CN115607806B - Parameter adjusting method based on brain wave signal and related equipment - Google Patents

Abstract

The invention discloses a parameter adjusting method based on brain wave signals and related equipment, and relates to the technical field of intelligent sleep assistance, wherein the method comprises the following steps: after detecting that the user wears the sleep head ring, recommending a matched sleep mode to the user according to the current position data and the current time data of the user; after the sleep head loop is controlled to start the matched sleep mode, receiving a preset action of a user in the current sleep mode, which is acquired by the sleep head loop, and acquiring a brain wave signal corresponding to the preset action; and controlling the sleep head ring to adjust the music switching, the volume or the electric stimulation intensity in the current sleep mode according to the brain wave signals. According to the method and the device, various parameters in the current sleep mode are adjusted by acquiring the brain wave signals corresponding to the preset actions made in the sleep process of the user, the user does not need to manually turn on the terminal again for adjustment, the intelligentization is higher, and the method and the device are beneficial for the user to fall asleep quickly.

Description

Parameter adjusting method based on brain wave signal and related equipment

Technical Field

The invention relates to the technical field of intelligent sleep assistance, in particular to a method, a system, a terminal and a computer readable storage medium for adjusting parameters based on brain wave signals.

Background

Sleep is one of the most important physiological activities of human beings, and good sleep is beneficial to keep human bodies healthy. However, with the progress of the times, the pressure of people on work, study and life is increased, and more people suffer from sleep disorder. Sleep disorders cause a number of problems, including fatigue, anxiety, depression, and risk of death, among others, and are diseases that are of public harmfulness. Sleep disorder is a ubiquitous disease of sub-healthy people, manifested by poor sleep quality, insomnia and the like, and may induce various cardiovascular and cerebrovascular diseases.

Cognitive disorders, memory disorders, alzheimer's disease, cardiovascular disease and some chronic diseases have been found to be closely related to sleep quality. Therefore, people pay more and more attention to the maintenance of the body, sleep head rings are produced at the same time, the sleep head rings have the function of assisting users to fall asleep, and the sleep head rings are popular among users with poor sleep quality.

However, when the existing sleep head ring is used for assisting sleep of a user, if the user needs to adjust auxiliary parameters such as music, volume or stimulation intensity of the sleep head ring, a button on the sleep head ring needs to be manually adjusted or an intelligent terminal connected with the sleep head ring needs to be opened, which is inconvenient, and also can dissipate the drowsiness of the user, so that the user cannot fall asleep quickly, and the user experience is reduced.

Accordingly, the prior art is yet to be improved and developed.

Disclosure of Invention

The invention mainly aims to provide a parameter adjusting method, a system, a terminal and a computer readable storage medium based on brain wave signals, and aims to solve the problems that in the prior art, when a sleep head ring is used for assisting sleep of a user, the user needs to manually adjust auxiliary parameters of the sleep head ring, such as music, volume or stimulation intensity, the intelligent degree is not high, the user is inconvenient to operate, and sleepiness is dissipated.

In order to achieve the above object, the present invention provides a method for adjusting parameters based on brain wave signals, including the steps of:

after detecting that the user wears a sleep head ring, recommending a matched sleep mode to the user according to the current position data and the current time data of the user;

after the sleep head loop is controlled to start the matched sleep mode, receiving a preset action of the user in the current sleep mode, which is acquired by the sleep head loop, and acquiring a brain wave signal corresponding to the preset action;

and controlling the sleep head ring to adjust music switching, volume or electroencephalogram stimulation intensity in the current sleep mode according to the brain wave signals.

Optionally, the method for adjusting parameters based on brain wave signals, where after it is detected that a user wears a sleep head loop, recommending a matched sleep mode to the user according to the current position data and the current time data of the user, before further comprising:

when a sleep program application is started for the first time, adding the sleep head ring in the sleep program application to finish the binding operation of the sleep program application and the sleep head ring and establish the communication connection between the sleep program application and the sleep head ring;

wherein the sleep program application is pre-installed in the terminal.

Optionally, the method for adjusting parameters based on brain wave signals, where after it is detected that a user wears a sleep head loop, recommending a matched sleep mode to the user according to the current position data and the current time data of the user includes:

the sleep program application acquires current time data and current position data, matches sleep modes corresponding to the time data and the position data in a pre-established sleep mode relation database, and recommends the corresponding sleep modes to a user;

acquiring current position data of a user based on a positioning module in the terminal, and directly acquiring current time data of the terminal through the sleep program application;

wherein, the corresponding relation of time, position and sleep mode in the sleep mode relation database is preset by the user.

Optionally, the method for adjusting parameters based on brain wave signals, wherein the preset action includes:

the user blinks 2 times in succession;

the user blinks 3 times consecutively;

the user bites 1 time and for 2 seconds;

the user bites continuously 2 times and for 2 seconds;

the user bites 1 time with bite duration 2 seconds and blinks 1 time;

the user bites 1 time and for 2 seconds and blinks 2 times;

each preset action corresponds to one brain wave signal.

Optionally, the method for adjusting parameters based on brain wave signals, where the receiving of the preset action of the user in the current sleep mode, which is acquired by the sleep headring, and the acquiring of the brain wave signals corresponding to the preset action specifically includes:

when the preset action of the user is that the continuous blinking times of the user are 2 times, the user blinks for 2 times continuously and corresponds to the first brain wave signal;

when the preset action of the user is that the continuous blinking times of the user are 3 times, the user blinks for 3 times continuously and corresponds to a second brain wave signal;

acquiring a third brain wave signal corresponding to the situation that when the preset action of the user is that the user bites for 1 time and the biting lasts for 2 seconds, the user bites for 1 time and the biting lasts for 2 seconds;

acquiring a fourth brain wave signal corresponding to 2 times of continuous tooth biting and 2 seconds of continuous tooth biting of the user when the preset action of the user is that the user continuously bites for 2 times and the tooth biting lasts for 2 seconds;

acquiring that the preset actions of the user are that the user bites for 1 time, the biting lasts for 2 seconds and blinks for 1 time, and the user bites for 1 time, the biting lasts for 2 seconds and blinks for 1 time correspond to a fifth type of brain wave signal;

and acquiring that the preset actions of the user are that the user bites for 1 time and the biting lasts for 2 seconds and blinks for 2 times, and the user bites for 1 time and the biting lasts for 2 seconds and blinks for 2 times correspond to a sixth type of electroencephalogram signals.

Optionally, the method for adjusting parameters based on brain wave signals, wherein the controlling the sleep headring adjusts music switching, volume and intensity of electrical stimulation in a current sleep mode according to the brain wave signals specifically includes:

when the brain wave signal is a first brain wave signal, controlling the sleep head ring to increase the volume to a first volume preset value according to a preset gradient;

when the brain wave signals are second brain wave signals, controlling the sleep head ring to reduce the volume to a second volume preset value according to a preset gradient;

when the brain wave signal is a third brain wave signal, controlling the sleep head ring to strengthen the electric stimulation intensity to a first intensity preset value according to a preset gradient;

when the brain wave signal is a fourth brain wave signal, controlling the sleep head ring to weaken the electric stimulation intensity to a second intensity preset value according to a preset gradient;

when the brain wave signals are the fifth brain wave signals, controlling the sleep head ring to be switched to the next piece of music;

and when the brain wave signals are the sixth brain wave signals, controlling the sleep head ring to be switched to the last music.

Optionally, the brain wave signal-based parameter adjustment method further includes:

and based on the sleep information of the user in the sleep program application recording period or the preset time, carrying out sleep-falling analysis according to the sleep information to generate a sleep report and a sleep interpretation result.

In addition, in order to achieve the above object, the present invention also provides a brain wave signal-based parameter adjustment system, including:

the sleep mode matching module is used for recommending a matched sleep mode to the user according to the current position data and the current time data of the user after the user is detected to wear the sleep head ring;

the brain wave acquisition module is used for controlling the sleep head loop to start the matched sleep mode, receiving a preset action of the user in the current sleep mode acquired by the sleep head loop, and acquiring a brain wave signal corresponding to the preset action;

and the sleep parameter adjusting module is used for controlling the sleep head ring to adjust the music switching, the volume or the electric stimulation intensity in the current sleep mode according to the brain wave signals.

In addition, to achieve the above object, the present invention further provides a terminal, wherein the terminal includes: the brain wave signal-based parameter adjusting method comprises a memory, a processor and a brain wave signal-based parameter adjusting program stored on the memory and capable of running on the processor, wherein the brain wave signal-based parameter adjusting program realizes the steps of the brain wave signal-based parameter adjusting method when being executed by the processor.

Further, in order to achieve the above object, the present invention also provides a computer-readable storage medium storing a brain wave signal-based parameter adjustment program which, when executed by a processor, implements the steps of the brain wave signal-based parameter adjustment method as described above.

In the invention, after detecting that a user wears a sleep head ring, recommending a matched sleep mode to the user according to the current position data and the current time data of the user; after the sleep head loop is controlled to start the matched sleep mode, receiving a preset action of a user in the current sleep mode, which is acquired by the sleep head loop, and acquiring a brain wave signal corresponding to the preset action; and controlling the sleep head ring to adjust the music switching, the volume or the electric stimulation intensity in the current sleep mode according to the brain wave signals. According to the invention, various parameters in the current sleep mode are adjusted by acquiring the brain wave signals corresponding to the preset actions made in the sleep process of the user, and the change of the various parameters in the current sleep mode can be realized without manually turning on the terminal again for adjustment by the user, so that the intelligentization is higher, and the quick sleep of the user is facilitated.

Drawings

FIG. 1 is a flow chart illustrating a method for adjusting brain wave signal-based parameters according to a preferred embodiment of the present invention;

FIG. 2 is a schematic diagram of four sleep mode display interfaces in the preferred embodiment of the method for adjusting parameters based on brain wave signals according to the present invention;

FIG. 3 is a schematic diagram of a sleep-aiding music display interface according to a preferred embodiment of the method for adjusting parameters based on brain wave signals;

FIG. 4 is a diagram illustrating a sleep onset analysis and sleep report generation interface according to a preferred embodiment of the method for adjusting parameters based on brain wave signals;

FIG. 5 is a schematic diagram of the sleep time and sleep duration interface in the sleep report according to the preferred embodiment of the method for adjusting parameters based on brain wave signals of the present invention;

FIG. 6 is a diagram illustrating a sleep interpretation result interface according to a preferred embodiment of the method for adjusting parameters based on brain wave signals;

FIG. 7 is a schematic block diagram of a preferred embodiment of the brain wave signal-based parameter adjustment system of the present invention;

fig. 8 is a diagram illustrating an operating environment of the terminal according to the preferred embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer and clearer, the present invention is further described in detail below with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

As shown in fig. 1, the method for adjusting parameters based on brain wave signals according to the preferred embodiment of the present invention includes the following steps:

and S10, after the fact that the user wears the sleep head ring is detected, recommending a matched sleep mode to the user according to the current position data and the current time data of the user.

In particular, the sleep headpiece is similar to an eye shield during sleep, e.g., a sleep eye shield worn in four sleep modes as in fig. 2; the sleep headband comprises a headband to secure the sleep headband on the head; the main machine is arranged on the inner side of the headband and is detachably connected with the headband; the sensing module is arranged on the host and used for detecting the wearing state of the sleep head ring and switching the working mode, and the sensing module comprises an infrared detection module and a gravity detection module and is used for collecting the wearing state information and the motion state information of the sleep head ring; the electrode belt is arranged on the inner side of the head belt, one surface of the electrode belt is connected with the host, and the other surface of the electrode belt is in contact with the head; the electrodes (three electrodes which are contacted with the forehead) are arranged on the electrode belt (hydrogel patches can be placed on the electrodes when the electrode belt is worn) and are contacted with the head, so that the electroencephalogram data can be acquired.

Before the step S10, the method further includes: when a sleep program application is started for the first time, the sleep head ring is added in the sleep program application to finish the binding operation of the sleep program application and the sleep head ring and establish the communication connection of the sleep program application and the sleep head ring.

Specifically, a sleep program application special for sleep is pre-installed in a terminal (for example, a mobile terminal, for example, an electronic device such as a smart phone and a tablet computer) of a user, when the sleep program application is started for the first time, the sleep head ring is added to the sleep program application, which is equivalent to completing the binding operation between the sleep program application and the sleep head ring, and establishing a communication connection (for example, a bluetooth connection) between the sleep program application and the sleep head ring, so that the two can perform information interaction conveniently; therefore, when the sleep head ring detects that the user wears the sleep head ring (i.e. the sleep head ring is in a wearing state) through the infrared detection module, the sleep head ring collects a wearing operation signal and sends the wearing operation signal to the sleep program application, which indicates that the user finishes wearing the sleep head ring.

The step S10 specifically includes:

s11, the sleep program application acquires current time data and current position data.

Specifically, the sleep program application is installed in the terminal, and the sleep program application acquires current position data of the user based on a positioning module (e.g., a GPS positioning module) in the terminal, and directly acquires current time data through the sleep program application (it is sufficient to acquire the time displayed by the terminal in real time).

And S12, matching the sleep modes corresponding to the time data and the position data in a pre-established sleep mode relation database, and recommending the corresponding sleep modes to a user.

As shown in fig. 2, the sleep mode includes: the sleep modes include a lightning sleep mode (i.e., lightning falling asleep in fig. 2), a deep sleep mode (i.e., deep sleep in fig. 2), a midday sleep mode (i.e., midday rest in fig. 2), and a traveling sleep mode (i.e., traveling sleep in fig. 2).

Further, the interface of the sleep program application in fig. 2 also displays the wearing start time (11) of the sleep head ring and the falling asleep time (the falling asleep time does not display a specific time in view of that the user has not fallen asleep yet), so that after the specific falling asleep time is displayed, the time taken by the user from the beginning of wearing the sleep head ring to falling asleep can be known, and the user can conveniently know the falling asleep time of the user.

Specifically, the corresponding relationship between the position data and the time data and the sleep mode needs to be preset to generate the sleep mode relationship database, that is, a sleep mode relationship database is generated in advance, so that the most suitable sleep mode can be obtained by matching according to the position data and the time data in the following. The preset corresponding relation between the position data and the time data and the sleep mode is as follows:

(1) Setting the user position at a home position (the home position can be a preset range, such as a square circle and one kilometer range for home address positioning), and setting the corresponding sleep mode as a deep sleep mode, wherein the time period is from 9 pm to 8 am; the position of the home is preset or updated according to the requirement of the user, and the time period can be modified, for example, from 10 pm to 7 am.

(2) Setting the user position at the office position (the office position can be a preset range, such as a square-round one-kilometer range for office address positioning) or the home position, and the time period is from 11 am to 3 pm, and setting the corresponding sleep mode as a midday sleep mode; the office location is preset or updated according to the user's requirement (the home location can also be preset or updated according to the user's requirement), and the time period can be modified, for example, to 12 pm to 2 pm.

(3) Setting the user position at a non-office position or a non-home position, setting the corresponding sleep mode as a travel sleep mode, wherein the time period is from 9 pm to 8 am; the time period may be modified, for example, to 11 pm to 7 am.

(4) And setting the user position at a non-office position or a non-home position, wherein the time period is from 9 pm to 8 am, and the corresponding sleep mode is set as a lightning sleep mode.

After the corresponding relationship between the position data, the time data, and the sleep mode is set, and the sleep mode relationship database is generated, according to the position data and the time data acquired in the step S11, the sleep mode corresponding to the position data and the time data is matched in the sleep mode relationship database, which specifically includes:

(1) And if the position data accords with the position of the user at home and the time data is between 9 pm and 8 am, the sleep mode matched according to the sleep mode relation database is a deep sleep mode.

(2) And if the position data accords with the position of the user in the office or the position of the home, and the time data is between 11 am and 3 pm, the sleep mode matched according to the sleep mode relation database is a midday sleep mode.

(3) And if the position data accords with the situation that the position of the user is in a non-office position or a non-home position, and the time data is between 9 pm and 8 am, the sleep mode matched according to the sleep mode relation database is a traveling sleep mode.

(4) And if the position data accords with the situation that the position of the user is in a non-office position or a non-home position and the time data is beyond 9 pm to 8 am, the sleep mode matched according to the sleep mode relation database is the lightning sleep mode.

Wherein the deep sleep mode, the midday sleep mode, the travel sleep mode, and the lightning sleep mode each include CES sleep aid and sound wave sleep aid (i.e., two modes of sleep aid); the CES sleep aid is used for adjusting brain-related structures or brain-related physiological parameters to assist sleep; the sound wave sleep aid is used for helping a user to quickly enter a sleep state through sound wave guidance. And the concrete regulating functions of CES sleep aid and sound wave sleep aid in different sleep modes are different, and the corresponding functions are set according to the characteristics of the sleep modes as follows:

(1) Deep sleep mode:

CES helps sleep and can directly regulate the sub-cortical structures and brain stem structures from cerebral cortical structures, thalamus, island leaves, hypothalamus and the like, relieve the stress and anxiety of insomnia people before sleep and improve the sleep quality.

The sound wave helps sleep by different sound waves with the frequency difference of 4hz, which are played by the left ear and the right ear, the brain is induced to automatically synthesize low-frequency infrasonic waves (Delta waves), the frequency range of brain waves is stimulated to be reduced, and the brain enters a deep sleep state more quickly.

(2) The noon sleeping mode:

CES is used for assisting sleep in the daytime, the brain wave frequency can be guided to slowly change into Alpha waveforms in the sleep period, and the brain state is favorable for eliminating anxiety and rumination and quickly recovering vitality.

The sound wave helps sleeping, and the brain can generate resonance to external monotonous and regular white noise, so that the brain is in a quiet and relatively inactive state, and the body and mind enter a rest mode.

(3) Travel sleep mode:

during the journey, CES helps sleeping to reduce the secretion of stress hormones such as epinephrine and cortisol, quickly improve physiological signals such as heart rate, blood pressure and muscle tension, and eliminate stress and tension.

The sound wave helps sleep, uses slow rhythm music of 60bpm, and the cooperation of soft volume can help the rhythm of the heart reduce, pacifies restless sympathetic nerve, lets the brain produce Alpha brain wave under the state of relaxing, falls asleep in joyful relaxation.

(4) A lightning sleep mode:

CES helps sleep and effectively stimulates the brain to secrete 5-hydroxytryptamine, y-aminobutyric acid, endorphin, norepinephrine and other sleep-related transmitters to increase, so that the brain can gather and sleeps quickly.

The sound wave helps the pilot to sleep, similar to a pilot's guidance of falling asleep quickly, the pilot is trained for any time in a short time. The sound wave guide realizes effective sleep aid for most pilots when the pilots fall asleep at places and extreme conditions, and helps the pilots to quickly enter a sleep state.

The CES sleep aid includes a plurality of gears (for example, ten gears are set), and the gears can be adjusted according to user needs, for example, a user presses a key on the sleep head ring to increase or decrease the gears.

Wherein, the sleep-aid music (BBT brain wave sleep-aid) is shown in the interface of fig. 3, including 6 Delta deep sleep waves, 4 Theta sleep waves and 3 Alpha relaxation waves, and other functions such as breathing exercise, pure music and hypnotic story can be selected in fig. 3.

The user can press the keys on the sleep head ring to switch music, the tone of music sound can be increased or decreased by pressing the volume adjusting button on the terminal, and the electrical stimulation intensity can be increased or decreased by pressing the electrical stimulation adjusting button on the terminal.

And S20, after the sleep head loop is controlled to start the matched sleep mode, receiving a preset action of the user in the current sleep mode, which is acquired by the sleep head loop, and acquiring a brain wave signal corresponding to the preset action.

When a user wears a sleep head ring and selects a sleep mode, if parameters (such as volume, electrical stimulation intensity and the like) in the current sleep mode need to be adjusted during sleep, the user can make a preset action and send brain wave signals corresponding to the preset action to the sleep head ring.

Specifically, after the sleep program application controls the sleep head ring to start the matched sleep mode, the user may send out a corresponding brain wave signal to the sleep head ring by making a preset action, where the preset action includes:

the user blinks 2 times in succession;

the user blinks 3 times in succession;

the user bites 1 time and for 2 seconds;

the user bites continuously 2 times and for 2 seconds;

the user bites 1 time and for 2 seconds and blinks 1 time;

the user bites 1 time and for 2 seconds and blinks 2 times;

it should be noted that the preset action may include a single action, such as: duration and number of consecutive bites, number of consecutive blinks, may also include combined actions such as: after biting for 2 seconds, the user quickly blinks N (N =1,2,3.) at the same time, blinks the teeth twice quickly, blinks or closes the eyes, and the like.

The preset actions can be freely set by the user according to the preference, and are not limited to the six preset actions, and each preset action uniquely corresponds to one brain wave signal.

Further, the receiving the preset action of the user in the current sleep mode, which is acquired by the sleep head loop, and acquiring the brain wave signal corresponding to the preset action includes:

when the preset action of the user is that the continuous blinking times of the user are 2, acquiring that the user blinks for 2 times continuously and corresponding to the first brain wave signal;

when the preset action of the user is that the continuous blinking times of the user are 3 times, the user blinks for 3 times continuously and corresponds to a second brain wave signal;

acquiring a third brain wave signal corresponding to the situation that when the preset action of the user is that the user bites for 1 time and the biting lasts for 2 seconds, the user bites for 1 time and the biting lasts for 2 seconds;

acquiring a fourth type of brain wave signal corresponding to the situation that when the preset action of the user is that the user bites for 2 times continuously and the biting lasts for 2 seconds, the user bites for 2 times continuously and the biting lasts for 2 seconds;

acquiring that the preset actions of the user are that the user bites for 1 time, the biting lasts for 2 seconds and blinks for 1 time, and the user bites for 1 time, the biting lasts for 2 seconds and blinks for 1 time correspond to a fifth type of brain wave signal;

and acquiring that the preset actions of the user are that the user bites for 1 time and the biting lasts for 2 seconds and blinks for 2 times, and the user bites for 1 time and the biting lasts for 2 seconds and blinks for 2 times correspond to a sixth type of electroencephalogram signals.

Each preset action corresponds to one brain wave signal uniquely, each brain wave signal correspondingly adjusts one parameter, the parameter can be volume, electrical stimulation intensity or music, and a user can set the brain wave signal in sleep program application according to self requirements and use habits.

And S30, controlling the sleep head ring to adjust music switching, volume or electroencephalogram stimulation intensity in the current sleep mode according to the electroencephalogram signals.

Parameters in the current sleep mode, including: the user can switch music by pressing the music switching key on the sleep head ring, can adjust the tone of music sound to be large or small by pressing the volume adjusting button on the terminal, can adjust the electrical stimulation intensity to be large or small by pressing the electrical stimulation adjusting button on the terminal, or can adjust parameters in the application of a sleep program on a mobile phone, but the action with larger activity amplitude can reduce the drowsiness of the user, and the user is not favorable for falling asleep quickly.

Further, the present invention also provides a method for controlling the sleep head loop to automatically adjust various current parameters, wherein the sleep head loop is controlled to automatically adjust the music switching, the volume or the strength of the brain electrical stimulation in the current sleep mode through the brain wave signal of the preset action of the user obtained in step S20.

Specifically, when the brain wave signals are first brain wave signals, the sleep head ring is controlled to increase the volume to a first volume preset value according to a preset gradient;

when the brain wave signals are second brain wave signals, controlling the sleep head ring to reduce the volume to a second volume preset value according to a preset gradient;

when the brain wave signal is a third brain wave signal, controlling the sleep head ring to strengthen the electric stimulation intensity to a first intensity preset value according to a preset gradient;

when the brain wave signal is a fourth brain wave signal, controlling the sleep head ring to weaken the electric stimulation intensity to a second intensity preset value according to a preset gradient;

when the brain wave signal is a fifth brain wave signal, controlling the sleep head ring to switch to the next piece of music;

and when the brain wave signals are the sixth brain wave signals, controlling the sleep head ring to be switched to the last music.

The first volume preset value and the second volume preset value are predefined volume sizes, the volume of the first volume preset value is larger than the second volume preset value, for example, the first volume preset value may be 60 db, the second volume preset value may be 40 db, only two music preset values, that is, two gradients, are set, in actual operation, more preset values may be divided as needed, and after the sleep head loop receives corresponding brain wave signals, the volume sizes are adjusted according to the gradients; the preset value of the electrical stimulation intensity is the same as the volume, and is not described again here.

Further, based on the sleep program application recording period (for example, a week) or the sleep information of the user within a preset time (for example, a day), a sleep-in analysis is performed according to the sleep information to generate a sleep report and a sleep interpretation result.

As shown in fig. 4, the sleep report is displayed as a sleep report of one day, a graph of the change of the brain state of the user with time is displayed in the interface of fig. 4, the shift of CES sleep aid displayed is 3, and sleep aid music is played for 2 minutes.

As shown in fig. 5, the sleep report is shown as a sleep report of one week (e.g., 11 months, 14 days-11 months, 20 days), and after the user uses the sleep head ring for one week, the sleep program application counts the sleep information of one week to generate a sleep report of one week.

As shown in fig. 6, a sleep interpretation result is generated by performing sleep onset analysis according to the sleep information, for example, the sleep interpretation result of the sleep program application interface includes sleep monitoring duration (including sleep onset time and sleep off time) and a sleep state, and a user can know sleep related data of the user according to the displayed sleep interpretation result, so as to adjust a sleep habit of the user according to the sleep data.

Further, as shown in fig. 7, based on the above-mentioned brain wave signal-based parameter adjustment method, the present invention also provides a brain wave signal-based parameter adjustment system, wherein the brain wave signal-based parameter adjustment system includes:

the sleep mode matching module 51 is configured to recommend a matching sleep mode to the user according to the current position data and the current time data of the user when the user wearing the sleep head ring is detected;

the brain wave acquisition module 52 is configured to control the sleep head loop to start the matched sleep mode, receive a preset action of the user in the current sleep mode acquired by the sleep head loop, and acquire a brain wave signal corresponding to the preset action;

and the sleep parameter adjusting module 53 is used for controlling the sleep head ring to adjust the music switching, the volume or the electric stimulation intensity in the current sleep mode according to the brain wave signals.

Further, as shown in fig. 8, based on the above-mentioned method and system for adjusting parameters based on brain wave signals, the present invention also provides a terminal, which includes a processor 10, a memory 20 and a display 30. Fig. 8 shows only some of the components of the terminal, but it should be understood that not all of the shown components are required to be implemented, and more or fewer components may be implemented instead.

The memory 20 may in some embodiments be an internal storage unit of the terminal, such as a hard disk or a memory of the terminal. The memory 20 may also be an external storage device of the terminal in other embodiments, such as a plug-in hard disk, a Smart Media Card (SMC), a Secure Digital (SD) Card, a Flash memory Card (Flash Card), and the like provided on the terminal. Further, the memory 20 may also include both an internal storage unit and an external storage device of the terminal. The memory 20 is used for storing application software installed in the terminal and various types of data, such as program codes of the installation terminal. The memory 20 may also be used to temporarily store data that has been output or is to be output. In one embodiment, the memory 20 stores a brain wave signal-based parameter adjustment program 40, and the brain wave signal-based parameter adjustment program 40 is executable by the processor 10, so as to implement the brain wave signal-based parameter adjustment method of the present application.

The processor 10 may be a Central Processing Unit (CPU), a microprocessor or other data Processing chip in some embodiments, and is used to run program codes stored in the memory 20 or process data, such as executing the brain wave signal-based parameter adjustment method.

The display 30 may be an LED display, a liquid crystal display, a touch-sensitive liquid crystal display, an OLED (Organic Light-Emitting Diode) touch panel, or the like in some embodiments. The display 30 is used for displaying information at the terminal and for displaying a visual user interface. The components 10-30 of the terminal communicate with each other via a system bus.

In one embodiment, when the processor 10 executes the brain wave signal-based parameter adjustment program 40 in the memory 20, the following steps are implemented:

after detecting that the user wears the sleep head ring, recommending a matched sleep mode to the user according to the current position data and the current time data of the user;

after the sleep head loop is controlled to start the matched sleep mode, receiving a preset action of a user in the current sleep mode, which is acquired by the sleep head loop, and acquiring a brain wave signal corresponding to the preset action;

and controlling the sleep head ring to adjust music switching, volume or electroencephalogram stimulation intensity in the current sleep mode according to the brain wave signals.

Optionally, the method for adjusting parameters based on brain wave signals, where after it is detected that a user wears a sleep head loop, recommending a matched sleep mode to the user according to the current position data and the current time data of the user, before further comprising:

when a sleep program application is started for the first time, adding the sleep head ring in the sleep program application to finish the binding operation of the sleep program application and the sleep head ring and establish the communication connection between the sleep program application and the sleep head ring;

wherein the sleep program application is pre-installed in the terminal.

Optionally, the method for adjusting parameters based on brain wave signals, where after it is detected that a user wears a sleep head loop, recommending a matched sleep mode to the user according to the current position data and the current time data of the user includes:

the sleep program application acquires current time data and current position data, matches sleep modes corresponding to the time data and the position data in a pre-established sleep mode relation database, and recommends the corresponding sleep modes to a user;

acquiring current position data of a user based on a positioning module in the terminal, and directly acquiring current time data of the terminal through the sleep program application;

wherein, the corresponding relation of time, position and sleep mode in the sleep mode relation database is preset by the user.

Optionally, the method for adjusting parameters based on brain wave signals, wherein the preset action includes:

the user blinks 2 times in succession;

the user blinks 3 times consecutively;

the user bites 1 time and for 2 seconds;

the user bites continuously for 2 times and for 2 seconds;

the user bites 1 time and for 2 seconds and blinks 1 time;

the user bites 1 time and for 2 seconds and blinks 2 times;

each preset action corresponds to one brain wave signal.

Optionally, the method for adjusting parameters based on brain wave signals, where the receiving of the preset action of the user in the current sleep mode, which is acquired by the sleep headring, and the acquiring of the brain wave signals corresponding to the preset action specifically includes:

when the preset action of the user is that the continuous blinking times of the user are 2 times, the user blinks for 2 times continuously and corresponds to the first brain wave signal;

when the preset action of the user is that the continuous blinking times of the user are 3 times, the user blinks for 3 times continuously and corresponds to a second brain wave signal;

acquiring a third brain wave signal corresponding to the situation that when the preset action of the user is that the user bites for 1 time and the biting lasts for 2 seconds, the user bites for 1 time and the biting lasts for 2 seconds;

acquiring a fourth type of brain wave signal corresponding to the situation that when the preset action of the user is that the user bites for 2 times continuously and the biting lasts for 2 seconds, the user bites for 2 times continuously and the biting lasts for 2 seconds;

acquiring that the preset actions of the user are that the user bites for 1 time, the biting lasts for 2 seconds and blinks for 1 time, and the user bites for 1 time, the biting lasts for 2 seconds and blinks for 1 time correspond to a fifth type of brain wave signal;

and acquiring that the preset actions of the user are that the user bites for 1 time and the biting lasts for 2 seconds and blinks for 2 times, and the user bites for 1 time and the biting lasts for 2 seconds and blinks for 2 times correspond to a sixth type of electroencephalogram signals.

Optionally, the method for adjusting parameters based on brain wave signals, wherein the controlling the sleep headring adjusts music switching, volume and intensity of electrical stimulation in a current sleep mode according to the brain wave signals specifically includes:

when the brain wave signal is a first brain wave signal, controlling the sleep head ring to increase the volume to a first volume preset value according to a preset gradient;

when the brain wave signals are second brain wave signals, controlling the sleep head ring to reduce the volume to a second volume preset value according to a preset gradient;

when the brain wave signal is a third brain wave signal, controlling the sleep head ring to strengthen the electric stimulation intensity to a first intensity preset value according to a preset gradient;

when the brain wave signal is a fourth brain wave signal, controlling the sleep head ring to weaken the electric stimulation intensity to a second intensity preset value according to a preset gradient;

when the brain wave signal is a fifth brain wave signal, controlling the sleep head ring to switch to the next piece of music;

and when the brain wave signals are the sixth brain wave signals, controlling the sleep head ring to be switched to the last music.

Optionally, the brain wave signal-based parameter adjustment method further includes:

and based on the sleep information of the user in the sleep program application recording period or the preset time, carrying out sleep-falling analysis according to the sleep information to generate a sleep report and a sleep interpretation result.

The present invention also provides a computer-readable storage medium, wherein the computer-readable storage medium stores a brain wave signal-based parameter adjustment program, which implements the steps of the brain wave signal-based parameter adjustment method as described above when executed by a processor.

In summary, the present invention provides a method for adjusting parameters based on brain wave signals and related equipment, the method comprising: after detecting that the user wears the sleep head ring, recommending a matched sleep mode to the user according to the current position data and the current time data of the user; after the sleep head loop is controlled to start the matched sleep mode, receiving a preset action of a user in the current sleep mode, which is acquired by the sleep head loop, and acquiring a brain wave signal corresponding to the preset action; and controlling the sleep head ring to adjust the music switching, the volume or the electric stimulation intensity in the current sleep mode according to the brain wave signals. According to the invention, various parameters in the current sleep mode are adjusted by acquiring the brain wave signals corresponding to the preset actions made in the sleep process of the user, and the change of the various parameters in the current sleep mode can be realized without manually turning on the terminal again by the user, so that the intelligentization is higher, and the quick sleep of the user is facilitated.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or terminal that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or terminal. Without further limitation, an element defined by the phrase "comprising a … …" does not exclude the presence of another identical element in a process, method, article, or terminal that comprises the element.

Of course, it will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by instructing relevant hardware (such as a processor, a controller, etc.) through a computer program, and the program can be stored in a computer readable storage medium, and when executed, the program can include the processes of the embodiments of the methods described above. The computer readable storage medium may be a memory, a magnetic disk, an optical disk, etc.

It is to be understood that the invention is not limited to the examples described above, but that modifications and variations may be effected thereto by those of ordinary skill in the art in light of the foregoing description, and that all such modifications and variations are intended to be within the scope of the invention as defined by the appended claims.

Claims (6)

1. A method for adjusting parameters based on brain wave signals, the method comprising:

after detecting that the user wears the sleep head ring, recommending a matched sleep mode to the user according to the current position data and the current time data of the user;

after detecting that the user wears the sleep head ring, recommending a matched sleep mode to the user according to the current position data and the current time data of the user, wherein the method also comprises the following steps:

when a sleep program application is started for the first time, adding the sleep head ring in the sleep program application to finish the binding operation of the sleep program application and the sleep head ring and establish the communication connection between the sleep program application and the sleep head ring; wherein the sleep program application is pre-installed in the terminal;

after the sleep head ring of the user is detected to be worn, recommending a matched sleep mode to the user according to the current position data and the current time data of the user, specifically comprising:

the sleep program application acquires current time data and current position data, matches sleep modes corresponding to the time data and the position data in a pre-established sleep mode relation database, and recommends the corresponding sleep modes to a user; acquiring current position data of a user based on a positioning module in the terminal, and directly acquiring current time data of the terminal through the sleep program application;

wherein, the corresponding relation of time, position and sleep mode in the sleep mode relation database is preset by the user; after the sleep head loop is controlled to start the matched sleep mode, receiving a preset action of a user in the current sleep mode, which is acquired by the sleep head loop, and acquiring a brain wave signal corresponding to the preset action;

the preset action comprises the following steps:

the user blinks 2 times in succession;

the user blinks 3 times consecutively;

the user bites 1 time and for 2 seconds;

the user bites continuously 2 times and for 2 seconds;

the user bites 1 time and for 2 seconds and blinks 1 time;

the user bites 1 time and for 2 seconds and blinks 2 times;

each preset action corresponds to a brain wave signal;

controlling the sleep head ring to adjust music switching, volume or electroencephalogram stimulation intensity in the current sleep mode according to the brain wave signals;

and based on the sleep information of the user in the sleep program application recording period or the preset time, carrying out sleep-falling analysis according to the sleep information to generate a sleep report and a sleep interpretation result.

2. The method for adjusting parameters based on brain wave signals according to claim 1, wherein the receiving the preset actions of the user in the current sleep mode acquired by the sleep headring and acquiring the brain wave signals corresponding to the preset actions specifically includes:

when the preset action of the user is that the continuous blinking times of the user are 2 times, the user blinks for 2 times continuously and corresponds to the first brain wave signal;

when the preset action of the user is that the continuous blinking times of the user are 3 times, the user blinks for 3 times continuously and corresponds to a second brain wave signal;

acquiring a third brain wave signal corresponding to the situation that when the preset action of the user is that the user bites for 1 time and the biting lasts for 2 seconds, the user bites for 1 time and the biting lasts for 2 seconds;

acquiring a fourth type of brain wave signal corresponding to the situation that when the preset action of the user is that the user bites for 2 times continuously and the biting lasts for 2 seconds, the user bites for 2 times continuously and the biting lasts for 2 seconds;

acquiring that the preset actions of the user are that the user bites for 1 time, the biting lasts for 2 seconds and blinks for 1 time, and the user bites for 1 time, the biting lasts for 2 seconds and blinks for 1 time correspond to a fifth type of brain wave signal;

and acquiring that the preset actions of the user are that the user bites for 1 time and the biting lasts for 2 seconds and blinks for 2 times, and the user bites for 1 time and the biting lasts for 2 seconds and blinks for 2 times correspond to a sixth type of electroencephalogram signals.

3. The method for adjusting parameters based on brain wave signals according to claim 2, wherein the controlling the sleep headring to adjust the music switch, the volume or the intensity of the electrical stimulation in the current sleep mode according to the brain wave signals specifically comprises:

when the brain wave signal is a first brain wave signal, controlling the sleep head ring to increase the volume to a first volume preset value according to a preset gradient;

when the brain wave signals are second brain wave signals, controlling the sleep head ring to reduce the volume to a second volume preset value according to a preset gradient;

when the brain wave signal is a third brain wave signal, controlling the sleep head ring to strengthen the electric stimulation intensity to a first intensity preset value according to a preset gradient;

when the brain wave signal is a fourth brain wave signal, controlling the sleep head ring to weaken the electric stimulation intensity to a second intensity preset value according to a preset gradient;

when the brain wave signal is a fifth brain wave signal, controlling the sleep head ring to switch to the next piece of music;

and when the brain wave signals are the sixth brain wave signals, controlling the sleep head ring to be switched to the last music.

4. A brain wave signal-based parameter adjustment system, comprising:

the sleep mode matching module is used for recommending a matched sleep mode to the user according to the current position data and the current time data of the user after the user is detected to wear the sleep head ring;

after the fact that the user wears the sleep head ring is detected, a matched sleep mode is recommended to the user according to the current position data and the current time data of the user, and the method also comprises the following steps:

when a sleep program application is started for the first time, adding the sleep head ring in the sleep program application to finish the binding operation of the sleep program application and the sleep head ring and establish the communication connection between the sleep program application and the sleep head ring; wherein the sleep program application is pre-installed in the terminal;

after the sleep head ring of the user is detected to be worn, recommending a matched sleep mode to the user according to the current position data and the current time data of the user, specifically comprising:

the sleep program application acquires current time data and current position data, matches sleep modes corresponding to the time data and the position data in a pre-established sleep mode relation database, and recommends the corresponding sleep modes to a user; acquiring current position data of a user based on a positioning module in the terminal, and directly acquiring current time data of the terminal through the sleep program application;

wherein, the corresponding relation of time, position and sleep mode in the sleep mode relation database is preset by the user; the brain wave acquisition module is used for receiving the preset action of the user in the current sleep mode acquired by the sleep head loop after controlling the sleep head loop to start the matched sleep mode and acquiring a brain wave signal corresponding to the preset action;

the preset action comprises the following steps:

the user blinks 2 times in succession;

the user blinks 3 times consecutively;

the user bites 1 time and for 2 seconds;

the user bites continuously 2 times and for 2 seconds;

the user bites 1 time and for 2 seconds and blinks 1 time;

the user bites 1 time and for 2 seconds and blinks 2 times;

each preset action corresponds to a brain wave signal;

the sleep parameter adjusting module is used for controlling the sleep head ring to adjust music switching, volume or electric stimulation intensity in the current sleep mode according to the brain wave signals;

and based on the sleep information of the user in the sleep program application recording period or the preset time, carrying out sleep-falling analysis according to the sleep information to generate a sleep report and a sleep interpretation result.

5. A terminal, characterized in that the terminal comprises: a memory, a processor and a brain wave signal-based parameter adjustment program stored on the memory and executable on the processor, the brain wave signal-based parameter adjustment program implementing the steps of the brain wave signal-based parameter adjustment method according to any one of claims 1 to 3 when executed by the processor.

6. A computer-readable storage medium, characterized in that the computer-readable storage medium stores a brain wave signal-based parameter adjustment program which, when executed by a processor, implements the steps of the brain wave signal-based parameter adjustment method according to any one of claims 1 to 3.

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