CN113577499A

CN113577499A - Sleep-aiding system

Info

Publication number: CN113577499A
Application number: CN202110836116.9A
Authority: CN
Inventors: 钟建华; 方燕红; 于文军; 王春生; 甘艳; 钟勤香
Original assignee: Individual
Current assignee: Jian College
Priority date: 2021-07-23
Filing date: 2021-07-23
Publication date: 2021-11-02
Anticipated expiration: 2041-07-23
Also published as: CN113577499B

Abstract

The invention discloses a sleep-aiding system which can help a user to sleep as soon as possible through sleep-aiding music, and the playing speed of the sleep-aiding music of the user in different sleep states is different, so that the user has the most appropriate playing speed of the sleep-aiding music in different sleep states. The invention can help the user to sleep as soon as possible so as to solve the problem of anxiety and insomnia of the user.

Description

Sleep-aiding system

Technical Field

The invention relates to a sleep-aiding system.

Background

As people know, one third of the life of a person is spent on sleeping, so that the sleeping plays a crucial role in our lives, i sleep most easily in the period of children, people are used to sleep late and insomnia is a common thing along with the rapid progress of social networks after the people grow up because of no more worries, and how to solve the sleeping problem of modern people is a problem to be solved at present.

Disclosure of Invention

The invention aims to provide a sleep-assisting system which can help a user to sleep as soon as possible so as to solve the problem of anxiety and insomnia of the user.

In order to solve the above technical problem, the sleep-aiding system provided by the present invention comprises:

a processor;

the storage module is electrically connected with the processor and used for storing the sleep-aiding music;

the playing module is electrically connected with the processor and is used for playing the sleep-aiding music;

the adjusting module is electrically connected with the processor and used for adjusting the playing speed of the playing module for playing the sleep-aiding music;

the first detection module is electrically connected with the processor and used for detecting the hand motion state of the user to acquire first sleep state information;

the second detection module is electrically connected with the processor and used for detecting the brain wave frequency of the user to acquire second sleep state information, and the first sleep information and the second sleep information are combined to determine that the user is in a wakeful state, a light sleep state or a deep sleep state;

the control module is electrically connected with the processor and used for being controlled by a user when the user is ready to sleep to send an instruction to the processor so that the processor enters a working mode, then the processor controls the playing module to play the sleep-aiding music in the storage module in sequence, at the moment, the user can adjust the playing speed of the sleep-aiding music through the adjusting module, the playing speed of the sleep-aiding music after the completion of the adjustment is A, and when the user is in a waking state, the playing speed of the sleep-aiding music is controlled by the processor to be A all the time; when the user enters a light sleep state, the processor controls the playing speed of the sleep-aid music to be B, wherein A is greater than B; when the user enters a deep sleep state, the processor controls the playing speed of the sleep-aid music to be gradually reduced from B to 0.

Preferably, the first detection module is an acceleration sensor.

Preferably, after the user sleeps, if the acceleration sensor detects that the hand of the user moves and the single movement amplitude is greater than or equal to the preset value C, the first sleep state information indicates that the user is in a waking state within a certain time period after the situation occurs; if the acceleration sensor detects that the hand of the user moves and the single movement amplitude is smaller than the preset value C, the first sleep state information means that the user is in a light sleep state within a certain time period after the situation occurs; if the acceleration sensor detects that the hands of the user do not move within a certain time span, the first sleep state information indicates that the user is in a deep sleep state.

Preferably, the second detection module is a brain wave sensor.

Preferably, after the user sleeps, if the brain wave frequency detected by the brain wave sensor is greater than or equal to D, the second sleep state information indicates that the user is in a waking state; if the brain wave sensor detects that the brain wave frequency of the user is greater than or equal to E and smaller than D, the second sleep state information means that the user is in a light sleep state; if the brain wave sensor detects that the brain wave frequency of the user is greater than or equal to F and smaller than E, the second sleep state information means that the user is in a deep sleep state;

when the first sleep state information and the second sleep state information both indicate that the user is currently in the waking state, determining that the user is currently in the waking state;

when the first sleep state information and the second sleep state information both indicate that the user is currently in the shallow sleep state, determining that the user is currently in the shallow sleep state;

when the first sleep state information and the second sleep state information both indicate that the user is currently in a waking state, determining that the user is currently in a light sleep state;

when the current state of the user indicated by the first sleep state information is different from the current state of the user indicated by the second sleep state information, acquiring the time length X for the processor to enter the working mode at this time, and if the X is smaller than a preset value Y, taking the first sleep state information as the current state of the user; and if the X is larger than or equal to the preset value Y, taking the second sleep state information as the current state of the user.

Preferably, the sleep-assisting system further comprises:

and the third detection module is electrically connected with the processor and used for detecting the heart rate of the user to acquire third sleep state information.

Preferably, the third detection module is a heart rate sensor.

Preferably, when the user prepares to sleep, the control module sends an instruction to the processor to enable the processor to enter the working mode, the heart rate sensor acquires the current heart rate of the user as U1, when the user enters a light sleep state, the heart rate sensor acquires the real-time heart rate of the user as U2, and the playing speed B of the sleep-aid music when the user is in the light sleep state is changed in real time, wherein the instruction is sent to the processor by the control module, so that the processor enters the working mode, and the playing speed B of the sleep-aid music when the user is in the light sleep state is changed in real time, and the user is in the sleep-aid music playing mode when the user is in the light sleep state

After adopting the structure, compared with the prior art, the invention has the following advantages:

the sleep-aiding system can help the user to sleep as soon as possible through the sleep-aiding music, and the playing speed of the sleep-aiding music is different when the user is in different sleep states, so that the user has the most appropriate playing speed of the sleep-aiding music in different sleep states, and the user can be better helped to fall asleep as soon as possible.

Drawings

Fig. 1 is a schematic structural view of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

As shown in fig. 1, the sleep-aiding system of the present invention includes a processor, a storage module, a playing module, an adjusting module, a first detecting module, a second detecting module, a control module, a communication module, a power module, and a third detecting module.

The power module is used for supplying power for other modules.

The storage module is electrically connected with the processor and used for storing the sleep-aiding music, the storage module is provided with a plurality of sleep-aiding music, when the sleep-aiding music is played, the sleep-aiding music is played from the first head in sequence, and when the last music is played, the sleep-aiding music is played from the first head again.

The communication module is used for being in communication connection with the intelligent terminal, so that the intelligent terminal can transmit the sleep-assisting music to the storage module for storage, and a user can conveniently select the favorite sleep-assisting music.

The playing module is electrically connected with the processor and is used for playing the sleep-aiding music.

The adjusting module is electrically connected with the processor and is used for adjusting the playing speed of the playing module for playing the sleep-aiding music.

The first detection module is electrically connected with the processor and used for detecting the hand motion state of the user to acquire first sleep state information.

The second detection module is electrically connected with the processor and is used for detecting the brain wave frequency of the user to acquire second sleep state information, and the first sleep information and the second sleep information are combined to determine the current sleep state of the user, wherein the sleep state comprises a waking state, a light sleep state and a deep sleep state.

The control module is electrically connected with the processor, the control module has a touch function, when a user prepares to sleep, touch operation is carried out through the control module, so that an instruction is sent to the processor to enable the processor to enter a working mode, then the processor controls the playing module to play the sleep-aiding music in the storage module in sequence, at the moment, the user can adjust the playing speed of the sleep-aiding music through the adjusting module, and the playing speed of the sleep-aiding music after the completion of the adjustment is A, so that the user can adjust the current playing speed of the sleep-aiding music to a state suitable for the user, of course, the user can not adjust the playing speed of the sleep-aiding music at the moment, and at the moment, the sleep-aiding music is played at a default playing speed;

when the user is in a waking state, the processor controls the playing speed of the sleep-aiding music to be A all the time; when the user enters a light sleep state, the processor controls the playing speed of the sleep-assisting music to be B, wherein A is greater than B, so that after the user enters the light sleep state, the playing speed of the sleep-assisting music is reduced by the processor, and the user can be better guided to enter a deep sleep state; when the user enters the deep sleep state, the processor controls the playing speed of the sleep-aid music to be gradually reduced from B to 0, so that after the user enters the deep sleep state, the playing speed of the sleep-aid music is gradually reduced until the sleep-aid music stops playing, rather than directly stopping the sleep-aid music, and therefore the user in the deep sleep state can more easily continue the current sleep state, and the deep sleep state of the user can be more easily maintained.

After the user enters deep sleep, the playing speed of the sleep-aiding music is gradually reduced from B to 0, so that the sleep-aiding music stops playing, and therefore the sleep-aiding music cannot be started again at night in the same day, and the sleep-aiding music cannot be played again when the user wakes up in the middle of the night.

Whether the user is in the awake state, the light sleep state, or the deep sleep state can be judged by combining the first sleep information and the second sleep information.

First detection module be acceleration sensor, acceleration sensor sets up on the bracelet, the bracelet cover is put on user's wrist.

After the user sleeps, if the acceleration sensor detects that the hand of the user moves and the single movement amplitude is larger than or equal to the preset value C, the first sleep state information indicates that the user is in a waking state within a certain time period after the situation occurs, wherein the certain time period can be 5 minutes, the acceleration sensor does not detect when the user is judged to be in the waking state, and the acceleration sensor restarts to detect until the certain time period is finished;

if the acceleration sensor detects that the hand of the user moves and the single movement amplitude is smaller than the preset value C, the first sleep state information indicates that the user is in a light sleep state within a certain time period after the situation occurs, wherein the certain time period can be 10 minutes, the acceleration sensor does not detect when the user is judged to be in the light sleep state, and the acceleration sensor restarts to detect until the certain time period is over;

if the acceleration sensor detects that the hand of the user does not move within the time length of 15 minutes, the first sleep state information indicates that the user is in a deep sleep state, the deep sleep state is confirmed after the time length of 15 minutes is reached, and then the user is in the deep sleep state until the acceleration sensor detects that the hand of the user moves, so that the sleep state of the user is not changed.

The second detection module is a brain wave sensor, the brain wave sensor is arranged on a head ring, and the head ring is worn on the head of a user.

After the user sleeps, if the brain wave frequency of the user detected by the brain wave sensor is greater than or equal to D, the second sleep state information means that the user is in a waking state; if the brain wave sensor detects that the brain wave frequency of the user is greater than or equal to E and smaller than D, the second sleep state information means that the user is in a light sleep state; if the brain wave sensor detects that the brain wave frequency of the user is greater than or equal to F and smaller than E, the second sleep state information indicates that the user is in a deep sleep state, and therefore the sleep state of the user can be judged according to the brain wave frequency.

When the first sleep state information and the second sleep state information both indicate that the user is currently in the awake state, it is determined that the user is currently in the awake state.

And when the first sleep state information and the second sleep state information both indicate that the user is currently in the light sleep state, determining that the user is currently in the light sleep state.

When the first sleep state information and the second sleep state information both indicate that the user is currently in the awake state, it is determined that the user is currently in the shallow sleep state.

When the current state of the user indicated by the first sleep state information is different from the current state of the user indicated by the second sleep state information, acquiring the time length X of the processor entering the working mode at this time, wherein the longer the X is, the longer the time length for the user to prepare for sleeping is, and if the X is smaller than a preset value Y, taking the first sleep state information as the current state of the user; if X is larger than or equal to the preset value Y, the second sleep state information is used as the current state of the user, so that if the time for the user to prepare for sleeping is short, the hand movement state is used as the judgment basis of the sleep state, and the judgment result can be more accurate; if the time for the user to prepare for sleeping is long, the electroencephalogram frequency is used as the judgment basis of the sleeping state, so that the judgment result is more accurate.

The third detection module is electrically connected with the processor, the third detection module is used for detecting the heart rate of the user to acquire third sleep state information, and the third sleep state information refers to the heart rate of the user during sleep.

The third detection module be heart rate sensor, heart rate sensor sets up on the bracelet, the bracelet is worn on user's wrist.

When a user prepares to sleep, the control module sends an instruction to the processor to enable the processor to enter a working mode, the heart rate sensor acquires the current heart rate of the user as U1, when the user enters a light sleep state, the heart rate sensor acquires the real-time heart rate of the user as U2, namely U2 changes in real time, and the playing speed B of the sleep-assisting music when the user is in the light sleep state changes in real time, wherein the playing speed B of the sleep-assisting music is changed in real time

Therefore, the user is easy to be awakened when in the light sleep state, and the playing speed of the sleep-aiding music is matched with the heart rate in real time when the user is in the light sleep state, so that the sleep-aiding music can better adapt to the physical state of the user and better help the user to enter the deep sleep state as soon as possible.

The above description is only about the preferred embodiment of the present invention, but it should not be understood as limiting the claims, and the present invention may be modified in other structures, not limited to the above structures. In general, all changes which come within the scope of the invention as defined by the independent claims are intended to be embraced therein.

Claims

1. A sleep-aid system, comprising:

a processor;

2. A sleep-aid system according to claim 1, wherein said first detection module is an acceleration sensor.

3. The sleep-aid system according to claim 2, wherein when the user sleeps, if the acceleration sensor detects that the hand of the user moves and the single movement amplitude is greater than or equal to the preset value C, the first sleep state information indicates that the user is awake for a certain period of time after the situation occurs; if the acceleration sensor detects that the hand of the user moves and the single movement amplitude is smaller than the preset value C, the first sleep state information means that the user is in a light sleep state within a certain time period after the situation occurs; if the acceleration sensor detects that the hands of the user do not move within a certain time span, the first sleep state information indicates that the user is in a deep sleep state.

4. The sleep-aid system according to claim 3, wherein the second detecting module is a brain wave sensor.

5. The sleep-aid system according to claim 4, wherein the second sleep state information is that the user is in a waking state if the brain wave sensor detects that the brain wave frequency of the user is greater than or equal to D after the user sleeps; if the brain wave sensor detects that the brain wave frequency of the user is greater than or equal to E and smaller than D, the second sleep state information means that the user is in a light sleep state; if the brain wave sensor detects that the brain wave frequency of the user is greater than or equal to F and smaller than E, the second sleep state information means that the user is in a deep sleep state;

6. A sleep aid system according to claim 5, wherein said sleep aid system further comprises:

7. A sleep aid system according to claim 6, wherein the third detection module is a heart rate sensor.

8. The sleep-aid system according to claim 7, wherein when the user is ready to sleep, the control module sends an instruction to the processor to make the processor enter the working mode, the heart rate sensor obtains the current heart rate of the user as U1, when the user enters the light sleep state, the heart rate sensor obtains the real-time heart rate of the user as U2, and the playing speed B of the sleep-aid music when the user is in the light sleep state is changed in real time, wherein