CN110825235B - Earphone sleep monitoring method, device and system - Google Patents

Abstract

The application relates to a method, a device and a system for monitoring the sleep of an earphone. The earphone sleep monitoring method comprises the following steps: sending a wake-up instruction to the vibrator when the displacement signal transmitted by the motion sensor is not received in the sleep monitoring time period; the wake-up instruction is used for indicating the vibrator to work according to a preset vibration rule; the preset vibration rule comprises that the vibration frequency is randomly generated, the vibration intensity is increased gradually along with time, and the vibration direction gradually vibrates along with time towards the direction away from the ears; when the vibrator works according to a preset vibration rule, judging whether the earphone is in a state of being separated from the ear at present; if yes, the earphone is instructed to execute the shutdown operation. The application not only remarkably improves the intelligent degree of man-machine interaction, but also effectively prolongs the service life of the earphone and reduces the damage probability of the earphone.

Description

Earphone sleep monitoring method, device and system

Technical Field

The present application relates to the field of bluetooth communication technologies, and in particular, to a method, an apparatus, and a system for monitoring sleep of an earphone.

Background

At present, a bluetooth headset is used as a common audio playing device, and is worn frequently during work, study and travel, and the bluetooth headset is matched with a mobile phone bluetooth end mainly by utilizing a bluetooth module of the bluetooth headset to realize wireless transmission of audio signals, but because a user possibly enters deep study or rest, rest or unconscious sleep state when using the bluetooth headset, the bluetooth headset can continuously play audio.

In the implementation process, the inventor finds that at least the following problems exist in the conventional technology: the traditional technology can not effectively process the Bluetooth headset, and the human-computer interaction intelligent degree is low; and play for a long time and play when the user is unnecessary, not only can reduce the life of bluetooth headset playback devices, still easily increase the earphone damage probability.

Disclosure of Invention

In view of the foregoing, it is desirable to provide a method, apparatus and system for monitoring sleep of an earphone, which can effectively control the earphone.

In order to achieve the above object, in one aspect, an embodiment of the present invention provides a method for monitoring sleep of an earphone, in which a motion sensor and a vibrator are built in the earphone; the method comprises the following steps:

sending a wake-up instruction to the vibrator when the displacement signal transmitted by the motion sensor is not received in the sleep monitoring time period; the wake-up instruction is used for indicating the vibrator to work according to a preset vibration rule; the preset vibration rule comprises that the vibration frequency is randomly generated, the vibration intensity is increased gradually along with time, and the vibration direction gradually vibrates along with time towards the direction away from the ears;

when the vibrator works according to a preset vibration rule, judging whether the earphone is in a state of being separated from the ear at present;

If yes, the earphone is instructed to execute the shutdown operation.

In one embodiment, the sleep monitoring period includes a first period, a second period, and a third period that are consecutive in sequence; the direction of separating from the ear comprises the direction perpendicular to the plane of the sound outlet of the earphone;

the preset vibration rule further includes:

the vibration intensity corresponding to the first time period is one third of the vibration intensity corresponding to the third time period; the vibration direction corresponding to the first time period is along the direction parallel to the plane where the earphone sound outlet is positioned;

the vibration intensity corresponding to the second time period is two thirds of the vibration intensity corresponding to the third time period; the vibration direction corresponding to the second time period is along the direction perpendicular to the plane where the sound outlet of the earphone is positioned;

the third time period corresponds to a vibration intensity range of 70 to 200 revolutions per second; the vibration direction corresponding to the third time period is along the direction perpendicular to the plane of the earphone sound outlet.

In one embodiment, the method further comprises the steps of:

when the vibrator works according to a preset vibration rule, a displacement signal transmitted by the motion sensor is received, and a stop instruction is sent to the vibrator; the stop instruction is used for indicating the vibrator to stop working.

In one embodiment, before the step of sending a wake-up instruction to the vibrator when the displacement signal transmitted by the motion sensor is not received in the sleep monitoring period, the method further includes the steps of:

confirm earphone and pair earphone connect successfully;

wherein, the pair earphone is internally provided with a motion sensor and a vibrator.

On the other hand, the embodiment of the invention also provides an earphone sleep monitoring device, which comprises:

the wake-up module is used for sending a wake-up instruction to the vibrator when the displacement signal transmitted by the motion sensor is not received in the sleep monitoring time period; the wake-up instruction is used for indicating the vibrator to work according to a preset vibration rule; the preset vibration rule comprises that the vibration frequency is randomly generated, the vibration intensity is increased gradually along with time, and the vibration direction gradually vibrates along with time towards the direction away from the ears;

the separation judging module is used for judging whether the earphone is in a state of separating from the ear currently when the vibrator works according to a preset vibration rule;

and the shutdown instruction module is used for instructing the earphone to execute shutdown operation if the judgment result is yes.

A vibration frequency generator, which is applied to the earphone;

the vibration frequency generator is used for executing any one of the earphone sleep monitoring methods.

In one embodiment, the vibration frequency generator is applied to any one of the pair-connected bluetooth headsets.

In one embodiment, the vibration frequency generator is further configured to communicate with a terminal device connected to the bluetooth headset, and output a corresponding vibration frequency based on a result of the communication.

A Bluetooth headset sleep monitoring system comprises a master headset and a slave headset;

the main earphone is internally provided with a first motion sensor, a first vibrator and a vibration frequency generator;

a second motion sensor and a second vibrator are arranged in the earphone;

the vibration frequency generator is used for executing any one of the earphone sleep monitoring methods.

In one embodiment, the first motion sensor is arranged at the position of 2mm-5mm of the edge of the sound outlet of the main earphone; the first vibrator is arranged in a position 2mm away from the charging end of the main earphone;

the second motion sensor is arranged in the position of 2mm-5mm from the edge of the sound outlet of the earphone; the second vibrator is built in at a distance of 2mm from the charging end of the earphone.

In one embodiment, the master earphone and the slave earphone both comprise built-in infrared sensors;

the first motion sensor and the second motion sensor are human motion sensors;

the first vibrator and the second vibrator are motors; the motor includes a centrifugal motor and a general motor.

A computer readable storage medium having stored thereon a computer program which when executed by a processor implements any of the aforementioned methods of earphone sleep monitoring.

One of the above technical solutions has the following advantages and beneficial effects:

the application provides a sleep monitoring mechanism of an earphone, which is characterized in that in a sleep monitoring time period, when a motion sensor does not detect a signal of the head of a user, a random vibration frequency is obtained, meanwhile, a staged vibration strategy is adopted in the working process of a vibrator, the vibration intensity is continuously improved in the vibration time, the vibration direction gradually vibrates along the direction of separating from the ear along with the time until the earphone falls off from the ear, the active separation of the ear is completed, the connection of the ear is disconnected, and the playing of audio is further paused; not only remarkably improves the intelligent degree of man-machine interaction, but also effectively prolongs the service life of the earphone and reduces the damage probability of the earphone.

Drawings

Other features, objects and advantages of the present application will become more apparent upon reading of the detailed description of non-limiting embodiments, made with reference to the accompanying drawings in which:

FIG. 1 is a diagram of an application environment for a method of monitoring the sleep of a tympanic machine in one embodiment;

FIG. 2 is a flow chart of a method of monitoring the sleep of a tympanic membrane in one embodiment;

FIG. 3 is a schematic diagram of vibration rules during a first time period in one embodiment;

FIG. 4 is a schematic diagram of vibration rules in a second time period in one embodiment;

FIG. 5 is a schematic diagram of vibration rules in a third time period in one embodiment;

FIG. 6 is a block diagram of a device for monitoring the sleep of a tympanic machine in one embodiment;

FIG. 7 is a block diagram of a tympanic membrane sleep monitoring system in one embodiment;

FIG. 8 is a schematic diagram of vibration direction perpendicular to a plane of the earphone sound outlet in an embodiment;

FIG. 9 is a left side view of a vibration direction parallel to a plane in which the earphone sound outlet lies in one embodiment;

fig. 10 is a schematic workflow diagram of a tympanic membrane sleep monitoring system in one embodiment.

Detailed Description

In order that the application may be readily understood, a more complete description of the application will be rendered by reference to the appended drawings. Preferred embodiments of the present application are shown in the drawings. This application may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "connected" to another element, it can be directly connected to and integrated with the other element or intervening elements may also be present. The terms "internal", "outlet edge", "charging end" and the like are used herein for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. The terminology used in the description of the application herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

In the traditional technology, a user needs to manually set a timing closing play audio in advance at a mobile phone end, when the Bluetooth headset detects that the Bluetooth headset is not in a working state, the Bluetooth headset is automatically dormant, and the headset is still worn on the ear of the user.

Therefore, the user can manually set the timing to close the playing audio in advance at the mobile phone end, when the Bluetooth headset detects that the Bluetooth headset is not in a working state, the Bluetooth headset is automatically dormant, the headset is still worn on the ear of the user, if the Bluetooth headset is not processed, the Bluetooth headset is played for a long time and is played when the user is unnecessary to use, the service life of the Bluetooth headset playing device is prolonged, and the ear of the user is chronically damaged. For example, when a user wears a bluetooth headset for a long time, the headset is stuck to the ear, bacteria may grow, and diseases such as otitis media are caused, and the blood circulation is poor, and meanwhile, the loss is caused to the eardrum.

Further, under the condition that timing closing is not set in advance, a user may enter deep learning or unconscious sleep when using the Bluetooth headset, and at this time, the Bluetooth headset may continue to play audio, so that the service life of the Bluetooth headset playing device may be reduced; the time of setting the timing closing is inconsistent with the sleeping time, and the intelligent degree of human-computer interaction is low. If the user is in a sleeping state, the audios are played and the ears are clamped by the earphones, so that the hearing of the ears is easy to be reduced, the sleeping posture of the human body can be changed after the user sleeps, and the earphones are easy to crush when the user turns over to sleep sideways.

Therefore, the application provides a method, a device and a system for monitoring the sleep of an earphone; the present application will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present application more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the application.

The method for monitoring the sleep of the earphone can be applied to an application environment shown in figure 1. The earphone can be in communication connection with the matched earphone, and further, the earphone can be connected with the terminal equipment; the terminal device can be, but is not limited to, various personal computers, notebook computers, smart phones, tablet computers and portable wearable devices; the headset may be a bluetooth headset. Specifically, the earphone is internally provided with a motion sensor and a vibrator. In one example, the earphone can also be internally provided with a vibration frequency generator according to actual requirements; for example, the vibration frequency generator may be built into either of the paired two headphones; for another example, both headphones are paired with a vibration frequency generator built into them.

In one embodiment, as shown in fig. 2, a method for monitoring sleep of an earphone is provided, and the method is applied to the vibration frequency generator in fig. 1 for illustration, and includes the following steps:

step 202, sending a wake-up instruction to a vibrator when a displacement signal transmitted by a motion sensor is not received in a sleep monitoring time period;

the wake-up instruction is used for indicating the vibrator to work according to a preset vibration rule; the preset vibration rule includes that the vibration frequency is randomly generated, the vibration intensity is increased with time, and the vibration direction gradually vibrates along the direction away from the ears with time.

Specifically, the motion sensor can detect the displacement of the head of the human body; in a specific example, the motion sensor may be a human motion sensor, and when the head shakes, the change generated by acceleration is converted into an electrical signal and fed back to a vibration frequency generator inside the earphone. After the head of a user shakes or moves to a certain extent, the motion sensor can check and sense the head in time.

When the motion sensor detects head shaking (for example, human body motion, only needs to shake the head slightly), the motion sensor transmits a displacement signal to the vibration frequency generator, namely, confirms that the user is in a current awake state, and at the moment, the earphone can maintain a current normal working state or the earphone in a current vibration state stops vibrating (namely, the vibrator stops working); if the motion sensor does not detect the displacement of the head of the user within a preset time period (for example, a sleep monitoring time period), that is, the user is confirmed to be in a state of sleeping or deep learning, etc., a displacement signal is not transmitted to the vibration frequency generator. At this time, the vibration frequency generator may randomly generate a vibration frequency, for example, transmit a wake-up instruction to the vibrator, the wake-up instruction being used to instruct the vibrator to operate with a preset vibration rule.

According to the application, when the motion sensor does not detect that a user is in a waking state, the vibration amplitude of a motor or a motor and other vibration starting equipment arranged at the tail end (charging end) of the Bluetooth headset is continuously enhanced, the random vibration frequency and the vibration intensity are selected, the obtained vibration signal (namely a waking instruction) is followed to execute the vibration action, and the irregular vibration can firstly alert the user, embody intelligent man-machine interaction and can initially detect the using state of the headset; further, the user can be awakened, and whether the earphone is in a normal use state or not is confirmed; again, shutdown pre-warning may be performed, and if no feedback is received from the user regarding the vibration (i.e., the motion sensor does not transmit a displacement signal), the vibration intensity may be maintained or increased in time, and whether the headset is vibrating away from the target object (e.g., the user's ear) may be monitored in real time.

In a specific embodiment, before the step of sending a wake-up instruction to the vibrator when the displacement signal transmitted by the motion sensor is not received in the sleep monitoring period, the method further includes the steps of:

confirm earphone and pair earphone connect successfully;

wherein, the pair earphone is internally provided with a motion sensor and a vibrator.

Specifically, only after the left earphone and the right earphone (i.e. the earphone and the paired earphone, or the master earphone and the slave earphone, the application is not limited thereto) are successfully paired, and the data synchronization transmission is completed, the following sleep monitoring step can be executed.

Further, if the pairing of the left and right bluetooth earphones is not considered, the vibration frequency generators are required to be built in the left and right earphones, that is, two vibration frequency generators can be used without considering the cost. Meanwhile, the data synchronously transmitted by the data can comprise an audio signal, a vibration control signal (on or off), a vibration frequency signal, an electric quantity prompt and the like.

In one example, when two headphones are not paired, the two headphones may also be executed in a single ear, and if pairing is completed, the two headphones need to operate synchronously, play audio synchronously, and vibrate synchronously. It should be noted that: on the one hand, two vibration frequency generators may be required to work at different frequencies (i.e. two headphones paired with each other need to have built-in frequency generators), which may increase the cost; on the other hand, the vibration of the same frequency can enable a user to discontinuously receive a vibration signal, and different frequencies can possibly cause the situation that the earphone is disconnected when the vibration falls off and the earphone does not fall off.

The sleep monitoring time period in the application can be set according to actual application requirements; in a specific example, the sleep monitoring time period may include a plurality of time periods (for example, a first time period, a second time period, and a third time period that are sequentially continuous and may sequentially correspond to the corresponding detection function, the pre-determination function, the sleep detection function, and the like), so that a staged vibration strategy may be adopted for each time period until the earphone falls off from the ear, and active separation from the human ear is completed.

When the Bluetooth earphone is worn, the tail end of the earphone is exposed to the outside, no object is blocked or limited, and when the tail end shakes to reach a certain strength, the Bluetooth earphone can fall off from the human ear, so that the disconnection of the left earphone and the right earphone is realized, and the earphone enters a shutdown mode when the earphone is unnecessarily used. Meanwhile, the terminal equipment can be disconnected, and simultaneously, the playing of the audio is paused, so that the power consumption of the earphone and the terminal equipment can be effectively reduced, the service life of the earphone is effectively prolonged, the damage of the earphone to the human ear can be reduced, and the damage probability of the earphone is also reduced.

Further, the vibration frequency generator may send a wake-up instruction to the vibrator when the displacement signal transmitted by the motion sensor is not received (i.e., no displacement action is detected by any motion sensor built in the earphone); the wake-up instruction is used for indicating the vibrator to work; the vibrator in the present application may refer to a motor, for example, a centrifugal motor, a general motor, or the like. Meanwhile, the vibrator in the application can also adopt a terminal equipment vibrator, and the direction of the applied centrifugal force is continuously changed along with the rotation of the cam.

Correspondingly, the wake-up instruction can contain data such as vibration frequency generated by the vibration frequency generator, so that the vibrator works according to a preset vibration rule; the vibration frequency generator sends data such as the vibration frequency to the vibrator (the vibrator can be any vibrator of the earphone or the vibrators of the left and right earphones) through Bluetooth communication, and meanwhile, the vibrator is confirmed to receive the data such as the vibration frequency, and then the vibrator in the left and right earphones or the vibrator in any earphone is started to work according to corresponding vibration rules.

It should be noted that, the preset vibration rule in the present application may include that the vibration frequency is randomly generated, the vibration intensity is increased with time, and the vibration direction is gradually vibrated in a direction away from the ear with time. On the one hand, the randomly generated vibration frequency can be irregular vibration, so that the user can be alerted, and a precondition is provided for the earphone to be separated from the ear; on the other hand, the vibration intensity increases with time, and the vibration intensity in the application can be set to corresponding vibration intensity values in different time periods in the sleep monitoring time period; again, the direction of separating from the ear may include a direction perpendicular to the plane in which the earphone sound outlet is located, and specifically, taking the earphone entity as an example, the present application proposes that the earphone sound outlet may be regarded as a plane, i.e. irregular vibration is performed in the perpendicular direction of the plane.

In a specific example, the vibration intensity corresponding to the first period is one third of the vibration intensity corresponding to the third period; the vibration direction corresponding to the first time period is along the direction parallel to the plane where the earphone sound outlet is positioned; at this stage, the user can be alerted and prompted, and the use state of the earphone is detected initially.

The vibration intensity corresponding to the second time period is two thirds of the vibration intensity corresponding to the third time period; the vibration direction corresponding to the second time period is along the direction perpendicular to the plane where the sound outlet of the earphone is positioned; this stage can wake up the user and confirm whether the headset is currently in normal use.

The third time period corresponds to a vibration intensity range of 70 to 200 revolutions per second; the vibration direction corresponding to the third time period is along the direction perpendicular to the plane of the earphone sound outlet. The vibration at this stage is shutdown pre-warning processing, and if the user does not receive the corresponding feedback of the vibration, the vibration intensity is maintained or the vibration intensity is timely improved, so as to monitor whether the earphone vibrates away from the target object (for example, the ear of the user) in real time.

Specifically, the vibration frequency generator may randomly select the vibration frequency, but in different detection periods, the vibration intensity may set a fixed value in each period; the first time period corresponds to the following first vibration requirement, the second time period corresponds to the following second vibration requirement, and the third time period corresponds to the following third vibration requirement. The preset vibration rule in the present application may include a first vibration requirement, a second vibration requirement, and a third vibration requirement.

As shown in fig. 3, in the predetermined time t1 (t1=21s) (i.e., the first period), the vibration intensity of the first vibration request is the vibration intensity n of the third vibration request _m The vibration frequency is randomly supplied by a vibration frequency generator. The vibration frequency may be to wait three seconds, vibrate three seconds, stop two seconds, continue vibrating four seconds, stop one second, vibrate three seconds, stop two seconds, continue vibrating four seconds after the first vibration request (i.e., wake-up instruction) is received by both the left earpiece and the right earpiece. The irregular vibration required by the first vibration in the first stage can alert the user and perform initial detection on the use state of the earphone, for example, the earphone is in the current use state for a period of time.

As shown in fig. 4, the vibration intensity of the second vibration request is the vibration intensity n of the third vibration request, as in the predetermined determination time t2 (t2=21s) (i.e., the second period) _m The vibration frequency is randomly supplied by a vibration frequency generator. The vibration frequency can be that after the left earphone and the right earphone both receive the second vibration request, the left earphone and the right earphone wait for two seconds, vibrate for three seconds, stop for two seconds, continue vibrating for four seconds, stop for one second, vibrate for three seconds, stop for two seconds, and continue vibrating for four seconds; in the second stage, irregular vibration required by the second vibration can wake up a user and confirm whether the earphone is in a normal use state at present; the normal use state may include: Normally playing music, synchronizing audio by using a mobile phone, and the like;

as shown in fig. 5, i.e., the third period of time, the third vibration requires the vibration intensity n _m ；n _m The vibration sensitivity degree can be set according to different vibration sensitivity degrees of different users, for example, a relatively sensitive user can be set to be lower, and a insensitive user can be set to be higher; the application provides the vibration intensity n _m Must be provided randomly by the vibration frequency generator at a vibration intensity that is capable of vibrating it off the human ear. In a specific example, the frequency vibration range adopted is 70 to 200 revolutions per second according to the rotating speed of the motor, so that the earphone is vibrated; the vibration frequency and intensity are changed to 150 per second, so that the earphone can be separated from the human ear.

The vibration frequency of the third vibration request may be to wait two seconds, vibrate for three seconds, stop for two seconds, continue vibrating for four seconds, stop for two seconds, vibrate for two seconds, stop for two seconds, and continue vibrating for three seconds after the third vibration request is received by both the left earphone and the right earphone; the third vibration requirement also requires the selection of continuous or suspension of vibration depending on whether the earphone is detached from the user's ear. In a specific example, in the third stage, irregular vibration required by the third vibration is detected, shutdown early warning is performed, if no corresponding feedback is received from the user to the vibration (i.e. the motion sensor does not detect a displacement signal), the vibration intensity is maintained or the vibration intensity is timely improved, and whether the earphone vibrates away from the ear of the user is detected in real time.

Step 204, when the vibrator works according to a preset vibration rule, judging whether the earphone is in a state of being separated from the ear currently.

Specifically, when the vibrator works according to a preset vibration rule, the application provides a method for monitoring and judging whether the earphone is in a state of being separated from the ear currently in real time, so that the human-computer interaction intelligent degree can be remarkably improved; wherein, can confirm whether the earphone leaves the people's ear through the built-in infrared sensor in the earphone discernment response.

In a specific embodiment, the method further comprises the steps of:

when the vibrator works according to a preset vibration rule, a displacement signal transmitted by the motion sensor is received, and a stop instruction is sent to the vibrator; the stop instruction is used for indicating the vibrator to stop working.

Specifically, when any one of the motion sensors detects a signal that the ear of the user is displaced, a stop signal is sent to the vibrator, so that the earphone is not vibrated any more and is in a normal working state (for example, music is played normally).

Step 206, if the result of the determination is yes, instruct the earphone to execute the shutdown operation.

Specifically, when the earphone is confirmed to be separated from the ear of the user, the earphone is instructed to enter a power-off state;

when it is confirmed that the earphone is not separated from the user's ear, the motion sensor detects cyclically whether a signal that the user's ear is displaced exists or not, and at the same time, the vibrator is still operated with a requirement of a preset vibration rule (e.g., vibration frequency, vibration intensity, and vibration direction corresponding to the third period of time).

In the earphone sleep monitoring method, when the motion sensor does not detect the signals of the head of the user, which are displaced, in the sleep monitoring time period, a random vibration frequency is obtained, meanwhile, a staged vibration strategy is adopted in the working process of the vibrator, the vibration intensity is continuously improved in the vibration time, the vibration direction gradually vibrates along the direction of separating from the ears along with the time until the earphone falls off from the ears, the active separation from the human ears is completed, the pair of ears are disconnected, and then the playing of the audio is paused; not only remarkably improves the intelligent degree of man-machine interaction, but also effectively prolongs the service life of the earphone and reduces the damage probability of the earphone.

It should be understood that, although the steps in the flowcharts of fig. 2 and 10 are shown in order as indicated by the arrows, these steps are not necessarily performed in order as indicated by the arrows. The steps are not strictly limited to the order of execution unless explicitly recited herein, and the steps may be executed in other orders. Moreover, at least some of the steps in fig. 2, 10 may include multiple sub-steps or multiple stages, which are not necessarily performed at the same time, but may be performed at different times, which are not necessarily performed sequentially, but may be performed alternately or alternately with at least a portion of the other steps or sub-steps of other steps.

In one embodiment, as shown in fig. 6, there is provided an earphone sleep monitoring apparatus, including:

the wake-up module 610 is configured to send a wake-up instruction to the vibrator when the displacement signal transmitted by the motion sensor is not received in the sleep monitoring period; the wake-up instruction is used for indicating the vibrator to work according to a preset vibration rule; the preset vibration rule comprises that the vibration frequency is randomly generated, the vibration intensity is increased gradually along with time, and the vibration direction gradually vibrates along with time towards the direction away from the ears;

the detachment judgment module 620 is configured to judge whether the earphone is currently in a state of detachment from the ear when the vibrator works with a preset vibration rule;

and the shutdown instruction module 630 is configured to instruct the earphone to perform a shutdown operation if the result of the determination is yes.

For specific limitations of the earphone sleep monitoring device, reference may be made to the above limitations of the earphone sleep monitoring method, and no further description is given here. The modules in the earphone sleep monitoring device can be realized in whole or in part by software, hardware and a combination thereof. The above modules may be embedded in hardware or may be independent of a processor in the computer device, or may be stored in software in a memory in the computer device, so that the processor may call and execute operations corresponding to the above modules.

In one embodiment, a vibration frequency generator is applied to an earphone;

the vibration frequency generator is used for executing any one of the earphone sleep monitoring methods.

In one embodiment, the vibration frequency generator is applied to any one of the pair-connected bluetooth headsets.

In one embodiment, the vibration frequency generator is further configured to communicate with a terminal device connected to the bluetooth headset, and output a corresponding vibration frequency based on a result of the communication.

Specifically, the vibration frequency generator can be arranged in the earphone and used for randomly generating a vibration frequency, and the vibration frequency is irregular vibration, so that the intelligent degree of man-machine interaction can be improved; transmitting the vibration frequency to the vibrator, waking up the vibrator, and enabling the left earphone vibrator and the right earphone vibrator to work at the same vibration frequency and the same vibration intensity (also can be a single earphone vibrator to work, see the foregoing for details); meanwhile, the vibration frequency generator can also be connected with the terminal equipment according to the earphone, and the vibration frequency can be set at the terminal equipment according to the user instruction.

In one embodiment, a Bluetooth headset sleep monitoring system is provided, comprising a master headset and a slave headset;

The main earphone is internally provided with a first motion sensor, a first vibrator and a vibration frequency generator;

a second motion sensor and a second vibrator are arranged in the earphone;

the vibration frequency generator is used for executing any one of the earphone sleep monitoring methods.

In one embodiment, the first motion sensor is arranged at the position of 2mm-5mm of the edge of the sound outlet of the main earphone; the first vibrator is arranged in a position 2mm away from the charging end of the main earphone;

the second motion sensor is arranged in the position of 2mm-5mm from the edge of the sound outlet of the earphone; the second vibrator is built in at a distance of 2mm from the charging end of the earphone.

In one embodiment, the master earphone and the slave earphone both comprise built-in infrared sensors;

the first motion sensor and the second motion sensor are human motion sensors;

the first vibrator and the second vibrator are motors; the motor includes a centrifugal motor and a general motor.

The following describes the above scheme with reference to a specific example, in which the earphone is a bluetooth earphone, the right bluetooth earphone is a master earphone, and the left bluetooth earphone is a slave earphone as an example:

as shown in fig. 7, the bluetooth headset sleep monitoring system includes: the device comprises a Bluetooth left earphone, a Bluetooth right earphone, a first motion sensor, a second motion sensor, a vibration frequency generator, a first vibrator and a second vibrator.

The Bluetooth left earphone comprises a built-in device, a Bluetooth left earphone body and a Bluetooth left earphone body, wherein the built-in device comprises a first motion sensor and a first vibrator;

the Bluetooth right earphone comprises a built-in device which comprises a second motion sensor, a vibration frequency generator and a second vibrator;

the first motion sensor can be arranged at the position of 2mm of the sound outlet of the Bluetooth left earphone and is used for detecting the displacement change of the left earphone and sending the detected signal to the vibration frequency generator of the right earphone;

the second motion sensor can be arranged at the position of 2mm of the sound outlet of the right Bluetooth earphone and is used for detecting the displacement change of the right ear and sending the detected signal to the vibration frequency generator;

it should be noted that, the position of the motion sensor in the present application may not be limited; in a specific example, the sound outlet is set at an optimal position, the position is closest to an object to be measured (for example, the ear of a user), and when the head of the user shakes or moves to a certain displacement, the motion sensor can check and sense in time, so that the defect of insufficient precision of the motion sensor can be overcome. The 2mm data can be obtained through estimation, the in-ear width of a general earphone is 15mm, and the application provides a position range of 2-5mm of the motion sensor, so that the detection is convenient.

The vibration frequency generator is arranged in the Bluetooth right earphone, randomly generates a vibration frequency, the vibration frequency is irregular vibration, sends the vibration frequency to the first vibrator and the second vibrator, wakes up the first vibrator and the second vibrator to enable the first vibrator and the second vibrator to work under a vibration frequency and a vibration intensity, and can also be connected with mobile communication equipment (namely terminal equipment) according to the Bluetooth earphone, and can be set at the mobile communication equipment end according to user instructions.

The first vibrator can be arranged at the tail end (charging end) of the Bluetooth left earphone and is 2mm away from the tail end, and vibration prompts a user whether the Bluetooth left earphone needs to be used continuously or not;

the second vibrator can be arranged at the tail end (charging end) of the Bluetooth right earphone and is 2mm away from the tail end, and vibration prompts a user whether the Bluetooth right earphone needs to be used continuously or not;

the vibration in the application is operated according to the vibration requirement provided by the vibration frequency generator, and the vibration requirement can comprise the vibration frequency, the vibration intensity, the vibration direction and the like; the vibration direction in the present application can be as shown in fig. 8 and 9; fig. 8 and fig. 9 are both illustrative examples of a right bluetooth headset (i.e., the right bluetooth headset in fig. 7); further, for convenience of explanation, fig. 9 is a left side view of the earphone.

The first motion sensor and the second motion sensor can be human body motion sensors, and when the head shakes, the change generated by acceleration is converted into an electric signal to be fed back to the vibration frequency generator inside the Bluetooth headset.

It will be appreciated by persons skilled in the art that the structures shown in fig. 7-9 are block diagrams of only portions of structures associated with the present inventive arrangements and are not limiting of the computer device to which the present inventive arrangements may be implemented, and that a particular computer device may include more or fewer components than shown, or may be combined with certain components, or have different arrangements of components.

Further, the following description of the working procedure of the bluetooth headset sleep monitoring system according to the present application is provided with reference to fig. 10, and as shown in fig. 10, the working procedure may include the following steps:

1) The Bluetooth left earphone and the Bluetooth right earphone are successfully paired and connected, data are synchronously transmitted, when the two motion sensors do not detect signals of the displacement of ears of a user within the detection time t0, pre-judging processing is carried out, the first motor and the second motor work with first vibration requirements along the direction parallel to the sound outlet of the earphone, the first vibration requirements are irregular vibration, the user can be alerted to be prompted, and the using state of the earphone is initially detected;

2) In the pre-judging time t1, when the two motion sensors do not detect signals of the displacement of the ears of the user, sleep detection processing is carried out, the first motor and the second motor work with second vibration requirements along the direction perpendicular to the sound outlet of the earphone respectively, irregular vibration of the second vibration requirements wakes up the user, and whether the earphone is in a normal use state at present is confirmed;

3) In the sleep detection time t2, when the two motion sensors do not detect signals of the displacement of the ears of the user, shutdown early warning processing is carried out, the first motor and the second motor work with third vibration requirements along the direction perpendicular to the sound outlet of the earphone respectively, irregular vibration of the third vibration requirements is carried out, shutdown early warning processing is carried out, if the corresponding feedback of the vibration is not received by the user (namely, the motion sensors do not detect displacement signals), the vibration intensity is kept or the vibration intensity is timely improved, and whether the earphone vibrates away from the ears of the user is detected in real time;

4) Further, judging whether the Bluetooth headset is separated from the ear of the user when the third vibration requirement works;

5) When the Bluetooth headset is separated from the ear of the user, the Bluetooth headset enters a power-off state;

6) When the Bluetooth headset is not separated from the ear of the user, the motion sensor circularly detects whether a signal of the displacement of the ear of the user exists or not, and meanwhile, the first motor and the second motor work with a third vibration requirement;

7) And when any one of the first motion sensor or the second motion sensor detects a signal of the displacement of the user's ear, sending a stop signal to the first motor and the second motor to enable the Bluetooth left earphone and the Bluetooth right earphone to be in a normal working state.

8) The first motion sensor and the second motion sensor detect signals of whether the ears of the user are displaced, and according to the signals that the user shakes the head, or the two motion sensors can detect signals of displacement changes by rotating the head; the first motion sensor and the second motion sensor can be started or not started on the mobile equipment according to the mobile equipment on which the Bluetooth headset is connected.

9) Detecting time t0, wherein the first motor and the second motor do not start to work and are in a waiting awakening state; when the earphone is in a wake-up state, the first motor and the second motor work with a first vibration requirement along a direction parallel to the sound outlet of the earphone respectively.

10 The Bluetooth left earphone and the Bluetooth right earphone are subjected to pre-judging treatment, and the first motor and the second motor work with second vibration requirements along the direction perpendicular to the sound outlet of the earphone respectively.

11 Sleep detection time t2, the left Bluetooth earphone and the right Bluetooth earphone perform sleep detection processing, and the first motor and the second motor work with third vibration requirements along the direction perpendicular to the sound outlet of the earphone respectively.

In the application, the pre-judging process, the sleep detecting process and the shutdown pre-warning process respectively adopt unordered vibration modes with different intensities and different frequencies, so that not only can the reminding of users be achieved and the degree of intelligentization of man-machine interaction be improved, but also the actions of actively separating from human ears can be completed, the ears are disconnected, and further, the playing of audio is paused, thereby effectively prolonging the service life of the earphone and reducing the damage probability of the earphone.

In one embodiment, a computer readable storage medium is provided having a computer program stored thereon, which when executed by a processor implements any of the foregoing methods of earphone sleep monitoring.

Those skilled in the art will appreciate that implementing all or part of the above described methods may be accomplished by way of a computer program stored on a non-transitory computer readable storage medium, which when executed, may comprise the steps of the embodiments of the methods described above. Any reference to memory, storage, database, or other medium used in embodiments provided herein may include non-volatile and/or volatile memory. The nonvolatile memory can include Read Only Memory (ROM), programmable ROM (PROM), electrically Programmable ROM (EPROM), electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), dynamic RAM (DRAM), synchronous DRAM (SDRAM), double Data Rate SDRAM (DDRSDRAM), enhanced SDRAM (ESDRAM), synchronous Link DRAM (SLDRAM), memory bus direct RAM (RDRAM), direct memory bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM), among others.

The technical features of the above-described embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above-described embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The above examples illustrate only a few embodiments of the application, which are described in detail and are not to be construed as limiting the scope of the application. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the application, which are all within the scope of the application. Accordingly, the scope of protection of the present application is to be determined by the appended claims.

Claims (11)

1. The method for monitoring the sleep of the earphone is characterized in that a motion sensor and a vibrator are arranged in the earphone; the method comprises the following steps:

sending a wake-up instruction to the vibrator when the displacement signal transmitted by the motion sensor is not received in the sleep monitoring time period; the wake-up instruction is used for indicating the vibrator to work according to a preset vibration rule; the preset vibration rules comprise that the vibration frequency is randomly generated, the vibration intensity is increased gradually along with time, and the vibration direction gradually vibrates along with time towards the direction away from the ears; the direction of separating from the ear comprises a direction vertical to a plane where the sound outlet of the earphone is positioned; the vibration direction also comprises a first direction parallel to the plane of the earphone sound outlet; matching the vibration frequency and the vibration intensity of the first direction for warning prompt until the user is awakened;

Judging whether the earphone is in a state of being separated from an ear currently when the vibrator works according to the preset vibration rule;

if the judgment result is yes, the earphone is instructed to execute a shutdown operation;

the sleep monitoring time period comprises a first time period, a second time period and a third time period which are sequentially continuous;

the preset vibration rule further includes:

the vibration intensity corresponding to the first time period is one third of the vibration intensity corresponding to the third time period; the vibration direction corresponding to the first time period is along the direction parallel to the plane where the earphone sound outlet is positioned; the vibration at this stage is used for reminding the user, and the use state of the earphone is detected for the first time;

the vibration intensity corresponding to the second time period is two thirds of the vibration intensity corresponding to the third time period; the vibration direction corresponding to the second time period is along the direction perpendicular to the plane where the earphone sound outlet is positioned; the vibration at this stage is used for waking up the user and confirming whether the earphone is in a normal use state at present;

the vibration intensity range corresponding to the third time period is 70-200 revolutions per second; the vibration direction corresponding to the third time period is along the direction perpendicular to the plane where the earphone sound outlet is positioned; the vibration at this stage is used for shutdown early warning processing, and if the corresponding feedback of the user on the vibration is not received, the vibration intensity is maintained or the vibration intensity is timely improved so as to monitor whether the earphone vibrates away from the ear in real time.

2. The method for monitoring the sleep of an earphone according to claim 1, further comprising the steps of:

when the vibrator works according to the preset vibration rule, receiving a displacement signal transmitted by the motion sensor, and sending a stop instruction to the vibrator; the stop instruction is used for indicating the vibrator to stop working.

3. The headphone sleep monitoring method according to claim 1 or 2, further comprising, before the step of transmitting a wake-up instruction to the vibrator when the displacement signal transmitted by the motion sensor is not received in the sleep monitoring period, the step of:

confirming that the earphone is successfully connected with the matched earphone;

wherein the pair of headphones incorporates the motion sensor and the vibrator.

4. An earphone sleep monitoring device, comprising:

the wake-up module is used for sending a wake-up instruction to the vibrator when the displacement signal transmitted by the motion sensor is not received in the sleep monitoring time period; the wake-up instruction is used for indicating the vibrator to work according to a preset vibration rule; the preset vibration rules comprise that the vibration frequency is randomly generated, the vibration intensity is increased gradually along with time, and the vibration direction gradually vibrates along with time towards the direction away from the ears; the direction of separating from the ear comprises a direction vertical to a plane where the sound outlet of the earphone is positioned; the vibration direction also comprises a first direction parallel to the plane of the earphone sound outlet; matching the vibration frequency and the vibration intensity of the first direction for warning prompt until the user is awakened;

The separation judging module is used for judging whether the earphone is in a state of separating from the ear currently when the vibrator works according to the preset vibration rule;

the shutdown indication module is used for indicating the earphone to execute shutdown operation if the judging result is yes;

the sleep monitoring time period comprises a first time period, a second time period and a third time period which are sequentially continuous;

the preset vibration rule further includes:

the vibration intensity corresponding to the first time period is one third of the vibration intensity corresponding to the third time period; the vibration direction corresponding to the first time period is along the direction parallel to the plane where the earphone sound outlet is positioned; the vibration at this stage is used for reminding the user, and the use state of the earphone is detected for the first time;

the vibration intensity corresponding to the second time period is two thirds of the vibration intensity corresponding to the third time period; the vibration direction corresponding to the second time period is along the direction perpendicular to the plane where the earphone sound outlet is positioned; the vibration at this stage is used for waking up the user and confirming whether the earphone is in a normal use state at present;

the vibration intensity range corresponding to the third time period is 70-200 revolutions per second; the vibration direction corresponding to the third time period is along the direction perpendicular to the plane where the earphone sound outlet is positioned; the vibration at this stage is used for shutdown early warning processing, and if the corresponding feedback of the user on the vibration is not received, the vibration intensity is maintained or the vibration intensity is timely improved so as to monitor whether the earphone vibrates away from the ear in real time.

5. A vibration frequency generator, wherein the vibration frequency generator is applied to headphones;

the vibration frequency generator being adapted to perform the method of any one of claims 1 to 3.

6. The vibration frequency generator of claim 5, wherein the vibration frequency generator is applied to any one of the pair-connected bluetooth headsets.

7. The vibration frequency generator according to claim 6, further configured to communicate with a terminal device to which the bluetooth headset is connected, and output the corresponding vibration frequency based on a result of the communication.

8. A Bluetooth headset sleep monitoring system is characterized by comprising a master headset and a slave headset;

the main earphone is internally provided with a first motion sensor, a first vibrator and a vibration frequency generator;

the secondary earphone is internally provided with a second motion sensor and a second vibrator;

the vibration frequency generator being adapted to perform the method of any one of claims 1 to 3.

9. The Bluetooth headset sleep monitoring system of claim 8,

the first motion sensor is arranged in the position of 2mm-5mm of the edge of the sound outlet of the main earphone; the first vibrator is arranged in a position 2mm away from the charging end of the main earphone;

The second motion sensor is arranged in the position of 2mm-5mm of the edge of the sound outlet of the slave earphone; the second vibrator is built-in at a distance of 2mm from the charging end of the slave earphone.

10. The system for monitoring sleep of a Bluetooth headset according to claim 8 or 9, wherein,

the master earphone and the slave earphone both comprise built-in infrared sensors;

the first motion sensor and the second motion sensor are human motion sensors;

the first vibrator and the second vibrator are motors; the motor includes a centrifugal motor and a general motor.

11. A computer readable storage medium, on which a computer program is stored, characterized in that the computer program, when being executed by a processor, implements the steps of the method of any of claims 1 to 3.