340, the second earphone wakes up the second communication mode in a low power consumption mode at the appointed moment according to the triggered first timer;

step S350, the second headset receives the data packet sent by the first headset through the awakened second communication mode.

The first timer set in the second earphone is triggered at the appointed time to wake up the second communication mode in the low power consumption mode in the second earphone, so that the second earphone exits the low power consumption mode, and the data packet sent in the first earphone is received in the second communication mode.

In the embodiment shown in fig. 5, the wakeup and the data reception can be performed on time according to the first timer before the interaction time, so that the efficiency and the timeliness of the wakeup and the data reception are improved.

Optionally, referring to fig. 6, fig. 6 is a schematic flowchart of a third data interaction method provided in the embodiment of the present application, where the method may further include steps S410 to S420.

Step S410, after the second earphone receives the data packet, the second earphone sends success information of successfully receiving the data packet to the first earphone through the second communication mode.

In order to verify whether the data packet is successfully transmitted between the first earphone and the second earphone, the second earphone sends success information to the first earphone through the awakened second communication mode after successfully receiving the data packet within the interaction duration after the appointed time, and the first earphone is informed that the data packet is successfully received.

Step S420, after the first earphone receives the success information through the second communication mode, the first earphone and the second earphone process the communication parameters when the second communication mode is in the low power consumption mode according to the data amount information during transmission.

And after the first earphone successfully receives the success information, the data packet is successfully transmitted between the first earphone and the second earphone. Due to the difference in the size of the data amount during transmission, the communication parameters suitable for different data amounts during transmission in the second communication mode are different. Therefore, in order to improve the efficiency of data transmission, the first earphone and the second earphone can correspondingly process the communication parameters of the second communication mode low power consumption mode according to the data amount information. The communication parameters may include various parameters such as anchor point time of the low power mode, sleep period of the low power mode, and the like.

Optionally, the processing manner may include two types: 1. original communication parameters are kept; 2. and updating the original communication parameters. For example, when the transmitted data volume information is small, the original communication parameters may be maintained for transmission; when the transmitted data volume information is large, anchor points, sleep cycles and the like in the communication parameters can be updated according to the time information in the appointed time, and the updating mode can comprise various adjustments such as advancing or delaying the anchor points at the subsequent interactive time, so that a large amount of data can be transmitted more timely and efficiently. When the data volume is large, the communication parameters can be updated to the parameters of the working mode, so that the low power consumption mode is not entered immediately, and the normal working mode is kept for a period of time for data transmission. According to the data transmission method and device, appropriate communication parameters can be selected to transmit various different data according to the size of the data volume, the efficiency of data transmission is further improved, and the use experience of a user is improved.

Optionally, the awakened second communication mode can also exit the low power consumption mode and enter an active mode (working mode) according to the actual use condition of the headset device.

Optionally, because there is a case of data transmission failure during the interaction, in the interaction duration after the appointed time, if the first earphone does not receive the success information that the second earphone confirms that the data packet is successfully received, the first earphone may continuously resend the data packet until the interaction duration is ended.

It is worth to be noted that, after the interaction duration is over, when the first earphone does not receive the success information, the first earphone determines a second duration between the interaction time and the current transmission failure time; and when the interaction duration is shorter than the second duration, the first earphone and the second earphone retransmit the data packet through the awakened second communication mode at the current transmission failure moment. And when the interaction duration is longer than the second duration, the first earphone and the second earphone retransmit the data packet through the awakened second communication mode at the interaction moment.

When the interaction duration after the appointed time is over and the first earphone still does not receive the success information after being overtime, the transmission of the data packet may fail. In order to improve the success rate of data packet transmission, the first earphone may continue to calculate the second duration, and continue to determine whether the first earphone and the second earphone can complete the data transmission interaction again in the second communication mode before the interaction time according to the second duration and the interaction duration. When the second duration is shorter than the interaction duration, the time is enough, so that the first earphone and the second earphone immediately retransmit the data packet through the awakened second communication mode, and the success rate of data transmission and the response speed and the real-time performance of the earphones under various conditions are further improved. And when the interaction duration is longer than the second duration, the time is not enough, and the condition that the communication parameters in the two earphones are not synchronous when the data packet interaction fails is considered. In order to enable the two earphones to interact synchronously, the modification of the communication parameters of the second communication mode in the first earphone or the first earphone is cancelled, the original communication parameters of the second communication mode are used, the data are retransmitted through the awakened second communication mode at the original interaction time in the sleep cycle, and therefore the two earphones can still interact synchronously according to the original interaction time under the condition that the data packet interaction fails, and the reliability of data transmission is improved.

In the embodiment shown in fig. 6, whether the low power consumption mode is updated or not can be determined according to the receiving condition of the data packet, so as to select the corresponding interaction mode for interaction.

Referring to fig. 7, fig. 7 is a schematic structural diagram of an earphone device according to an embodiment of the present disclosure, where the earphone device includes a first earphone 510 and a second earphone 520.

The first headset 510, configured to set a target timer with the second headset 520 through a first communication mode;

the second headset 520, configured to set the target timer with the first headset 510 through a first communication mode;

at the appointed time triggered by the target timer, the first headset 510 is further configured to wake up a second communication mode in a low power consumption mode, so as to transmit a data packet with the second headset 520 through the second communication mode;

at the appointed time triggered by the target timer, the second headset 520 is further configured to wake up the second communication mode in a low power consumption mode, so as to transmit the data packet with the first headset 510 through the second communication mode;

when the first earphone 510 and the second earphone 520 communicate in the second communication mode, a next communication time at a current time is an interaction time, and the appointed time is between the current time and the interaction time.

As the principle of the headset device in the embodiment of the present application to solve the problem is similar to that in the foregoing embodiment of the data interaction method, the implementation of the headset device in the embodiment of the present application may refer to the description in the foregoing embodiment of the data interaction method, and repeated details are not repeated.

The embodiment of the present application further provides a computer-readable storage medium, where computer program instructions are stored, and when the computer program instructions are read and executed by a processor, the computer program instructions execute steps in any implementation manner in the data interaction method provided in the embodiment of the present application.

To sum up, the embodiment of the application provides a data interaction method, an earphone device and a computer readable storage medium, which can perform communication between two earphones through other communication modes when an event occurs after the earphones enter a low power consumption mode, so as to wake up the earphones in advance at an appointed time before an interaction time and perform interaction in an original communication mode, so that the earphone device can still respond to the interaction requirements of a user in time when in a longer sleep cycle, the electric energy of the earphone device is saved, the response efficiency and the real-time performance of the earphones are effectively improved, and the use experience of the user when the user uses the earphone device is improved.

In the several embodiments provided in the present application, it should be understood that the disclosed apparatus may be implemented in other manners. The above-described apparatus embodiments are merely illustrative, for example, the block diagrams in the figures illustrate the architecture, functionality, and operation of possible implementations of apparatus according to various embodiments of the present application. In this regard, each block in the block diagrams may represent a module, segment, or portion of code, which comprises one or more executable instructions for implementing the specified logical function(s). It should also be noted that, in some alternative implementations, the functions noted in the block may occur out of the order noted in the figures. For example, two blocks shown in succession may, in fact, be executed substantially concurrently, or the blocks may sometimes be executed in the reverse order, depending upon the functionality involved. It will also be noted that each block of the block diagrams, and combinations of blocks in the block diagrams, can be implemented by special purpose hardware-based systems which perform the specified functions or acts, or combinations of special purpose hardware and computer instructions.

In addition, functional modules in the embodiments of the present application may be integrated together to form an independent part, or each module may exist separately, or two or more modules may be integrated to form an independent part.

The functions, if implemented in the form of software functional modules and sold or used as a stand-alone product, may be stored in a computer readable storage medium. Therefore, the present embodiment further provides a readable storage medium, in which computer program instructions are stored, and when the computer program instructions are read and executed by a processor, the computer program instructions perform the steps of any of the block data storage methods. Based on such understanding, the technical solution of the present application or portions thereof that substantially contribute to the prior art may be embodied in the form of a software product stored in a storage medium and including instructions for causing a computer device (which may be a personal computer, a server, or a network device) to execute all or part of the steps of the method according to the embodiments of the present application. And the aforementioned storage medium includes: various media capable of storing program codes, such as a usb disk, a removable hard disk, a Read-Only Memory (ROM), a RanDom Access Memory (RAM), a magnetic disk, or an optical disk.

The above description is only an example of the present application and is not intended to limit the scope of the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in 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.

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 person skilled in the art can easily think of the changes or substitutions within the technical scope of the present application, and shall be covered by the scope of the present application.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

Claims (10)

1. A data interaction method is applied to a headset device, wherein the headset device comprises a first headset and a second headset, and the method comprises the following steps:

the first earphone and the second earphone set a target timer through a first communication mode;

at the appointed moment triggered by the target timer, the first earphone and the second earphone awaken a second communication mode in a low power consumption mode so as to transmit a data packet through the second communication mode;

when the first earphone and the second earphone communicate in the second communication mode, the next communication time at the current time is an interaction time, and the appointed time is between the current time and the interaction time.

2. The method of claim 1, wherein before the first headset and the second headset set the target timer via the first communication mode, the method further comprises:

the first earphone acquires preset interaction duration of the second communication mode;

the first earphone determines a first duration between the interaction time and the current time;

when the interaction duration is longer than the first duration, the first earphone wakes up the second communication mode at the interaction moment so as to send the data packet to the second earphone through the second communication mode;

and the second earphone wakes up the second communication mode at the interaction moment so as to receive the data packet through the second communication mode.

3. The method of claim 2, wherein the target timer comprises a first timer and a second timer; the first headset and the second headset set a target timer through a first communication mode, comprising:

when the interaction duration is less than the first duration, the first earphone determines the appointed time between the current time and the interaction time according to the current time and the interaction duration;

the first earphone sends a notification signal notifying the appointed moment to the second earphone through the first communication mode;

after the second earphone receives the notification signal through the first communication mode, the second earphone sets the first timer based on the appointed time determined by the notification signal;

the second earphone sends feedback information of successfully receiving the notification signal to the first earphone through the first communication mode;

after the first earphone receives the feedback information through the first communication mode, the first earphone sets the second timer based on the appointed time.

4. The method of claim 3, wherein the first headset and the second headset wake up a second communication mode in a low power consumption mode to transmit data packets through the second communication mode, comprising:

the first earphone determines the data packet corresponding to the triggered event instruction;

the first earphone wakes up the second communication mode in a low power consumption mode at the appointed moment according to the triggered second timer;

and the first earphone sends the data packet to the second earphone through the awakened second communication mode.

5. The method of claim 3, wherein the first and second headsets wake up a second communication mode in a low power consumption mode to transmit data packets via the second communication mode, further comprising:

the second earphone wakes up the second communication mode in a low power consumption mode at the appointed moment according to the triggered first timer;

and the second earphone receives the data packet sent by the first earphone through the awakened second communication mode.

6. The method of claim 5, further comprising:

after the second earphone receives the data packet, the second earphone sends success information of successfully receiving the data packet to the first earphone through the second communication mode;

and after the first earphone receives the success information through the second communication mode, the first earphone and the second earphone process the communication parameters when the second communication mode is in the low power consumption mode according to the data volume information during transmission.

7. The method of claim 6, further comprising:

when the first earphone does not receive the success information, the first earphone determines a second time length between the interaction time and the current transmission failure time;

and when the interaction duration is less than the second duration, the first earphone and the second earphone retransmit the data packet in the current transmission failure moment through the awakened second communication mode.

8. The method of claim 7, further comprising:

and when the interaction duration is longer than the second duration, the first earphone and the second earphone retransmit the data packet in the interaction time through the awakened second communication mode.

9. An earphone device, characterized in that the earphone device comprises: a first earphone and a second earphone;

the first earphone is used for setting a target timer with the second earphone through a first communication mode;

the second earphone is used for setting the target timer with the first earphone through a first communication mode;

at the appointed moment triggered by the target timer, the first earphone is also used for waking up a second communication mode in a low power consumption mode so as to transmit a data packet with the second earphone through the second communication mode;

at the appointed moment triggered by the target timer, the second headset is further configured to wake up the second communication mode in a low power consumption mode, so as to transmit the data packet with the first headset through the second communication mode;

when the first earphone and the second earphone communicate in the second communication mode, the next communication time at the current time is an interaction time, and the appointed time is between the current time and the interaction time.

10. A computer-readable storage medium having computer program instructions stored thereon for execution by a processor to perform the steps of the method of any of claims 1-8.

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