CN112401842A - Sleep quality monitoring system, method and device and mobile equipment - Google Patents

Abstract

The invention discloses a sleep quality monitoring system, method and device and mobile equipment, and belongs to the field of intelligent equipment and health monitoring. According to the invention, the body parameters used for indicating the body state of the user and the environment parameters used for indicating the environment where the user is located are monitored in the sleeping process of the user, so that the sleeping process is more comprehensively monitored, and the accuracy of sleeping monitoring is ensured.

Description

Sleep quality monitoring system, method and device and mobile equipment

Technical Field

The invention relates to the field of intelligent equipment and health monitoring, in particular to a sleep quality monitoring system, method and device and mobile equipment.

Background

The sleep quality is one of the signs for measuring whether the human body is healthy, and with the continuous development of intelligent equipment and human body monitoring technology, people can monitor the sleep process.

The sleep quality monitoring provided by the related art is to monitor the sleep quality of a user through a wearable device, and further, monitor a heart rate parameter of the user after the user enters sleep to verify the sleep quality of the user.

However, the heartbeat is only used for representing the heart state of the user in the sleep state, and factors influencing the sleep quality of the user are numerous, and the sleep quality of the user cannot be accurately monitored only by the heart rate.

Disclosure of Invention

In order to solve the problems in the prior art, embodiments of the present invention provide a sleep quality monitoring system, method, apparatus, and mobile device. The technical scheme is as follows:

in a first aspect, a sleep quality monitoring system is provided, the system comprising a sleep monitoring device, an environment monitoring device, a human body monitoring device and a mobile device; wherein:

when a user is in a sleep state, the environment monitoring device acquires the environment parameters of the environment where the user is located in real time;

the human body monitoring device acquires the body parameters of a user in real time;

the sleep monitoring device monitors the sleep quality of the user according to the environmental parameters and the physical parameters and calculates the sleep quality parameters;

the mobile device displaying a sleep quality parameter of a user, the environmental parameter, and the physical parameter;

the environmental parameters include one or more of temperature, humidity, air quality, light intensity, and noise intensity, and the physical parameters include one or more of heartbeat, breathing parameters, body movement parameters, and snoring time.

In a second aspect, a sleep quality monitoring method is provided, including:

when a user is in a sleep state, acquiring environmental parameters of the environment where the user is located and body parameters of the user in real time;

monitoring the sleep quality of the user according to the environmental parameters and the physical parameters, and calculating the sleep quality parameters;

the environmental parameters include one or more of temperature, humidity, air quality, light intensity, and noise intensity, and the physical parameters include one or more of heartbeat, breathing parameters, body movement parameters, and snoring time.

In a third aspect, a sleep quality monitoring device is provided, comprising:

the first acquisition module is used for acquiring the environmental parameters of the environment where the user is located in real time when the user is in a sleep state;

the second acquisition module is used for acquiring the body parameters of the user in real time;

the monitoring module is used for monitoring the sleep quality of the user according to the environmental parameters and the body parameters and calculating the sleep quality parameters;

the environmental parameters include one or more of temperature, humidity, air quality, light intensity, and noise intensity, and the physical parameters include one or more of heartbeat, breathing parameters, body movement parameters, and snoring time.

In a fourth aspect, a mobile device is provided, comprising:

the acquisition module is used for acquiring the environmental parameters of the environment where the user is located and the body parameters of the user in real time;

a display module for displaying the environmental parameter and the physical parameter;

the environmental parameters include one or more of temperature, humidity, air quality, light intensity, and noise intensity, and the physical parameters include one or more of heartbeat, breathing parameters, body movement parameters, and snoring time.

The embodiment of the invention provides a sleep quality monitoring system, a method, a device and mobile equipment, wherein the system comprises a sleep monitoring device, an environment monitoring device, a human body monitoring device and the mobile equipment; wherein: when a user is in a sleep state, the environment monitoring device acquires the environment parameters of the environment where the user is located in real time; the human body monitoring device acquires the body parameters of a user in real time; the sleep monitoring device monitors the sleep quality of the user according to the environmental parameters and the physical parameters and calculates the sleep quality parameters; the mobile device displays the sleep quality parameters, the environmental parameters and the body parameters of the user; the environmental parameters include temperature, humidity, air quality, illumination intensity and noise intensity, and the physical parameters include heartbeat, breathing parameters, body movement parameters and snoring time.

The technical scheme provided by the embodiment of the invention has the following beneficial effects:

1. the body parameters used for indicating the body state of the user and the environment parameters used for indicating the environment where the user is located are monitored in the sleeping process of the user, so that the user can monitor the sleeping process more comprehensively, and the accuracy of sleeping monitoring is guaranteed.

2. The sleep quality parameters are used for monitoring the sleep of the user, so that the user can know the sleep quality more intuitively.

Drawings

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

Fig. 1 is a schematic diagram of a sleep quality monitoring system according to an embodiment of the present invention;

fig. 2 is a schematic diagram of a sleep quality monitoring system according to an embodiment of the present invention;

fig. 3 is a flowchart of a sleep quality monitoring method according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a sleep quality monitoring apparatus according to an embodiment of the present invention;

fig. 5 is a schematic structural diagram of a mobile device according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example one

The embodiment of the invention provides a sleep quality monitoring system, which is shown in figure 1 and comprises a sleep monitoring device, an environment monitoring device, a human body monitoring device and mobile equipment; in practical applications, the environment monitoring device may include a temperature sensor, a humidity sensor, an air quality sensor, an illumination sensor, and a noise sensor; the air quality sensor can be integrated by a plurality of sensors capable of detecting harmful gases in the air, wherein the harmful gases can be sulfur dioxide, carbon monoxide, nitrogen dioxide, inhalable particles and the like; the human body monitoring device comprises a heart rate sensor, respiration monitoring equipment, a snore detecting device for snore detection and a pressure sensor arranged on a bed body where a user is located; correspondingly, the environmental parameter includes one or more of temperature, humidity, air quality, illumination intensity and noise intensity; the physical parameters include one or more of heartbeat, breathing parameters, body movement parameters, and snoring time.

In another preferred embodiment, referring to fig. 2, the human body monitoring device according to the embodiment of the present invention may further include a ceramic pressure sensor disposed on the bed, and the heartbeat, the breathing parameter, the body movement parameter, and the snoring time are calculated from pressure values detected by the ceramic pressure sensor.

The system specifically comprises:

when a user is in a sleep state, the environment monitoring device acquires the environment parameters of the environment where the user is located in real time; the process may specifically be:

the temperature sensor monitors the temperature of the environment where the user is located in real time;

the humidity sensor monitors the humidity of the environment where the user is located in real time;

the air quality sensor monitors the air quality of the environment where the user is located in real time, wherein the air quality can be the concentration of sulfur dioxide, carbon monoxide, nitrogen dioxide and inhalable particles;

the illumination sensor monitors the illumination intensity of the environment where the user is located in real time;

the noise sensor monitors the noise intensity of the environment where the user is located in real time;

the sensors respectively transmit the environmental parameters to the sleep monitoring device after monitoring the corresponding environmental parameters.

Optionally, in practical application, in order to save cost and further facilitate use of a user, the environmental parameters may also be obtained by other devices, specifically:

the sleep monitoring device acquires the environmental parameters sent by other servers or equipment, and the other servers or other equipment comprise equipment which can acquire the environmental parameters and realize the receiving and sending of the environmental parameters, such as home environment monitoring equipment in an intelligent home or air conditioners and other equipment, so that the acquisition of the environmental parameters can be realized without installing additional equipment, and meanwhile, home equipment installed by a user is fully utilized, so that the cost is saved, and the use of the user is further facilitated.

The human body monitoring device acquires the body parameters of a user in real time; the process may specifically be:

the heart rate sensor monitors the heartbeat of a user in real time;

the respiration monitoring equipment is used for monitoring the respiration parameters of the user in real time;

the pressure sensor is used for monitoring the body motion parameters of the user in real time, and in practical application, the body motion times can be the body motion frequency and the body motion intensity of the user; when a user shakes the bed body due to body movement, the pressure sensor monitors the pressure change of the bed body in the shaking process, and records the pressure change value and the pressure change frequency, wherein the pressure change value is the body movement intensity, and the pressure change frequency is the body movement frequency;

the snore detecting device monitors the snore intensity and the snore duration time of a user in real time;

the sensors respectively transmit the body parameters to the sleep monitoring device after monitoring the corresponding body parameters.

In another preferred embodiment, the human body monitoring device is a ceramic pressure sensor disposed on the bed body, the heartbeat, the breathing parameter, the body movement parameter and the snoring time are calculated by pressure values detected by the ceramic pressure sensor, and the process may specifically be:

the ceramic pressure sensor acquires pressure parameters of the bed body in real time according to a sampling period, wherein the pressure parameters can be specifically measured values of the ceramic pressure sensor, and the measured values reflect vibration of the bed body in the sampling period and frequency and amplitude of the vibration;

in practical application, in order to accurately reflect the real vibration condition of the bed body, the sampling period may be any value between 100ms and 150ms, further, in order to improve accuracy, the sampling period may also be any value between 200ms and 300ms, and after sampling is completed, the measurement value in one-half period of the sampling period is selected as the pressure parameter.

The sleep monitoring device calculates the physical parameters according to the pressure parameters, and the process can be specifically as follows:

splitting the pressure parameter according to different frequencies to obtain a plurality of sub-pressure parameters in different frequency ranges, wherein the splitting process can be completed through Fourier transform or fast Fourier transform; for example, in practical applications, the different frequency ranges may be a first range, a second range, and a third range; the first frequency range may be 1hz to 8hz, the second frequency range may be 8hz to 20hz, and the third frequency range may be 60hz to 120 hz; the first frequency range is used for indicating the bed body vibration in the breathing process of a user, the second frequency range is used for indicating the bed body vibration in the heartbeat process of the user, and the third frequency range is used for indicating the bed body vibration in the snoring process of the user.

The method comprises the following steps of performing secondary splitting on a plurality of sub-pressure parameters in different frequency ranges to obtain a plurality of pressure parameters in different sub-frequency ranges, wherein the splitting process can be completed through Fourier transform or fast Fourier transform, and the process specifically comprises the following steps:

splitting the pressure parameter in the first frequency range to obtain the pressure parameter in a first sub-frequency range, wherein the first sub-frequency range can be 0.1hz to 1 hz;

splitting the pressure parameter in the second frequency range to obtain the pressure parameter in a second sub-frequency range, wherein the second sub-frequency range can be 0.1hz to 1 hz;

splitting the pressure parameter in the third frequency range to obtain the pressure parameter in a third sub-frequency range, wherein the third sub-frequency range can be 0.5hz to 2 hz;

calculating the body parameter according to a plurality of pressure parameters in different sub-frequency ranges, wherein the process can be as follows:

calculating the breath of the user according to the pressure parameter in the first sub-frequency range, and further calculating the breath frequency of the user according to the pressure parameter in the first sub-frequency range;

calculating the heartbeat of the user according to the pressure parameter in the second sub-frequency range, and further calculating the heartbeat frequency of the user according to the pressure parameter in the second sub-frequency range;

and calculating the snoring of the user according to the pressure parameter in the third sub-frequency range, and further calculating the snoring frequency of the user according to the pressure parameter in the third sub-frequency range.

The sleep monitoring device can calculate the body movement according to the pressure parameters, and the process of calculating the body movement can be as follows:

and calculating the frequency when the peak value of the pressure parameter is greater than a preset value in the sampling period of the ceramic pressure sensor, wherein the frequency is the body movement frequency of the user, and recording the pressure parameter.

In practical application, the physical parameter may be measured by a heart rate sensor, a respiration monitoring device, a snore detecting device for detecting snore, a pressure sensor arranged on a bed body where a user is located, or calculated by a pressure value detected by a ceramic pressure sensor arranged on the bed body.

The body parameters are calculated by the pressure values detected by the ceramic pressure sensors arranged on the bed body, so that special equipment such as a heart rate sensor, a respiration monitoring device, a snore detecting device for snore detection and a pressure sensor arranged on the bed body where the user is located are not required to be additionally installed, the space and the cost are saved, and the use of the user is further facilitated.

The sleep monitoring device monitors the sleep quality of the user according to the environmental parameters and the physical parameters and calculates the sleep quality parameters; the process may be:

the sleep monitoring device acquires the environmental parameters transmitted by the environmental monitoring device and the body parameters transmitted by the human body monitoring device in real time, and calculates the sleep quality parameters according to the environmental parameters and the body parameters, wherein the calculation process can specifically be as follows:

the sleep monitoring device calculates a plurality of sleep stages according to the body parameters; the sleep stages may be a wake stage, a light sleep stage, a deep sleep stage, and a REM (Rapid Eye Movement) sleep stage, and the process may specifically be:

if the frequency of continuously monitoring the pressure parameter to be greater than the preset value in the preset period is greater than or equal to the frequency threshold value, frequently exercising by the user and confirming that the user is in the awakening stage;

if the user is not in the awakening stage within the preset time, confirming that the user is in the light sleep stage; or

If the user is in deep sleep and the frequency of continuously monitoring the pressure parameter to be greater than the preset value in the preset period is greater than or equal to the frequency threshold value, determining that the user is in a light sleep stage;

if the user is in a light sleep stage, the frequency that the pressure parameter is not monitored to be larger than the preset value in the preset period is larger than or equal to the frequency threshold value, and the heartbeat of the user is lower than the average value, the user is confirmed to be in a deep sleep stage; or

If the user is in REM sleep and the heartbeat is continuously decreased for a plurality of times (two or more times) within the monitoring time and is lower than the average value, confirming that the user is in a deep sleep stage;

and if the user is in the deep sleep stage and the heartbeat continuously rises above the average value for multiple times within the monitoring time, confirming that the user is in the deep sleep stage.

The sleep monitoring device calculates the sleep quality parameter according to the plurality of sleep stages and the weight coefficients corresponding to the plurality of sleep stages, and the process may specifically be:

setting the weight coefficient of a wake-up stage as a%, setting the weight coefficient of a light sleep stage as b%, setting the weight coefficient of a deep sleep stage as c%, setting the weight coefficient of REM sleep as d%, wherein:

a+b+c+d=100；

for a calculation period, the calculation formula of the sleep quality parameter is as follows:

sleep quality parameter = (wake stage time · a% + light sleep stage time × + b% + deep sleep stage × c% + REM sleep × d%)/count cycle;

since the user quality is affected by snoring in the snoring process, in order to further improve the accuracy of sleep quality monitoring, the process of calculating the sleep quality parameters may further include:

setting the weight coefficient of the snoring time as e%, wherein:

a+b+c+d+e=100；

for a calculation period, the calculation formula of the sleep quality parameter is as follows:

sleep quality parameter = (wake-up stage time · a% + light sleep stage time · b% + deep sleep stage · c% + REM sleep · d% + snore time = e%)/calculation period;

the above process of calculating the sleep quality parameter is only exemplary, and in practical applications, the calculation of the sleep quality parameter may also be implemented by other manners, and the specific calculation manner is not limited in the embodiment of the present invention.

It should be noted that, the above-mentioned sleep quality parameter calculation process may also be performed by the mobile device, and the process may be:

the sleep monitoring device sends the environmental parameters and the physical parameters to the mobile equipment;

the mobile device calculates the sleep quality parameter according to the environmental parameter and the physical parameter, and the calculation process is the same as that of the sleep monitoring device, and is not described herein again.

Through the sleep quality parameters, the quality of the user in the sleep process is comprehensively monitored, the user can conveniently know the sleep quality, and therefore the user experience is further improved. In addition, because the sleep quality of the wake-up stage, the light sleep stage, the deep sleep stage and the REM sleep is different, the sleep process of the user can be finely monitored through the stages, and the accuracy of the sleep quality monitoring is further improved.

The sleep monitoring device sends the environmental parameters, the body parameters and the sleep quality parameters to the mobile equipment;

the mobile device displays the sleep quality parameter, the environmental parameter and the physical parameter of the user, and the display process may specifically be:

the mobile equipment displays the sleep quality parameters and the environment parameters and the body parameters corresponding to the sleep quality parameters;

the mobile device displays the sleep stage, and the corresponding environmental parameters and physical parameters within the sleep stage.

The display process may specifically be:

displaying the sleep quality parameters on an interface, and displaying the sleep stages corresponding to the sleep quality parameters, the environmental parameters and the body parameters after a user inputs gestures such as clicking and the like at the sleep quality parameters;

after the user inputs gestures such as clicking and the like at the sleep stage, the environment parameters and the body parameters corresponding to the sleep stage are displayed.

By displaying the sleep quality parameters, the environmental parameters and the body parameters of the user, the user can conveniently check the sleep quality, thereby further facilitating the use of the user.

Optionally, the method may further include:

setting a body parameter safety interval and an environment parameter safety interval, wherein the setting process of the body parameter safety interval can specifically be as follows:

setting a heartbeat safety interval, a respiration safety interval, a physical movement safety interval and a snoring safety interval;

the setting process of the environment parameter safety interval can be as follows:

setting a temperature safety interval, a humidity safety interval, an air quality safety interval, an illumination intensity safety interval and a noise intensity safety interval;

if the environmental parameter is not in the environmental parameter safety interval or the body parameter is not in the body parameter safety interval, displaying warning information to other users to remind the other users to perform corresponding operation so as to ensure the sleep quality of the users, wherein the other users can be family members or guardians of the users; the process of displaying the warning information to other users may be:

sending alert information to mobile devices of other users; or

And playing alert audio to other users.

The alert information or alert audio includes at least a specific environmental parameter within a safe interval of environmental parameters.

Optionally, the system further comprises a control device, wherein the control device comprises a bed body control device, a temperature/humidity control device, an illumination control device and a noise control device;

the mobile device at least displays a first control instruction input interface, the first control instruction comprises a control device selected by a user and control parameters, the first control instruction input interface at least comprises virtual icons used for indicating the plurality of control devices, the other users display a control sub-interface after clicking the virtual icons used for indicating the control devices, the display sub-interface at least comprises a control parameter input interface, the user inputs specific control parameters through modes of inputting numerical values or dragging gestures and the like on the control parameter input interface, and the specific control parameters are as follows:

if the virtual icon indicates a bed body control device, the control parameters are the rising or falling of the upper half part of the bed body and the rising height or the falling height;

if the virtual icon indicates a temperature/humidity control device, the control parameters are temperature/humidity increase or decrease, and increase or decrease values;

if the virtual icon indicates the illumination control device, the control parameters are to reduce the illumination intensity and reduce the numerical value;

if the virtual icon indicates a noise control device, the control parameters are noise reduction and numerical reduction.

After other users trigger a first control instruction on the mobile equipment, the mobile equipment sends the first control instruction to the sleep monitoring device; specifically, after clicking the virtual icon, other users input control parameters on a display sub-interface; the first control instruction at least comprises a control device and a control parameter corresponding to the virtual icon. In addition, the process that the other user triggers the first control instruction on the mobile device may be completed by the other user on a touch display screen of the mobile device.

The sleep monitoring device sends the first control instruction to the corresponding control device, so that the control device executes the first control instruction, and the process is specifically that the sleep monitoring device transmits the first control instruction to the control device corresponding to the virtual icon. Wherein:

the process of the bed body control device executing the first control instruction may specifically be:

the bed body control device sends control parameters to a plurality of driving motors arranged on the bed body, and the driving motors control the upper half part of the bed body to ascend according to the ascending height or descend according to the descending height.

The process of the temperature/humidity control device executing the first control instruction may specifically be:

the temperature/humidity control device sends the control parameters to a corresponding humidifier, and the humidifier carries out humidification according to the rising value; or

The temperature/humidity control device sends the control parameters to the corresponding dehumidifier, and the dehumidification is carried out according to the reduction value;

the temperature/humidity control device sends the control parameters to a corresponding air conditioner, and the air conditioner heats according to the rising value or cools according to the falling value;

the process of executing the first control instruction by the illumination control device may specifically be:

the illumination control device sends the control parameters to the corresponding light controller, and the light controller reduces the illumination intensity according to the reduction value.

The process of executing the first control instruction by the noise control device may specifically be:

and the noise control device sends the control parameters to noise reduction equipment, and the noise reduction equipment performs noise reduction according to the reduction value.

Alternatively to this, the first and second parts may,

if the environmental parameters and the physical parameters indicate that the environment where the user is located affects the sleep of the user, the sleep monitoring device generates a second control instruction;

specifically, the setting process of the comfortable interval of the body parameters and the comfortable interval of the environmental parameters is the same as the setting process of the safe interval of the body parameters and the safe interval of the environmental parameters, and the detailed description is omitted here.

It should be noted that the physical parameter comfort interval includes a physical parameter safety interval, and the environmental parameter comfort interval includes an environmental parameter safety interval.

If the environmental parameter is not in the environmental parameter comfortable interval or the body parameter is not in the body parameter comfortable interval, the sleep monitoring device generates a second control instruction;

and the sleep monitoring device sends the second control instruction to the corresponding control device, so that the control device executes the second control instruction until the environmental parameter and the physical parameter indicate that the environment where the user is located does not influence the sleep of the user.

Specifically, the mode in which the sleep monitoring device sends the second control instruction to the corresponding control device so that the control device executes the second control instruction is the same as the mode in which the sleep monitoring device sends the first control instruction to the corresponding control device so that the control device executes the first control instruction, and details are not repeated here.

Alternatively to this, the first and second parts may,

the mobile equipment displays the sleep history after a user triggers display operation;

the sleep history comprises sleep quality parameters of each sleep of the user, and environment parameters and body parameters corresponding to the sleep quality parameters.

Optionally, the system further includes a cloud server, where the cloud server stores and updates a sleep database in real time, and the sleep database at least includes sleep histories of multiple users;

the sleep monitoring device or the mobile equipment uploads the sleep quality parameters, the environmental parameters and the body parameters to the cloud server;

the cloud server generates new sleep quality parameters according to the sleep database and sends the new sleep quality parameters to the mobile equipment; the process may be:

the server adjusts the weight coefficient corresponding to each sleep stage and calculates the sleep quality parameter according to the adjusted weight coefficient.

The cloud server generates adjustment parameters according to the sleep database, and sends the adjustment parameters to the sleep monitoring device, wherein the adjustment parameters are used for adjusting the first control instruction and the second control instruction.

Alternatively to this, the first and second parts may,

the mobile equipment displays the monitored plurality of beds;

after the user inputs the confirmation instruction, the mobile device connects with at least one bed indicated by the confirmation instruction.

It should be noted that all the parameters described in the above embodiments are included, and in practical applications, any number of the parameters may be included, and the embodiments of the present invention are not limited.

Example two

An embodiment of the present invention provides a sleep quality monitoring method, and as shown in fig. 3, the method includes:

301. and when the user is in a sleep state, acquiring the environmental parameters of the environment where the user is located in real time.

302. And acquiring the physical parameters of the user in real time.

303. And monitoring the sleep quality of the user according to the environmental parameters and the physical parameters, and calculating the sleep quality parameters.

Wherein the environmental parameter comprises one or more of temperature, humidity, air quality, light intensity, and noise intensity; the physical parameters include one or more of heartbeat, breathing parameters, body movement parameters, and snoring time.

Optionally, the acquiring the physical parameters of the user in real time further includes:

acquiring pressure parameters of the bed body in real time;

and calculating the body parameter according to the pressure parameter.

Optionally, calculating the sleep quality parameter includes:

calculating a plurality of sleep stages according to the body parameters;

and calculating the sleep quality parameters according to the plurality of sleep stages and the weight coefficients corresponding to the plurality of sleep stages.

Optionally, the method further includes:

acquiring a first control instruction triggered by a user;

and sending the first control instruction to the corresponding control device so that the control device executes the first control instruction.

Optionally, the method further includes:

if the environmental parameters and the body parameters indicate that the environment where the user is located affects the sleep of the user, generating a second control instruction;

and sending the second control instruction to the corresponding control device so that the control device executes the second control instruction until the environmental parameter and the physical parameter indicate that the environment where the user is located does not affect the sleep of the user.

Optionally, the method further includes:

uploading the sleep quality parameters, the environmental parameters and the body parameters to a cloud server so that the cloud server generates new sleep quality parameters according to a sleep database; sending the new sleep quality parameters to the mobile equipment;

and after the cloud server generates the adjusting parameters according to the sleep database, receiving the adjusting parameters sent by the speech segment server, wherein the adjusting parameters are used for adjusting the first control instruction and the second control instruction.

EXAMPLE III

An embodiment of the present invention provides a sleep quality monitoring device, and as shown in fig. 4, the device includes:

the first acquisition module is used for acquiring the environmental parameters of the environment where the user is located in real time when the user is in a sleep state;

the second acquisition module is used for acquiring the body parameters of the user in real time;

the monitoring module is used for monitoring the sleep quality of the user according to the environmental parameters and the body parameters and calculating the sleep quality parameters;

the environmental parameter comprises one or more of temperature, humidity, air quality, illumination intensity, and noise intensity; the physical parameters include one or more of heartbeat, breathing parameters, body movement parameters, and snoring time.

Optionally, the monitoring module is further specifically configured to:

acquiring pressure parameters of the bed body in real time;

calculating the body parameter according to the pressure parameter.

Optionally, the monitoring module is specifically configured to:

calculating a plurality of sleep stages according to the body parameter;

and calculating the sleep quality parameters according to the sleep stages and the weight coefficients corresponding to the sleep stages.

Optionally, the apparatus further includes a third obtaining module, configured to obtain a first control instruction triggered by a user;

the device also comprises a sending module used for sending the first control instruction to the corresponding control device so as to enable the control device to execute the first control instruction.

Optionally, the monitoring module is further specifically configured to:

if the environmental parameters and the body parameters indicate that the environment where the user is located affects the sleep of the user, generating a second control instruction;

and sending the second control instruction to the corresponding control device so that the control device executes the second control instruction until the environmental parameter and the physical parameter indicate that the environment where the user is located does not affect the sleep of the user.

Optionally, the apparatus:

the sending module is further specifically used for uploading the sleep quality parameters, the environment parameters and the body parameters to the cloud server, so that the cloud server generates new sleep quality parameters according to the sleep database; sending the new sleep quality parameters to the mobile equipment;

the device further comprises a receiving module, which is used for receiving the adjusting parameters sent by the speech segment server after the cloud server generates the adjusting parameters according to the sleep database, wherein the adjusting parameters are used for adjusting the first control instruction and the second control instruction.

Example four

An embodiment of the present invention provides a mobile device, and as shown in fig. 5, the mobile device includes:

the acquisition module is used for acquiring the environmental parameters of the environment where the user is located and the body parameters of the user in real time;

a display module for displaying the environmental parameter and the physical parameter; in practical application, the display module can be a touch display screen;

the environmental parameters include one or more of temperature, humidity, air quality, light intensity, and noise intensity, and the physical parameters include one or more of heartbeat, breathing parameters, body movement parameters, and snoring time.

Optionally, the mobile device further includes a monitoring module, configured to:

acquiring pressure parameters of the bed body in real time;

calculating the body parameter according to the pressure parameter.

Optionally, the monitoring module is further specifically configured to:

calculating a plurality of sleep stages according to the body parameter;

and calculating the sleep quality parameters according to the sleep stages and the weight coefficients corresponding to the sleep stages.

Optionally, the display module is specifically configured to:

displaying the sleep quality parameters and the environment parameters and the body parameters corresponding to the sleep quality parameters;

and displaying the sleep stage and the corresponding environmental parameters and physical parameters in the sleep stage.

Optionally, the display module is specifically configured to:

displaying the sleep quality parameters on an interface, and displaying the sleep stages corresponding to the sleep quality parameters, the environmental parameters and the body parameters after a user inputs gestures such as clicking and the like at the sleep quality parameters;

after the user inputs gestures such as clicking and the like at the sleep stage, the environment parameters and the body parameters corresponding to the sleep stage are displayed.

Optionally, the display module is further specifically configured to:

displaying a first control instruction input interface, wherein the first control instruction comprises a control device selected by a user and control parameters, the first control instruction input interface at least comprises virtual icons used for indicating the plurality of control devices, the other users display a control sub-interface after clicking the virtual icons used for indicating the control devices, the display sub-interface at least comprises a control parameter input interface, the user inputs specific control parameters through numerical value input or dragging gestures and the like on the control parameter input interface, and the specific control parameters are as follows:

if the virtual icon indicates a bed body control device, the control parameters are the rising or falling of the upper half part of the bed body and the rising height or the falling height;

if the virtual icon indicates a temperature/humidity control device, the control parameters are temperature/humidity increase or decrease, and increase or decrease values;

if the virtual icon indicates the illumination control device, the control parameters are to reduce the illumination intensity and reduce the numerical value;

if the virtual icon indicates a noise control device, the control parameters are noise reduction and numerical reduction.

The mobile device also comprises a sending module, which is used for sending a first control instruction to the sleep monitoring device by the mobile device after the first control instruction is triggered by other users on the mobile device;

optionally, the display module is further specifically configured to:

displaying at least a first control instruction input interface, wherein the first control instruction comprises a control device selected by a user and control parameters, the first control instruction input interface at least comprises a virtual icon for indicating the plurality of control devices, the other users display a control sub-interface after clicking the virtual icon for indicating the control device, and the display sub-interface at least comprises a control parameter input interface

Acquiring specific control parameters input by a user through modes such as inputting numerical values or dragging gestures and the like on the control parameter input interface, wherein the specific control parameters are as follows:

if the virtual icon indicates a bed body control device, the control parameters are the rising or falling of the upper half part of the bed body and the rising height or the falling height;

if the virtual icon indicates a temperature/humidity control device, the control parameters are temperature/humidity increase or decrease, and increase or decrease values;

if the virtual icon indicates the illumination control device, the control parameters are to reduce the illumination intensity and reduce the numerical value;

if the virtual icon indicates a noise control device, the control parameters are noise reduction and numerical reduction.

Optionally, the mobile device further includes a sending module, configured to send the first control instruction to the sleep monitoring apparatus after the first control instruction is triggered by the other user on the display module.

Optionally, the display module is further specifically configured to:

after a user triggers display operation, displaying sleep history;

the sleep history comprises sleep quality parameters of each sleep of the user, and environment parameters and body parameters corresponding to the sleep quality parameters.

Optionally, the display module is further configured to:

displaying the monitored plurality of beds;

after the user inputs the confirmation instruction, the mobile device connects with at least one bed indicated by the confirmation instruction.

All the above-mentioned optional technical solutions can be combined arbitrarily to form the optional embodiments of the present invention, and are not described herein again.

It should be noted that: in the sleep quality monitoring system and the sleep quality monitoring device provided in the above embodiments, when the sleep quality monitoring method is executed, only the division of the above functional modules is taken as an example, and in practical applications, the above function distribution may be completed by different functional modules according to needs, that is, the internal structures of the system and the device are divided into different functional modules to complete all or part of the above described functions. In addition, the embodiments of the sleep quality monitoring system, the sleep quality monitoring method and the sleep quality monitoring device provided by the embodiments belong to the same concept, and specific implementation processes thereof are described in the embodiments of the methods for details, which are not described herein again.

It will be understood by those skilled in the art that all or part of the steps for implementing the above embodiments may be implemented by hardware, or may be implemented by a program instructing relevant hardware, where the program may be stored in a computer-readable storage medium, and the above-mentioned storage medium may be a read-only memory, a magnetic disk or an optical disk, etc.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (10)

1. A sleep quality monitoring system is characterized by comprising a sleep monitoring device, an environment monitoring device, a human body monitoring device and a mobile device; wherein:

when a user is in a sleep state, the environment monitoring device acquires the environment parameters of the environment where the user is located in real time;

the human body monitoring device acquires the body parameters of a user in real time;

the sleep monitoring device monitors the sleep quality of the user according to the environmental parameters and the physical parameters and calculates the sleep quality parameters;

the mobile device displaying the sleep quality parameter, the environmental parameter, and the physical parameter;

the environmental parameters include one or more of temperature, humidity, air quality, light intensity, and noise intensity, and the physical parameters include one or more of heartbeat, breathing parameters, body movement parameters, and snoring time.

2. The system of claim 1, wherein the human monitoring device obtaining the physical parameters of the user in real time further comprises:

the human body monitoring device acquires pressure parameters of the bed body in real time;

the sleep monitoring device calculates the physical parameters according to the pressure parameters.

3. The system of claim 1 or 2, wherein the sleep monitoring device calculating sleep quality parameters comprises:

the sleep monitoring device calculates a plurality of sleep stages according to the body parameters;

and the sleep monitoring device calculates the sleep quality parameters according to the sleep stages and the weight coefficients corresponding to the sleep stages.

4. The system of claim 3, wherein the mobile device displaying the sleep quality parameter, the environmental parameter, and the physical parameter comprises:

the mobile equipment displays the sleep quality parameters and the environment parameters and the body parameters corresponding to the sleep quality parameters;

the mobile device displays a sleep stage, and corresponding environmental parameters and physical parameters within the sleep stage.

5. The system of claim 4, further comprising control means, said control means comprising bed control means, temperature/humidity control means, illumination control means and noise control means;

after other users trigger a first control instruction on the mobile equipment, the mobile equipment sends the first control instruction to the sleep monitoring device;

the sleep monitoring device sends a first control instruction to a corresponding control device, so that the control device executes the first control instruction.

6. A sleep quality monitoring method, the method comprising:

when a user is in a sleep state, acquiring environmental parameters of the environment where the user is located and body parameters of the user in real time;

monitoring the sleep quality of the user according to the environmental parameters and the physical parameters, and calculating the sleep quality parameters;

the environmental parameters include one or more of temperature, humidity, air quality, light intensity, and noise intensity, and the physical parameters include one or more of heartbeat, breathing parameters, body movement parameters, and snoring time.

7. The method of claim 6, wherein the obtaining of the physical parameters of the user in real time further comprises:

acquiring pressure parameters of the bed body in real time;

calculating the body parameter according to the pressure parameter.

8. The method of claim 7, wherein the calculating sleep quality parameters comprises:

calculating a plurality of sleep stages according to the body parameter;

and calculating the sleep quality parameters according to the sleep stages and the weight coefficients corresponding to the sleep stages.

9. A sleep quality monitoring apparatus, characterized in that the apparatus comprises:

the first acquisition module is used for acquiring the environmental parameters of the environment where the user is located in real time when the user is in a sleep state;

the second acquisition module is used for acquiring the body parameters of the user in real time;

the monitoring module is used for monitoring the sleep quality of the user according to the environmental parameters and the body parameters and calculating the sleep quality parameters;

the environmental parameters include one or more of temperature, humidity, air quality, light intensity, and noise intensity, and the physical parameters include one or more of heartbeat, breathing parameters, body movement parameters, and snoring time.

10. A mobile device, characterized in that the mobile device comprises:

the acquisition module is used for acquiring the environmental parameters of the environment where the user is located and the body parameters of the user in real time;

a display module for displaying the environmental parameter and the physical parameter;

the environmental parameters include one or more of temperature, humidity, air quality, light intensity, and noise intensity, and the physical parameters include one or more of heartbeat, breathing parameters, body movement parameters, and snoring time.

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