CN113709617A - Wireless earphone control method and device, wireless earphone and storage medium - Google Patents

Abstract

The application discloses a control method and device of a wireless earphone, the wireless earphone and a storage medium. The method is applied to the wireless earphone, and the wireless earphone comprises a control module, an anti-false touch module and a touch module; the false touch prevention module is electrically connected with the control module, and the touch module is electrically connected with the control module. The method comprises the following steps: receiving touch operation corresponding to the touch module; acquiring false touch prevention data corresponding to the false touch prevention module; if the false touch prevention data meets the false touch prevention condition, determining a control instruction corresponding to the touch operation, wherein the false touch prevention condition is a condition which is met when the touch operation is judged to be the non-false touch operation; and controlling the wireless headset based on the control instruction. This application judges through whether the mistake that prevents that module receipt is touched to mistake and whether satisfies the mistake and touch the condition, and then confirms that touch operation is the maloperation, has effectively reduced the probability that the phenomenon appears triggering by mistake in the daily use of wireless earphone to the user.

Description

Wireless earphone control method and device, wireless earphone and storage medium

Technical Field

The present application relates to the field of wireless headset technologies, and in particular, to a method and an apparatus for controlling a wireless headset, and a storage medium.

Background

The TWS earphone, namely a True Wireless Stereo (TWS) earphone, gets rid of the restriction of the traditional earphone on wires, and further improves the comfort of daily listening to songs, talking and wearing of a user by forming a Stereo system by two independent earphones in Bluetooth communication and adding professional acoustic pickup technology, intelligent noise reduction technology, Artificial Intelligence (AI) algorithm noise reduction technology and the like.

In order to realize the man-machine interaction between the TWS headset and the user, a touch module is often arranged on the TWS headset to sense the touch, the knocking and other operations of the user, so as to realize the operation of the user on the TWS headset in different use scenes. For example, a user in a song listening mode may pause/continue playing a song with a single click on the headset, a double click may switch to the next song, a triple click may wake up a voice assistant, and so on.

Disclosure of Invention

The embodiment of the application provides a control method and device of a wireless earphone, the wireless earphone and a storage medium.

In a first aspect, some embodiments of the present application provide a wireless headset, which includes a control module, a false touch prevention module, and a touch module; the false touch prevention module is electrically connected with the control module, and the touch module is electrically connected with the control module; the touch module is used for receiving touch operation; the anti-false touch module is used for acquiring anti-false touch data, the anti-false touch data is used for judging whether the wireless earphone meets an anti-false touch condition, and the anti-false touch condition is a condition which is met when the touch operation is judged to be non-false touch operation; the control module is used for responding to touch operation under the condition that the false touch prevention data meet the false touch prevention condition.

In a second aspect, some embodiments of the present application further provide a control method for a wireless headset, where the wireless headset includes a control module, a false touch prevention module, and a touch module; prevent mistake and touch module and control module electric connection, this method includes: receiving touch operation corresponding to the touch module; acquiring false touch prevention data corresponding to the false touch prevention module; if the false touch prevention data meets the false touch prevention condition, determining a control instruction corresponding to the touch operation, wherein the false touch prevention condition is a condition which is met when the touch operation is judged to be the non-false touch operation; and controlling the wireless headset based on the control instruction.

In a third aspect, some embodiments of the present application further provide a control device for a wireless headset, where the wireless headset includes a control module, a false touch prevention module, and a touch module; prevent mistake and touch module and control module electric connection, this wireless earphone's controlling means includes: the operation receiving module is used for receiving touch operation corresponding to the touch module; the data acquisition module is used for acquiring false touch prevention data corresponding to the false touch prevention module; the instruction determining module is used for determining a control instruction corresponding to the touch operation if the false touch prevention data meets a false touch prevention condition, wherein the false touch prevention condition is a condition which is met when the touch operation is judged to be a non-false touch operation; and the earphone control module is used for controlling the wireless earphone based on the control instruction.

In a fourth aspect, the present invention also provides a computer-readable storage medium, which stores program codes, wherein the program codes, when executed by a processor, implement the above-mentioned control method for a wireless headset.

The application provides a control method and device of a wireless earphone, the wireless earphone and a storage medium. Under the condition that the touch module receives touch operation, the false touch prevention module receives false touch prevention data, and if the received false touch prevention data meets the false touch prevention condition, the control module responds to the touch operation; and if the received false touch prevention data does not meet the false touch prevention condition, the control module does not respond to the touch operation. Therefore, whether this application meets the mistake and touches the condition through preventing that the mistake that prevents that the mistake from touching the module and receive touches the data and judges, and then confirms whether touch operation is the maloperation, has effectively reduced the probability that the phenomenon appears triggering by mistake in wireless earphone daily use.

Drawings

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

Fig. 1 shows a schematic diagram of a TWS headset according to an embodiment of the present application.

Fig. 2 shows a schematic diagram of a TWS headset according to an embodiment of the present application.

Fig. 3 shows a schematic diagram of a third TWS headset provided in an embodiment of the present application.

Fig. 4 shows a schematic diagram of a fourth TWS headset provided in an embodiment of the present application.

Fig. 5 shows a schematic diagram of a fifth TWS headset according to an embodiment of the present application.

Fig. 6 shows a schematic diagram of a sixth TWS headset according to an embodiment of the present application.

Fig. 7 shows a flowchart of a first method for controlling a wireless headset according to an embodiment of the present application.

Fig. 8 is a flowchart illustrating a second method for controlling a wireless headset according to an embodiment of the present application.

Fig. 9 is a flowchart illustrating a third method for controlling a wireless headset according to an embodiment of the present application.

Fig. 10 is a flowchart illustrating a fourth method for controlling a wireless headset according to an embodiment of the present application.

Fig. 11 shows a flowchart of a method for controlling a wireless headset according to an embodiment of the present application.

Fig. 12 is a flowchart illustrating a method for controlling a wireless headset according to another embodiment of the present application.

Fig. 13 is a flowchart illustrating a method for controlling a wireless headset according to another embodiment of the present application.

Fig. 14 shows a block diagram of a wireless headset control device according to an embodiment 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 exemplary only for the purpose of explaining the present application and are not to be construed as limiting the present application. Meanwhile, in the description of the present application, the terms "first", "second", and the like are used only for distinguishing the description, and are not to be construed as indicating or implying relative importance.

In order to make the technical solutions of the present application better understood by those skilled in the art, 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 to be understood that the embodiments described are only a few embodiments of the present application and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

In daily use of the TWS earphone, the TWS earphone has the problem of false triggering due to misoperation such as false touch, false tapping and the like of a user.

In view of the above problems, the present application provides a method and an apparatus for controlling a wireless headset, and a storage medium. Under the condition that the touch module receives touch operation, the false touch prevention module receives false touch prevention data, and if the received false touch prevention data meets the false touch prevention condition, the control module responds to the touch operation; and if the received false touch prevention data does not meet the false touch prevention condition, the control module does not respond to the touch operation. Therefore, whether this application meets the mistake and touches the condition through preventing that the mistake that prevents that the mistake from touching the module and receive touches the data and judges, and then confirms whether touch operation is the maloperation, has effectively reduced the probability that the phenomenon appears triggering by mistake in wireless earphone daily use.

Based on the above problem, referring to fig. 1 in particular, fig. 1 schematically illustrates a first TWS headset provided in an embodiment of the present application. Specifically, the TWS headset 10 is a rod-shaped headset, and mainly includes a touch module 100, an anti-accidental-touch module 110, and a control module 120.

In one embodiment, the touch module 100 is electrically connected to the control module 120 for receiving a touch operation. The touch operation is an operation of controlling the TWS headset 10 by the user, and common touch operations include a long-press operation, a single-click operation, a multi-click operation, an up-slide operation, a down-slide operation, and the like. The touch module 100 may include a touch sensor that generates an electrical signal based on a touch operation, such as a capacitive touch sensor, a resistive touch sensor, and the like.

The false touch prevention module 110 is electrically connected to the control module 120, and configured to receive the false touch prevention data and determine whether the false touch prevention data meets a false touch prevention condition, where the false touch prevention condition is a condition that is met when the touch operation received by the TWS headset 10 is determined to be a non-false touch operation, and if the touch operation is the non-false touch operation, it is determined that a false trigger event does not occur, and otherwise, if the touch operation is determined not to be the non-false touch operation, it is determined that the false trigger event occurs. In some embodiments, the false touch prevention module 110 may include a touch sensor, and the corresponding false touch prevention data may be detection data received on the touch sensor, and the corresponding false touch prevention condition may be further configured to determine whether the detection data satisfies a predetermined detection data characteristic. If the detection data meet the preset detection data characteristics, the false touch prevention data meet the false touch prevention conditions; otherwise, the false touch prevention data does not meet the false touch prevention condition.

In other embodiments, the false touch prevention module 110 may include a gravity sensor, the corresponding false touch prevention data may be acceleration data received by the gravity sensor, and the corresponding false touch prevention condition may be further set to determine whether the acceleration data satisfies a predetermined acceleration data characteristic. If the acceleration data meets the preset acceleration data characteristic, the false touch prevention data meets the false touch prevention condition; otherwise, the false touch prevention data does not meet the false touch prevention condition.

Further, the anti-false touch module 110 may further include a determination unit, in addition to the sensor unit (e.g., the touch sensor or/and the gravity sensor), for determining whether the anti-false touch data satisfies the anti-false touch condition based on the data received by the sensor unit. Specifically, the determination unit may convert, based on the false touch prevention data (e.g., an analog signal of capacitance change caused by touch) received by the sensor unit, the false touch prevention data into a digital signal and then analyze a characteristic of the digital signal to determine whether the false touch prevention data satisfies a false touch prevention condition. In some embodiments, the determining unit may be a circuit processing unit independent of the sensor unit, or/and may be a processing chip independent of the sensor unit. In other embodiments, the determining unit may be a circuit processing unit or/and a processing chip integrated inside the sensor unit, for example, the sensor unit has a capability of detecting the false touch prevention data, and can further convert the false touch prevention data into a digital signal and then analyze the characteristic of the digital signal to determine whether the false touch prevention data satisfies the false touch prevention condition.

The control module 120 includes a control chip, which mainly processes, analyzes, and converts electrical signals input by other modules or/and units, generates a control command, and outputs a control signal. In this embodiment, the control module 120 is configured to respond to the touch operation when the false touch prevention data obtained by the false touch prevention module 110 meets the false touch prevention condition. The other modules include, but are not limited to: a touch module 100, a false touch prevention module 110, and the like.

Further, the TWS headset 10 also includes an earbud portion 130, an ear portion 140, a microphone 150, a speaker 160, and a wear sensor 170.

As an embodiment, the TWS headset 10 is relatively small in size, typically not much different in size from the concha cavity of the user, and when worn, the sound emitting surface of the ear plug portion 130 is in contact with the concha cavity of the ear, the top end of the ear stem portion 140 is connected to the ear plug portion 130, and the bottom end of the ear stem portion 140 is located near the earlobe of the user.

The microphone 150 is a sensor for picking up sound, and is generally disposed at the bottom end of the ear stem portion 140, and is connected to the control module 120. The microphone 150 may be an electret microphone or a silicon microphone. The microphone 150 is mainly used for collecting sound signals outside the TWS headset 10, and converting the sound signals into electric signals to be transmitted to the control module 120 for processing, so as to realize the functions of active noise reduction, voice call, call noise reduction, voice recording, voice assistant awakening and the like of the TWS headset 10.

The speaker 160 is a transducer device for converting an electrical signal into an acoustic signal, and is generally disposed on the top of the earplug portion 130 and connected to the control module 120, and the principle thereof is that audio power vibrates a cone or a diaphragm inside the speaker 160 through an electromagnetic, piezoelectric or electrostatic effect and resonates with the surrounding air to generate a sound.

The wearing sensor 170 is used to determine the wearing state of the TWS headset 10, and is generally disposed at one side of the earplug portion 130 and connected to the control module 120. The wear sensor 170 may be a capacitive sensor or an optical sensor. The principle of wearing the sensor 170 is to convert the variation of the capacitance into an electrical signal through a capacitance sensor, or convert the variation of the optical path into an electrical signal through an optical sensor, and transmit the electrical signal to the control module 120 for analysis, so as to determine whether the TWS headset 10 is in a wearing state.

The TWS earphone provided by the embodiment of the application is provided with the false touch prevention module used for receiving the false touch prevention data. Under the condition that the touch module receives touch operation, the false touch prevention module receives false touch prevention data, and if the received false touch prevention data meets the false touch prevention condition, the control module responds to the touch operation; and if the received false touch prevention data does not meet the false touch prevention condition, the control module does not respond to the touch operation. Therefore, whether this application meets the mistake and touches the condition through preventing that the mistake that prevents that the mistake from touching the module and receive touches the data and judges, and then confirms whether touch operation is the maloperation, has effectively reduced the probability that the phenomenon appears triggering by mistake in wireless earphone daily use.

As shown in fig. 2, fig. 2 schematically illustrates another TWS headset provided in an embodiment of the present application. In the TWS headset 20 provided in the embodiment of the present application, the false touch prevention module 210 includes at least one touch unit, and the at least one touch unit is configured to acquire the false touch prevention data.

In some embodiments, the at least one touch unit includes at least one touch sensor, and the touch sensor may be a resistive touch sensor or a capacitive touch sensor. The resistance type touch sensor mainly comprises a thin film layer and a glass layer, when touch operation occurs, the thin film layer deforms and contacts with the glass layer, so that the resistance value of a contact point is changed, and an electric signal is generated. The capacitive touch sensor utilizes a current induction principle, and an electric field exists in a human body, so that when touch operation occurs, a coupling capacitor is formed between a user and the surface of the sensor, the current value at a contact point is changed, and an electric signal is generated. The electric signal is the false touch prevention data and is used for the subsequent control module to judge whether the false touch prevention data meets the false touch prevention condition.

In other embodiments, the anti-false touch module 210 includes a signal processing circuit in addition to at least one touch unit. The at least one touch unit includes at least one touch sensor, and the touch sensor may be a resistive touch sensor or a capacitive touch sensor. The touch sensor receives touch operation to generate an electric signal, and further transmits the electric signal to the signal processing circuit. Specifically, the signal processing circuit may be a judging circuit, the internal of which may be preset with characteristic data of the electrical signal, and the judging circuit is configured to judge whether the received electrical signal meets the preset electrical signal characteristic, and output an electrical signal corresponding to a judgment result to the control module. Specifically, if the electrical signal received by the judgment circuit meets the preset electrical signal characteristic, it indicates that the false touch prevention data meets the false touch prevention condition, and at this time, the judgment circuit can output a high level signal to the control module; otherwise, the judging circuit outputs a low level signal to the control module.

The number of the touch units is not limited in the embodiment of the application. In the touch operation, in order to perform the operation of sliding up and down, a plurality of touch units arranged in sequence may be disposed in the touch module 200 to detect the sliding operation input by the user. Taking the touch module 200 including three touch units as an example, as shown in fig. 3, the first touch unit 2002, the second touch unit 2004 and the third touch unit 2006 are sequentially disposed from top to bottom along the length direction of the ear portion 220, and when the user slides from the top to the bottom of the ear portion 220 along the length direction of the ear portion 220, the first touch unit 2002, the second touch unit 2004 and the third touch unit 2006 receive touch operations at different times. Specifically, assuming that the timings of detecting that the first touch unit 2002, the second touch unit 2004 and the third touch unit 2006 receive the touch operations are t1, t2 and t3, respectively, if t1 is earlier than t2 and t2 is earlier than t3, it can be determined that the slide gesture input by the user is a top-to-bottom slide.

In one embodiment, the false touch prevention data includes detection data of a touch unit included in the false touch prevention module 210, where the detection data is detection data of a preset operation, and the preset operation is set by the wireless headset by default, or is set by a user by self-definition, for example, the preset operation is a pressing operation corresponding to the touch unit included in the false touch prevention module 210.

In another embodiment, the anti-false touch data includes designation data indicating that the touch operation corresponding to the touch unit included in the anti-false touch module 210 is not received when the touch operation corresponding to the touch module 200 is received.

Further, referring to fig. 2, the anti-false touch module 210 includes a fourth touch unit 2102 and a fifth touch unit 2104, and is disposed on an outer surface of the ear handle portion 220. The touch module 200 is disposed on an outer surface of the ear portion 220. Likewise, the touch module 200 includes a touch unit. Specifically, the fourth touch unit 2102 and the fifth touch unit 2104 are respectively disposed at two sides of the ear handle portion 220 and are disposed opposite to each other, the touch module 200 is disposed in the middle of the fifth touch unit 2104 of the fourth touch unit 2102, and an angle of an included angle between a line direction between the center of the touch module 200 and the center of the fourth touch unit 2102 and a length direction of the ear handle portion 220 is a right angle, that is, the fourth touch unit 2102, the fifth touch unit 2104 and the touch module 200 are located at the same horizontal height.

As an embodiment, in order to avoid touching the module 210 when the touch module 200 is touched, the position of the touch module 200 is further adjusted, so that the relative position between the touch module 200 and the module 210 is limited as follows: an angle of an included angle between a direction of a connection line between the center of the touch module 200 and the center of the fourth touch unit 2102 and a length direction of the ear part is smaller than a first preset angle; an angle of an angle between a direction of a connection line between the center of the touch module 200 and the center of the fifth touching unit 2104 and a length direction of the ear part is smaller than a second preset angle. In some examples, the "center" may be understood as a "geometric center", as shown in fig. 4, each of the touch module 200, the fourth touch unit 2102 and the fifth touch unit 2104 may be a relatively regular geometric figure (such as a rectangle), and an angle of a first included angle between a direction of a connection line between a point a of the geometric center of the touch module 200 and a point B1 of the geometric center of the fourth touch unit 2102 and a length direction of the handle portion is smaller than a first preset angle; a second included angle between a direction of a connection line between the point a of the geometric center of the touch module 200 and the point B2 of the geometric center of the fifth touch unit 2104 and the length direction of the ear stem portion is smaller than a second preset angle.

The first preset angle and the second preset angle are set by a technician based on experience or experiment. The first preset angle and the second preset angle may be the same or different. For example, the first predetermined angle is 40 degrees, and the second predetermined angle is also 40 degrees. In this embodiment, the fourth touch unit 2102, the fifth touch unit 2104, and the touch module 200 are located at different levels, so that the probability of touching the false touch prevention module 210 when a touch operation is applied to the touch module 200 is reduced.

In the wireless headset provided by the embodiment of the application, the anti-false-touch module comprises at least one touch unit, under the condition that the touch module receives touch operation, the anti-false-touch data is received through the at least one touch unit, and if the received anti-false-touch data meets the anti-false-touch condition, the control module responds to the touch operation; if the received false touch prevention data does not meet the false touch prevention condition, the control module does not respond to touch operation; whether the mistaken touch preventing data received by the at least one touch unit meets the mistaken touch preventing condition is judged, whether the touch operation is the mistaken operation is further confirmed, and the probability of the mistaken triggering phenomenon in daily use of the wireless earphone of a user is effectively reduced.

As shown in fig. 5, fig. 5 schematically illustrates a fifth TWS headset provided in an embodiment of the present application. In the TWS headset 30 provided in the embodiment of the present application, the false touch prevention module 300 includes a Gravity sensor (G-sensor), and the G-sensor is configured to acquire motion data, that is, the false touch prevention data, based on the motion state of the wireless headset 30.

In some embodiments, the motion data includes acceleration data generated by the G-sensor under the action of a touch operation. Specifically, when the touch module 310 receives a touch operation from a user, the touch operation causes a displacement of the mass inside the G-sensor, and the G-sensor can calculate acceleration data corresponding to the displacement of the mass in real time. For example, the user performs a single-click operation on the touch module 310, and the G-sensor calculates acceleration data corresponding to the single-click operation. The acceleration data is the false touch prevention data and is used for the subsequent control module to judge whether the false touch prevention data meets the false touch prevention condition.

In other embodiments, the anti-false touch module 300 includes a signal processing circuit in addition to the G-sensor. And further transmitting the acceleration data to a signal processing circuit based on the acceleration data corresponding to the touch operation calculated by the G-sensor. Specifically, the signal processing circuit may be a judging circuit, a data characteristic of the acceleration data may be preset in the signal processing circuit, and the judging circuit is configured to judge whether the received acceleration data meets the preset acceleration data characteristic, and output an electrical signal corresponding to a judgment result to the control module. Specifically, if the acceleration data received by the judgment circuit meets the preset acceleration data characteristic, the false touch prevention data meets the false touch prevention condition, and at this time, the judgment circuit can output a high level signal to the control module; otherwise, the judging circuit outputs a low level signal to the control module.

In one embodiment, as shown in fig. 5, the G-sensor is disposed inside the ear plug portion 320, and the touch module 310 is disposed in the ear stem portion 330. As another embodiment, as shown in fig. 6, the G-sensor is disposed inside the ear portion 330, and the touch module 310 is disposed in the ear portion 330.

In the wireless headset provided by the embodiment of the application, the false touch prevention module comprises a G-sensor, under the condition that the touch module receives touch operation, motion data of the touch operation is calculated through the G-sensor, and if the motion data meets the false touch prevention condition, the control module responds to the touch operation; if the motion data does not meet the false touch prevention condition, the control module does not respond to touch operation; whether the motion data calculated by the G-sensor meets the false touch prevention condition is judged, whether the touch operation is false operation is further confirmed, and the probability of false triggering in daily use of the wireless earphone by a user is effectively reduced.

As shown in fig. 7, fig. 7 schematically illustrates a first method for controlling a wireless headset according to an embodiment of the present application. The method is applied to any one of the TWS headset shown in fig. 1 to 6, and the control method may include the following steps S110 to S140.

Step S110: and receiving touch operation corresponding to the touch module.

The touch operation is an operation of controlling the TWS headset by the user, and includes and is not limited to: long press operation, single click operation, multi-click operation, up-sliding operation, down-sliding operation, and the like. Different touch operations correspond to different functions. Taking the mode of listening to songs as an example, the touch operation of the user on the touch module can be single-click, double-click, multi-click and the like, the single-click operation on the touch module can pause/continue playing songs, the double-click operation can switch the next song, and the three-click operation can wake up a voice assistant and the like.

Step S120: and acquiring false touch prevention data corresponding to the false touch prevention module.

And under the condition of receiving the touch operation corresponding to the touch module, the false touch prevention module reads the false touch prevention data generated by the false touch prevention module and judges whether the false touch prevention data meets the false touch prevention condition. The false touch prevention data is a judgment basis for making a false touch prevention judgment, and the data content is flexibly set according to the hardware structure of the false touch prevention module, which will be described in the following embodiments.

Step S130: and if the false touch prevention data meets the false touch prevention condition, determining a control instruction corresponding to the touch operation.

And under the condition that the false touch prevention data meets the false touch prevention condition, the wireless earphone identifies the touch data corresponding to the touch operation to determine the type of the touch operation, and determines the control instruction corresponding to the touch operation by searching a mapping table between the type of the touch operation and the control instruction.

And under the condition that the false touch prevention data is judged not to meet the false touch prevention condition, the wireless earphone determines that a false trigger event occurs, and does not respond to the touch operation corresponding to the touch module at the moment.

Similarly, taking a song listening mode as an example, the touch module receives the clicking operation, and the wireless instruction searches the control instruction corresponding to the clicking operation in the mapping table between the type of the touching operation and the control instruction as a song pause/continue playing instruction under the condition that the mistaken touch prevention data meets the mistaken touch prevention condition; and under the condition that the false touch prevention data does not meet the false touch prevention condition, the wireless earphone does not execute the step of determining the control instruction corresponding to the touch operation.

Step S140: and controlling the wireless headset based on the control instruction.

And the control module transmits the control instruction to an execution unit included in the wireless headset under the condition that the control instruction corresponding to the touch operation is confirmed, and the execution unit executes the control instruction. Taking the song listening mode as an example, when the control module confirms that the control instruction corresponding to the clicking operation is a song pause/continue playing instruction, the song pause/continue playing instruction is transmitted to the loudspeaker in the wireless earphone, and the loudspeaker is turned on or turned off.

In the embodiment of the application, a wireless earphone control method is provided, wherein under the condition that a touch module receives touch operation, false touch prevention data is received through a false touch prevention module, and if the received false touch prevention data meets a false touch prevention condition, a control module responds to the touch operation; if the received false touch prevention data does not meet the false touch prevention condition, the control module does not respond to touch operation; whether the mistaken touch preventing data received by the mistaken touch preventing module meets the mistaken touch preventing condition is judged, whether the touch operation is the mistaken operation is further confirmed, and the probability of the mistaken triggering phenomenon of the user in daily use of the wireless earphone is effectively reduced.

As shown in fig. 8, fig. 8 schematically illustrates a second method for controlling a wireless headset according to an embodiment of the present application. The method is applied to any one of the TWS earphones shown in fig. 2 to 4, the false touch prevention module on the TWS earphone comprises at least one touch unit, and the control method may include the following steps S210 to S250.

Step S210: and receiving touch operation corresponding to the touch module.

In this embodiment, the specific implementation of step S210 may refer to the description of step S110 provided in the above embodiments, and details are not repeated here.

Step S220: a touch operation corresponding to at least one touch unit is acquired.

In this embodiment, the anti-false-touch module comprises at least one touch unit, and the anti-false-touch data corresponding to the anti-false-touch module is acquired to be: a touch operation corresponding to at least one touch unit is acquired. Touch operations include, but are not limited to: a press operation, a single click operation, a double click operation, and a multi-click operation. In some embodiments, the wireless headset acquires a touch operation corresponding to the at least one touch unit before acquiring the touch operation corresponding to the touch module. In other embodiments, the wireless headset acquires a touch operation corresponding to at least one touch unit when acquiring the touch operation corresponding to the touch module.

In some embodiments, the false touch prevention module comprises a first touch unit and a second touch unit, and the obtaining of the false touch prevention data corresponding to the false touch prevention module is realized by: a first touch operation corresponding to the first touch unit is acquired, and a second touch operation corresponding to the second touch unit is acquired.

The first touch operation includes, but is not limited to: a press operation, a single click operation, a double click operation, and a multi-click operation. The second touch operation includes, but is not limited to: a press operation, a single click operation, a double click operation, and a multi-click operation. In some embodiments, the wireless headset acquires a first touch operation corresponding to the first touch unit and a second touch operation corresponding to the second touch unit before acquiring the touch operation corresponding to the touch module. Specifically, within a preset time after the anti-false touch module (the first touch unit and the second touch unit) on the wireless headset receives the clicking operation of the user, the touch module receives the sliding operation of the user.

In other embodiments, the wireless headset acquires a first touch operation corresponding to the first touch unit and a second touch operation corresponding to the second touch unit when the touch operation corresponding to the touch module is acquired. Specifically, within a preset time period after the touch module receives the sliding operation of the user, the anti-false touch module (the first touch unit and the second touch unit) on the wireless headset receives the clicking operation of the user.

In still other embodiments, the wireless headset acquires a first touch operation corresponding to the first touch unit and a second touch operation corresponding to the second touch unit while acquiring a touch operation corresponding to the touch module. Specifically, the anti-false touch units (the first touch unit and the second touch unit) on the wireless headset receive the pressing operation of the user, and the pressing operation is continued until the user applies a sliding operation to the touch module.

The time for the wireless headset to acquire the first touch operation and the time for the wireless headset to acquire the second touch operation may be the same or different. Specifically, within a preset time period after the first touch unit on the wireless headset receives the clicking operation of the user, the second touch unit receives the clicking operation of the user.

Step S230: and if the touch operation corresponding to at least one touch unit is a preset operation, determining that the false touch prevention data meets the false touch prevention condition.

The preset operation is set by the wireless earphone in a default mode or is set by a user in a self-defined mode. The preset operations include, but are not limited to: a press operation, a single click operation, a double click operation, and a multi-click operation. In this embodiment, the anti-false-touch module includes at least one touch unit, and the wireless headset determines that the anti-false-touch data satisfies the anti-false-touch condition when the touch operation corresponding to the at least one touch unit is the preset operation. And under the condition that the wireless earphone determines that the touch operation corresponding to at least one touch unit is not the preset operation, determining that the false touch prevention data does not meet the false touch prevention condition.

When the anti-false touch module includes the first touch unit and the second touch unit, step S230 is implemented as: and if the first touch operation is a first preset operation and the second touch operation is a second preset operation, determining that the false touch prevention data meets the false touch prevention condition.

The first preset operation and the second preset operation are set by the wireless earphone in a default mode or are set by a user in a self-defined mode. The first preset operation includes, but is not limited to: a press operation, a single click operation, a double click operation, and a multi-click operation, the second preset operation including and not limited to: a press operation, a single click operation, a double click operation, and a multi-click operation. The first preset operation and the second preset operation may be the same or different.

In this embodiment, the anti-false-touch module includes a first touch unit and a second touch unit, and the wireless headset determines that a first touch operation corresponding to the first touch unit is a first preset operation, and determines that the anti-false-touch data satisfies the anti-false-touch condition when a second touch operation corresponding to the second touch unit is a second preset operation. And the wireless earphone determines that the false touch prevention data does not meet the false touch prevention condition under the condition that the first touch operation corresponding to the first touch unit is not the first preset operation and/or the second touch operation corresponding to the second touch unit is not the second preset operation.

Specifically, corresponding to the example in step S220, in a preset time period after the anti-false touch units (the first touch unit and the second touch unit) on the wireless headset receive the click operation of the user, when the touch module receives the sliding operation of the user, if both the first preset operation and the second preset operation in the wireless headset are click operations, the anti-false touch data satisfies the anti-false touch condition; and if the first preset operation and/or the second preset operation in the wireless earphone is not a clicking operation, the anti-false touch data does not meet the anti-false touch condition.

Step S240: and if the false touch prevention data meets the false touch prevention condition, determining a control instruction corresponding to the touch operation.

In this embodiment, reference may be made to the description of step S130 provided in the above embodiments for specific implementation of step S240, and details are not repeated here.

Step S250: and controlling the wireless headset based on the control instruction.

In this embodiment, the specific implementation of step S250 may refer to the description of step S140 provided in the above embodiments, and details are not repeated here.

In the embodiment of the application, a novel wireless headset control method is provided, and a false touch prevention module is arranged in the wireless headset and comprises at least one touch unit. Under the condition that the touch module receives touch operation, receiving false touch prevention data through a touch sensor on the false touch prevention module, and responding to the touch operation if the received false touch prevention data meets a false touch prevention condition; and if the received false touch prevention data does not meet the false touch prevention condition, the control module does not respond to the touch operation. Therefore, whether the mistaken touch preventing data received by the at least one touch unit meets the mistaken touch preventing condition is judged, whether the touch operation is the mistaken operation is further confirmed, and the probability of the mistaken triggering phenomenon of the user in daily use of the wireless earphone is effectively reduced.

As shown in fig. 9, fig. 9 schematically illustrates a third method for controlling a wireless headset according to an embodiment of the present application. The method is applied to any one of the TWS earphones shown in fig. 2 to 4, the false touch prevention module on the TWS earphone comprises at least one touch unit, and the control method may include the following steps S310 to S350.

Step S310: and receiving touch operation corresponding to the touch module.

In this embodiment, reference may be made to the description of step S110 provided in the above embodiments for specific implementation of step S310, and details are not repeated here.

Step S320: and when receiving the touch operation corresponding to the touch module, acquiring detection data corresponding to at least one touch unit.

In this embodiment, the specific implementation of step S320 may refer to the description of step S220 provided in the above embodiments, and details are not repeated here.

Step S330: and if the detection data corresponding to at least one touch unit is designated data, determining that the false touch prevention data meets the false touch prevention condition.

The designation data is used to indicate that a touch operation corresponding to at least one touch unit is not received. In this embodiment, the anti-false-touch module includes at least one touch unit, and if the wireless headset determines that the touch operation corresponding to the touch module is received and the touch operation corresponding to the touch unit of the anti-false-touch module is not received, it is determined that the anti-false-touch data meets the anti-false-touch condition. If the wireless earphone determines that at the same time of receiving the touch operation corresponding to the touch module and at least one touch unit in the false touch prevention module receives the touch operation, it is determined that the false touch prevention data does not meet the false touch prevention condition.

When the anti-false touch module includes the first touch unit and the second touch unit, step S230 is implemented as: and if the first detection data is first designated data and the second detection data is second designated data, determining that the false touch prevention data meets the false touch prevention condition.

The first designation data is used to indicate that a touch operation corresponding to the first touch unit is not received. The second designation data is used to indicate that a touch operation corresponding to the second touch unit is not received. In this embodiment, the anti-false-touch module includes a first touch unit and a second touch unit, and if the wireless headset determines that the first touch unit does not receive the touch operation and the second touch unit does not receive the touch operation, it is determined that the anti-false-touch data meets the anti-false-touch condition. And if the wireless earphone determines that the first touch unit receives the touch operation and/or the second touch unit receives the touch operation, determining that the false touch prevention data does not meet the false touch prevention condition.

Specifically, under the condition that a touch module on the wireless headset receives a clicking operation of a user, first detection data and second detection data corresponding to a first touch unit and a second touch unit on the anti-false touch module are received, and if the first detection data and the second detection data indicate that the first touch unit and the second touch unit do not receive the touching operation (for example, a pressing operation), the wireless headset responds to the clicking operation; if the first detection data and the second detection data indicate that a touch operation (such as a pressing operation) is received on the first touch unit and/or a touch operation (such as a pressing operation) is received on the second touch unit, the wireless headset does not respond to the clicking operation.

Step S340: and if the false touch prevention data meets the false touch prevention condition, determining a control instruction corresponding to the touch operation.

In this embodiment, the specific implementation of step S340 may refer to the description of step S130 provided in the above embodiments, and details are not repeated here.

Step S350: and controlling the wireless headset based on the control instruction.

In this embodiment, the specific implementation of step S350 may refer to the description of step S140 provided in the above embodiments, and details are not repeated here.

In the embodiment of the application, a novel wireless headset control method is provided, and a false touch prevention module is arranged in the wireless headset and comprises at least one touch unit. Under the condition that the touch module receives the touch operation, at least one touch unit does not receive the touch operation, and the control module responds to the touch operation; if the touch unit which receives the touch operation exists in at least one touch unit, the control module does not respond to the touch operation; whether the mistaken touch preventing data received by the at least one touch unit meets the mistaken touch preventing condition is judged, whether the touch operation is the mistaken operation is further confirmed, and the probability of the mistaken triggering phenomenon in daily use of the wireless earphone of a user is effectively reduced.

As shown in fig. 10, fig. 10 schematically illustrates a fourth method for controlling a wireless headset according to an embodiment of the present application. The method is applied to any one of the TWS earphones shown in fig. 5 to 6, the false touch prevention module on the TWS earphone comprises a G-sensor, and the control method may comprise the following steps S410 to S450.

Step S410: and receiving touch operation corresponding to the touch module.

In this embodiment, reference may be made to the description of step S110 provided in the above embodiments for specific implementation of step S410, and details are not repeated here.

Step S420: motion data was acquired by the G-sensor.

In this embodiment, the false touch prevention module includes a G-sensor, and the motion data acquired by the G-sensor includes acceleration data generated by the G-sensor under the action of touch operation or/and tap operation. Specifically, when the touch module receives touch operation or/and knocking operation from a user, the touch operation or/and knocking operation simultaneously causes displacement of the mass block inside the G-sensor, and the G-sensor can calculate acceleration data corresponding to the displacement of the mass block in real time.

Step S430: and if the motion data meet the preset motion data characteristics, determining that the false touch prevention data meet the false touch prevention condition.

The preset exercise data characteristics are set by the wireless headset in a default mode or are set by a user in a self-defined mode. The preset motion data features include, but are not limited to: acceleration data characteristics generated by the G-sensor under pressing operation, single-click operation, double-click operation and multi-click operation. In this embodiment, the false touch prevention module comprises a G-sensor, and the wireless headset determines that the false touch prevention data meets the false touch prevention condition when the wireless headset determines that the motion data meets the preset motion data characteristic. And under the condition that the wireless earphone determines that the motion data does not meet the preset motion data characteristics, determining that the false touch prevention data does not meet the false touch prevention condition.

Specifically, under the condition that a touch module on the wireless earphone receives clicking operation of a user, motion data (namely acceleration data) corresponding to the clicking operation is obtained through a G-sensor, and if the acceleration data meets acceleration data characteristics generated by the preset G-sensor for the clicking operation, it is determined that mistaken touch prevention data meets mistaken touch prevention conditions; otherwise, determining that the false touch prevention data does not meet the false touch prevention condition.

As another embodiment, the wireless headset may further determine whether the anti-false touch data satisfies the anti-false touch condition through the following steps S431 to S433.

Step S431: and if the motion data meet the preset motion data characteristics, determining a first operation type and a second operation type of the touch operation.

The operation type is a type of control operation applied by a user to the touch module, and the type of control operation includes, but is not limited to: a press operation, a single click operation, a double click operation, and a multi-click operation. The first operation type is determined based on motion data acquired by the G-sensor. The second operation type is determined based on the touch data acquired by the touch module. Specifically, the wireless headset determines that the motion data meets the preset motion data characteristics, and determines a first operation type of the touch operation based on the motion data. Meanwhile, the wireless headset determines a second operation type of the touch operation based on the touch data corresponding to the touch operation. In the embodiment of the application, the motion data is acquired through the G-sensor, and under the condition that the touch data is acquired through the touch module, the operation type (also referred to as a first operation type) of the touch operation is determined based on the motion data, and the operation type (also referred to as a second operation type) of the touch operation is determined based on the touch data, so that whether the touch operation determined through the G-sensor and the touch operation determined through the touch module are the same touch operation is judged.

Specifically, under the condition that a touch module on the wireless earphone receives a double-click operation of a user, motion data (namely acceleration data) corresponding to the double-click operation is obtained through a G-sensor, and if the acceleration data meets the acceleration data characteristics generated by the preset double-click operation G-sensor, the first operation type is determined to be the double-click operation; meanwhile, touch data corresponding to the double-click operation are obtained through a touch module on the wireless earphone, and if the touch data meet the preset touch data characteristics of the double-click operation, the second operation type is determined to be the double-click operation.

And the wireless earphone does not execute the subsequent steps under the condition that the movement data does not meet the preset movement data characteristics.

Step S433: and if the first operation type is the same as the second operation type, determining that the false touch prevention data meets the false touch prevention condition.

Under the condition that the wireless earphone determines that the first operation type is the same as the second operation type, the touch operation determined through the G-sensor and the touch operation determined through the touch module are determined to be the same touch operation, and then the fact that the mistaken touch prevention data meet the mistaken touch prevention condition is determined. Under the condition that the wireless earphone determines that the first operation type is different from the second operation type, it is determined that the touch operation determined by the G-sensor is not the same as the touch operation determined by the touch module, and therefore it is determined that the mistaken touch prevention data does not meet the mistaken touch prevention condition.

As shown in fig. 11, which shows a flowchart for determining whether the anti-false-touch data meets the anti-false-touch condition according to an embodiment of the present application, the determining process includes the following steps.

Step S435: and confirming that the touch operation is the double-click operation according to the motion data generated by the G-sensor.

And under the condition that the wireless earphone determines that the motion data meet the preset motion data characteristics, determining a first operation type of touch operation, namely double-click operation, based on the motion data.

Step S437: and confirming that the touch operation is double-click operation according to the touch data generated by the touch module.

And under the condition that the wireless earphone determines that the motion data meets the preset motion data characteristics, determining a second operation type of touch operation, namely double-click operation, based on the touch data. It should be noted that step S437 may be performed before step S435.

Step S439: responding to the double-click operation.

And under the condition that the wireless earphone determines that the first operation type and the second operation type are both double-click operations, determining that the false touch prevention data meets the false touch prevention condition, and responding to the double-click operations. And under the condition that the wireless earphone determines that the first operation type is different from the second operation type, determining that the false touch prevention data does not meet the false touch prevention condition, and not responding to the double-click operation.

Step S440: and if the false touch prevention data meets the false touch prevention condition, determining a control instruction corresponding to the touch operation.

In some embodiments, in the case that the false touch prevention data is determined to satisfy the false touch prevention condition, the wireless headset identifies the motion data corresponding to the G-sensor to determine the type of the touch operation, and determines the control instruction corresponding to the touch operation by looking up a mapping table between the type of the touch operation and the control instruction. And under the condition that the false touch prevention data is judged not to meet the false touch prevention condition, the wireless earphone determines that a false trigger event occurs, and does not respond to the touch operation corresponding to the touch module at the moment.

In one example, as shown in fig. 12, the control method of the wireless headset includes steps S510 to S555.

Step S510: and receiving touch operation corresponding to the touch module.

Step S515: motion data was acquired by the G-sensor.

Step S520: judging whether the motion data meet the data characteristics of the clicking operation, if so, executing the step S525; if not, go to step S530.

Step S525: responding to the single click operation.

Step S530: judging whether the motion data meet the data characteristics of the double-click operation, if so, executing step S535; if not, go to step S540.

Step S535: responding to the double-click operation.

Step S540: judging whether the motion data meet the data characteristics of the three-click operation, and if so, executing the step S545; if not, go to step S550.

Step S545: responding to the three-click operation.

Step S550: judging whether the motion data meet the data characteristics of other preset operations, and if so, executing the step S555; if not, the process is ended.

Step S555: responding to other preset operations.

In other embodiments, when it is determined that the anti-false touch data meets the anti-false touch condition, the wireless headset identifies the touch data corresponding to the touch operation acquired on the touch module to determine the type of the touch operation, and determines the control instruction corresponding to the touch operation by searching a mapping table between the type of the touch operation and the control instruction. And under the condition that the false touch prevention data is judged not to meet the false touch prevention condition, the wireless earphone determines that a false trigger event occurs, and does not respond to the touch operation corresponding to the touch module at the moment.

In one example, as shown in fig. 13, the method of controlling a wireless headset includes steps S610 to S655.

Step S610: and receiving touch operation corresponding to the touch module, and acquiring motion data by the G-sensor.

Step S615: and acquiring touch data of touch operation through the touch module.

Step S620: judging whether the touch data meet the data characteristics of the clicking operation, if so, executing a step S625; if not, go to step S630.

Step S625: responding to the single click operation.

Step S630: judging whether the touch data meet the data characteristics of the double-click operation, if so, executing the step S635; if not, go to step S640.

Step S635: responding to the double-click operation.

Step S640: judging whether the touch data meet the data characteristics of the three-click operation, if so, executing step S645; if not, go to step S650.

Step S645: responding to the three-click operation.

Step S650: judging whether the touch data meet the data characteristics of other preset operations, if so, executing step S655; if not, the process is ended.

Step S655: responding to other preset operations.

Step S450: and controlling the wireless headset based on the control instruction.

In this embodiment, the specific implementation of step S450 may refer to the description of step S140 provided in the above embodiments, and is not repeated here.

In the embodiment of the application, a novel wireless earphone control method is provided, and a false touch prevention module is arranged in a wireless earphone and comprises a G-sensor. Under the condition that the touch module receives touch operation, motion data corresponding to the touch operation is acquired through a G-sensor on the false touch prevention module, and if the acquired motion data meets the false touch prevention condition, the control module responds to the touch operation; and if the acquired motion data does not meet the false touch prevention condition, the control module does not respond to touch operation. Therefore, whether the motion data corresponding to the touch operation acquired by the G-sensor meets the false touch prevention condition or not is judged, whether the touch operation is false operation or not is further confirmed, and the probability of the false triggering phenomenon of the user in daily use of the wireless headset is effectively reduced.

As shown in fig. 14, fig. 14 schematically shows a block diagram of a wireless headset control device 40 according to an embodiment of the present application. The wireless earphone control device 40 is applied to a wireless earphone, and the wireless earphone comprises a control module, an anti-false touch module and a touch module; prevent mistake and touch module and control module electric connection, this wireless earphone's controlling means 40 includes: an operation reception module 400, a data acquisition module 410, an instruction determination module 420, and an earphone control module 430. The operation receiving module 400 is configured to receive a touch operation corresponding to a touch module; the data acquisition module 410 is used for acquiring false touch prevention data corresponding to the false touch prevention module; the instruction determining module 420 is configured to determine a control instruction corresponding to the touch operation if the false touch prevention data meets a false touch prevention condition, where the false touch prevention condition is a condition that is met when the touch operation is determined to be a non-false touch operation. The headset control module 430 is used to control the wireless headset based on the control instructions.

In some embodiments, the wireless headset control device 40 further comprises: a condition confirmation module (not shown in fig. 14).

In some embodiments, the anti-false touch module includes at least one touch unit, and the data obtaining module 410 is configured to obtain a touch operation corresponding to the at least one touch unit; the condition confirmation module is used for determining that the false touch prevention data meets the false touch prevention condition if the touch operation corresponding to the at least one touch unit is a preset operation.

In some embodiments, the false touch prevention module includes a first touch unit and a second touch unit, and the data acquisition module 410 is configured to acquire a first touch operation corresponding to the first touch unit and acquire a second touch operation corresponding to the second touch unit; the condition confirmation module is used for determining that the mistaken touch preventing data meets the mistaken touch preventing condition if the first touch operation is a first preset operation and the second touch operation is a second preset operation.

In some embodiments, the anti-false touch module includes at least one touch unit, and the data obtaining module 410 is configured to obtain detection data corresponding to the at least one touch unit when a touch operation corresponding to the touch module is received; the condition confirmation module is used for determining that the false touch prevention data meets the false touch prevention condition if the detection data corresponding to the at least one touch unit is designated data, and the designated data is used for indicating that the touch operation corresponding to the at least one touch unit is not received.

In some embodiments, the false touch prevention module includes a gravity sensor, and the data acquisition module 410 is configured to acquire the motion data through the gravity sensor; the condition confirmation module is used for determining that the false touch prevention data meets the false touch prevention condition if the motion data meets the preset motion data characteristics.

In some embodiments, the wireless headset control device 40 further comprises: an operation type confirmation module (not shown in fig. 14).

In some embodiments, the false touch prevention module includes a gravity sensor, and the data acquisition module 410 is configured to acquire the motion data through the gravity sensor; the operation type confirming module is used for determining a first operation type of the touch operation based on the motion data; determining a second operation type of the touch operation based on the touch data corresponding to the touch operation; the condition confirmation module is used for determining that the false touch prevention data meets the false touch prevention condition if the first operation type is the same as the second operation type.

It can be clearly understood by those skilled in the art that, for convenience and brevity of description, the specific working processes of the above-described apparatuses and modules may refer to the corresponding processes in the foregoing method embodiments, and are not described herein again.

In the several embodiments provided in the present application, the coupling between the modules may be electrical, mechanical or other type of coupling.

In addition, functional modules in the embodiments of the present application may be integrated into one processing module, or each of the modules may exist alone physically, or two or more modules are integrated into one module. The integrated module can be realized in a hardware mode, and can also be realized in a software functional module mode.

In the scheme that this application provided, be provided with in the TWS earphone and be used for receiving the mistake of preventing touching the module of mistake that the mistake touched the data. Under the condition that the touch module receives touch operation, the false touch prevention module receives false touch prevention data, and if the received false touch prevention data meets the false touch prevention condition, the control module responds to the touch operation; and if the received false touch prevention data does not meet the false touch prevention condition, the control module does not respond to the touch operation. Therefore, whether this application meets the mistake and touches the condition through preventing that the mistake that prevents that the mistake from touching the module and receive touches the data and judges, and then confirms whether touch operation is the maloperation, has effectively reduced the probability that the phenomenon appears triggering by mistake in wireless earphone daily use.

Embodiments of the present application further provide a computer-readable storage medium, in which computer program instructions are stored, and the computer program instructions can be called by a processor to execute the method described in the above embodiments.

The computer-readable storage medium may be an electronic memory such as a flash memory, an EEPROM (electrically erasable programmable read only memory), an EPROM, a hard disk, or a ROM. Alternatively, the computer-readable storage medium includes a non-volatile computer-readable storage medium. The computer readable storage medium has a storage space for program code for performing any of the method steps of the above-described method. These program codes can be read from or written to one or more computer program products, which can be compressed, for example, in a suitable form.

Although the present application has been described with reference to the preferred embodiments, it is to be understood that the present application is not limited to the disclosed embodiments, but rather, the present application is intended to cover various modifications, equivalents and alternatives falling within the spirit and scope of the present application.

Claims (13)

1. A wireless earphone is characterized by comprising a control module, an anti-false touch module and a touch module;

the mistaken touch preventing module is electrically connected with the control module, and the touch module is electrically connected with the control module;

the touch module is used for receiving touch operation;

the false touch prevention module is used for acquiring false touch prevention data and judging whether the false touch prevention data meets a false touch prevention condition, wherein the false touch prevention condition is a condition which is met when the touch operation is judged to be a non-false touch operation;

the control module is used for responding to the touch operation under the condition that the false touch prevention data meet the false touch prevention condition.

2. The wireless headset of claim 1, wherein the anti-false touch module comprises at least one touch unit, and the at least one touch unit is configured to obtain the anti-false touch data according to the received touch operation.

3. The wireless headset of claim 2, wherein the wireless headset comprises an eartip portion and an earstem portion connected to the eartip portion, and the anti-false touch module comprises a first touch unit and a second touch unit;

the first touch unit and the second touch unit are disposed at the ear handle portion.

4. The wireless headset of claim 3, wherein the touch module comprises a third touch unit disposed at the ear stem portion;

the angle of a first included angle between the direction of a connecting line between the center of the third touch unit and the center of the first touch unit and the length direction of the ear handle part is smaller than a first preset angle;

and the angle of a second included angle between the connecting line direction between the center of the third touch unit and the center of the second touch unit and the length direction of the ear handle part is smaller than a second preset angle.

5. The wireless headset of claim 1, wherein the anti-false touch module comprises a gravity sensor configured to obtain the anti-false touch data based on a motion state of the wireless headset.

6. The control method of the wireless earphone is characterized by being applied to the wireless earphone, wherein the wireless earphone comprises a control module, an anti-false touch module and a touch module; the mistaken touch preventing module is electrically connected with the control module, and the touch module is electrically connected with the control module; the method comprises the following steps:

receiving touch operation corresponding to the touch module;

acquiring false touch prevention data corresponding to the false touch prevention module;

if the false touch prevention data meets a false touch prevention condition, determining a control instruction corresponding to the touch operation, wherein the false touch prevention condition is a condition which is met when the touch operation is judged to be a non-false touch operation;

controlling the wireless headset based on the control instruction.

7. The method according to claim 6, wherein the anti-false touch module comprises at least one touch unit;

the mistake that obtains to correspond to mistake and prevent touching the module and touch data, includes: acquiring a touch operation corresponding to at least one touch unit;

and if the touch operation corresponding to at least one touch unit is a preset operation, determining that the false touch prevention data meets the false touch prevention condition.

8. The method according to claim 7, wherein the false touch prevention module comprises a first touch unit and a second touch unit; the acquiring of the touch operation corresponding to at least one touch unit includes:

acquiring a first touch operation corresponding to the first touch unit, and acquiring a second touch operation corresponding to the second touch unit;

and if the first touch operation is a first preset operation and the second touch operation is a second preset operation, determining that the false touch prevention data meets the false touch prevention condition.

9. The method according to claim 6, wherein the anti-false touch module comprises at least one touch unit;

the mistake that obtains to correspond to mistake and prevent touching the module and touch data, includes: when the touch operation corresponding to the touch module is received, acquiring detection data of at least one touch unit;

and if the detection data are designated data, determining that the false touch prevention data meet the false touch prevention condition, wherein the designated data are used for indicating that the touch operation corresponding to at least one touch unit is not received.

10. The method of claim 6, wherein the anti-false touch module comprises a gravity sensor;

the mistake that obtains to correspond to mistake and prevent touching the module and touch data, includes: acquiring motion data through the gravity sensor;

and if the motion data meet the preset motion data characteristics, determining that the false touch prevention data meet the false touch prevention condition.

11. The method of claim 6, wherein the anti-false touch module comprises a gravity sensor;

the mistake that obtains to correspond to mistake and prevent touching the module and touch data, includes:

acquiring motion data through the gravity sensor;

determining a first operation type of the touch operation based on the motion data;

determining a second operation type of the touch operation based on touch data corresponding to the touch operation;

and if the first operation type is the same as the second operation type, determining that the false touch prevention data meets the false touch prevention condition.

12. The control device of the wireless earphone is characterized by being applied to the wireless earphone, wherein the wireless earphone comprises a control module, an anti-false touch module and a touch module; the mistaken touch preventing module is electrically connected with the control module, and the touch module is electrically connected with the control module; the control device of the wireless headset comprises:

the operation receiving module is used for receiving touch operation corresponding to the touch module;

the data acquisition module is used for acquiring false touch prevention data corresponding to the false touch prevention module;

the instruction determining module is used for determining a control instruction corresponding to the touch operation if the false touch prevention data meets a false touch prevention condition, wherein the false touch prevention condition is a condition which is met when the touch operation is judged to be a non-false touch operation;

and the earphone control module is used for controlling the wireless earphone based on the control instruction.

13. A computer-readable storage medium, having stored thereon program code that can be invoked by a processor to perform the method according to any one of claims 6 to 11.

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