CN115316953A

CN115316953A - Control method of physiological monitoring system and related device

Info

Publication number: CN115316953A
Application number: CN202211039909.9A
Authority: CN
Inventors: 张彧
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-08-29
Filing date: 2022-08-29
Publication date: 2022-11-11

Abstract

The application provides a control method of a physiological monitoring system and a related device, wherein the method comprises the following steps: when a preset event corresponding to the target event type is detected to occur, controlling the task execution module to start an induction mode; acquiring real-time physiological data of the user by using the physiological monitoring module, and calculating to obtain a real-time depth parameter corresponding to the preset state based on the real-time physiological data and a calculation strategy corresponding to the target event type; when detecting that the real-time depth parameter of the user is in a descending trend and the descending amount of a first preset time length is larger than a corresponding first depth threshold value, controlling the task execution module to start a maintenance mode; and when a preset wake-up event is detected to occur, controlling the task execution module to start a wake-up mode, acquiring state evaluation information corresponding to the user and sending the state evaluation information to user equipment. The whole-course control of early induction, middle-period state maintenance and late awakening of the whole sleeping or meditation process is realized.

Description

Control method of physiological monitoring system and related device

Technical Field

The present application relates to the field of physiological monitoring technologies, and in particular, to a control method and a related apparatus for a physiological monitoring system.

Background

Sleep, as a complex physiological process, is an important link for restoration, integration and consolidation of the body. The sleep can help the human body to recover fatigue and relieve emotion, and sufficient sleep is very necessary for normal life of the human body. In modern society, people who suffer from insomnia, somnolence and other symptoms are not in a few, and insufficient sleep often has great influence on the daytime life of people, resulting in other mental and physical problems.

Meditation (meditation) is a form of changing consciousness that enhances self-knowledge and well-being by obtaining a deep tranquil state. Meditation generally provides many benefits to the trainers, including improving a person's mood (e.g., making the person more calm, more focused, more relaxed, more happy, improved mental state, reduced anxiety, etc.), performance (e.g., athletic performance, occupational performance, etc.), addictive help (e.g., help overcome drug abuse, etc.), sleep pattern help (e.g., sleep time, sleep duration, etc.), insight, and/or overall health.

Patent CN113398470a discloses a neural regulation system capable of enhancing sleep, which comprises: the system comprises a microcontroller acquisition unit, a computing terminal, an electroencephalogram acquisition unit, an analog-to-digital conversion circuit, an electrical stimulation unit and an atomizer unit; the microcontroller acquisition unit is used for acquiring sleep electroencephalogram signals of the tested object in real time, and the computing terminal carries out computing according to the sleep electroencephalogram signals acquired in real time to obtain sleep depth information of the tested object; and the computing terminal controls the working states of the electroencephalogram acquisition unit, the analog-to-digital conversion circuit, the electrical stimulation unit and the atomizer unit according to the sleep depth information of the tested object. However, this system only works during deep and light sleep of the user and does not have the functions of inducing sleep and waking up.

Therefore, it is desirable to provide a control method of a physiological monitoring system and a related device to solve the problems of the prior art.

Disclosure of Invention

The invention aims to provide a control method and a related device of a physiological monitoring system, which realize the whole-course closed-loop control of early induction, middle state maintenance and late awakening of the whole sleeping or meditation process.

The purpose of the application is realized by adopting the following technical scheme:

in a first aspect, the present application provides a method of controlling a physiological monitoring system, the physiological monitoring system including a physiological monitoring module and a task execution module, the method comprising:

when detecting that a preset event corresponding to the target event type occurs, controlling the task execution module to start an induction mode so as to enable a user to enter a preset state corresponding to the target event type;

acquiring real-time physiological data of the user by using the physiological monitoring module, and calculating to obtain a real-time depth parameter corresponding to the preset state based on the real-time physiological data and a calculation strategy corresponding to the target event type;

when detecting that the real-time depth parameter of the user is in a descending trend and the descending amount of a first preset time length is greater than a corresponding first depth threshold value, controlling the task execution module to start a maintenance mode so as to maintain the user in the preset state;

when a preset wake-up event is detected to occur, controlling the task execution module to start a wake-up mode so as to wake up the user, acquiring state evaluation information corresponding to the user and sending the state evaluation information to user equipment;

the target event type is a sleep event type or a meditation event type, the preset state corresponding to the sleep event type is a sleep state, and the preset state corresponding to the meditation event type is a meditation state;

the preset event corresponding to the sleep event type comprises the following steps: the contact time of the user and a preset sleep article is not less than a second preset time;

the preset events corresponding to the meditation event types comprise: the contact time of the user and the preset meditation supplies is not less than the second preset time;

the preset wake-up event comprises at least one of the following: the current time is within a preset time range; the concentration of the indoor fuel gas is not less than a first concentration threshold value; the smoke concentration in the room is not less than the second concentration threshold, and the vibration amplitude of the indoor floor is not less than the first preset amplitude.

The technical scheme has the beneficial effects that: when the contact time of the user and a preset sleep article (a mattress or a pillow) is not less than a second preset time, such as 20 minutes or 30 minutes, controlling the task execution module to start an induction mode to hypnotize the user; after a user sleeps, the physiological monitoring module is used for acquiring real-time physiological data of the user, the real-time physiological data are analyzed and processed, a sleep real-time depth parameter is obtained through calculation, when the real-time depth parameter is in a descending trend and the descending amount of a first preset time length is larger than a first depth threshold value, the fact that the sleep of the user is deep and shallow is shown, the sleep depth is quickly descended, the user possibly cannot enter deep sleep autonomously, and the user has a waking trend, at the moment, the task execution module is controlled to start a maintenance mode, sleep aid is conducted on the user, and the user is helped to sleep well again; when a preset wake-up event occurs (1, the current time is in a preset time range, such as 7-8 am; 2, the indoor gas concentration is not less than a first concentration threshold value and a risk of gas leakage; 3, the indoor smoke concentration is not less than a second concentration threshold value and a risk of fire, and 4, the vibration amplitude of an indoor floor is not less than a first preset amplitude value and a risk of earthquake), the task execution module is controlled to start a wake-up mode, a user is awakened in time, the sleep condition of the user is evaluated, and state evaluation information corresponding to the sleep is sent to the user equipment.

Correspondingly, when the contact time of the user with the preset meditation articles (yoga mats or meditation cushion) is not less than a second preset time, such as 20 minutes or 30 minutes, the control task execution module starts an induction mode to induce the user to enter the meditation state; after the meditation starts, the physiological monitoring module is used for acquiring real-time physiological data of the user, analyzing and processing the real-time physiological data, calculating to obtain a real-time depth parameter of the meditation, and when the real-time depth parameter is in a descending trend and the descending amount of a first preset time length is larger than a first depth threshold value, indicating that the meditation of the user is interrupted, controlling the task execution module to start a maintenance mode at the moment, and helping the user to enter the meditation state again; when a preset awakening event occurs, the task execution module is controlled to start the awakening mode to awaken the user in time, the current meditation condition of the user is evaluated, and the state evaluation information corresponding to the current meditation is sent to the user equipment.

The physiological monitoring system can realize the whole-process closed-loop control of early induction, middle-period state maintenance and late awakening of the whole sleeping or meditation process, and timely maintain the user to maintain the sleeping or meditation state when the sleeping or meditation of the user is about to be interrupted by monitoring the real-time physiological data of the user, thereby improving the sleeping or meditation quality of the user.

In some optional embodiments, the physiological monitor module comprises a contact monitor unit and/or a non-contact monitor unit;

the non-contact monitoring unit comprises at least one of the following: BCG electrocardiosignal acquisition unit, millimeter wave radar and microphone; the contact monitoring unit comprises at least one of the following: the device comprises an electroencephalogram signal acquisition unit, a PCG heart sound signal acquisition unit, an ECG electrocardiosignal acquisition unit, an acceleration sensor, a body temperature detection unit, a blood oxygen detection unit, a blood pressure detection unit and a microcirculation detection unit;

the task execution module comprises at least one of the following: the device comprises an audio unit, a massage unit, a breathing lamp unit, an electrical stimulation delivery unit, an aroma release unit, a semiconductor temperature control unit and a home control unit;

the household control unit is used for establishing communication connection with the intelligent household equipment, and the intelligent household equipment comprises at least one of the following components: the intelligent curtain sweeping robot comprises an intelligent curtain, a sweeping robot, an intelligent closestool, a humidity control device and an air purifier.

The technical scheme has the beneficial effects that: the physiological monitoring module of the physiological monitoring system can adopt a contact monitoring unit and/or a non-contact monitoring unit, the non-contact monitoring unit can monitor vital signs in a non-contact manner without disturbing the normal work and rest of a user, and the measurement precision of the contact monitoring unit is higher.

The task execution module can adopt an audio unit to play corresponding audio; the massage unit can be used, for example, an air bag arranged on the head and the neck of the user, and the massage unit is matched with the breathing frequency of the user to do weak fluctuation vibration so as to adjust the posture of the head and the neck of the user; the breathing lamp unit can be adopted, and different colored lights are utilized to realize functions of induction, maintenance, awakening and the like; an electrical stimulation delivery unit, such as a patch electrode, may be used to apply weak electrical stimulation to the user; an aroma release unit can be adopted to release aroma of corresponding types; a semiconductor temperature control unit can be adopted to adjust the local body surface temperature of a user, and the functions of induction, maintenance, awakening and the like are realized; the home control unit can be adopted, and the corresponding intelligent home equipment is controlled to work, so that the functions of induction, maintenance, awakening and the like are realized.

In some optional embodiments, the task execution module comprises an audio unit;

the controlling the task execution module to start an induction mode includes:

playing preset audio corresponding to the induction mode by using the audio unit;

the controlling the task execution module to start a wake-up mode includes:

playing a preset audio frequency corresponding to the awakening mode by using the audio unit;

the preset audio comprises at least one of the following: white noise, human voice, artificially synthesized audio and difference audio obtained after the biphase audio is subjected to difference frequency processing;

the controlling the task execution module to start the maintenance mode includes:

and acquiring audio information of the indoor noise by using the audio unit, and playing noise reduction audio corresponding to the audio information based on the audio information so as to perform reverse noise reduction on the indoor noise.

The technical scheme has the beneficial effects that: the task execution module can comprise an audio unit, and in an induction mode or an awakening mode, the audio unit can play corresponding preset audio so as to induce or awaken the user; in the maintenance mode, the audio unit can acquire the audio information of the indoor noise, and after analysis processing, play the noise reduction audio corresponding to the audio information, so as to perform reverse noise reduction on the indoor noise, help the user to sleep soundly or deeply meditation, and improve the sleep or meditation quality of the user.

In some optional embodiments, the task execution module includes an aromatherapy release unit and a home control unit, and the home control unit establishes a communication connection with the sweeping robot;

the method further comprises the following steps:

receiving indoor layout information sent by the sweeping robot by using the home control unit;

and acquiring recommended placement information corresponding to the aroma release unit based on the indoor layout information, and sending the recommended placement information to the user equipment, wherein the recommended placement information comprises placement quantity and placement positions.

The technical scheme has the beneficial effects that: the task execution module can include an aroma release unit and a home control unit, and is in communication connection with the sweeping robot through the home control unit, so that indoor layout information (house type, area, door opening orientation, furniture placement position and the like) sent by the sweeping robot is received, and recommended placement information corresponding to the aroma release unit is obtained according to the indoor layout information and is sent to the user equipment.

Generally speaking, the effect of champignon has certain relation with the position of putting of champignon, and when the spacious ventilation department was arranged in to the champignon, the champignon can spread other places indoor very fast, and when the airtight corner in room was arranged in to the champignon, the champignon was difficult to spread other places indoor. The corresponding recommended placement information can be automatically acquired according to the indoor layout information, so that the user can make a decision when placing the aroma release unit, and the intelligent degree is high.

In some optional embodiments, the aroma release unit comprises at least one openable and closable aroma box for containing aroma and a heating assembly for heating aroma, the physiological monitoring system further comprises an infrared sensing device comprising at least one of: the infrared camera, the PIR infrared detector and the microwave induction device;

the method further comprises the following steps:

acquiring body temperature and body state information of the user by using the infrared sensing device, wherein the body state information comprises height and body shape;

acquiring a first release strategy corresponding to the aromatherapy release unit in the induction mode, a second release strategy corresponding to the aromatherapy release unit in the maintenance mode and a third release strategy corresponding to the aromatherapy release unit in the awakening mode based on the body temperature, the posture information and the state evaluation information of the user;

wherein, each kind of release tactics in first to third release tactics for instruct aromatherapy box corresponding aromatherapy type, aromatherapy box's the degree of opening and heating sequence, heating time and heating temperature that heating element corresponds.

The technical scheme has the beneficial effects that: the types and the corresponding release amounts of the aromatherapy applied to the users with different postures are different, and the types and the corresponding release amounts of the aromatherapy applied to the users with different sleeping qualities are also different.

According to the method and the device, the body temperature, the body state information and the state evaluation information of the user are considered, and the corresponding release strategies of the aromatherapy release unit in different modes are obtained according to the body temperature, the body state information and the state evaluation information, so that the corresponding types of aromatherapy are adopted, and the release amount of the aromatherapy of the types is controlled. Specifically, the release amount of the fragrance may be controlled by the opening degree (half-open or full-open) of the fragrance box and the heating sequence, heating time and heating temperature corresponding to the heating assembly. Therefore, a customized aroma release strategy can be set according to the body temperature, the posture and the state evaluation information of the user, the effects of induction, maintenance and awakening are further improved, and the sleeping or meditation quality of the user is improved.

In some optional embodiments, the task execution module includes a home control unit, and the home control unit establishes a communication connection with the humidity control device;

the method further comprises the following steps:

acquiring personal information of the user, wherein the personal information comprises at least one of the following: age, gender, skin information, history of rheumatism, history of rhinitis, and history of asthma;

acquiring a recommended humidity range corresponding to the user based on the personal information and the state evaluation information;

and when the indoor humidity is not in the recommended humidity range, the household control unit is utilized to control the humidity control device to work so as to enable the indoor humidity to be in the recommended humidity range.

The technical scheme has the beneficial effects that: personal information such as the user's age, sex, skin information, history of rheumatism, history of rhinitis, history of asthma, etc. are key factors for determining the indoor humidity to which the user is applied.

According to the method and the device, the recommended humidity range corresponding to the user is obtained according to the personal information and the state evaluation information of the user, and when the indoor humidity is not in the recommended humidity range, the household control unit is used for controlling the humidity control device to work so as to enable the indoor humidity to be in the recommended humidity range.

In some optional embodiments, the task execution module comprises an aroma release unit, wherein the aroma release unit comprises a plurality of aroma firmware, a negative ion generator and a heating component for heating the aroma firmware;

the method further comprises the following steps:

receiving an aroma configuration operation of the user by using the user equipment to acquire an aroma configuration strategy of the user, wherein the aroma configuration strategy is used for indicating a heating sequence and a heating temperature corresponding to each aroma firmware;

and controlling the aroma release unit to release aroma according to the aroma release strategy.

The technical scheme has the beneficial effects that: the user can utilize the user equipment to set the aromatherapy configuration strategy according to the preference of the user, and the sleep or meditation quality of the user is improved under the aromatherapy atmosphere blended by the user.

In some optional embodiments, the method further comprises:

receiving a selection operation of the user for a sharing user by utilizing the user equipment;

and responding to the selection operation, and sending the aroma configuration strategy of the user to the terminal equipment corresponding to the sharing user.

The technical scheme has the beneficial effects that: the user can share the aromatherapy configuration strategy set by the user for other people, the aromatherapy configuration strategy set by other people in advance can be called through sharing of the aromatherapy configuration strategy, and the use experience of the user is improved.

In some optional embodiments, the task execution module includes an audio unit and an electrical stimulation delivery unit, and an electrical stimulation waveform adopted by the electrical stimulation delivery unit is a pulse square wave;

the method further comprises the following steps:

the audio frequency played by the audio unit is used as an amplitude modulation wave, and the pulse square wave of the electrical stimulation delivery unit is subjected to composite co-wave processing so as to adjust the neural excitability of the user in the sleeping process or meditation process;

the audio played by the audio unit is a combination of single audio or audio obtained after biphase audio is subjected to difference frequency processing.

The technical scheme has the beneficial effects that: the square wave electric signals of the electric stimulation delivery unit are subjected to complex wave frequency modulation and amplitude modulation processing through the audio effect, and the complex electric signal effect matched with the playing of the difference frequency tone can enhance the low-frequency brain waves generated by the induction of the difference frequency tone in the brain domain of a user, so that a strong brain wave induction gain effect is achieved, the activity of the body responding to the electric signals is improved, and the device is particularly obviously helpful for nerve excitement regulation and microcirculation metabolism in the sleeping or meditation process.

In a second aspect, the present application provides a control device for a physiological monitoring system, the physiological monitoring system including a physiological monitoring module and a task execution module, the device comprising:

the state induction module is used for controlling the task execution module to start an induction mode when a preset event corresponding to the target event type is detected to occur so that a user enters a preset state corresponding to the target event type;

the depth calculation module is used for acquiring real-time physiological data of the user by using the physiological monitoring module, and calculating to obtain a real-time depth parameter corresponding to the preset state based on the real-time physiological data and a calculation strategy corresponding to the target event type;

the state maintenance module is used for controlling the task execution module to start a maintenance mode to maintain the user in the preset state when the real-time depth parameter of the user is detected to be in a descending trend and the descending amount of a first preset duration is larger than a corresponding first depth threshold;

the wake-up evaluation module is used for controlling the task execution module to start a wake-up mode when a preset wake-up event is detected to occur so as to wake up the user, acquire state evaluation information corresponding to the user and send the state evaluation information to user equipment;

the preset events corresponding to the meditation event types comprise: the contact time of the user with the preset meditation supplies is not less than the second preset time;

In a third aspect, the present application provides a physiological monitoring system comprising a physiological monitoring module, a task execution module, and a data processing module, the data processing module comprising a processor configured to implement the steps of:

In some optional embodiments, the physiological monitoring system further comprises the preset sleeping products and/or the preset meditation products;

the preset sleep article comprises any one of the following components: pillows and mattresses;

the preset meditation supplies comprise any one of the following components: yoga mats and meditation mats.

In some optional embodiments, the data processing module and the preset sleeping article are combined into a whole; or, the data processing module and the preset meditation supplies are integrated.

the contactless monitoring unit comprises at least one of: BCG electrocardiosignal acquisition unit, millimeter wave radar and microphone; the contact monitoring unit comprises at least one of the following: the device comprises an electroencephalogram signal acquisition unit, a PCG heart sound signal acquisition unit, an ECG electrocardiosignal acquisition unit, an acceleration sensor, a body temperature detection unit, a blood oxygen detection unit, a blood pressure detection unit and a microcirculation detection unit;

the task execution module comprises at least one of the following: the intelligent electronic incense comprises an audio unit, a massage unit, a breathing lamp unit, an electrical stimulation delivery unit, an aromatherapy release unit, a semiconductor temperature control unit and a home control unit;

the household control unit is used for establishing communication connection with intelligent household equipment, and the intelligent household equipment comprises at least one of the following: the intelligent curtain sweeping robot comprises an intelligent curtain, a sweeping robot, an intelligent closestool, a humidity control device and an air purifier.

In a fourth aspect, the present application provides a computer-readable storage medium storing a computer program which, when executed by a processor, implements the steps of any of the methods described above.

Drawings

The present application is further described below with reference to the drawings and examples.

Fig. 1 is a flowchart illustrating a control method of a physiological monitoring system according to an embodiment of the present disclosure.

Fig. 2 is a block diagram of a control device of a physiological monitoring system according to an embodiment of the present disclosure.

Fig. 3 is a block diagram of a physiological monitoring system according to an embodiment of the present disclosure.

Fig. 4 is a schematic diagram of data processing by using a cloud data management platform according to an embodiment of the present application.

Fig. 5 is a block diagram of another physiological monitoring system according to an embodiment of the present application.

Fig. 6 is a block diagram of a program product according to an embodiment of the present application.

Detailed Description

The present application is further described with reference to the accompanying drawings and the detailed description, and it should be noted that, in the case of no conflict, any combination between the embodiments or technical features described below may form a new embodiment.

Referring to fig. 1, fig. 1 is a schematic flowchart of a control method of a physiological monitoring system according to an embodiment of the present disclosure.

The physiological monitoring system comprises a physiological monitoring module and a task execution module, and the method comprises the following steps:

step S101: when detecting that a preset event corresponding to the target event type occurs, controlling the task execution module to start an induction mode so as to enable a user to enter a preset state corresponding to the target event type;

step S102: acquiring real-time physiological data of the user by using the physiological monitoring module, and calculating to obtain a real-time depth parameter corresponding to the preset state based on the real-time physiological data and a calculation strategy corresponding to the type of the target event;

step S103: when detecting that the real-time depth parameter of the user is in a descending trend and the descending amount of a first preset time length is greater than a corresponding first depth threshold value, controlling the task execution module to start a maintenance mode so as to maintain the user in the preset state;

step S104: when a preset wake-up event is detected to occur, controlling the task execution module to start a wake-up mode so as to wake up the user, acquiring state evaluation information corresponding to the user and sending the state evaluation information to user equipment;

the preset wake-up event comprises at least one of the following: the current time is within a preset time range; the concentration of the fuel gas in the chamber is not less than a first concentration threshold value; the indoor smoke concentration is not less than a second concentration threshold value, and the vibration amplitude of the indoor floor is not less than a first preset amplitude value.

Therefore, when the contact time of the user with the preset sleeping article (mattress or pillow) is not less than a second preset time, such as 20 minutes or 30 minutes, the task execution module is controlled to start the induction mode to hypnotize the user; after a user sleeps, the physiological monitoring module is used for acquiring real-time physiological data of the user, the real-time physiological data are analyzed and processed, a sleep real-time depth parameter is obtained through calculation, when the real-time depth parameter is in a descending trend and the descending amount of a first preset time length is larger than a first depth threshold value, the fact that the sleep of the user is deep and shallow is shown, the sleep depth is quickly descended, the user possibly cannot enter deep sleep autonomously, and the user has a waking trend, at the moment, the task execution module is controlled to start a maintenance mode, sleep aid is conducted on the user, and the user is helped to sleep well again; when a preset wake-up event occurs (1, the current time is in a preset time range, such as 7-8 am; 2, the indoor gas concentration is not less than a first concentration threshold value and has a risk of gas leakage; 3, the indoor smoke concentration is not less than a second concentration threshold value and has a risk of fire, and 4, the vibration amplitude of an indoor floor is not less than a first preset amplitude value and has a risk of earthquake), the task execution module is controlled to start a wake-up mode to wake up the user in time, evaluate the sleep condition of the user, and send state evaluation information corresponding to the sleep to the user equipment.

The physiological monitoring system can realize the whole-course closed-loop control of early induction, middle-period state maintenance and late awakening of the whole sleeping or meditation process, and timely maintains the user when the sleeping or meditation of the user is about to be interrupted by monitoring the real-time physiological data of the user, so as to help the user to maintain the sleeping or meditation state, thereby improving the sleeping or meditation quality of the user.

The physiological monitoring system of the embodiments of the present application may be integrated with an ecological pillow, mattress, yoga mat, meditation cushion, bushel mat, sit-up mat, or table and chair.

The physiological monitoring system can be used for monitoring the sleeping process of a user, plays roles of hypnosis, sleep aiding and awakening, can also be used as a neurophysiological instrument forming an active feedback mechanism, and provides functions of real-time physiological monitoring, cloud algorithm analysis and real-time physiological and physical stimulation for the user in a waking state (performing activities such as yoga, meditation, exercise and the like).

In some embodiments, the physiological monitoring module may further include a visual detection device, and the contact time of the user with the preset sleeping product or the preset meditation product is acquired through image data collected by the visual detection device.

The preset sleeping article is an object related to the sleeping of the user, such as a pillow, a mattress or a reclining chair. The preset meditation articles are for example yoga mats, meditation seat mats, cattail mats or sitting mats.

The embodiment of the application does not limit the first preset time, the second preset time, the preset time range, the first concentration threshold, the second concentration threshold and the first preset amplitude.

The first preset time period is, for example, 1 minute, 5 minutes, or 10 minutes; the second preset time period is, for example, 10 minutes, 20 minutes or 30 minutes; the preset time range is, for example, 7 am to 8 am; the first concentration threshold is, for example, 35ppm, 50ppm or 150ppm; a second concentration threshold is, for example, 100ppm, 150ppm or 250ppm; the first predetermined amplitude is for example 0.05 meter, 0.1 meter or 0.2 meter.

In some embodiments, the real-time physiological data of the user may include, for example, at least one of: heart rate data, respiratory wave data, snore data, electroencephalogram data, body temperature data, body movement data, blood oxygen data, blood pressure data, microcirculation data, electrocardiogram data and sweat data.

The electroencephalogram signal data is used for indicating the wave band, frequency and amplitude of electroencephalogram waves.

Brain waves are electrical signals generated by the activity between neurons. The method is generally applied to clinical judgment of the brain electrical activity and is helpful for diagnosing epilepsy and other diseases. Brain waves have different rhythms and can be divided into different bands.

There are 4 categories of normal brain waves, which are: alpha waves, beta waves, theta waves, and delta waves. Alpha waves appear normally when quiet, awake and closed, beta waves appear when eyes are open and visual objects are seen, when sounds are suddenly heard or when thinking is wrong, theta waves appear when sleepiness, deep anesthesia or hypoxia occurs, delta waves do not generally appear in an awake state and appear when adults sleep, deep anesthesia or hypoxia occurs.

Alpha wave: the frequency is 8-13 Hz, the amplitude is 20-100 mV, belonging to the basic rhythm of normal brain wave. Beta wave: the frequency is 14-30 Hz. θ wave: the frequency is 4-7 Hz and the amplitude is 20-150 mV. Delta wave: frequency 0.5-3Hz per second, amplitude 20 to 200. Mu.m. Delta wave: frequency 0.3Hz per second and amplitude 20 to 200mV.

The sleep of a person is mainly divided into deep sleep and shallow sleep, and the periods of the two sleep stages are alternately repeated. The real-time depth parameter of the sleep state in the embodiment of the application is used for indicating the sleep depth of a user, the sleep depth can be represented by a number (0-100), 100 corresponds to the deepest sleep, 0 corresponds to the full waking, and the sleep depth corresponding to the deep sleep is higher than that of the shallow sleep. The deep sleep may range in value from 60 to 100 and the light sleep may range in value from 10 to 60.

Accordingly, the real-time depth parameter of the meditation status of the embodiment of the present application is used to indicate the meditation depth of the user, which may be represented by a number (0-100), 100 corresponding to the deepest meditation and 0 corresponding to no entry into meditation.

The meditation and the shallow sleep correspond to the brain wave frequency of the user in the range from beta wave to theta wave, and the main frequency is 5-20 HZ. Deep sleep, the corresponding brain wave frequency of the user is in the delta wave range.

In some embodiments, it is possible to determine the posture (sitting posture, lying posture) of the user, whether the eyes are closed and the motion amplitude of the corresponding limbs (hands, legs) in combination with the image data collected by the visual detection device (camera), and verify whether the user enters meditation or sleep state. In the meditation state, the user is not recommended to adopt a lying posture, because most of untrained individuals do meditation in the lying state, and easily fall asleep and lose effects. If the brain wave frequency of the user is in the range from the beta wave to the theta wave and the user adopts a sitting posture, it can be determined that the user is not asleep but is in a meditation state.

By detecting the brain wave frequency of the user, synchronously testing the respiratory frequency and the respiratory stability of the user and testing the Heart Rate Variability (HRV) data of the user, the sympathetic negative sympathetic nerve balance degree index of the user is calculated, and the sleep depth or meditation depth of the user is further obtained.

In some embodiments, the calculation strategy corresponding to the target event type may adopt a deep learning algorithm, a machine learning algorithm or a reinforcement learning algorithm.

In a specific application, the calculation process of the real-time depth parameter corresponding to the preset state is as follows:

inputting the real-time physiological data of the user into a depth calculation model to obtain a real-time depth parameter corresponding to the user;

wherein the training process of the depth calculation model comprises the following steps:

acquiring a first training set, wherein the first training set comprises a plurality of training data, and each training data comprises real-time physiological data of a sample object and marking data of a real-time depth parameter of the sample object;

for each training data in the first training set, performing the following:

inputting the real-time depth parameters of the sample objects in the training data into a preset first deep learning model to obtain prediction data of the real-time depth parameters of the sample objects;

updating the model parameters of the first deep learning model based on the prediction data and the annotation data of the real-time depth parameters of the sample object;

detecting whether a preset training end condition is met; if yes, taking the trained first deep learning model as the deep calculation model; and if not, continuing to train the first deep learning model by utilizing the next training data.

The embodiment of the application does not limit the acquisition mode of the labeling data of the real-time depth parameters, for example, a manual labeling mode can be adopted, and an automatic labeling or semi-automatic labeling mode can also be adopted.

The training process of the depth calculation model is not limited in the embodiments of the present application, and for example, the above-mentioned supervised learning training mode may be adopted, or a semi-supervised learning training mode may be adopted, or an unsupervised learning training mode may be adopted.

The preset training ending condition is not limited in the embodiment of the present application, and may be, for example, that the training frequency reaches a preset frequency (the preset frequency is, for example, 1 time, 3 times, 10 times, 100 times, 1000 times, 10000 times, and the like), or training data in a training set completes one or more times of training, or a total loss value obtained by this training is not greater than a preset loss value.

In other embodiments, the calculation strategy corresponding to the target event type may adopt a preset depth calculation formula, and the obtained real-time physiological data of the user is input into the preset depth calculation formula, so as to calculate a real-time depth parameter corresponding to the preset state.

The preset depth calculation formula is not limited in the present application, and is, for example, a univariate polynomial or a multivariate polynomial, and is, for example, a linear polynomial or a nonlinear polynomial. And calculating a dependent variable (a real-time depth parameter corresponding to the preset state) by using the preset depth calculation formula and the independent variable (one or more of heart rate data, respiratory wave data, snore data, electroencephalogram data, body temperature data, body movement data, blood oxygen data, blood pressure data, microcirculation data, electrocardio data and sweat data of the user, generally multiple types). In the calculation process based on the calculation formula, the consumed calculation resources are less, the consumed calculation time is short, and the calculation efficiency is higher.

In some embodiments, the induction pattern of the sleep event type and the induction pattern of the meditation event type may employ similar, but not identical, means, and accordingly, the maintenance pattern may also employ similar, but not identical, means. The sleep event type wake-up pattern and the meditation event type wake-up pattern may employ the same means.

In a specific application, in the sleep event type induction mode, a breathing lamp (green light) and aromatherapy can be adopted to induce a user to sleep; under the induction mode of the meditation event type, a breathing lamp (blue light) light is combined with the aromatherapy to induce the user to enter the meditation, meanwhile, more negative ions are output in the aromatherapy, and the aromatherapy adopts pungent odor type, such as mint, eucalyptus essential oil and the like, so that the user is prevented from sleeping.

Under the maintenance mode of the sleep event type, the semiconductor temperature control unit can use the auxiliary temperature slightly higher than the body temperature, is matched with massage assistance, and performs synchronous scaling by pneumatically inflating and deflating the leather bag and matching with the breathing rhythm frequency to massage the head and the neck of a user lying on the pillow; in the maintenance mode of the meditation event type, the semiconductor temperature control unit may use an auxiliary temperature lower than the body temperature, for example, 24 to 26 ℃.

In some embodiments, the obtaining the state evaluation information corresponding to the user includes:

inputting the real-time physiological data of the user into a state evaluation model to obtain state evaluation information corresponding to the user;

wherein the training process of the state evaluation model comprises:

acquiring a second training set, wherein the second training set comprises a plurality of second training data, and each second training data comprises real-time physiological data of a sample object and marking data of state evaluation information of the sample object;

for each second training data in the second training set, performing the following:

inputting the state evaluation information of the sample object in the second training data into a preset second deep learning model to obtain prediction data of the state evaluation information of the sample object;

updating model parameters of the second deep learning model based on the prediction data and the labeling data of the state evaluation information of the sample object;

detecting whether a preset training end condition is met; if yes, taking the trained second deep learning model as the state evaluation model; and if not, continuing to train the second deep learning model by utilizing the next second training data.

Therefore, through design, a proper amount of neuron calculation nodes and a multilayer operation hierarchical structure are established, a proper input layer and a proper output layer are selected, a preset second deep learning model can be obtained, through learning and tuning of the preset second deep learning model, a function relation from input to output is established, although the function relation between input and output cannot be found 100%, the function relation can be close to a real association relation as much as possible, the state evaluation model obtained through training can be used for obtaining the state evaluation information corresponding to the user based on real-time physiological data of the user, and the accuracy and the reliability of calculation results are high.

The method for acquiring the labeled data of the state evaluation information is not limited in the embodiment of the application, and for example, a manual labeling mode may be adopted, and an automatic labeling or semi-automatic labeling mode may also be adopted.

The training process of the state evaluation model is not limited in the embodiments of the present application, and may adopt, for example, the above-described training mode of supervised learning, or may adopt the training mode of semi-supervised learning, or may adopt the training mode of unsupervised learning.

The state evaluation information of the sleep state may be a sleep evaluation report, and the state evaluation information of the meditation state may be a meditation evaluation report. The content of the state evaluation information may be, for example: state quality scoring: 70 (percent, higher score, more excellent state), state improvement recommendations: soaking hot water and drinking hot milk every night.

The embodiment of the application does not limit user equipment, and the user equipment is, for example, an intelligent terminal device such as a mobile phone, a tablet computer, a notebook computer, a desktop computer, an intelligent wearable device and the like, or can be a workstation or a console.

In a specific application, after waking up the user every morning, the state quality score of the current day can be automatically acquired, and the state quality score is compared with the state quality score of the past (yesterday, last week or last month) to obtain the change trend of the state quality score, so that the corresponding state improvement suggestion is updated.

Therefore, the physiological monitoring module of the physiological monitoring system can adopt a contact type monitoring unit and/or a non-contact type monitoring unit, the non-contact type monitoring unit can monitor vital signs in a non-contact manner without disturbing the normal work and rest of a user, and the measurement precision of the contact type monitoring unit is higher.

In some embodiments, the physiological monitor module may further include a static pressure sensor, a PIR infrared scanning motion detection unit.

BCG (Ballistocardiography) is a mechanical feature of the heart that indicates subtle changes in the pressure on the surface of the body caused by the beating of the heart, arterial blood flow. The BCG signal acquisition unit consists of a BCG sensor and a signal conditioning circuit. The BCG sensor can be arranged in a weight scale, a pillow, a mattress, a yoga mat and a table and chair, and vital sign monitoring is carried out under the condition of non-contact and no disturbance to normal work and rest of a user.

By arranging the BCG signal acquisition unit, the physiological data such as the heart rate, the respiratory waves and the like of the user can be monitored in real time without wearing; by arranging the static pressure sensor, the dynamic acceleration sensor and the millimeter wave radar, the position and the posture of the body part (head and neck) can be analyzed in real time; the microphone can be used for detecting the snore of the user to obtain the snore data of the user, and can also be used for detecting indoor noise to obtain audio information of the indoor noise.

The audio unit can comprise a microphone and a loudspeaker, can output pure music, hypnotic music, white noise and natural fitting sound, and can realize induction or awakening effect through two paths of combined audio (difference frequency audio signals played by two players). The audio unit can also capture main characteristic audio in indoor noise, play corresponding noise reduction audio after analysis and calculation, actively and reversely reduce noise, realize effective silencing effect in a local range, and play a role in assisting sleep or meditation.

The massage unit can set up in the mattress, including inflating and deflating mechanism and gasbag, inflate near the gasbag of deflating mechanism to user's head and neck through the multichannel gas circuit of adjustment inflation to carry out attitude control to user's head and neck, simultaneously, the dynamic fit user respiratory frequency does weak fluctuation and vibrates, realizes the induction.

The breathing lamp is a lamp with the brightness which rises in an exponential curve firstly and then falls in an exponential curve, and the breathing frequency of a user can be guided through the brightness change of the breathing lamp.

The electric stimulation delivery unit can be matched with the difference frequency audio signal of the audio unit to apply weak electric stimulation to the user, and the weak electric stimulation acts on corresponding organs of the human body to achieve an induction effect.

The champignon release unit can cooperate anion generator to realize that local environment is gaseous to be optimized, adopts the mode of heating to do the volume of volatilizing and the control of the chronogenesis of volatilizing to the champignon consumptive material of multiple different grade type, realizes the effect of the whole smell odor type of combination.

The semiconductor cold and hot unit can be used to regulate the body surface temperature of the user's local part, generally speaking, the temperature is slightly higher to fall asleep or meditation, and the temperature is slightly lower to wake up easily.

the controlling the task execution module to start an induction mode includes:

the controlling the task execution module to start a wake-up mode includes:

the preset audio comprises at least one of the following: white noise, human voice, artificially synthesized audio and biphase audio are subjected to difference frequency processing to obtain difference frequency sound;

Therefore, the task execution module can comprise an audio unit, and in an induction mode or an awakening mode, the audio unit can play corresponding preset audio so as to induce or awaken the user; in the maintenance mode, the audio unit can acquire the audio information of the indoor noise, and after analysis processing, play the noise reduction audio corresponding to the audio information, so as to perform reverse noise reduction on the indoor noise, help the user to sleep soundly or deeply meditation, and improve the sleep or meditation quality of the user.

In some optional embodiments, the task execution module comprises an aroma release unit and a home control unit, and the home control unit is in communication connection with the sweeping robot;

the method further comprises the following steps:

From this, task execution module can include champignon release unit and house the control unit, establishes communication connection through house the control unit and the robot of sweeping the floor to receive the indoor layout information (house type, area, gate orientation, furniture locating position etc.) that the robot of sweeping the floor sent, according to indoor layout information, obtain the recommendation that champignon release unit corresponds and put the information and send to user equipment.

The recommended placement information is, for example: please place 2 fragrance release units at the head of the bed close to the doorway and place 1 fragrance release unit at the windowsill. "

the method further comprises the following steps:

acquiring body temperature and posture information of the user by using the infrared sensing device, wherein the posture information comprises height and body type;

wherein, each of the first to third release strategies is used for indicating the type of aroma corresponding to the aroma box, the opening degree of the aroma box, and the heating sequence, the heating time and the heating temperature corresponding to the heating component.

Therefore, users with different body states have different applicable aromatherapy types and corresponding release amounts, and users with different sleep qualities have different applicable aromatherapy types and corresponding release amounts.

According to the embodiment of the application, the body temperature, the body state information and the state evaluation information of the user are considered, and the corresponding release strategies of the aromatherapy release unit in different modes are obtained according to the body temperature, the body state information and the state evaluation information, so that the corresponding types of aromatherapy are adopted, and the release amount of the aromatherapy of the types is controlled. Specifically, the release amount of the fragrance may be controlled by the opening degree (half-open or full-open) of the fragrance box and the heating sequence, heating time and heating temperature corresponding to the heating assembly. Therefore, a customized aroma release strategy can be set according to the body temperature, the posture and the state evaluation information of the user, the effects of induction, maintenance and awakening are further improved, and the sleeping or meditation quality of the user is improved.

In some embodiments, a user may be scanned and sensed using a PIR infrared detector and a microwave sensing device to obtain the body temperature, body posture and body posture information of the user, which may include height and body shape.

PIR (Passive Infrared Detector) Infrared detectors are also known as Passive Infrared detectors or body sensors.

The passive infrared detector is provided with two key elements, one is a pyroelectric infrared sensor (PIR), the PIR can convert infrared signal change with the wavelength of 8-12um into an electric signal and can have an inhibiting effect on a white light signal in the nature, therefore, in an alert area of the passive infrared detector, when no human body moves, the pyroelectric infrared sensor senses only background temperature, and when the human body enters the alert area, the pyroelectric infrared sensor senses a difference signal of the human body temperature and the background temperature through a Fresnel lens, therefore, the basic concept of infrared detection of the infrared detector is to sense the difference of the temperatures of a moving object and a background object. Another device is a fresnel lens, which has two forms, i.e., refractive and reflective. The fresnel lens acts on two: firstly, the focusing effect, be about to the infrared signal refraction (reflection) of releasing heat on the PIR, the second effect is with dividing into a plurality of bright district and dark space in the alert district, makes the removal object that gets into the alert district can produce the infrared signal of releasing heat of change on the PIR with the form of temperature variation, and the PIR just can produce the signal of telecommunication of change like this.

A microwave induction device, also called a microwave radar, is an instrument manufactured by using the doppler principle of electromagnetic waves. The reaction speed is fast, the sensitivity is higher, the induction area is wide, the safety and stability are high, and the influence of temperature, air flow, dust and smoke is avoided.

Any wave has a reflective characteristic, when a wave of a certain frequency hits the obstacle, a part of the wave is reflected back, if the obstacle is stationary, the wavelength of the reflected wave is constant, if the obstacle moves towards the wave source, the wavelength of the reflected wave is shorter than that of the wave source, if the obstacle moves away from the wave source, the wavelength of the reflected wave is longer than that of the wave source, and a change in wavelength means a change in frequency. The microwave induction is that moving objects approach or move away from the object just through the change of reflected waves.

The champignon box is provided with the box body and with box body sliding connection's upper cover, slides on the box body through the upper cover and realizes totally sealed effect of opening completely. The heating member is, for example, an electric heating sheet.

In a specific application, three types of fragrance release units, namely lavender, chamomile and vetiver, are placed in a user bedroom.

The first release strategy is: the opening degree of the lavender fragrance box is fully opened, the opening degree of the chamomile fragrance box is fully opened, the opening degree of the vetiver fragrance box is half opened, the heating temperature of heating components of the lavender fragrance box and the chamomile fragrance box is 140 ℃ for example, and the heating temperature of the heating component of the vetiver fragrance box is 120 ℃ for example;

the second release strategy is: the opening degree of the lavender fragrance box is half-open, the opening degree of the chamomile fragrance box is half-open, the opening degree of the vetiver fragrance box is half-open, and the heating temperature of heating components of the lavender fragrance box, the chamomile fragrance box and the chamomile fragrance box is 120 ℃ for example;

the third release strategy is: the opening degree of the lavender fragrance box, the chamomile fragrance box and the chamomile fragrance box is fully closed, and the heating components of the lavender fragrance box, the chamomile fragrance box and the chamomile fragrance box stop heating.

the method further comprises the following steps:

Thus, personal information such as the user's age, sex, skin information, history of rheumatism, rhinitis, and asthma is a key factor in determining the indoor humidity to which the user is applied.

The skin information is used for indicating the dryness degree of the skin surface, the rheumatism history is used for indicating whether the user suffers from rheumatism and the severity of the rheumatism, the rhinitis history is used for indicating whether the user suffers from rhinitis and the severity of the rhinitis, and the asthma history is used for indicating whether the user suffers from asthma and the severity of the asthma.

The recommended humidity range is, for example, 30% to 60%.

The humidity control device may include a dehumidifier and a humidifier, and the dehumidifier may be controlled to operate to lower the humidity in the room and the humidifier may be controlled to operate to raise the humidity in the room.

In some optional embodiments, the task execution module includes a home control unit, and the home control unit establishes a communication connection with the intelligent toilet;

the method further comprises the following steps:

when the fact that the real-time depth parameter of the sleep state of the user is in a descending trend and the descending amount of the first preset time length is larger than a first depth threshold value is detected, the intelligent closestool is controlled to heat the closestool cushion through the household control;

and when the fact that the real-time depth parameter of the sleep state of the user is larger than a second depth threshold value is detected, the intelligent closestool is controlled by the household control to stop heating the closestool cushion.

Therefore, when the real-time depth parameter of the sleep state of the user is in a descending trend and the descending amount of the first preset time length is larger than the first depth threshold value, the fact that the sleep of the user is deep and shallow is shown, the sleep depth is quickly reduced, the user possibly cannot enter deep sleep autonomously, the user has a waking trend, and the intelligent closestool is controlled to preheat the closestool cushion by utilizing the home control before the user wakes up, so that the user can use the warm closestool cushion when going to the toilet at night; when the real-time depth parameter of the sleep state of the user is detected to be larger than the second depth threshold value, the fact that the user is asleep is indicated, the user cannot go to the toilet in a short time, the intelligent closestool is controlled to stop heating the closestool cushion through the household control, and energy consumption is saved at night.

The intelligent closestool in the prior art can heat the closestool seat cushion as long as the intelligent closestool is in a power-on state, and keeps a certain temperature all the day, the embodiment of the application improves the situation, the closestool seat cushion of the intelligent closestool is continuously heated in daytime (non-sleep time period), when the time is up to night, when the real-time depth parameter of the sleep state of a user is greater than a second depth threshold value (entering the sleep state), the closestool seat cushion is stopped to be heated, when the user is about to wake up at night, the closestool seat cushion is preheated in advance until the user returns to the bed to sleep again, and the closestool seat cushion is stopped to be heated.

The embodiments of the present application do not limit the first depth threshold, such as 30, 50, or 60, and the second depth threshold, such as 20, 30, or 40.

When the user is going to wake up, the toilet seat cushion is controlled to be preheated in advance, and when the user goes to the toilet and goes back to bed to sleep again after the toilet is finished, the task execution module is controlled to start the induction mode to help the user fall asleep again.

the method further comprises the following steps:

Therefore, the user can set the aroma configuration strategy according to the preference of the user by utilizing the user equipment, and the sleep or meditation quality of the user is improved under the aroma atmosphere prepared by the user.

In some embodiments, the aromatherapy firmware can be, for example, an aromatherapy candle or an aromatherapy capsule, the volatilization amount is negligible at normal temperature, and the volatilization speed is accelerated along with the increase of the heating temperature after heating.

In some optional embodiments, the method further comprises:

Therefore, the user can share the aromatherapy configuration strategy set by the user with other people, the aromatherapy configuration strategy set by other people in advance can be called through sharing of the aromatherapy configuration strategy, and the use experience of the user is improved.

In a concrete application, the fragrance release unit comprises 4 fragrance candles, the types of the 4 fragrance candles are 'grass', 'soil', 'lotus' and 'mint', the corresponding numbers are 1, 2, 3 and 4 respectively, the fragrance of different fragrance candles can form a composite fragrance atmosphere through combination, such as 'desert', 'forest' and 'sea', the user A can set a fragrance configuration strategy according to the number of the corresponding fragrance candle, such as '1423', namely, firstly, the fragrance candle 1 is heated, then, the fragrance candle 4 is heated, then, the fragrance candle 2 is added, and finally, the fragrance candle 4 is added, when the user A feels that the sleep aiding effect of the fragrance configuration strategy set by the user A is not wrong, the fragrance configuration strategy '1423' can be shared with a friend user B, and the user B can call the fragrance configuration strategy '1423' of the user A by using user equipment (a mobile phone, a tablet computer, intelligent wearable equipment and the like) of the user A in a one key mode.

the method further comprises the following steps:

the audio played by the audio unit is used as an amplitude modulation wave, and the pulse square wave of the electrical stimulation delivery unit is subjected to composite co-wave processing so as to adjust the neural excitability of the sleep process or meditation process of the user;

the audio played by the audio unit is a combination of single audio or audio obtained by performing difference frequency processing on biphase audio.

Therefore, the square wave electric signals of the electric stimulation delivery unit are subjected to complex wave frequency modulation and amplitude modulation processing through the audio effect, and the complex electric signal effect matched with the playing of the difference frequency tone can enhance the low-frequency brain waves generated by the induction of the difference frequency tone in the brain domain of a user, so that a strong brain wave induction gain effect is achieved, the activity of the body responding to the electric signals is improved, and the device is particularly obviously helpful for nerve excitement regulation and microcirculation metabolism in the sleeping or meditation process.

Conventional audio electrotherapy is a medium frequency electrotherapy method. By adopting equal-amplitude sine intermediate frequency electrotherapy, has the functions of diminishing inflammation, reducing swelling, easing pain, promoting the recovery of vascular nerve function and the like. It can be used for treating various clinical diseases, especially intestinal adhesion, large-area keloid, lateral femoral cutaneous neuritis, herpes zoster, lymphangitis, thrombophlebitis, etc.

The pulse square wave can be used as a basic wave, and pulse direct current or pulse alternating current can be formed by frequency modulation. Meanwhile, the pulse square wave can be subjected to composite co-wave processing by matching with an audio signal.

The embodiment of the application improves the conventional audio electrotherapy, adopts pulse square waves as basic waveforms, and the frequency of the square waves is in the range of 1kHz to 20 KHz; the audio signal is used as an amplitude modulation wave, and composite co-wave processing is carried out on the pulse square wave; the audio signals are not only single audio signal composite, but also can be subjected to difference frequency processing through biphase audio signals, the adopted audio signals are the same sound effect, only are signals with different sound wave frequencies, the frequency difference is kept within the range of 5-200 Hz, and the method is mainly used for brain electric field co-wave induction.

Through the compound induction of the audio frequency electric signals, the activity of the body responding to the electric signals is improved, and the compound induction of the audio frequency electric signals is particularly helpful for adjusting the nerve excitation and the microcirculation metabolism.

Referring to fig. 2, fig. 2 is a block diagram of a control device of a physiological monitoring system according to an embodiment of the present disclosure.

The physiological monitoring system comprises a physiological monitoring module and a task execution module, the specific implementation mode of the control device is consistent with the implementation mode and the achieved technical effect recorded in the method embodiment, and part of the content is not described again.

The device comprises:

the state induction module 101 is configured to, when detecting that a preset event corresponding to a target event type occurs, control the task execution module to start an induction mode, so that a user enters a preset state corresponding to the target event type;

the depth calculation module 102 is configured to acquire real-time physiological data of the user by using the physiological monitoring module, and calculate a real-time depth parameter corresponding to the preset state based on the real-time physiological data and a calculation policy corresponding to the target event type;

the state maintenance module 103 is configured to control the task execution module to start a maintenance mode to maintain the user in the preset state when it is detected that the real-time depth parameter of the user is in a descending trend and a descending amount of a first preset duration is greater than a corresponding first depth threshold;

the wake-up evaluation module 104 is configured to, when a preset wake-up event is detected to occur, control the task execution module to start a wake-up mode so as to wake up the user, obtain state evaluation information corresponding to the user, and send the state evaluation information to user equipment;

Referring to fig. 3, fig. 3 is a block diagram of a physiological monitoring system 100 according to an embodiment of the present disclosure.

The physiological monitoring system 100 comprises a physiological monitoring module 10, a task execution module 20 and a data processing module 30, the data processing module 30 comprising a processor configured to implement the steps of:

when detecting that a preset event corresponding to the target event type occurs, controlling the task execution module 20 to start an induction mode, so that the user enters a preset state corresponding to the target event type;

acquiring real-time physiological data of the user by using the physiological monitoring module 10, and calculating to obtain a real-time depth parameter corresponding to the preset state based on the real-time physiological data and a calculation strategy corresponding to the target event type;

when detecting that the real-time depth parameter of the user is in a descending trend and the descending amount of the real-time depth parameter in a first preset time length is greater than a corresponding first depth threshold value, controlling the task execution module 20 to start a maintenance mode so as to maintain the user in the preset state;

when detecting that a preset wake-up event occurs, controlling the task execution module 20 to start a wake-up mode to wake up the user, and acquiring state evaluation information corresponding to the user and sending the state evaluation information to user equipment;

In some embodiments, the physiological monitoring system 100 can constitute an environment for inducing whole sleep, the physiological monitoring module 10 and the task execution module 20 are adopted (sound, light, smell, and corresponding electromagnetic heat and other means are combined), the whole system builds extensible physiological data acquisition, local Apps control and cloud computing, multiple physical therapy modes (as combined physical therapy modules) which can be selected and combined by the task execution module 20 can jointly constitute a closed loop of a system solution, early-stage induced sleep of sleep is realized, middle-stage monitoring and sleep aid are realized, and a later-stage comfortable awakening full function is realized.

1. The active hypnosis induction stage is used for playing white noise, background noise, difference frequency sound and the like, is matched with warm light breathing lamp induction under a certain wavelength, is matched with pillow leather bag stretching massage of the breathing frequency of a user, is combined with hypnosis and fragrance smell induction and is also combined with semiconductor cold and hot temperature regulation module induction.

2. The process helps sleeping, and the sleep condition of the user is judged by monitoring the snore (microphone and sensor) of the user in the sleep and the moving frequency (monitored by pressure and acceleration sensors) of the user in the sleep, and the multi-channel split leather bag is adopted to stretch and retract, so that the posture of the head and the neck in the sleep is adjusted, and the breathing gas circuit of the human body is optimized. Deep sleep is done, and background sounds (soothing music, white noise and the like) are played.

3. Awakening after sleeping, awakening blue-green, white light, refreshing aroma smell, a cold and hot temperature adjusting module and the like through gradual natural awakening sound or user self-selection sound effect, and helping the user to awaken naturally.

Referring to fig. 4 and 5, fig. 4 is a schematic diagram of data processing by using a cloud data management platform according to an embodiment of the present disclosure, and fig. 5 is a block diagram of another physiological monitoring system according to an embodiment of the present disclosure.

In some embodiments, the physiological monitoring system 100 can also host a cloud data management platform, an algorithm platform, and a local data acquisition management workstation (including a HIS system). The HIS System (Hospital Information System) is an Information System that comprehensively manages the flows of people, logistics, and financial resources of a Hospital and its various departments by using modern means such as computer software and hardware technology and network communication technology, collects, stores, processes, extracts, transmits, and summarizes data generated at various stages of medical activities, and processes the data to form various Information, thereby providing comprehensive automatic management and various services for the overall operation of the Hospital.

In some embodiments, the physiological monitoring system 100 can also include a lower computer and a cloud.

The lower computer is used for collecting data and is connected to a mobile phone or other mobile internet terminals through the Bluetooth of the lower computer, and the internet terminals are provided with Apps and embedded basic algorithms to analyze and process real-time physiological data of users, obtain real-time reports and monitoring results and provide primary early warning capability.

The real-time physiological data are uploaded to a cloud end (a cloud server), the cloud end establishes a corresponding user physiological record database, performs deep analysis, and can download the data to a data service terminal (a mobile phone and the like) linked with a lower computer, so that a more comprehensive data analysis report is provided, for example, a trend analysis report in a long time period (one month or one year), and meanwhile, the trend analysis report can be externally connected to an HIS or other medical service information platform to be connected with other pre-diagnosis and expert online services.

In some optional embodiments, the physiological monitoring system 100 further comprises the preset sleeping products and/or the preset meditation products;

the preset sleeping article comprises any one of the following components: pillows and mattresses;

In some optional embodiments, the data processing module 30 and the predetermined sleeping article are integrated; alternatively, the data processing module 30 and the preset meditation supplies are integrated.

In some alternative embodiments, the physiological monitor module 10 includes a contact monitor unit and/or a non-contact monitor unit;

the task execution module 20 includes at least one of: the device comprises an audio unit, a massage unit, a breathing lamp unit, an electrical stimulation delivery unit, an aroma release unit, a semiconductor temperature control unit and a home control unit;

The embodiment of the present application further provides a computer-readable storage medium, where the computer-readable storage medium is used for storing a computer program, and when the computer program is executed, the steps of any one of the methods are implemented, and a specific implementation manner of the method is consistent with the implementation manner and the achieved technical effect described in the foregoing method embodiment, and some details are not repeated.

Referring to fig. 6, fig. 6 shows a schematic structural diagram of a program product provided in an embodiment of the present application.

The program product is for implementing any of the methods described above. The program product may employ a portable compact disc read only memory (CD-ROM) and include program code, and may be run on a terminal device, such as a personal computer. However, the program product 300 of the present invention is not so limited, and in this application, a readable storage medium may be any tangible medium that can contain, or store a program for use by or in connection with an instruction execution system, apparatus, or device. Program product 300 may employ any combination of one or more readable media. The readable medium may be a readable signal medium or a readable storage medium. A readable storage medium may be, for example, but not limited to, an electronic, magnetic, optical, electromagnetic, infrared, or semiconductor system, apparatus, or device, or any combination of the foregoing. More specific examples (a non-exhaustive list) of the readable storage medium include: an electrical connection having one or more wires, a portable disk, a hard disk, a Random Access Memory (RAM), a read-only memory (ROM), an erasable programmable read-only memory (EPROM or flash memory), an optical fiber, a portable compact disc read-only memory (CD-ROM), an optical storage device, a magnetic storage device, or any suitable combination of the foregoing.

A computer readable storage medium may include a propagated data signal with readable program code embodied therein, for example, in baseband or as part of a carrier wave. Such a propagated data signal may take many forms, including, but not limited to, electro-magnetic, optical, or any suitable combination thereof. A readable storage medium may also be any readable medium that can communicate, propagate, or transport a program for use by or in connection with an instruction execution system, apparatus, or device. Program code embodied on a readable storage medium may be transmitted using any appropriate medium, including but not limited to wireless, wireline, optical fiber cable, RF, etc., or any suitable combination of the foregoing. Program code for carrying out operations for aspects of the present invention may be written in any combination of one or more programming languages, including an object oriented programming language such as Java, C + + or the like and conventional procedural programming languages, such as the C language or similar programming languages. The program code may execute entirely on the user's computing device, partly on the user's device, as a stand-alone software package, partly on the user's computing device and partly on a remote computing device, or entirely on the remote computing device or server. In situations involving remote computing devices, the remote computing devices may be connected to the user computing device through any kind of network, including a Local Area Network (LAN) or a Wide Area Network (WAN), or may be connected to external computing devices (e.g., through the internet using an internet service provider).

While the present application is described in terms of various aspects, including exemplary embodiments, the principles of the invention should not be limited to the disclosed embodiments, but are also intended to cover various modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

Claims

1. A method of controlling a physiological monitoring system, the physiological monitoring system including a physiological monitoring module and a task execution module, the method comprising:

the preset wake-up event comprises at least one of the following: the current time is within a preset time range; the concentration of the indoor fuel gas is not less than a first concentration threshold value; the indoor smoke concentration is not less than a second concentration threshold value, and the vibration amplitude of the indoor floor is not less than a first preset amplitude value.

2. The method of claim 1, wherein the physiological monitor module comprises a contact monitor unit and/or a non-contact monitor unit;

3. The method of controlling a physiological monitoring system according to claim 2 wherein the task performance module includes an audio unit;

the controlling the task execution module to start an induction mode includes:

the controlling the task execution module to start a wake-up mode includes:

playing preset audio corresponding to the awakening mode by using the audio unit;

4. The control method of the physiological monitoring system according to claim 2, wherein the task execution module comprises an aromatherapy release unit and a home control unit, and the home control unit is in communication connection with the sweeping robot;

the method further comprises the following steps:

5. The method of controlling a physiological monitoring system according to claim 4, wherein said aroma release unit comprises at least one openable and closable aroma box for containing aroma and a heating assembly for heating aroma, said physiological monitoring system further comprising an infrared sensing device comprising at least one of: the infrared camera, the PIR infrared detector and the microwave induction device;

the method further comprises the following steps:

6. The control method of the physiological monitoring system according to claim 2, wherein the task execution module comprises a home control unit, and the home control unit establishes a communication connection with the humidity control device;

the method further comprises the following steps:

7. The control method of the physiological monitoring system according to claim 2, wherein the task execution module includes an aromatherapy release unit, the aromatherapy release unit includes a plurality of aromatherapy firmware, a negative ion generator, and a heating component for heating the aromatherapy firmware;

the method further comprises the following steps:

8. The method of controlling the physiological monitoring system of claim 7 further comprising:

9. The control method of the physiological monitoring system according to claim 2, wherein the task execution module includes an audio unit and an electrical stimulation delivery unit, and an electrical stimulation waveform adopted by the electrical stimulation delivery unit is a pulse square wave;

the method further comprises the following steps:

10. A control apparatus for a physiological monitoring system, the physiological monitoring system including a physiological monitoring module and a task execution module, the apparatus comprising:

11. A physiological monitoring system comprising a physiological monitoring module, a task execution module, and a data processing module, the data processing module comprising a processor configured to implement the steps of:

when the real-time depth parameters of the user are detected to be in a descending trend and the descending amount of a first preset duration is larger than a corresponding first depth threshold value, controlling the task execution module to start a maintenance mode so as to maintain the user in the preset state;

12. The physiological monitoring system according to claim 11, further comprising the preset sleeping products and/or the preset meditation products;

13. The physiological monitoring system of claim 12 wherein said data processing module is integrated with said predetermined sleep article; or, the data processing module and the preset meditation supplies are integrated.

14. The physiological monitoring system of claim 11 wherein the physiological monitoring module includes a contact monitoring unit and/or a non-contact monitoring unit;

15. A computer-readable storage medium, in which a computer program is stored which, when being executed by a processor, carries out the steps of the method according to any one of claims 1 to 9.